nc manufacturing infrastructure
TRANSCRIPT
NC Manufacturing Infrastructure
User's Guide
Version 5 Release 16
Special NoticesCATIA® is a registered trademark of Dassault Systèmes.
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NC Manufacturing Infrastructure
Overview
Conventions
What's New?
Getting Started
Manage Workbenches Manage Documents Set Up and Part Positioning Design Changes
User Tasks
Part Operations and Manufacturing Programs Part Operation Machine Editor Manufacturing Program Process Table Auto-Sequence Operations in a Program Generate Transition Paths in a Program Create a Process Template
Machining Processes Create a Machining Process Organize Machining Processes in Catalogs Apply a Machining Process Apply Machining Processes Automatically
Auxiliary Operations Tool Change Machine Rotation Machining Axis Change PP Instruction COPY Operator TRACUT Operator Copy Transformation Instruction Opposite Hand Machining
Machining Entities Edit a Tool in an Operation Edit a Tool in the Resource List Edit a Tool Assembly in an Operation Edit a Tool Assembly in the Resource List Create a Tool Catalog from the Resource List Replace Tools in the Resource List Manage Tools in the Resource List and TDM
Use Tooling Resources from TDM Specify Tool Compensation Define the Tool Axis Create and Use a Machining Pattern Manufacturing View Define Macros on a Milling Operation Define Macros on an Axial Machining Operation Define Macros on a Turning Operation Build and Use a Macros Catalog Status Management User Parameters in PP Instructions
Verification and Simulation Tool Path Replay Photo Mode for Material Removal Simulation Video Mode for Material Removal Simulation Using Tool Path Data Video Mode for Material Removal Simulation Using NC Code Check Machine Accessibility at Tool Axis Definition Generic Machine Accessibility (CATProduct) VNC Machine Accessibility (*.dev device)
Program Output Interactive Generation of NC Output Batch Generation of APT Source Code Batch Generation of Clfile Code Batch Generation of NC Code Batch Generation of a CATProduct MfgBatch Utility for Generating NC Data Batch Queue Management NC Documentation Generation Import APT Source
Workbench Description
Menu Bar Toolbars
Manufacturing Program Toolbars Auxiliary Operations Toolbar Transition Path Management Toolbar NC Output Management Toolbar Machining Features Toolbar Auxiliary Commands Toolbar Edge and Face Selection Toolbars Machining Process Toolbars Manufacturing Program Optimization Toolbar Machine Management Toolbar Measure Toolbar
Specification Tree
Customizing
Machining General Resources Operation
Output Program Photo/Video
Build a Tools Catalog Access External Tool Catalogs PP Word Syntaxes NC Documentation Workbenches and Tool Bars
Reference Information
Machining Resources Machine Tool Resources Tool Assembly Resources Tool and Insert Holder Resources Insert Resources
NC Macros Transition Path Management PP Tables and PP Word Syntaxes Feeds and Speeds NC Data Options APT Formats
Generated APT Syntaxes NURBS Formats in APT Output APT Output Modifications Syntaxes Interpreted by APT Import
Clfile Formats NC Data Import to Support Legacy Data Feature Attributes for Tool Queries, Checks and Formula PLM Integration
CATProcess Documents Support in SmartTeam CATProcess Documents Support in Process Engineer
Methodology
Machining Processes Knowledgeware in Machining Processes CATProduct and CATProcess Document Management Copy/Paste and External Referencing of NC Manufacturing Data Design Changes and Associativity Mechanisms Product-Setup Link in Manufacturing Hub Context NC Synchronization in Manufacturing Hub Context Lock/Unlock Mechanisms Part Operation and Set Up Documents Material Removal Simulation Opposite Hand Machining User Features for Machining Properties of a Machining Operation
Glossary
Index
OverviewWelcome to the NC Manufacturing Infrastructure User's Guide. This guide is intended for users who need to become quickly familiar with the NC Manufacturing Infrastructure Version 5.
This overview provides the following information:
● NC Manufacturing Infrastructure in a Nutshell
● Before Reading this Guide
● Getting the Most Out of this Guide
● Accessing Sample Documents
● Conventions Used in this Guide.
NC Manufacturing Infrastructure in a NutshellNC Manufacturing Solutions enable you to define and manage NC programs dedicated to machining parts designed in 3D wireframe or solids geometry using 2.5 to 5-axis machining techniques.
It offers an easy-to-use and easy-to-learn graphic interface that makes it suitable for shop floor-oriented use. Moreover, its leading edge technologies together with a tight integration with Version 5 design methodologies and DELMIA's digital manufacturing environment, fully satisfy the requirements of office programming. NC Manufacturing is a unique solution that reconciliates office and shop floor activities.
An integrated Post Processor engine allows the product to cover the whole manufacturing process from tool trajectory (APT source or Clfile) to NC data.
NC Manufacturing Infrastructure offers the following main functions:
● Common platform for 2.5 to 5-axis axis machining capabilities, which include mill, drill and turn operations
● Management of tools and tool catalogs
● Flexible management of the manufacturing program with intuitive and easy-to-learn user interface based on graphic dialog boxes
● Tight interaction between tool path definition, verification and generation
● Knowledgeware customization facilities through f(x) formula and Edit search facilities
● Seamless NC data generation thanks to an integrated Post Processor Access solution
● Automatic shop floor documentation in HTML format
● High associative level of the manufacturing program ensures productive design change management thanks to the integration with CATIA V5 modeling capabilities
● Based on the Process Product Resources (PPR) model, the manufacturing applications are integrated with Digital Process for Manufacturing (DPM).
Before Reading this Guide
Before reading this guide, you should be familiar with basic Version 5 concepts such as document windows, standard and view toolbars. Therefore, we recommend that you read the Infrastructure User's Guide that describes generic capabilities common to all Version 5 products. It also describes the general layout of V5 and the interoperability between workbenches.
Getting the Most Out of this GuideTo get the most out of this guide, we suggest that you start reading and performing the step-by-step scenarios in the User Tasks section, which gives relevant information about the common functionalities of NC Manufacturing Solutions. The Reference section provides useful complementary information.
The Workbench Description section, which describes the commands that are common to NC Manufacturing Solutions, and the Customizing section, which explains how to customize your Machining environment, and the Methodology section, which provides useful information about recommended work methods, will also certainly prove useful.
Accessing Sample DocumentsTo perform the scenarios, you will be using sample documents contained in the doc/online/mfgug_C2/samples or doc/online/mfgug_D2/samples folder. For more information about this, refer to Accessing Sample Documents in the Infrastructure User's Guide.
ConventionsCertain conventions are used in CATIA, ENOVIA & DELMIA documentation to help you recognize and understand important concepts and specifications.
Graphic Conventions
The three categories of graphic conventions used are as follows:
● Graphic conventions structuring the tasks
● Graphic conventions indicating the configuration required
● Graphic conventions used in the table of contents
Graphic Conventions Structuring the Tasks
Graphic conventions structuring the tasks are denoted as follows:
This icon... Identifies...
estimated time to accomplish a task
a target of a task
the prerequisites
the start of the scenario
a tip
a warning
information
basic concepts
methodology
reference information
information regarding settings, customization, etc.
the end of a task
functionalities that are new or enhanced with this release
allows you to switch back to the full-window viewing mode
Graphic Conventions Indicating the Configuration Required
Graphic conventions indicating the configuration required are denoted as follows:
This icon... Indicates functions that are...
specific to the P1 configuration
specific to the P2 configuration
specific to the P3 configuration
Graphic Conventions Used in the Table of Contents
Graphic conventions used in the table of contents are denoted as follows:
This icon... Gives access to...
Site Map
Split View Mode
What's New?
Overview
Getting Started
Basic Tasks
User Tasks or Advanced Tasks
Interoperability
Workbench Description
Customizing
Administration Tasks
Reference
Methodology
Frequently Asked Questions
Glossary
Index
Text Conventions
The following text conventions are used:
● The titles of CATIA, ENOVIA and DELMIA documents appear in this manner throughout the text.
● File -> New identifies the commands to be used.
● Enhancements are identified by a blue-colored background on the text.
How to Use the Mouse
The use of the mouse differs according to the type of action you need to perform.
Use thismouse button... Whenever you read...
● Select (menus, commands, geometry in graphics area, ...)
● Click (icons, dialog box buttons, tabs, selection of a location in the document window, ...)
● Double-click
● Shift-click
● Ctrl-click
● Check (check boxes)
● Drag
● Drag and drop (icons onto objects, objects onto objects)
● Drag
● Move
● Right-click (to select contextual menu)
What's New?
Enhanced Functionalities
New Product-Setup Link in Manufacturing Hub ContextPart Operations will be always associated to product instances. This harmonization enables to associate or replace a Product whatever the methodology used. In addition, the link to product instances enables the following:
❍ Making the link between Setup and Product persistent after save in IPD.
❍ Managing several machining phases of the same Product in a unique Process, each phase corresponding to one instance of the Product. User can manage different setups or constraints for a same Product.
❍ Making design changes local to the Setup and not necessarily global to the Process.
NC Synchronization in Manufacturing Hub ContextThis enhancement will enable the user to delete at least one Part belonging to the NC Setup Assembly or replace the current version of it by a new version. User has the possibility to manually or automatically synchronize the Process with the new version of the Part.
Support Machines with external axes in MPS and provide lock axis capabilityNC Machine Tool Simulation must be installed. See NC Machine Tool Simulation User's Guide for more information.
Support simulation based on ISO codeNC Machine Tool Simulation must be installed. See NC Machine Tool Simulation User's Guide for more information.
Getting StartedBefore getting into the detailed instructions for using Machining products, this section deals with some important concepts about your working environment.
Manage WorkbenchesManage Documents
Set Up and Part PositioningDesign Changes
Manage Workbenches
This section explains what happens when you open a design part and enter a Machining workbench (Prismatic Machining, for example), and how to switch to and from Machining and Design workbenches.
1. Select File > Open then select the desired CATPart document.
2. Select Machining > Prismatic Machining from the Start menu. The Prismatic Machining workbench appears. The part is displayed in the Setup Editor window along with the PPR specification tree.
The CATPart is automatically associated to the Part Operation and an instance of the part is created in the Product List.
3. Select Manufacturing Program.1 in the tree to make it the current entity.
To insert program entities such as machining operations, tools and auxiliary commands you can either: ● make the program current before clicking the insert program entity command
● click the insert program entity command then make the program current.
4. Double-click the Part entity in the tree to switch to a Mechanical Design workbench (such as Part Design or Wireframe and Surface Design depending on your configuration).
5. Double-click a Machining entity in the tree to switch back to the Machining workbench.
If the NC Machine Tool Simulation product is installed, you can switch from a Machining workbench to the NC Machine Tool Simulation workbench as follows:
● By means of a contextual command: right-click the Manufacturing Program or a machining operation in the tree and select Simulate Machine using Tool Path or Simulate Machine using NC Code.
● By means of a toolbar command: select Starts Machine Simulation in the NC Output Management
toolbar.
Please note the following points:
● When you switch to the NC Machine Tool Simulation workbench you can use tools and tool assemblies directly from the resource list for clash checking.
● If a machining operation's tool path is manually modified in the NC Machine Tool Simulation workbench (for example, by jogging the machine), the operation's status changes from Computed to Modified. During a tool path replay, any zones where points have been modified, inserted or removed are displayed as dashed lines.
Refer to the NC Machine Tool Simulation User's Guide for more information.
Manage Documents
This section shows how you can create a new CATPart document in the Product List dedicated to storing complementary geometry.
1. Select the Create a CATPart to store geometry checkbox in Tools > Options > Machining > General.
2. Open your design part and start the Machining workbench as described in the previous section.
Two CATPart documents are present in the Product list: the design part and a CATPart for storing Complementary Geometry in your Part Operation.
This enables you to create geometry which may be necessary for your manufacturing model without modifying the design part. This geometry can be created by switching to a Design workbench as mentioned in the previous section.
Being in a Machining workbench means being able to work in a multi-model environment.
The CATProcess references one or more CATPart and/or CATProduct documents.
You can have links between a CATProcess document and:
● CATPart and/or CATProduct documents (design part, associated geometry, stock, and so on)
● APT, Clfile or NC Code output (if associated using the CATMfgBatch utility)
● Packed tool path files stored on disk (if these tlp files were stored)
● CATPart documents relative to tool/tool assembly representation (if associated to a tool or assembly).
The links between documents can be visualized using the Edit > Links command.
Set Up and Part Positioning
This task shows you how to manage part set up.
You must create a CATProduct entity for each part set up you want to represent.
1. Enter a Machining workbench and double-click the Part Operation.1 entity in the tree.
The Part Operation dialog box appears.
2. Click Product to associate a product to the part operation.
3. Select a CATProduct from the Associated Product list, then click Open to display the corresponding part set up.
4. Click OK in the Part Operation dialog box.
5. Click Part Operation to create the Part Operation.2 entity in the tree.
6. Associate another product to Part Operation.2 in the same way as described above.
7. Click OK in the Part Operation dialog box.
To display the desired part set up, just select the corresponding Part Operation in the tree.
Design Changes
This task shows you how to manage your design changes.
For more information on this topic please refer to Design Changes and Associativity Mechanisms.
1. Create a Profile Contouring operation and replay the tool path.
All the tabs of the Profile Contouring dialog box display a green status.
The Profile Contouring entity is displayed in the tree with no related symbol.
2. Switch to the window showing the CATPart design and modify the part geometry.
3. Switch to the Setup Editor window.
The Profile Contouring entity is now displayed in the tree with an Update symbol (or mask) .
4. Double-click the Profile Contouring entity to edit the operation.
The Geometry tab has an orange status, indicating that the geometry has been modified.
5. Select the Analyze contextual command in the sensitive icon zone of the dialog box.
The Geometry Analyzer dialog box appears showing the status of the referenced geometry.
6. Click the Smart icon to highlight the geometry that was used in the operation before the part was modified.
Geometry highlighted in this way helps you to analyze the design change.
7. Click OK to return to the Profile Contouring dialog box.
8. Replay the tool path to make sure that the machining is consistent with the design change.
You should check that there is no longer an Update symbol beside the Profile Contouring entity in the graph.
Analyze and Remove Geometry
You can analyze and, if needed, remove the geometry specified on a Machining Operation.
In the Machining Operation editor, three icon commands appear at the bottom of the Strategy, Geometry, and Macros tab pages. They provide capability to:
● preview the geometry specified by means of the current tab page
● preview the smart geometry by means of the current tab page
● remove the geometry specified by means of the current tab page.
To analyze one geometry aggregate (guiding element, for example), right-click the corresponding sensitive area of the Machining Operation editor and the Geometry Analyser dialog box appears.
In the Geometry Analyser dialog box, the same three icon commands as above are available. They provide capability to:
● preview the geometry corresponding to the rows selected in the dialog box
● preview the smart geometry corresponding to the rows selected in the dialog box
● remove the geometry corresponding to the rows selected in the dialog box. You can easily
remove unwanted or unused geometry (short lines that were automatically inserted in guides, for example).
The first column lists the geometry names (Guides 1-1, Guides 1-2, and so on when several geometric elements are defined on Guides 1, or Bottom when only one geometric element is defined on the Bottom).
The second column lists the names of the referenced geometries: Edge, Face, and so on.
The third column lists the geometry status: Up to date, Not up to date, or Not found.
The columns of the Geometry Analyser dialog box can be sorted by clicking on the column header. Multi-selection is possible .
User TasksThe user tasks you will perform using Machining products involve creating, editing and managing part operations, manufacturing programs and other entities of the manufacturing process.
Part Operations and Manufacturing ProgramsMachining ProcessesAuxiliary OperationsMachining Entities
Verification and SimulationProgram Output
Part Operations and Manufacturing ProgramsThis section deals with creating and managing the following major entities of the Machining environment.
Create and Edit a Part Operation: Select Part Operation then specify the entities to be referenced by the part operation: machine tool, machining axis system, tool change point, part set up, and so on.
Create and Edit a Manufacturing Program: Select Manufacturing Program to add a program to the current part operation then insert all necessary program entities: machining operations, tool changes, PP instructions, and so on.
Process Table: Right-click a Manufacturing Program or a Part Operation selection in the PPR tree, and select Process Table to activate a view in which the various operations of the program or PO are presented in a table format.
Auto-sequence Operations in a Program (P2 functionality): Verify the administrator's settings for sequencing rules and priorities. If you are authorized, you can adjust these settings before applying the Auto-sequencing to your program.
Generate Transition Paths in a Program (P2 functionality): Automatically creates all necessary transition paths and machine rotations in the program according to the kinematics of the machine tool assigned to the Part Operation and user-defined transition planes.
Create a Process Template
Part Operation
This task shows you how to create a part operation in the manufacturing process.
When you open a Machining workbench on a CATPart or CATProduct document, the manufacturing document is initialized with a part operation.
1. Select Part Operation .
A new part operation is initialized in the manufacturing process and a Part Operation entity is added to the tree.
To access the parameters of the part operation, double-click the Part Operation entity in the tree or use the contextual menu. The Part Operation dialog box appears.
Name and Comment
2. If needed, enter a new part operation name and assign comments to the part operation.
Machine
3. Click Machine to assign a machine tool to the part operation.
Please refer to Machine Editor for more information.
Reference Machining Axis System
4. Click Reference Machining Axis System to assign a reference machining axis system to
the part operation. The Machining Axis System dialog box appears.
This is similar to the procedure described in Insert a Machining Axis Change.
Output coordinates will be expressed in the reference machining axis system. If a local machining axis system is inserted in the program, coordinates will be expressed in the local axis system.
Product or Part
5. Click Product or Part to associate an existing product (CATProduct) or part (CATPart) to
the part operation. This procedure is described in Set Up and Part Positioning.
Note: In a Manufacturing Hub context, Product Instance Selection replaces Product
or Part in the Part Operation editor.
Geometry tab
6. Select the Geometry tab to associate the following geometry to the part operation:
● Design part: Just click Design Part then select the desired geometry. This is useful if
you want to do material removal simulations later.
● Stock: Just click Stock then select the desired geometry. This is useful for certain
surface machining operations and also for material removal simulations.
● Fixtures: Just click Fixtures then select the desired geometry. This is useful if you
want to do material removal simulations later.
● Safety plane: Just click Safety Plane then select the desired plane that will be used
as a global safety plane for the part operation.
● Traverse box planes: Just click Traverse Box Planes then select 5 planes that
define a global traverse box for the part operation.
● Transition planes: Just click Transition Planes then select the desired planes that
will be used as a global transition planes for the part operation.
● Rotary planes: Just click Rotary Planes then select the desired planes that will be
used as a global rotary planes for the part operation.
The generation of transition paths in the program takes into account:
● Traverse box planes and Transition planes to create linear tool path motions
● Rotary planes to create machine rotations:❍ between machining operations
❍ between tool change and machining operation.
The Safety plane is not taken into account for the generation of transition paths.
When the geometry is selected, the identifiers are displayed in the corresponding fields and tool tips (see example below).
Position tab
7. Select the Position tab to specify the following reference positions on the part operation:
● Tool change point
For machines created using the NC Machine Tool Builder product, the tool change point is read from the machine and cannot be modified in the Part Operation. For Multi-slide lathe machines, the tool change point is read from the machine and cannot be modified in the Part Operation.
● Table center setup
● Home pointYou can select the checkbox to use the Home point defined on the machine.
Simulation tab
8. Select the Simulation tab to specify the stock tessellation tolerance. In previous releases, this tolerance was fixed at 0.2mm.
Option tab
9. Select the Option tab to specify the following option:
● Automatic stock selection for turning operations. This enables automatically updating the input stock for operations in a manufacturing program for turning (that is, turning operations and axial operations along the spindle axis). A lathe machine must be selected in this case.
10. Click OK to create the part operation. The tree is updated with the new entity.
Machine EditorThis task shows you how to use the Machine Editor to assign a machine to a Part Operation.
1.Click Machine in the Part Operation dialog box. The Machine Editor dialog box appears.
2. Select the desired machine tool in one of the following ways.
● By clicking a Default machine icon :
● 3-axis machine
● 3-axis machine with rotary table
● 5-axis machine
● horizontal lathe machine
● vertical lathe machine
● multi-slide lathe machine (refer to Multi-Slide Lathe Machining User's Guide for more information about this machine).
● By clicking then selecting a Generic machine
A generic machine is a CATProduct representation that was created using the NC Machine Tool Builder product. Available machine types are:
● 3-axis machine with no rotary axis
● 3-axis machine with 1 rotary axis on table
● 3-axis machine with 2 rotary axes on table
● 3-axis machine with 1 rotary axis on table and 1 rotary axis on head
● 3-axis machine with 1 rotary axis on head
● 3-axis machine with 2 rotary axes on head
● 5-axis continuous machine (without generation of ROTABL or ROTHEAD instruction).
Each machine contains all the necessary NC parameters and kinematic definition data for the Part Operation.A number of sample generic machines are provided at this location:..\OS\startup\Manufacturing\Samples\NCMachineToollib\DEVICES.
● By clicking to select a machine directly from the PPR tree.
The characteristics of the selected machine are displayed and the following parameters can be edited to correspond to your actual machine tool.
Machine Name and Comment
If needed, enter a new name for the machine and assign comments to it.
Numerical Control Tab
You can also specify the following.
● Controller Emulator and Post Processor: Note that a Controller Emulator/Post Processor vendor must be set in the Tools > Options > Machining > Output tab.
● Post Processor words table: Sample PP word tables are delivered with the product in the ..\startup\manufacturing\PPTables folder.
● NC data type: Defines whether APT, Clfile or NC code is the preferred output type.
● NC data format: Defines whether tool point coordinates (x,y,z) or tool point coordinates and tool axis components (x,y,z,i,j,k) is the preferred output format.
● Home point strategy: Defines whether a GOTO or FROM instruction is to be generated in the output APT source for the Home Point.
● Rapid feedrate: This is used to compute accurate machining time (in tool path replay and NC documentation, for example) and can be used to replace the RAPID instruction in the output APT source.
● Axial/radial movement: Defines whether axial/radial transitions are to be used between the end of one operation and the start of the next operation.
Tooling Tab
Displays tooling parameters including the Tools catalog. Spindle Tab
Displays spindle parameters. Turret Tab
Displays turret parameters for vertical and multi-axis lathe machines. Rotary Table or Rotary Data Tab
For 3-axis machine with rotary table, rotary table parameters are displayed.
For machines with more than one rotary axis on head or table, parameters are displayed for each axis.
The rotary axis name can be set on a generic machine in NC Machine Tool Builder. This allows a better coverage of machines for automatic generation of transition paths (for example, when the rotary axis of the machine is not parallel to the X, Y or Z axis of the absolute axis system).
Compensation
Cutter compensation options are displayed for 3D contact compensation.
Note: Use of the 3D contact compensation capability is restricted as from V5R14 SP4. Contact and Tip & Contact compensation modes can no longer be globally applied to all operations supporting this 3D Cutter compensation.
The check box can only be selected when the No option is selected (see example below), otherwise a warning message is issued.
If the Contact or the Tip & Contact option is selected and the checkbox is not selected (see example below), a Compensation tab appears in the Strategy page of the machining operation editor.
In this case, 3D contact compensation can be managed at machining operation level.Please note that some machining operations propose cutter compensation modes other than 3D contact (2D radial profile, for example).
The table below specifies the modes available for each machining operation that supports compensation. NC Output
For generic machines created using the NC Machine Tool Builder product, the Machine Editor centralizes all NC output options. If such a machine is defined on the Part Operation, all options for NC data generation can be read automatically from the machine definition.
Please note that generic machines (CATProducts) adhere to the Instance/Reference mechanism described in CATProduct and CATProcess Document Management. A generic machine is added to the ResourceList in flexible mode. This means that any modification to the machine in the CATProcess is valid only for that instance of the machine in that CATProcess: the modification is not propagated to the reference (that is, the CATProduct file).
3.Click OK to validate any modified machine parameters and assign the machine to the Part Operation. The Part Operation dialog box is displayed again.
The Resource List is updated with selected machine. Example of a selected Default machine:
Example of a selected Generic machine:
In this case the machine appears directly in the 3D viewer. It is possible to use the Hide/Show contextual command on the machine nodes in the tree to hide all or part of the machine.
Machining Operations Supporting Cutter Compensation
The following table specifies the Compensation output modes available for each operation. Cutter compensation instructions are generated on the NC data output depending on the selected mode as follows:
● 2D radial tipCompensation is computed in a plane normal to the tool axis, and activated with regard to a cutter side (left or right). The radius that is compensated is the cutter radius.Output is the tool tip point (XT).
● 2D radial profileCompensation is computed in a plane normal to the tool axis, and activated with regard to a cutter side (left or right). The radius that is compensated is the cutter radius.Output is the tool profile point (XP).
● 3D radialCompensation is computed along a 3D vector (PQR), normal to the drive surface, in contact with the flank of the tool. The radius that is compensated is the cutter radius.Output is the tool tip point (XT) and PQR vector. Tool axis vector (IJK) is output in multi-axis.
● 3D contactCompensation is computed along a 3D vector (XN), normal to the part surface, in contact with the end of the tool. The radius that is compensated is the corner radius.Output is the contact point (XC) and XN vector. The tool tip point (XT) may also be given if this choice is set on the machine. Tool axis vector (IJK) is output in multi-axis.
Machining Operation 2D radial tip 2D radial profile 3D radial 3D contact
Profile Contouring (between planes) Yes Yes - -
Pocketing Yes Yes - -Circular Milling Yes Yes - -Sweeping - - - YesContour Driven - - - -Spiral Milling - - - -Z Level - - - YesSweep Roughing - - - -Isoparametric Machining - - - Yes
Multi Axis Sweeping - - - YesMulti Axis Curve (Contact) - - - Yes
Multi Axis Contour Driven - - - Yes
Multi Axis Helix Machining - - - Yes
Multi Axis Flank Contouring - Yes Yes -
Manufacturing Program
A number of capabilities are available for managing manufacturing programs.
● Create
● Edit
● Insert entities
● Reorder using Copy / Paste or Drag / Drop
● Delete.
This task shows you how you can edit a manufacturing program.
When you open a Machining workbench on a CATPart document, the manufacturing document is initialized with a manufacturing program.
When you select Manufacturing Program , a new program is initialized in the part operation and
a new Manufacturing Program entity is added to the tree.
Open the HoleMakingOperations.CATPart document, then select a Machining workbench from the Start menu.
1.
Double-click the Manufacturing Program in the specification tree. The Manufacturing Program dialog box appears.
Rename the program and add a comment as shown below then click OK.
2.
Create a drilling operation on the circular pattern of 6 holes.
3.
Create a spot drilling operation on the circular pattern of 6 holes and the rectangular pattern of 10 holes.
4.
Create another drilling operation on the rectangular pattern of 10 holes.
The three operations are assigned the same default tool.
5.
Edit the spot drilling operation to assign a spot drill tool.
Each operation now has an associated tool change.
6.
Right-click the first Drilling operation and select Cut.
7.
Right-click the second Drilling operation and select Paste.
The program is reordered. You can delete unnecessary tool changes to give the following result.
The same result could have been obtained by using the drag and drop capability.
Program Simulation and Replay
The program can be simulated using NC code data or tool path data. The program can be replayed using tool path data.
For this, the Manufacturing Program dialog box includes the following commands:
● Start Machine Simulation : if the NC Machine Tool Simulation product is installed, you
can switch from the Machining workbench to the NC Machine Tool Simulation workbench by clicking this icon.
● Start Video Simulation : allows direct access to Video material removal simulation for
the program.
● Tool Path Replay : allows direct access to tool path replay for the program.
To choose simulation using NC code data, select the NC Code Based Simulation check box. Otherwise, simulation is done using tool path data.
When simulation is done using NC code data, the following commands are available:
● Display Origin Management Panel : displays the Workpiece Origin Management panel,
which controls G53, G54, G55, G56, G57, G58, G59 NC code data.
● Display Cutter Compensation Panel : displays the Cutter Compensation panel, which
controls G41 and G42 (radial compensation) and G43 (2- and 3-axis length compensation) NC codes.
Please refer to the NC Machine Tool Simulation User's Guide for a description of these capabilities.
Process Table
This task shows you how use the Process Table. This table gives a tabular view of the Process, or a given Part Operation or a given Manufacturing Program. It provides an alternative view to the PPR tree.
From a Manufacturing Program or a Part Operation selection in the PPR tree, the Process Table command activates a Process View in which the various operations of the Manufacturing Program or Part Operation are presented in a table format.If no pre-selection is performed, the Process Table shows the detail of all the Part Operations of the Process document.
1. Open the Processfinal.CATProcess document. The Setup Editor window appears showing the PPR tree as follows. The part is displayed held in place by fixtures, with the stock hidden.
2. Right-click the Part Operation in the tree, then select Process Table . The Process Table appears presenting the
Part Operation, the Manufacturing Program and the various operations in a table format.
3. Right-click in the Process Table to access a contextual menu as follows:
These commands allow you to customize the table and manage the program.
Column Filter
Select the columns that you want to include in the Process Table. You can use the Cntl and Shift keys to make multiple selections.
Other columns in process table can be used to visualize tool information: nominal diameter, corner radius/nose radius, cutting length, body diameter, and non-cutting diameter.
Column Order
You can change the order of the filtered columns in the Process Table by selecting a line and moving it in the list by means of the Up / Down buttons.
Select by String
You can use the pop-up that appears to search for any character string in the Process Table (pocket, for example). All lines containing the searched string will be selected.
Compared with the Process Table shown above, the following table has:● re-ordered columns
● all pocketing operations selected.This was done by using the Select by String command with string set to 'pocket'.
Selected Objects
When you right-click selected line or lines in the Process Table, you access a menu of contextual commands. For example, in the case of the selected pocketing operations above, the following menu is displayed:
A number of parameters (such as Machining feedrate, Spindle speed, Machining tolerance, Retract feedrate and
Approach feedrate) can be edited contextually. Note that these edit commands are displayed in the contextual menu only if the column filtering makes them visible in the Process Table.
How to Edit a Parameter of a Single Machining Operation
● Select a machining operation in the table.
● Right-click on the selected line.
● Choose the parameter to be edited (machining feedrate, for example).
● Edit the parameters in the pop-up that appears.
How to Globally Edit a Parameter of Several Machining Operations
● Select the desired machining operations in the table (for example, all the pocketing operations).
● Right-click on a selected line.
● Choose the parameter to be edited (machining feedrate, for example).
● Edit the parameters in the pop-up that appears.
In this example, the machining feedrate of all the pocketing operations will be changed as follows:
If you click From in the Edit Parameters pop-up, you will be prompted to select a machining operation in the PPR tree. The parameter value will be taken from the selected operation.
Delete
The Delete contextual command allows you to delete one or more lines in the Process Table.
Rename Current View
You can specify up to four different named views in the Process Table. The procedure is as follows:
● Select a view from the View combo.
● Customize the table using the Column Order and Column Filter commands (for example, to show cutting condition information):
❍ right-click in the table and select Rename Current View
❍ enter the name for the view in the pop-up that appears and click OK.
Here is an example of such a view:
Any modifications done to the Process using the contextual commands are propagated to the PPR tree.
Operations that are locked cannot be edited using the contextual commands.
If the parameter is defined by a formula, this is indicated in the Process Table:
and the Edit Parameter pop-up:
Auto-Sequence Operations in a Program
This task shows how to optimize the order of operations in a program according to pre-defined sequencing rules.
The Sequencing rules have been set up by the administrator. The Program settings under Tools > Options > Machining are described in Program settings.
Make sure that the document in the sequencing rules path is accessible in Read/Write.
A sample sequencing rules document is delivered with the product at the following location:../startup/Manufacturing/samples/AutoSequence/AllSequencingRules.CATProduct.
1. Create a program containing the following operations.
2. Select Rules Manager to visualize the administrator's sequencing rule settings. Change these
settings as follows: ● de-select all rules except for Sort by operation type and Sort by increasing tool diameter
● click the [...] button to visualize the sequencing priority between operations. Make Facing the highest priority machining operation in the list by assigning a priority of 50. Spot drilling remains unchanged at 40 and Drilling remains unchanged at 25.
3. Select Auto Sequence to display the Auto Sequence dialog box. Click the Select All button
to select all the operations of the program.
Click Apply to sequence the operations according to the defined rules and priorities.
4. The program is re-sequenced as follows.
You can click Undo if you want to cancel the auto-sequence results.
It is possible to impose a constraint (called strong precedence) to force a group operations to remain together after sequencing.
Applying a strong precedence constraint means that in addition to imposing an order between two operations A and B, it is not possible to have another operation C between them. The sequence A - C - B is not allowed, only A - B is allowed if a strong precedence exists between A and B.
For this, a parameter named Strong must be added to operation B.
For example, in auto-sequencing this could be used to prevent inserting a threading operation between a drilling operation and a reaming operation.
Machining axis changes are taken into account in auto-sequencing without having to impose strong precedence criteria.
Generate Transition Paths in a Program
This task shows how to generate all necessary transition paths between operations in a program. This is done by taking the selected machine's kinematic characteristics and specified transition planes into account.
For more information, please refer to Transition Path Management in the Reference section.
Select File > Open then select the Stepped.CATPart document. You may need to use Fit All In
to view the part correctly in the window.
Select Start > Machining and select the desired workbench (Prismatic Machining, for example).
1. Double-click the Part Operation to display the Part Operation dialog box.
Click Machine and select a generic milling machine (CATProduct). See Machine Editor for
more information.
A suitable machine for this scenario is jomach35.1.CATProduct which is a 5-axis machine delivered in:..\startup\Manufacturing\Samples\NCMachineToollib\DEVICES.
Click OK to validate the machine selection.
2. In the Part Operation dialog box, click Traverse box planes then select 5 planes that define
a traverse box for the part operation.
Note that an arrow that represents the external normal vector is displayed on the top plane of the Traverse Box. The top plane is the traverse box planes that is perpendicular to all the other planes.This arrow is be oriented from the plane to the outside of the traverse box.
3. Click OK to validate the Part Operation parameters.
Click OK to validate the modifications to the Part Operation.
You may want to position the part on the machine, although this is not necessary for the rest of this user scenario. To do this:
● double-click the Machining Axis System label in the 3D view. Select the origin point in the dialog box that appears and select the point in the model to reposition the machining axis system on this point
● select Workpiece Automatic Mount to automatically mount the workpiece on the machine.
4. Select the Manufacturing Program node in the tree, then create 2 Drilling operations in the program (on Hole1 and Hole9, for example).
5. Right-click the program and select Compute Tool Path.
6. Select Generate Transition Paths . The Transition Paths dialog box appears. Select the
manufacturing program to be processed and set the desired options.
Please refer to Transition Path Options in the Reference section for a description of the proposed options.
Click OK to validate the options and start generating transition paths.
7. The program is updated with the generated transition paths.
8. Select the program then select Replay to verify the generated transition paths.
The figure below illustrates that the transition path between the 2 operations respects the traverse box defined on the part operation. Please note that the retract and approach paths are perpendicular to the traverse box planes as specified in the Transition Paths dialog box.
9. To illustrate the effect of the traverse box with retract and approach paths along the tool axis:
● select Update Transition Paths to display the Transition Paths dialog box
● change the Approach/Retract option to Along operation tool axis
● select the program
● click OK to update the transition paths.
10.
To obtain the transition path in the figure below:● edit the Part Operation to specify an additional transition plane (inclined plane in figure)
● update the transition path using Update Transition Paths .
More About Generating Transition Paths
● You can use Remove Transition Paths to remove all generated transition paths.
● A transition path can include linear transitions and/or machine rotations as follows: Linear transition A Machine rotation i Machine rotation j Machine rotation k Linear transition BMachine rotations can be generated depending on the machine and rotary plane referenced in the Part Operation, and the options selected in the Transition Paths dialog box. A machine with rotary table is required.
Note that, if needed, transition paths can be deleted and replaced by machine rotations (see Insert a Machine Rotation).
● If a transition path includes at least one machine rotation, it can be browsed. Just double-click the Transition Path (Ext Rotation) entity in the tree to display a dialog box like the one shown below.
● The rotary axis name can be set on a generic machine in NC Machine Tool Builder. This allows a better coverage of machines for automatic generation of transition paths (for example, when the rotary axis of the machine is not parallel to the X, Y or Z axis of the absolute axis system).
Create a Process Template
This task shows you how to create a Process Template, starting from an existing CATProcess. The template is created by means of the following automatic steps:
● isolate the CATProcess file from all the files which are linked to it
● disconnect the CATProcess from the geometry
● remove the generated tool path from each machining operation.
The purpose of this is to reuse the CATProcess structure to program the machining of a new design by keeping the sequence of operations and the parameter values that were used in the previous program.
1. Open the Processfinal.CATProcess document. The Setup Editor window appears showing the PPR tree as follows.
2. Select Tools > Machining Tools > Isolate Process Data. The Process Template dialog box appears.
3. If needed, select the check boxes concerning NC Setup Assembly and Tool Paths then click OK to 'clean' the process.
The following steps are done:
Isolate the CATProcess document from all the documents that were linked to it:
● drawings of the part in different steps (.CATDrawing files)
● NC Documentation (.html files)
● APT file, CL file or NC code file
● pictures (.jpg)
● intermediate material removal video results (.wpc).
Disconnect the CATProcess from the geometry:
● Disconnect each elementary machining operation from the part geometry
● Disconnect each Part Operation from the design, the stock and complementary geometry.
Only the link with the NC Setup Assembly is not disconnected if the checkbox is set.
However, even if you choose to keep the NC Setup Assembly in the CATProcess, it must be disconnected from the machining operation.
An IPM Body is associated to the NC Setup Assembly. If you choose to remove the NC Setup Assembly, the IPM Body is also removed.
Remove the generated tool paths for each machining operation:
If the checkbox is not set, the tool paths are removed even if the operations or tool paths are locked.
If you want to keep the generated tool paths, set the checkbox. They will be locked, without locking the operation parameters. If the operation is already locked, it remains locked and nothing more is done.
For more information about lock/unlock, refer to Lock/Unlock Mechanisms.
4. When the operation is finished, save the 'cleaned' process as a process template in the location where you want to store process templates, and then lock it in writing.
Machining ProcessesThis section deals with creating and using machining processes.
Create a Machining Process (P2 functionality): Select the Machining Process icon to create a machining process, which can then be stored as a catalog component.
Organize Machining Processes (P2 functionality): In the Catalog Editor workbench, store the machining process as a Catalog component.
Apply a Machining Process (P2 functionality): Select the Open Catalog icon to access the machining process to be applied to selected geometry.
Apply Machining Processes Automatically (P2 functionality): Select the Machining Processes Application icon to apply all the machining processes of a catalog on a set of selected features.
Create a Machining Process
This task shows how to create a machining process containing a sequence of axial machining operations: Spot Drilling, Drilling, and Tapping.
For each operation you can associate Knowledgeware expressions such as formula and checks and specify a tooling query.
This enables to establish relations on data such as features, machines, and tools that are not yet known at machining process build time. For example, you can use this capability to determine the depth of cut from the hole depth.
In addition, you can use f(x) capability to link the various parameters of machining operations. For example, for an machining process where a rework phase follows a roughing phase, the offsets of the rework can be determined from the offsets used in the roughing step.
For more information about these capabilities, refer to Knowledgeware in Machining Processes.
Select a Machining workbench from the Start menu. No CATPart or CATProcess is needed at this stage.
If the Machining Process toolbar is not already displayed, select it using View > Toolbars.
Make sure that Start Edit mode is set in Tools > Options > Machining > Operations.
Initialize the Machining Process with Machining Operations1. Select Machining Process View . The Machining Process View dialog box appears.
2. Select Machining Process . The dialog box is updated with a new machining process as
shown.
3. Select the Spot Drilling icon. The Spot Drilling dialog box appears.
At this stage you can set certain parameters such as feeds and speeds and machining strategy. However, there is only limited access to geometry parameters and it is not possible to specify a tool.
4. Just click OK to add a reference Spot Drilling operation to the machining process.
The reference operation has an associated Tooling Query.
5. In the same way add Drilling and Tapping operations to the machining process by selecting first the Drilling icon then the Tapping icon. The Machining Process View dialog box is updated as shown.
Associate Formula to the Machining Operations6. Right-click the Spot Drilling operation in the Machining Process View and select Edit Formula.
The Formula Editor dialog box appears.
Define a formula as shown below. It corresponds to the following criteria: the tool tip approach clearance is half the depth of the Spot Drill machining feature.
7. Click OK to assign the formula to the Spot Drilling operation.
You can assign formula to the Drilling and Tapping operations in the same way.
Associate Checks to the Machining Operations
8. Right-click the Spot Drilling operation in the Machining Process View and select Edit Checks. The Checks Editor dialog box appears.
Define a check as shown below. It corresponds to the criteria: the Spot Drilling operation is only available for design holes with a diameter greater than 2mm.
You can assign checks to the Drilling and Tapping operations in the same way.
Define Tool Queries for the Machining Operations
9. Double-click the Tooling Query associated to the Spot Drilling operation. The Tool Query Definition dialog box appears.
Define a simple tooling query as shown below. It corresponds to the criteria:find a spot drill in the ToolsSampleMP tool repository whose name is Spot Drill D10.
10. Click OK to assign the tooling query to the Spot Drilling operation.
You can assign tool queries to the Drilling and Tapping operations in the same way (to find tools Drill D10.5 and Tap D12, for example).
Through the Copy/Paste mechanism, you can manage more than one Tooling Query on an operation. When you instantiate the Machining Process, the first query is executed. If there is no tool found, the next query is executed and so on until a result is obtained or the last query is reached. This enables you to query several tool catalogs, different tool types, and have less constrained queries.
11. Select File > Save As to save the machining process in a CATProcess document (called AxialMachiningProcess1.CATProcess, for example).
12. Right-click the Machining Process in the Machining Process View and select Save in Catalog.
The Save in Catalog dialog box appears. Click the [...] button and specify a new catalog name (catalogAxialMP1.catalog, for example).
Click OK to save the machining process as a component in the specified catalog.
The following are initialized automatically:
● family name: Machining Process
● component name: name given to the machining process using File > Save As.
However, you can change family or component in the Catalog Editor workbench. Click here to see how you can organize machining processes in a catalog using that workbench.
Please refer to Apply a Machining Process for information about applying machining processes to
geometry such as design features and machining patterns.
● Please note for Hole features, when you use string parameters in Checks, Formulas and Tool Queries you must put the value in double quotes ("). For example:Hole.Hole type = "Tapered"
● The Formula Editor, Checks Editor and Tool Query dialog boxes have several common areas:
1. All expressions of the current entity (tool query or machining operation and for a machining operation, either formulas or checks).
2. The commands list.3. Area for editing the current expression with restrictions and help for using Operator, Function
and Unit combos. To validate an edited expression, you must select the Add button.4. All the possible attributes that you can use in an expression, according to the Knowledgeware
description: ❍ the different Knowledgeware packages which group a set of object types: the Machining
Resources, Machining Features and Machining Activities packages are always available
❍ the object types list for the selected package
❍ the attributes list for a selected type: select an attribute to insert it in the expression.
5. For the Tool Query dialog box, a fifth area allows you to define the tool type and tool repository.
● In the same way as for machining operations, you can associate a check on a machining process. Just right-click the machining process in the Machining Process View and select Edit Checks. You can then constrain the domain of application of the machining process in the Checks Editor dialog box.
● In the same way as for machining operations, machining axis systems can be used in machining processes.
● Parameters can be added on machining operations and features in the Knowledge Advisor
workbench. Please refer to Knowledgeware in Machining Processes.In this case the Machining Process View displays a generic node named Parameters under the machining object node. Under this generic node appears the parameter node with its name, its value and/or its formula (depending on the Knowledge parameter display setting).
Organize Machining Processes in a Catalog
This task shows how to organize machining processes in a catalog file.
A catalog file allows you to display the machining processes list by means of the Catalog Editor workbench. Also, you use catalog files to interactively apply a machining process.
All CATProcess documents containing machining processes to be used in the catalog should be open.
1. In order to store a machining process as a catalog component, select the Catalog Editor workbench from the Start > Infrastructure menu.
2. Click Add Family to create a component family.
The Component Family Definition dialog box appears.
3. Enter a name for the component family (for example, AxialMachiningProcesses).
4. Double-click the AxialMachiningProcesses component family in the graph.
5. Click Add Component to create a catalog component.
The Description Definition dialog box appears.
6. Click Select external feature, then select AxialMachProcess1 in the Machining Process View of your AxialMachiningProcess1.CATProcess document.
7. Click OK to make the machining process a component of the catalog component family.
8. Select File > Save As to save the catalog (catalogAxialMP1.catalog, for example).
Please refer to Apply a Machining Process for information about applying machining processes to geometry such as design features and machining patterns.
Apply a Machining Process
This task shows how to apply a machining process to selected geometry.
Open the desired CATPart document, then select a Machining workbench from the Start menu.
The machining process application uses a standard mechanism of instantiation of features from a feature reference. In this case, the feature reference is the machining process to be applied.
When you apply a machining process, the following steps are executed for each operation:
● Default mapping execution in case of geometry selection
● Checks execution
● Tool query execution
● Cutting conditions execution
● Formula solving.
1. Select Open Catalog . Use the Catalog Browser to open the catalogAxialMP1.catalog you
created in the previous task.
2. Double-click the AxialMachiningProcesses component family.
3. Double-click the machining process to be applied: AxialMachProcess1.
The Insert Object dialog box appears allowing you to apply the machining process.
Two input types can be defined:
1. Geometry to machine. The default Geometry to machine is the Manufacturing View. If this is not redefined by selecting feature geometry, then only NC data of the machining process can be processed. In this case if geometry is referenced in checks, tool queries or formula, an error message is issued.
2. Insertion level in a program.The program input only appears if Insertion level in a program is activated. If no operation is yet inserted and only one Manufacturing Program is created, then that Manufacturing Program is the default program input.
Note that for drilling machining processes, if any selected design feature or geometry is linked to a design pattern, this pattern is taken as selected geometry.
4. Select the geometry to be machined. This may be either a design feature or a machining pattern.
Selecting a design feature
Note that the design feature can be a design hole or a hole pattern.
The design geometry is added on the machining pattern referenced by the machining operation.
Note that all the parameters (such as Jump Distance, Tool axis strategy, Projection mode, and Ordering mode) defined on the machining pattern at machining process creation time are kept.
Selecting a machining pattern
The selected machining pattern replaces the one defined on the operation at machining process creation time.
Note that the parameters of the selected machining pattern are taken into account. They replace the parameters (such as Jump Distance, Tool axis strategy, Projection mode, and Ordering mode) defined on the machining pattern referenced by the operation at machining process creation time.
The selected machining pattern is shared by all machining operations created in the program by the application of the machining process.
5. Click OK in the Insert Object dialog box.
6. The program is updated with the operations contained in the machining process: ● Spot Drilling
● Drilling
● Tapping.
These operations reference the selected geometry and make use of the formula and checks defined in the machining process.
In addition, the tool queries are resolved so that each operation references the desired tool.
Apply Machining Processes Automatically
This task shows how to apply all the machining processes of a catalog on a set of selected features.
Open the HoleMakingOperations.CATPart document, then select Machining > Prismatic Machining from the Start menu.
1. Select Machining Processes Application . The Machining Processes Instantiation Manager
appears.
2. Select the features to be machined. You can do this using the Manufacturing View, Edit Search facilities, and so on. The Machining Processes Instantiation Manager is updated.
3. Specify the insertion level in the program. This is usually the Manufacturing Program where you want the machining operations to be added.
4. Select the machining process catalog.
All the machining processes are listed. Select the machining processes to be applied.
Note that selecting a chapter (component family) in the Chapters List highlights all the machining processes in that chapter in the Machining Processes List. You can then apply all of these machining processes. Highlighted lines in the list can be deselected (using the Cntl key for example).
5. Click OK to apply all the machining processes of the catalog to the selected features. The Manufacturing Program is updated with the created machining operations.
Please note the behavior of the command buttons of the Machining Processes Instantiation Manager:
Apply: Apply the machining processes and keep dialog box open
OK: Apply the machining processes and quit the dialog box
Close: Quit the dialog box without applying the machining processes. However, if machining processes have already been applied they will remain applied.
Auxiliary OperationsThis section shows you how to insert auxiliary operations in the NC manufacturing program.
Insert Tool Change: Select Tool Change then select the tool type to be referenced in the tool change.
Insert Machine Rotation: Select Machine Rotation then specify the tool rotation characteristics.
Insert Machining Axis Change: Select Machining Axis Change then specify the characteristics of the new machining axis system.
Insert PP Instruction: Select PP Instruction then enter the syntax of the PP instruction.
Insert COPY Operator (P2 functionality): Select COPY Operator then select the sequence of operations to be processed. You can then specify the number of copies and the characteristics of the transformation.Insert TRACUT Operator (P2 functionality): Select TRACUT Operator then select the sequence of operations to be processed. You can then specify the characteristics of the transformation.Insert Copy-Transformation Instruction (P2 functionality): Select Copy-Transformation then select the list of operations you want to process. You can then specify the number of copies and the characteristics of the transformation.
Opposite Hand Machining: for machining symmetrical parts.
Choosing between TRACUT and COPY Operators and the Copy-Transformation Instruction
The essential differences are as follows:
A TRACUT operator is used to apply a transformation to a delimited sequence of activities in the program.The sequence is delimited by TRACUT-TRACUT/NOMORE type instructions.
A COPY operator is used to copy and apply a transformation to a delimited sequence of activities in the program.The sequence is delimited by COPY-INDEX type instructions.To compute the COPY all the referenced operations must:- be Up to date or Locked - have a Tool Path.
A Copy-Transformation instruction is used to copy and apply a transformation to selected list of operations (not a delimited sequence). To compute the Copy-Transformation all the referenced operations must:- have the same tooling - be Up to date or Locked - have a Tool Path. Tool path edition is possible with the Copy-Transformation instruction.
In addition:
TRACUT and COPY operators are very similar to their counterparts in APT NC language.
Also the same instructions were part of the CATIA Version 4 NC products, so V5 migration of V4 programs with COPY-INDEX and TRACUT-TRACUT/NOMORE sequences is possible.Tool path edition is not possible with TRACUT and COPY operators.
Insert a Tool ChangeThis task shows how to insert tool changes in the program. You can either add tool changes locally or generate all necessary tool changes automatically in the program.
To add a tool change locally:1. In the specification tree, select the program entity after which you want to add the tool change.
2.Select the desired icon in the Tool Change toolbar. The corresponding dialog box appears for defining the tool change.
3.Select the Tool tab page in order to specify the tool to be referenced by the tool change. You
can do this by either:● creating a new tool
● selecting another tool that is already used in the document
● selecting another tool either in the document or in tool catalogs by means of a query.
This is the same procedure as described in Select or Create a Tool.4.Select the Tool Assembly tab page if you want to:
● create a new tool assembly. In this case a tool assembly is added to the Resource List. Please refer to Edit a Tool Assembly in the Resource List for more information about how to specify the geometric and technological characteristics of the a tool assembly.
● select a tool assembly that is already used in the document.
5.Select the Syntax tab page .
● Select the Initialize from PP words table checkbox to consult the tool change syntax defined in the PP table that is referenced by the Part Operation.
● Otherwise, enter a PP instruction for your tool change. This user-defined syntax has no link with the PP table and its validity is not checked by the program.
● If the PP Instruction comprises a sequence of PP word syntaxes, you can choose the sequence to be used by means of the Sequence number spinner.
6.Click OK to create the tool change in the program.
You can click Replay Tool Path to visualize the tool at the tool change point.
This point is specified in the current Part Operation. To generate tool changes automatically:
1.Right-click the Manufacturing Program entity in the specification tree and select Generate Tool Changes.
The program is updated with all necessary tool changes. Each generated tool change is inserted just before the first machining operation in the program that requires the tool change.
Initial program:MO1 using Tool1PP instructionMO2 using Tool2PP instructionMO3 using Tool2MO4 using Tool3
Program after tool change generation:Generated Tool change1MO1 using Tool1PP instructionGenerated Tool change2MO2 using Tool2PP instructionMO3 using Tool2Generated Tool change3MO4 using Tool 3
To delete tool changes that were automatically generated: 1.Right-click the Manufacturing Program entity in the specification tree and select Delete Generated
Tool Changes.
All tool changes that were automatically generated are removed from the program.
Insert a Machine Rotation
This task shows how to insert a machine rotation in the program.
You can either add machine rotations manually or generate all necessary machine rotations automatically in the program.
Note: For machines created using NC Machine Tool Builder, automatic generation of machine rotations is not possible.
Either the program or a program entity must be current in the specification tree.
To add a machine rotation manually: 1. In the specification tree, select the program entity after which you want to add the machine
rotation, then select Machine Rotation .
For a default machine (see Machine Editor), the following Machine Rotation dialog box appears.
For a generic machine (that is, a machine created using NC Machine Tool Builder - see Machine Editor), the dialog box has two extra attributes:
● Rotary Axis: Name of the rotary axis A, B or C
● Category: Table or Head, depending on the selected rotary axis.
Note that these attributes are taken into account in tool path computation.
This provides the possibility to manually create machine rotations on generic machines and allows transitions to be managed between machining operations.
2. Select the Properties tab page to specify the characteristics of the machine rotation.
3. Specify the Rotary angle.
If the Definition combo is set to Manual, you can enter the angle value directly in the Rotary angle field.
If the Definition combo is set to Selected, you can specify the angle value using the graphic area in the dialog box:
1. Click the axis symbol in the graphic area then select an axis system in the 3D viewer.2. Click the vector symbol in the graphic area then select a line or cylinder in the 3D viewer.
In this case the angle between the z-axis of the selected axis system and the line or cylinder axis specifies the Rotary angle.
or
Click the point symbol in the graphic area then select a point in the 3D viewer. In this case the angle between the z-axis of the selected axis system and the line through the selected point and the axis system origin specifies the Rotary angle.
The machine table is rotated by this angle about the rotary axis (A, B or C). The rotary axis is defined:
● on the default machine is set on the Part Operation
● in the Machine Rotation dialog box is a generic machine is set on the Part Operation.
4. Select the Rotary direction: ● Clockwise
● Counter-clockwise
● Shortest.
The Rotary type is set to Absolute in this version.
5. Select the Syntax tab page .
● Select the Initialize from PP words table checkbox to consult the machine rotation syntax defined in the PP table that is referenced by the Part Operation.
● Otherwise, enter a PP instruction for your machine rotation. This user-defined syntax has no link with the PP table and its validity is not checked by the program.
6. Click OK to accept creation of the machine rotation in the program.
To generate machine rotations automatically: 1. Right-click the Manufacturing Program entity in the specification tree and select Generate
Machine Rotations.
The program is updated with all necessary machine rotations.
Note: this capability is available when a default machine (see Machine Editor) is set on the Part Operation.
To delete machine rotations that were automatically generated: 1. Right-click the Manufacturing Program entity in the specification tree and select Delete
Generated Machine Rotations.
All machine rotations that were automatically generated are removed from the program.
Insert a Machining Axis Change
This task shows how to insert a machining axis change in the program.
Output coordinates are computed in the current machining axis system as shown in the example below.
Tool path computed in machining axis system AXS1 with origin (0,0,0):
$$*CATIA0$$*AXS1$$ 1.00000 0.00000 0.00000 0.00000$$ 0.00000 1.00000 0.00000 0.00000$$ 0.00000 0.00000 1.00000 0.00000GOTO/ -40.00000, -30.00000, 20.00000GOTO/ -40.00000, 30.00000, 20.00000
Same tool path computed in machining axis system AXS2 with origin (0,0,20):
$$*CATIA0$$*AXS2$$ 1.00000 0.00000 0.00000 0.00000$$ 0.00000 1.00000 0.00000 0.00000$$ 0.00000 0.00000 1.00000 20.00000GOTO/ -40.00000, -30.00000, 0.00000GOTO/ -40.00000, 30.00000, 0.00000
Either the program or a program entity must be current in the specification tree.
1. Select Machining Axis Change . The corresponding dialog box is displayed directly at the
Geometry tab page .
You can define your axis system with the help of the sensitive icon in the dialog box.
2. In the Axis name field, you can enter a name for the machining axis system being created. This name will be displayed beside the representation of the axis system in the 3D view.
3. Select the symbol representing the origin in the sensitive icon, then select a point or a circle to define the origin of the machining axis.
In addition to point selection, you can also specify a point by means of its coordinates as follows: ● right-click the symbol representing the origin in the sensitive icon
● select the Coordinates contextual command
● enter the point coordinates in the dialog box that appears.
Coordinates are expressed in the absolute axis system.
4. Select one of the axes (Z, for example) in the sensitive icon to specify the orientation of that axis.
The following dialog box appears.
The Z axis is the privileged axis. You should define it first, then specify the X axis. The XY plane is perpendicular to the Z axis.
5. Select the desired method to specify the axis orientation using the combo:● Manual. In this case, choose one of the following:
❍ Components to define the orientation by means of I, J and K components
❍ Angles to define the orientation by means of a rotation specified by means of one or two angles:Angle 1 about X, Angle 2 about YAngle 1 about Z, Angle 2 about XAngle 1 about Y, Angle 2 about Z
● Selection. In this case just select a line or linear edge to define the orientation.
● Points in the View. In this case just select two points to define the orientation.
Just click OK to accept the specified orientation.
6. Repeat this procedure to specify the orientation of another axis (X, for example).
The specified origin along with the X and Z axes are sufficient to define the machining axis system.
You can also define a machining axis by selecting one of the triangular areas in the sensitive icon. In this case you must select an existing axis system and position it by selecting a point in the 3D view.
7. You can click the Origin checkbox if you want to specify an origin statement in the NC data output.
For certain machine types it may be useful to specify an origin number and group. This will result in the following type of output syntax:
$$*CATIA0$$Origin.1$$ 1.00000 0.00000 0.00000 0.00000$$ 0.00000 1.00000 0.00000 0.00000$$ 0.00000 0.00000 1.00000 0.00000ORIGIN/ 0.00000,0.00000,0.00000, 1, 1
This output is for an origin with coordinates (0,0,0) and whose origin number and group are both equal to 1.
8. Select the Syntax tab page .
● Select the Initialize from PP words table checkbox to consult the Machining Axis Change syntax defined in the PP table that is referenced by the Part Operation.
● Otherwise, enter a PP instruction for your machining axis change. This user-defined syntax has no link with the PP table and its validity is not checked by the program.
9. Click OK to create the machining axis change in the program. A feature representation of the corresponding Machining Axis System is created in the 3D view.
Please note the following:● It is possible to analyze the geometry referenced by a machining axis system. This geometry
may be a point, line, surface, or an axis defined in the design part. Right-click any sensitive area in the dialog box, and select the Analyze. The Geometry Analyser dialog box appears giving the referenced geometry, its name and status.
● A machining axis system can be shared by several machining axis change operations. Machining axis systems can be listed in Manufacturing View using the Sort by Features command.
Insert a PP Instruction
This task shows how to insert a PP instruction in the program.
Either the program or a program entity must be current in the specification tree.
1. In the specification tree, select a reference program entity. The PP instruction will be added after this entity in the program.
2. Select Post-Processor Instruction .
The Post-Processor Instruction dialog box appears, allowing you to enter the syntax of a PP instruction.
3. Enter one or more PP word syntaxes directly in the text area as shown below.
4. Click to access the PP Words Selection Assistant dialog box.
The content of the PP words table that is referenced in the current part operation is available for selection in this dialog box.
5. Select the desired major word. If syntaxes are defined for this major word in the table, they are also available for selection. Your selection is displayed in the Current Selection area. If the selected syntax contains parameters (&RVAL, for example ), you will be prompted to complete the syntax with numerical values. Pease refer to PP Tables and Word Syntaxes for more information.
Click Apply to add the selected syntax to the PP instruction.
6. Click OK to create the PP instruction in the program.
Please note the following points:● You can display the syntax of the PP instruction in a larger, resizable dialog box (16 lines of 72
characters) by clicking on the Larger View icon.
● A default contextual menu providing edition facilities is available by right-clicking in the text area (Undo/Cut/Copy/Paste/Delete/Select All).
● A Refresh icon is available to refresh the PP word syntax to take into account parameter modification in the other tab pages of the editor.
● You can define a PP instruction that references user parameters created in a design part, and output the result in the APT source when the PP instruction is processed.
● The program does not check the validity of your syntax.
Insert a COPY Operator
This task shows how to apply a COPY Operator to a delimited sequence of operations in the program.The sequence is delimited by COPY-INDEX type instructions.
Open the CopyTransfoSample.CATPart document.
1. Create a first Pocketing operation on the first square cut-out. Create a second Pocketing operation using a different tool on the first triangular cut-out. To create these pockets, make sure that the Island Detection contextual command is not active when define the pocket bottom.
2. Right-click the Manufacturing Program and select Compute Tool Path. Select the Compute if necessary option in the pop-up that appears.
3. Select the second Pocketing operation in the program.
Select COPY Operator .
A COPY Operator is inserted in the program after Pocketing.2 and the COPY Operator dialog box appears.
4. Select to create an INDEX instruction.
Select an entity in the program to specify the insertion level. In this scenario, select Tool Change.1 to insert the INDEX instruction before that tool change.
The COPY Operator will apply to the two tool changes and the two pocketing operations.
5. Set the desired number of copies to 3.
6. Set the Transformation type to Translation. Choose the Translation type to Absolute Coordinates.Specify the translation by setting the Distance along X to -100mm.
7. Click Tool Path Replay to visualize the tool path resulting from the defined COPY Operator.
The possible transformation types are as follows. ● Translation: choose the desired translation type then specify the translation by:
❍ either giving X, Y, Z components in the absolute or the current machining axis system
❍ or clicking the Direction area to select a linear geometric element for the direction and giving a length.
● Rotation: click the Axis area to select a linear geometric element as the axis of rotation then give a rotation angle. If a circular edge is selected, the normal axis of the circle is used.
● Mirror: click the Mirror area to select a planar geometric element as the axis of symmetry.
● Axis to axis: click the From area to select a first machining axis system then the To area to select a second machining axis system. The first axis system will be transformed into the second axis system.
● Affinity: select a Machining Axis System and define 3 scale factors to be applied along each of its axes: x,y,z. The transformation matrix in the selected Machining Axis System will be:
● Scale: select a planar surface or a point and a scale factor to be applied along the normal projection on the selected element.
● Matrix: This transformation will be defined by the matrix definition of the transformation in the absolute Axis System, the current Machining Axis System, or a selected Machining Axis System.
In case of definition of the matrix in the absolute Axis System or in the current Machining Axis, the matrix of the transformation is stored in the model in the absolute Axis System (it is invariant in this Axis System).Choosing one or the other mode only changes the display of the coordinates of the matrix. Out of a current Machining Axis System context, the Absolute Axis System will be used to display the matrix.
In case of definition of the matrix in a selected Machining Axis System, the matrix of the transformation is stored relatively to this selected Machining Axis System.
You can create an INDEX/NOMORE instruction in the program by clicking .
You can select an existing INDEX to be associated to the COPY operator by clicking .
8. If needed, select the Syntax tab page to consult the syntax that will be applied for the
COPY operator.
9. Click OK to create the COPY Operator in the program.
Status Management
COPY Operator will show an Exclamation mask in standard cases:
● a reference geometry has been deleted
● INDEX and INDEX/NOMORE are inconsistent.
COPY Operator will show an Update mask in standard cases:
● reference geometry has been modified
● a parameter has been modified.
COPY Operator can be computed if all the referenced operations:
● are Up to date or Locked
● have a Tool Path.
Deactivated Operations
Deactivated operations in the reference sequence are not taken into account when the Copy is processed.
Insert a TRACUT Operator
This task shows how to apply a TRACUT Operator to a delimited sequence of operations in the program.The sequence is delimited by TRACUT-TRACUT/NOMORE type instructions.
Open the CopyTransfoSample.CATPart document.
1. Create a first Pocketing operation on the first square cut-out. Create a second Pocketing operation using a different tool on the first triangular cut-out. To create these pockets, make sure that the Island Detection contextual command is not active before you define the pocket bottom.
2. Right-click the Manufacturing Program and select the Compute Tool Path contextual menu. Select the Compute if necessary option in the pop-up that appears.
3. Select Tool Change.1 in the program.
Select TRACUT Operator .
A TRACUT Operator is inserted in the program before Tool Change.1 and the TRACUT Operator dialog box appears.
4. Select to create a TRACUT/NOMORE instruction.
Select an entity in the program to specify the insertion level. In this scenario, select Pocketing.2 to insert the TRACUT/NOMORE instruction after that operation.
The TRACUT Operator will apply to the two tool changes and the two pocketing operations.
5. Set the Transformation type to Translation. Choose the Translation type to Absolute Coordinates.Specify the translation by setting the Distance along X to -100mm.
The possible transformation types are as follows. ● Translation: choose the desired translation type then specify the translation by:
❍ either giving X, Y, Z components in the absolute or the current machining axis system
❍ or clicking the Direction area to select a linear geometric element for the direction and giving a length.
● Rotation: click the Axis area to select a linear geometric element as the axis of rotation then give a rotation angle. If a circular edge is selected, the normal axis of the circle is used.
● Mirror: click the Mirror area to select a planar geometric element as the axis of symmetry.
● Axis to axis: click the From area to select a first machining axis system then the To area to select a second machining axis system. The first axis system will be transformed into the second axis system.
● Affinity: select a machining axis system and define 3 scale factors to be applied along each
of its axes: x,y,z. The transformation matrix in the selected machining axis system will be:
● Scale: select a planar surface or a point and a scale factor to be applied along the normal projection on the selected element.
● Matrix: This transformation will be defined by the matrix definition of the transformation in the absolute axis system, the current machining axis system, or a selected machining axis system.
In case of definition of the matrix in the absolute axis system or in the current machining axis system, the matrix of the transformation is stored in the model in the absolute axis system (it is invariant in this axis system).Choosing one or the other mode only changes the display of the coordinates of the matrix. Out of a current machining axis system context, the absolute axis system will be used to display the matrix.
In case of definition of the matrix in a selected machining axis system, the matrix of the transformation is stored relatively to this selected machining axis system.
6. If needed, select the Syntax tab page to consult the syntax that will be applied for the
TRACUT operator.
7. Click OK to create the TRACUT Operator in the program.
8. To visualize the tool path resulting from the defined TRACUT Operator, select the first tool change
in the program then click the Replay Tool Path .
Make sure that the TRACUT display mode is active in the Tool Path Replay dialog box.
Replay the tool changes and pocketing operations.
Close the dialog box at the end of the replay.
Status management
TRACUT Operator will show an Exclamation mask in standard cases:
● a reference geometry has been deleted.
TRACUT Operator will show an Update mask in standard cases:
● reference geometry has been modified
● a parameter has been modified.
Insert a Copy-Transformation Instruction
This task shows how to apply a Copy-Transformation instruction to a selected list of operations in the program. The selected list does not necessarily correspond to a sequence in the program. However, the operations must have the same tooling.
Open the CopyTransfoSample.CATPart document.
1. Create a first Pocketing operation on the first square cut-out, then a second Pocketing operation on the first triangular cut-out. To create these pockets, make sure that the Island Detection contextual command is not active when define the pocket bottom.
2. Select the second Pocketing operation in the program.
Select Copy-Transformation Instruction .
A Copy-Transformation instruction is inserted in the program after Pocketing.2 and the Copy-Transformation dialog box appears.
3. Click Add Operations then select the two Pocketing operations in the program.
The Copy-Transformation will apply to these two operations.
Selected operations must have the same tooling.
Move Up and Move Down allow you to move the selected operation up or down in the
list. Delete allows you to delete selected operations.
4. Set the desired number of copies to 3.
5. Set Ordering to Each operation N times.
6. Set the Transformation type to Translation. Choose the Translation type to Absolute Coordinates.Specify the translation by setting the Distance along X to -100mm.
7. You can click Replay to visualize the tool path resulting from the defined Copy-Transformation.
With the Each operation N times Ordering setting, the transformation is applied to the 3 square cut-outs first then to the 3 triangular cut-outs.
With the All operations N times Ordering setting, the transformation is applied to the first set of square and triangular cut-outs, then the second set, and finally the third set.
The possible transformation types are as follows. ● Translation: choose the desired translation type then specify the translation by:
❍ either giving X, Y, Z components in the absolute or the current machining axis system
❍ or clicking the Direction area to select a linear geometric element for the direction and giving a length.
● Rotation: click the Axis area to select a linear geometric element as the axis of rotation then give a rotation angle. If a circular edge is selected, the normal axis of the circle is used.
● Mirror: click the Mirror area to select a planar geometric element as the axis of symmetry
● Axis to axis: click the From area to select a first machining axis system then the To area to select a second machining axis system. The first axis system will be transformed into the second axis system.
● Scale: select a Machining Axis System and define 3 scale factors to be applied along each of its
axes: x,y,z. The transformation matrix in the selected Machining Axis System will be:
● Affinity: select a planar surface, a linear edge, or a point and a scale factor to be applied along the normal projection on the selected element.
● Matrix: This transformation will be defined by the matrix definition of the transformation in the absolute Axis System, the current Machining Axis System, or a selected Machining Axis System.
In case of definition of the matrix in the absolute Axis System or in the current Machining Axis, the matrix of the transformation is stored in the model in the absolute Axis System (it is invariant in this Axis System).Choosing one or the other mode only changes the display of the coordinates of the matrix. Out of a current Machining Axis System context, the absolute Axis System will be used to display the matrix.
In case of definition of the matrix in a selected Machining Axis System, the matrix of the transformation is stored relatively to this selected Machining Axis System.
8. Click OK to create the Copy-Transformation instruction in the program.
NC Data Output Considerations
Copy-Transformation allows you to produce NC data that takes into account the specificities of the selected machining operations (Cycle syntax or Goto statements, Compensation, Profile, Tip/Axis, Contact/Norm, PQR, and so on).
During NC data generation, the tool path of the Copy-Transformation of an ordered list of machining operations will, for each of its sub-paths corresponding to a specific machining operation, read the complementary information on this machining operation to associate to the particular treatment of this sub-path.
If the Cycle syntax is ON in a selected machining operation, the sub-path will be output is this mode.The tolerance and discretization step of the selected machining operation are taken into account to
process double points for this sub-path.If profile data exists on an operation, the sub-path will be output in this mode.Compensation data will be read for this sub-path on the selected machining operation.
The Copy-Transformation output will take into account data available in the tool path and in the elected machining operations.
If a Copy-Transformation references various machining operations with specific data that differs from one operation to another, each sub-path of the Copy-Transformation will be processed individually.
Machining operations using CYCLE syntaxes and GOTO statements can be mixed in a Copy-Transformation: the output will be composed of CYCLE syntaxes and GOTO statements.
Deactivated machining operations are taken into account for the computation of a Copy-Transformation.
Status Management
Copy-Transformation will show an Exclamation mask in standard cases:
● a reference geometry has been deleted
● all referenced operations have been deleted.
Copy-Transformation will show an Update mask in standard cases:
● reference geometry has been modified
● a referenced operation has been modified or deleted
● a parameter has been modified.
Copy-Transformation can be computed if all the referenced operations:
● have the same tooling
● are Up to date or Locked
● have a Tool Path.
Copy-Transformation and the Tool Path Editor
You can create a Copy-Transformation in the program when using the Tool Path Editor.
Before cutting an area of the tool path, you can choose to copy the area in the specification tree as follows:
● Select the Area Selection Option icon in the Tool Path Editor toolbar.
● Select the Copy-Transformation checkbox in the Selection Options dialog box that appears.
● Select the Cut icon and select an operation in the specification tree.
The Copy-Transformation is created after the selected operation.
In this case the Copy-Transformation dialog box includes a Tooling tab page .
This allows you to change the tool or tool assembly of the Copy-Transformation created with the Tool Path Editor's Cut command.
Double-click the Copy-Transformation instruction and select the Tool tab in the dialog box that
appears. Modify the tool as desired.
Click OK to accept the tool modification and update the PPR tree.
Previous Version Instruction
A Copy-Transformation instruction created in R9 which has lost its reference operation (operation deleted or replaced by a tool path by means of Add Tool Paths command in R9) behaves like a Copy-Transformation instruction created using the Tool Path Editor and the Cut command.
Opposite Hand Machining
This task shows how to easily and quickly define the complete manufacturing program of a symmetrical workpiece, when a symmetrical half of the workpiece is already programmed.
More information can be found in the Methodology section.
Open the ProcessDEMO.CATProcess document. The associated part is Left_Hand_Part.CATPart. The Left Program contains 3 machining operations for machining a left hand part.
To machine the symmetrical right hand part, proceed as follows.
1. Copy the Left Program in the Part Operation using Edit > Copy and Paste commands. Rename the new program as Right Program (using Edit > Properties).
2. Select the Right Program node in the tree and click TRACUT Operator .
3. In the TRACUT Operator dialog box, select the Transformation type to Mirror.
Click the Mirror selection field then select the YZ plane as the symmetrical plane.
Click OK to create the TRACUT operator.
4. Select the Right Program node in the tree and click Opposite Hand Machining Options .
In the dialog box that appears, make sure that Reverse Machining Conditions command can be applied to all the operations types in the program.
5. Click Reverse Machining Conditions .
A message box appears giving the result of the command: numbers of operations processed and number of operations updated.
6. Right-click the Right Program node in the tree and select Compute Tool Path.The tool paths of the Right Program are recalculated.
7. Right-click the Right Program node in the tree and select Replay Tool Path. Make sure that the TRACUT display mode is active in the Replay dialog box.
The replay shows the result of the opposite hand programming.
8. Save your document (ProcessDEMOResult.CATProcess, for example).
In most cases, your program may need to be finalized by means of some local editing. You can use:
● Reorder Operations List to reverse the order of one or more groups of operations
● Inverse Macros to inverse the approach and retract macros on an operation.
Machining EntitiesThis section deals with creating and managing the specific entities of the machining environment (other than machining operations and auxiliary commands).
Resources:● Edit the Tool of a Machining Operation: Double-click the machining operation in the program and select the
Tool tab page to edit the tool characteristics or search for another one.
● Edit a Tool in the Resource List: Double-click a tool in the resource list and edit the tool characteristics in the Tool Definition dialog box.
● Edit the Tool Assembly of a Machining Operation: Double-click the machining operation in the program and select the Tool Assembly tab page to edit the tool assembly characteristics or search for another one.
● Edit a Tool Assembly in the Resource List: Double-click a tool assembly in the resource list and edit the tool characteristics in the Tool Definition dialog box.
● Create a Tool Catalog from the Resource List: Right-click a tool in the resource list then select Send to Catalog
● Replace Tools in Resource List: Click Replace Tools to rename tools already used in your document.
● Manage Tools in the Resource List and TDM:
❍ access TDM and import a pre-defined tool list to the resource list
❍ create a tool list in TDM from selected tools in the resource list.
● Use Tooling Resources from TDM:
❍ define feeds and speeds on tools using the TDM database
❍ retrieve tool correctors for tools from the TDM database.
● Specify Tool Compensation Information: Double-click a tool referenced in the program or resource list and specify the tool compensation information in the Compensation tab page of the Tool Definition dialog box .
● Define the Tool Axis: Select the Tool axis symbol in the machining operation editor, then use one of the available modes to specify the orientation of the tool axis.
Machining Features:● Create and Use a Machining Pattern: Select Insert > Machining Feature > Machining Pattern then select a
pattern of holes to be machined.
● Manufacturing View: Select a feature using the Manufacturing view and create operations based on this feature.
Macros:● Define Macros on a Milling Operation: Select the Macros tab page when creating or editing a milling
operation, then specify the transition paths of the macros to be used in the operation.
● Define Macros on an Axial Machining Operation: Select the Macros tab page when creating or editing an axial machining operation, then specify the transition paths of the macros to be used in the operation.
● Define Macros on a Turning Operation: Select the Macros tab page when creating or editing a turning operation, then specify the transition paths of the macros to be used in the operation.
● Build and Use a Macros Catalog.
General capabilities:● Manage the Status of Manufacturing Entities: Use the status lights to know whether or not your operation
is correctly defined.
● Design or User Parameters in PP Instruction and APT Output.
Edit the Tool of a Machining Operation
This task shows you how to edit the tool of a machining operation. A machining operation always has a tool assigned to it (default tool, for example).
You can modify this tool in several ways:
● edit its characteristics, thereby creating a new tool
● replace it by selecting another tool that is already used in the document
● replace it by selecting another tool by means of a query.
1. Double-click the operation in the program. The machining operation dialog box appears. Select the Tooling tab page
then select the Tool tab .
2. To create a new tool:
If you want to change tool type, select the icon corresponding to the desired tool type. In this case the corresponding tool representation appears in the 2D viewer.
● Double-click the geometric parameter that you want to modify in the 2D viewer, then enter the desired value in the Edit Parameters dialog box that appears. Modify other parameters in the same way. The tool representation is updated to take the new values into account.
● Click More to expand the dialog box to access all the tool's parameters. Modify the values as desired.
● Use the spinner to increment the Tool number.
● Enter a name for the new tool.
3. To select a tool that is already used in the document: ● Select the button opposite Name.
● Select the desired tool from the list of tools already used in your document.
● The tool representation is displayed in the 2D viewer. It can be edited as described above.
4. To select another tool by means of a query: ● Click the Select a tool with query icon opposite Name. The Search Tool dialog box appears.
● Use the Look in combo to specify where you want to search for the tool: ❍ in the current document
❍ in a tool catalog
❍ in an external tool database such as the TDM (Tool Data Management) or CATIA Version 4 Manufacturing database.
● If you want to change tool type, select the icon corresponding to the desired tool.
● You can do a quick search in the Simple tab page by means of a character string on the tool name or a value for the tool's nominal diameter. The tools meeting the simple search criteria are listed.
● Select the desired tool from the list and click OK. The tool representation is displayed in the 2D viewer. It can be edited as described above.
● You can search a tool using finer constraints by selecting the Advanced tab page.
The example below shows the result of a search for a tool with body diameter between 8mm and 12mm in the catalog ToolsSample02.
5. Click OK to confirm using this new tool in the operation.
Cutting conditions (feeds and speeds) can be included in a tool catalog and in the TDM. Please refer to Feeds and Speeds for more information.
The TDB can allow several cutting speed and feedrate data for each tool. This information is displayed at tool selection time.
The feed and speed information of the selected tool is used in the machining operation definition.
Realistic DXF user representation of tools can be selected from the TDB. These can be used in tool path replay as well as Photo and Video simulations.
Edit a Tool in the Resource List
This task shows you how to edit a tool that is already used in your document.
1. To edit a tool in the resource list, right-click it and select Edit NC Resources.
The Tool Definition dialog box is displayed allowing you to edit the tool's geometric, technological, cutting condition, and compensation characteristics.
2. If needed, enter a new name for the tool. You can also assign a comment.
3. If needed, use the spinner to increment the Tool number.
4. Click More to expand the dialog box to access the Geometry, Technology, Feeds & Speeds, and Compensation tab pages.
5. You can specify the tool geometry in two ways: ● double-click a parameter in the large tool icon and enter the desired value in the Edit
Parameter dialog box that appears
● or enter the desired values in the Geometry tab page.
The icon representation of the tool is updated with these values.
6. Click the Technology tab and enter the desired values for the tool's technological parameters.
7. Click the Feeds & Speeds tab and enter the desired values for the tool's cutting conditions.
The units associated to each attribute are set using the Tools > Options > General > Parameters & Measure > Units tab page. For cutting speeds, you can to choose the industry standard unit you are accustomed to: m/mn or ft/mn. These are linear cutting speeds.
The Feedrate attribute used in previous releases is replaced by Feedrate per tooth.A Feedrate attribute representing the global feedrate of the tool is available.
If you modify Feedrate per tooth, the global Feedrate is updated using the formula:
global feedrate = feedrate per tooth * number of flutes.
If you modify global Feedrate, the Feedrate per tooth is updated using the formula:
feedrate per tooth = global feedrate / number of flutes.
8. If tool compensation is required, click the Compensation tab.
You can either edit an existing compensation site or add another site, if other sites are proposed. See Specify Tool Compensation for more information.
● Right-click the desired line to either edit or add tool compensation data. The Compensation Definition dialog box appears.
● Enter the desired values for the tool's compensation sites.
Edit the Tool Assembly of a Machining Operation
This task shows you how to create and edit the tool assembly of a machining operation.
You can modify this tool assembly in several ways:
● edit its characteristics, thereby creating a new tool assembly
● replace it by selecting another tool assembly that is already used in the document
● replace it by selecting another tool assembly by means of a query.
1. Double-click the operation in the program. The machining operation dialog box appears. Select the
Tooling tab page then select the Tool Assembly tab .
2. To create a new tool assembly:● Enter a name for the new tool assembly. A tool assembly representation appears in the 2D
viewer.
● Double-click the geometric parameter that you want to modify in the 2D viewer, then enter the desired value in the Edit Parameters dialog box that appears. Modify other parameters in the same way. The tool assembly representation is updated to take the new values into account.
● Click More to expand the dialog box to access all the tool assembly parameters. Modify the values as desired.
● Use the spinner to increment the Tool number.
3. To select a tool assembly that is already used in the document: ● Select the button opposite Name.
● Select the desired tool assembly from the list of tool assemblies already used in your document.
● The tool assembly representation is displayed in the 2D viewer. It can be edited as described above.
4. To select another tool assembly by means of a query: ● Click the Select a tool assembly with query icon opposite Name. The Search Tool Assembly
dialog box appears.
● Use the Look in combo to specify where you want to search for the tool: ❍ in the current document
❍ in a tool catalog
❍ in an external tool database such as the TDM (Tool Data Management) or CATIA Version 4 Manufacturing database.
● If you want to change the tool type associated with the tool assembly, select the icon corresponding to the desired tool.
● You can do a quick search in the Simple tab page by means of a character string on the tool assembly name. The tool assemblies meeting the simple search criteria are listed.
● Select the desired tool assembly from the list and click OK. The tool assembly representation is displayed in the 2D viewer. It can be edited as described above.
You can search a tool assembly using finer constraints by selecting the Advanced tab page.
The example below shows the result of a search in the TDM catalog for a tool assembly whose tool has a nominal diameter greater than 5mm.
5. Click OK to confirm using this new tool assembly in the operation.
Edit a Tool Assembly in the Resource List
This task shows you how to edit a tool assembly that is already used in your document.
1. To edit a tool assembly in the Resource List, right-click it and select Edit NC Resources.
The Tool Assembly Definition dialog box is displayed allowing you to edit the tool assembly's geometric and technological characteristics.
2. If needed, enter a new name for the tool assembly.
You can also assign a comment.
3. If needed, use the spinner to change the Tool number.
4. Click More to expand the dialog box to access the Geometry and Technology tab pages.
5. You can specify the tool assembly geometry in two ways: ● double-click a parameter in the 2D viewer and enter the desired value in the Edit Parameter
dialog box that appears
● or enter the desired values in the Geometry tab page.
In both cases the 2D viewer is refreshed after each modification to a geometric parameter.
You can use the Tool holder stages spinner to define between two and five stages on the tool holder of the assembly.
For two stages, specify the two tool holder diameters (D2 and D3) and two cone diameters (d1 and d2). Suitable values for the cone diameters allow the stages to be tapered.
For five stages, specify the five tool holder diameters (D2 to D6) and five cone diameters (d1 to d5). Suitable values for the cone diameters allow the stages to be tapered.
6. Click the Technology tab and enter the desired values for the tool assembly's technological parameters.
7. Click OK to accept the modifications made to the tool assembly.
A CATPart or CATProduct representation can be assigned to the tool assembly by means of the Add User Representation contextual command in the Resource List. In this case, if a component (tool, for example) of the assembly has a user representation, it will not be taken into account.
Create a Tool Catalog from the Resource List
This task shows you how to create a tool catalog from selected tools in the resource list.
A tool catalog can contain tool assemblies, tools and tool inserts.
1. Select tools in the resource list, then right-click to select Send to Catalog.
The Save in Catalog dialog box is displayed allowing you to create a new tool catalog or overwrite an existing one..
2. To create a new tool catalog, click the [...] button to navigate to the desired folder and enter a name for the catalog.
To overwrite an existing tool catalog, click the [...] button to navigate to the desired catalog.
3. Click OK to create the new or updated catalog. The resulting tool catalog appears in a new Catalog Editor window.
You can also build a tools catalog by customizing an Excel file and a VB macro file.
Replace Tools in the Resource List
This task shows you how to rename tools already used in your document. You can do this: ● automatically by means of new references listed in a tool replacement catalog
● manually by entering new names in a dialog box.
1. Click Replace Tools .
The Replace Tools dialog box is displayed.
2. In the Tool Table combo choose either Manual Mode or a tool replacement catalog.
You must have previously prepared this catalog with the desired names. A sample catalog is delivered in .../Startup/Manufacturing/Tools/ToolsReplacement.catalog.
3. Using the manual mode: ● select a tool to be renamed in the list then enter the new name in the To area
● if needed, change other tool references in the same way
● click OK to update all the tools in the document with the new references.
4. Using the tool replacement catalog:
● when you select the desired catalog, all the new tool references are listed opposite the old references
● click OK to update all the tools in the document with the new references.
An example of the PPR tree before and after the update is shown below:
Note that tool path storage information is not modified by this update.
Manage Tools in the Resource List and TDM
This task shows you how to:● access TDM and import a pre-defined tool list to the PPR Resource List
● create a tool list in TDM from selected tools in the PPR Resource List.
Import a tool list from the TDM to the Resource List
1. Open a Machining workbench (no CATPart or CATProduct document is needed at this stage). The manufacturing document is initialized as follows.
2. Select Import/List Tools in the Auxiliary Commands toolbar.
The Search Tool dialog box appears. Select TDM from the combo list.
3.Select Tool List Mode Access that appears at the end of the line of icons.
The Tool List Selection dialog box appears showing the tool lists currently in the TDM database.
4.
5. Filter the list. The example below shows how to enter a string to display the tool lists referenced by a given machine (the % character represents a character string).
6. Select the desired tool list and click OK. The Search Tool dialog box is updated.
If Tool preview after selection is set in Tools > Options > Machining > Resources, an image is displayed of any tool selected in the Search tool list. Please refer to Resource settings.
7. Select the tools that you want to import to the resource list and click OK. The PPR Resource List is updated with the selected tools.
Create a tool list in the TDM from tools selected in the Resource List
1. Select the tools in the PPR Resource List that you want to include in a TDM tool list.
2. Right-click the selected tools and select Create TDM Tool List from the NC Resources menu.
3. The Tool List Definition dialog box appears. Enter an identifier for the new tool list. Also enter names for the NC program, part, and NC machine. Click Create.
4. Select Import/List Tools in the Auxiliary Commands toolbar.
The Search Tool dialog box appears. Make sure TDM and Tool List Mode Access are
selected.
Click the [...] button opposite Tool List ID. The tool List Selection dialog box appears.
5. If needed, enter the % character in the Tool List ID field to display all the existing tool lists.
6. Select the tool list that you have just created (identifier A_TOOL_LIST) to check that this list contains the tools that you selected from the PPR tree.
Use Tooling Resources from TDM
This task shows some of the capabilities available when the TDM connection is available:● defining feeds and speeds on tools using the TDM database. Feeds and speeds can be selected according to a
specified machine tool and material.
● retrieving tool correctors for tools from the TDM database.
Defining feeds and speeds on tools
1. Double-click a Tool Change activity in the program. The Tool Change dialog box appears at the Tool tab .
2. Select the Tool Assembly tab .
3. Click the Select a tool assembly with query icon opposite Name. The Search Tool Assembly dialog box appears.
Select a machine. This filters the displayed lists to the tool assemblies and tools of that machine.
Note that a material can also be selected to further reduce the lists.
4. Select the desired tool assembly and associated tool.
5. As multiple feeds and speeds can be defined in TDM for an assembly, you must choose on from the displayed list.
The Tool Change dialog box is updated with the selected tooling.
Select the More button then select Feeds and Speeds tab to see the feedrate, cutting speed and other information of the selected tool.
Retrieving tool correctors from the TDM
6. In the Tool tab select the More button. Select the Compensation tab to display the list of tool correctors
retrieved from TDM.
Specify Tool Compensation
This task shows you how to specify tool compensation information.
1. Select the Compensation tab page of the Tool Definition dialog box.
2. Right-click the desired compensation site to either edit or add tool compensation data.
The Compensation Definition dialog box is displayed allowing you to specify the tool's compensation characteristics.
3. You can associate the following information to each compensation site on a tool: ● corrector identifier
● corrector number
● radius number (if Radius compensation is allowed on the machine referenced by the part operation)
● tool diameter in order to specify the exact location of the compensation site (if allowed for the tool). Site P2 of a drill, for example.
The following tool types have only one compensation site. This is the site P1 located at the extremity of the tool.
End mill Face mill Boring tool
Tap
Reamer
Thread mill
The following tool types have more than one compensation site. Some sites are defined by means of a diameter value.
Drill Multi-diameter drill Center drill
Spot drill Boring and chamfering tool T-slotter
Conical mill Countersink Two sides chamfering tool
4. Click OK to update the tool with the desired compensation information.
It is possible to define tool compensation site numbers for all machining operation types, if tool compensation numbers are already defined on the tool used by the machining operation.
In general, the tool compensation site number used by the operation can be specified.For operations such as Boring and Chamfering, Chamfering Two Sides or Contouring (when a T-slotter is used), two tool compensation site numbers can be used during machining.
For turning operations, tools (that is, insert holder and insert) have nine compensation sites P1 to P9. Their position depends on the type of insert used. Please refer to the Lathe Machining User's Guide for more information about cutter compensation.
Define the Tool Axis
This task shows how to define the tool axis orientation by means of the Tool Axis dialog box.
1. Select the tool axis symbol in the machining operation editor.
The Tool Axis dialog box appears.
2. Select one of the modes that are proposed for defining the tool axis.
Manual
Select Manual from the combo, then choose one of the following: ● Components to define the tool axis orientation by means of I, J and K components.
● Angles to define the orientation by means of a rotation specified by means of one or two angles.
❍ Angle 1 about X, Angle 2 about Y the tool axis is a rotated an Angle 1 about the x-axis, then rotated an Angle 2 about the y-axis
● Angle 1 about Z, Angle 2 about X the tool axis is a rotated an Angle 1 about the z-axis, then rotated an Angle 2 about the x-axis
● Angle 1 about Y, Angle 2 about Z the tool axis is a rotated an Angle 1 about the y-axis, then rotated an Angle 2 about the z-axis.
Selection Select Selection from the combo, then:
● if you select a line or linear edge, the tool axis will have the same orientation as that element
● if you select a planar element, the tool axis will be normal to that element.
Points in the view
Select Points in the View from the combo, then select two points in the 3D viewer to define the tool axis orientation.
Feature defined
Select Feature defined from the combo, then select the machining feature in the 3D viewer. For example, if you select an axial machining feature then the axis of the feature is taken as the tool axis.
The tool axis is visualized by means of an arrow. The direction can be reversed by clicking Reverse Direction in the dialog box.
You can also choose to display the tool at the Default position or at a User-defined position.
For a user-defined position, click the [...] button and select the desired position in the 3D viewer.
3. Click OK to accept the specified tool axis orientation.
When a generic machine with 1 or 2 rotary axis on the head is referenced by the Part Operation, you can check machine accessibility when defining the tool axis of a machining operation. The Tool axis dialog box includes more options in this case. Please refer to Check Machine Accessibility at Tool Axis Definition for more information.
Machining Patterns
This task shows you how to create a machining pattern, then use it by referencing it directly in a drilling operation. A machining pattern is a specific machining feature that represents hole positions to be machined.
Create a machining pattern
1. Select Machining Pattern . The Machining Pattern dialog box is displayed.
Click the No Point sensitive text in the dialog box. The Pattern Selection dialog box appears. It lists any available design and machining patterns. In the figure below, there are no machining patterns: Machining Pattern.1 is waiting to be created.
Select one of the design features and close the dialog box. The points in this design pattern will be used to create the machining pattern.
You can also select points in the 3D view to be included in the machining pattern.
It is possible to reference in a machining pattern one or more 3D Wireframe features (that is, Projection, Symmetry, Rotation and Translation operators) containing at least one point.
2. The Machining Pattern dialog box is updated with the number of selected points.
3. Click OK to create the machining pattern.
Use a machining pattern in a machining operation
1. Select Drilling . The Drilling dialog box appears directly at the Geometry tab page.
This tab page includes a sensitive icon to help you specify the geometry of the hole or hole pattern to be machined.
2. Select the red hole depth representation then select the machining pattern from the combo list. The pattern is highlighted in the model.
3. Click OK to create the drilling operation: the holes of the machining pattern will be drilled by this operation.
Manufacturing View
This task shows you how to use the Manufacturing View for feature based NC programming.
You can display the Manufacturing View sorted by Features, Operations, Patterns, Tooling or Machining Features. Just right-click the Manufacturing View to access the following menu:
You can delete unused machining features from the Manufacturing View using the following contextual commands:
1. Select Manufacturing View to display the Manufacturing View.
2. Select a feature in the View (Hole5, for example).
The operations to be created will be attached to this feature.
3. To attach a spot drilling operation to the feature, select Spot Drilling . The Spot Drilling dialog
box appears.
Select the Geometry tab page. This tab page includes a sensitive icon to help you specify the geometry of the hole or hole pattern to be machined.
4. Click the 1 Point sensitive text in the dialog box, then select the points to be included along with Hole5 in the machining pattern (Hole6, Hole7, Hole8, for example).
The icon is updated with this information.
5. Click OK to create the Spot Drilling operation, which is created with Machining Pattern.1 comprising 4 holes. The Manufacturing View is updated.
6. Select Drilling .
In Geometry tab page of the Drilling dialog box, click the No Points sensitive text in the dialog box, then select Machining Pattern.1 from the displayed list.
7. Click OK to create the Drilling operation, which is created with Machining Pattern.2, which references Machining Pattern.1 for the position of the four holes in the pattern. The Manufacturing View is updated.
8. Replay the two operations in the program to check that they both use the selected machining pattern based on the initial feature selection.
If you edit the Machining Pattern.1 (to include more points, for example) both the Spot Drilling and Drilling operations will be updated.
You can use the contextual menu to sort the Manufacturing View by Patterns.
The machining pattern nodes can be expanded to show machining pattern geometry, machining pattern technology, and axial operation information. Right-clicking the machining pattern gives access to contextual commands for copying and creating new patterns.
Machining pattern nodes are also displayed in the Manufacturing View sorted by Machining Features.
If the Part Operation contains parameters, relations or formula, these will be displayed in the Manufacturing View sorted by Features.
Parameters can be added on machining operations and features in the Knowledge Advisor workbench. In this case the Manufacturing View sorted by Machining Features displays a generic node named Parameters under the machining object node. Under this node the parameter node appears with its name, its value and/or its formula (depending on the Knowledge parameter display setting).
In the Machining workbench, you can edit a parameter by double-clicking it. If a formula has been added on the parameter, you can edit it by double-clicking the parameter, then clicking the f(x) button.
Define Macros on a Milling Operation
This task shows you how to define macros on a milling operation.
This is done using the Macros tab page of the machining operation editor. In this example you will add circular approach, circular retract, and linking macros to a Profile Contouring operation.
Predefined Macros
You can use predefined macros. These are made up from one or more paths in a specific order. Just select the desired mode in the Current Macro Toolbox. You can then adjust parameters of the macro (such as path length and feedrate).
User-Built Macros
You can also build your own macros using the Build by user mode.
Depending on the context, you can use the following icons to specify macro paths:
tangent motion
normal motion
axial motion
circular motion
ramping motion
PP word
motion perpendicular to a plane
axial motion to a plane
motion perpendicular to a line
distance along a given direction
tool axis motion
motion to a point.
In addition, the following icons allow you to:
remove all macro paths
remove current macro paths
copy the paths defined on the Approach macro on to the approach paths of other macros or copy the paths defined on the Retract macro on to the retract paths of other macros.
Macro Edition
A sensitive icon representing the elementary paths of the macro will help you to build or edit your macro. The current macro path is colored violet. Right-clicking a macro path gives you access to a contextual menu.
● Deactivate: Deactivates the selected macro path.
● Activate: Activates a path that was previously deactivated.
● Feedrate: Allows you to modify the feedrate type associated to the selected macro path by making a selection in the sub-menu. If local is selected, you can assign a local feedrate value.
● Parameter: Gives access to parameters of the selected macro path.
● Delete: Deletes the selected macro path.
● Insert: Inserts a macro path depending on the type chosen in the sub-menu.
Inherited Macros
If you create a machining operation and there are other operations of the same type in the program, the new operation will inherit the macros used in the most-recently edited operation of the same type. An operation is considered edited when you click OK to quit the operation definition dialog box.
Create a Profile Contouring operation as described in the Prismatic Machining User's Guide.
1. Double-click the Profile Contouring operation in the specification tree to edit that operation.
2.Select the Macros tab page in the operation definition dialog box. The initial status of all the macros in the Macro Management list is Inactive.
3. Right-click the Approach macro line and activate the macro by means of Activate.
In the Current Macro Toolbox select the Circular horizontal axial mode.
A sensitive icon representing the 3 elementary paths of this macro appears.
4. Double-click each elementary path to display a dialog box that allows you to specify the exact characteristics the path.
The following dialog box allows you to specify the exact characteristics of the circular path.
Set the values of the circular approach paths so as to have a 10mm vertical path followed by a 15mm
radius circular path.
5. You can then click Replay to check the circular approach. The status of the macro becomes Up to
date.
6. Activate the Retract macro in the Macro Management list and create a circular retract macro in the same way.
7. Select the Linking Retract macro line in the Macro Management list, then in the Current macro Toolbox select the Axial mode.
8. Double-click the displayed value, then assign a 20mm value to the retract path.
9. Select the Linking Approach line in the Macro Management list, then select the Axial mode. Assign a 20mm value to the approach path.
10. In the Options tab, click the Cornerized clearance with radius checkbox, then enter a corner radius value of 3mm.
11. Click Replay to validate the tool path.
In the Replay dialog box select the By colors mode in order to visualize feedrate changes. The tool path is displayed with the following colors:
● Yellow: approach feedrate
● Green: machining feedrate
● Blue: retract feedrate
● Red: Rapid feedrate
● White: user-defined feedrate.
Please note that transition paths are represented by dashed white lines.
The status of the macros are now Up to date.
12. Click OK to accept the modifications made to the operation.
The operation is updated with the specified macros.
PP Words in Macros
You can insert PP words in macros by double-clicking the green X symbols in the sensitive icons.
The PP Words Selection dialog box is displayed. You can enter the syntax in the following ways:
● enter one or more PP word syntaxes directly in the text field
● click to access the PP words table that is referenced in the current part operation. You can then
select predefined syntaxes from this table using the dialog box that appears.
For Pocketing and Profile Contouring operations, you should select the NC_CUTCOM_ON instruction in the list of available syntaxes if you want the program to interpret cutter compensation automatically (that is, by a CUTCOM/LEFT or CUTCOM/RIGHT instruction). If you choose different syntax in the list, it will be used as selected.The methodology for this is described in the section "How to Generate CUTCOM Syntaxes" in the Prismatic Machining User's Guide.
Default Linking Macros in Case of Collision
If a user-defined linking macro is not collision free, a default linking macro is applied.
Macro Motion Tangent to Tool Path and Parallel to Tool Axis
When the tangent to the tool path is parallel to the tool axis, the following macro motions are replaced by an axial motion:
● tangent motion
● normal motion
● circular motion
● ramping motion.
Define Macros on an Axial Machining Operation
This task shows you how to define macros on an axial machining operation.
This is done using the Macros tab page of the machining operation editor.
Macro Types
The following macro types can be defined on axial machining operations:
● Approach, which is used to approach the operation start point
● Retract, which is used to retract from the operation end point
● Linking, which is generally used to link points of a pattern
● Clearance, which can be used to define the feedrate on the horizontal path between two machining positions.
Some specific axial machining operations support additional macro types:
● Global approach and Global retract (Circular Milling and Thread Milling)The Approach macro is used to approach each drilled point in the pattern, and the Global approach macro is used in the approach of the first drilled point only. For the first point, the Global approach is added before the Approach macro.Similarly, the Retract macro is used to retract from each drilled point, and the Global retract macro is used in the retract from the last drilled point only. For the last point, the Global retract is added after the Retract macro.
● Return between levels (predefined macro in Circular Milling in Standard machining mode only, which is used link two consecutive levels). A special feature of this macro is the capability to specify a feedrate value on the approach motion between levels.
● Return in a level (predefined macro in Circular Milling in Standard machining mode only, which is used to link two consecutive paths in a given level).
User-Built Macros
You can use the following icons for specifying your macro paths:
axial motion
PP word
motion perpendicular to a plane
axial motion to a plane
motion perpendicular to a line
distance along a given direction
tool axis motion
motion to a point.
In addition, the following icons allow you to:
remove all macro motions
remove current macro motion
copy the motions defined on the Approach macro on to the approach motions of other macros or copy the motions defined on the Retract macro on to the retract motions of other macros.
Macro Edition
A sensitive icon representing the elementary paths of the macro will help you to build or edit your macro. The current macro path is colored violet. Right-clicking a macro path gives you access to a contextual menu.
● Deactivate: Deactivates the selected macro path.
● Activate: Activates a path that was previously deactivated
● Feedrate: Allows you to modify the feedrate type associated to the selected macro path by making a selection in the sub-menu. If local is selected, you can assign a local feedrate value.
● Parameter: Gives access to parameters of the selected macro path.
● Delete: Deletes the selected macro path.
● Insert: Inserts a macro path depending on the type chosen in the sub-menu
Inherited Macros
If you create a machining operation and there are other operations of the same type in the program, it will inherit the macros used in the most-recently edited operation of the same type. An operation is considered edited when you click OK to quit the operation definition dialog box.
Create a Drilling operation as described in the Prismatic Machining User's Guide.
1. Double-click the Drilling operation in the specification tree to edit that operation.
2.Select the Macros tab page in the operation definition dialog box. The initial status of all the macros in the Macro Management list is Inactive.
3. Right-click the Approach macro line and activate the macro by means of Activate.
In the Current Macro Toolbox, select Add Axial Motion . A sensitive icon representing the elementary paths of the macro appears.
4. Double-click the displayed value in order to edit it. A dialog box appears to allow you to specify the desired distance (30mm, for example).
5. You can then click Replay to check the axial approach. The status of the macro becomes Up
to date.
6. Activate the Retract macro in the Macro Management list, and create a 30 mm axial retract motion in the same way.
7. Activate the Linking Retract macro in the Macro Management list, and create a 25mm axial retract motion for the linking macro.
In the same way create a 25mm axial motion for the approach portion of the linking macro.
You can then click Replay to check the defined motions. The status of the macros change to
Up to date.
Note that if a jump distance is defined on the operation, it will be used in preference to the linking macro. Similarly if local entry/exit distances are defined on the operation, they will be used in preference to the linking macro.
8. Click Replay to validate the tool path.
In the Replay dialog box select the By colors mode in order to visualize feedrate changes. The tool path is displayed with the following colors:
● Yellow: approach feedrate
● Green: machining feedrate
● Blue: retract feedrate
● Red: Rapid feedrate
● Purple: plunge feedrate
● White: local feedrate.
9. Click OK to accept the modifications made to the operation.
The operation is updated with the specified macros.
PP Words in Macros
You can insert PP words in macros by double-clicking the green X symbols in the sensitive icons.
The PP Words Selection dialog box is displayed. You can enter the syntax in the following ways:
● enter one or more PP word syntaxes directly in the text field
● click to access the PP words table that is referenced in the current part operation. You can
then select predefined syntaxes from this table using the dialog box that appears.
For Circular Milling operations, you should select the NC_CUTCOM_ON instruction in the list of available syntaxes if you want the program to interpret cutter compensation automatically (that is, by a CUTCOM/LEFT or CUTCOM/RIGHT instruction). If you choose different syntax in the list, it will be used as selected.The methodology for this is described in the section "How to Generate CUTCOM Syntaxes" in the Prismatic Machining User's Guide.
Define Macros on a Turning Operation
This task shows you how to define macros on a turning operation.
This is done using the Macros tab page of the machining operation editor. In this example you will add approach and retract macros to a Longitudinal Rough Turning operation.
Predefined Macros
You can use predefined macros such as Direct or Axial-Radial approach. These are made up from one or more paths in a specific order. Just select the desired mode in the Current Macro Toolbox.
You can then adjust parameters (such as feedrate) of the macro.
User-Built Macros
You can also build your own macros using the Build by user mode.
Depending on the context, you can use the following icons to specify macro paths:
tangent motion
normal motion
circular motion
PP word
motion perpendicular to a plane
distance along a given direction
motion to a point.
In addition, the following icons allow you to:
remove all macro paths
remove current macro paths
copy the motions defined on the Approach macro on to the approach motions of other macros or copy the motions defined on the Retract macro on to the retract motions of other macros.
Macro Edition
A sensitive icon representing the elementary paths of the macro will help you to build or edit your macro. The current macro path is colored violet. Right-clicking a macro path gives you access to a contextual menu.
● Deactivate: Deactivates the selected macro path.
● Activate: Activates a path that was previously deactivated.
● Feedrate: Gives access to feedrates for the selected macro path.
● Parameter: Gives access to parameters of the selected macro path.
● Delete: Deletes the selected macro path.
● Insert: Inserts a macro path depending on the type chosen in the sub-menu.
Inherited Macros
If you create a machining operation and there are other operations of the same type in the program, the new operation will inherit the macros used in the most-recently edited operation of the same type. An operation is considered edited when you click OK to quit the operation definition dialog box.
Interruptible Macros
Linking macros, which are available for Rough, Groove, Recess, Ramp Rough and Ramp Recess Turning operations, can be interrupted. Interrupt conditions are defined in the Options tab of the Current Macro Toolbox.
Interrupt modes for Linking macros are:
● No: macro is not interrupted
● Start of path: interrupt macro at the start of the path where the specified time is reached
● End of path: interrupt macro at the end of the path where the specified time is reached
● On time: interrupt macro as soon as the specified time is reached
● Number of paths: interrupt macro at the end of the number of specified paths.
The specified time may correspond to the expected lifetime of the insert, for example. This allows you to interrupt an operation in order to change a worn insert. This is useful when machining very hard materials.
Create a Longitudinal Rough Turning operation as described in the Lathe Machining User's Guide.
1. Double-click the Longitudinal Rough Turning operation in the specification tree to edit that operation.
2.Select the Macros tab page in the operation definition dialog box. The initial status of all the macros in the Macro Management list is Inactive.
3. Right-click the Approach macro line and activate the macro by means of Activate.
In the Current Macro Toolbox, select the Axial radial mode.
A sensitive icon representing the paths of the approach macro appears.
4. Select the point symbol in the sensitive icon then select a point in the 3D window.
The radial and axial paths of the macro are calculated from the selected point to the start point of the operation.
5. You can then click Replay to check the approach motion. The status of the macro becomes
Up to date.
6. Right-click the Retract macro line and activate the macro by means of Activate.
In the Current Macro Toolbox, select the Radial axial mode.
7. Select the point symbol in the sensitive icon then select a point in the 3D window.
The axial and radial paths of the macro are calculated from the end point of the operation to the selected point.
8. Click Replay to validate the tool path. The status of the macro becomes Up to date.
In the Replay dialog box select the By colors mode in order to visualize feedrate changes. The tool path is displayed with the following colors:
● Yellow: approach or lead-in feedrate
● Green: machining feedrate
● Blue: retract feedrate
● Red: Rapid or lift-off feedrate
● White: user-defined feedrate.
Please note that transition paths are represented by dashed white lines.
9. Click OK to accept the modifications made to the operation.
The operation is updated with the specified macros.
PP Words in Macros
You can insert PP words in macros by double-clicking the green X symbols in the sensitive icons.
The PP Words Selection dialog box is displayed. You can enter the syntax in the following ways:
● enter one or more PP word syntaxes directly in the text field
● click to access the PP words table that is referenced in the current part operation.
You can then select predefined syntaxes from this table using the dialog box that appears.
Build and Use a Macros CatalogThis task shows you how to build a macros catalog from the sample catalog MACRO_Settings.catalog delivered with the product in the folder\Startup\Manufacturing\Macros.
You will then assign macros from the new catalog to a machining operation. Create a Profile Contouring operation as described in the Prismatic Machining User's Guide.
1. Double-click the Profile Contouring operation in the specification tree.
2. Select the Macros tab page in the operation definition dialog box. The initial status of all the
macros in the Macro Management list is Inactive.
3. Click Read macro from catalog . The Catalog Browser dialog box appears. If needed, navigate
to \Startup\Manufacturing\Macros\MACRO_Settings.catalog to make it the current catalog.
4. Double-click the Approach family. The AppSTD macro is listed.
Double-click the AppSTD macro. The Macros tab page in the Profile Contouring dialog box is initialized with the AppSTD macro.
5. Edit the AppSTD macro as shown below and rename it Modified AppSTD.
6. Click Save macro in catalog . The Save in Catalog dialog box appears. To create a new catalog,
click the [...] button and create a new catalog (MACRO_Settings_User.catalog in \Startup\Manufacturing\Macros, for example)
7. Repeat this procedure to create user macros in MACRO_Settings_User.catalog for Retract and Return in a Level macros.
Please note that macro types such as Return in a Level, Linking, Return between Levels, and Return to Finish Pass include both approach and retract motions. The approach and retract motions of these macro types can be similar (for example, a circular approach and a circular retract) or different (for example, an axial approach and a circular retract).
When this type of macro is read from a catalog, the entire macro entity comprising the approach and retract components is retrieved.
8. Double-click Pocketing to create a Pocketing operation, then select the Macros tab in the
Pocketing dialog box.
9. Click Read macro from catalog . The Catalog Browser dialog box appears. Navigate to
\Startup\Manufacturing\Macros\MACRO_Settings_User to make it the current catalog.
10.Double-click the Retract family. The Modified RetSTD macro is listed.
Double-click Modified RetSTD. The Macros tab page in the Pocketing dialog box is initialized with the Modified RetSTD macro.
Keep the Catalog Browser dialog box open and repeat this procedure to assign the Approach and Linking in a level macros to the Pocketing operation.
11.Click OK to update the Pocketing operation with the macros from the user-defined catalog.To assign a catalog macro to an operation, you can:
● select the operation in the specification tree
● select Open Catalog from the Auxiliary Commands toolbar
● select the desired macros from the Catalog Browser.
Whenever a macro catalog is created, an associated CATProcess document with the same name is also created in the same folder. It contains data about macro features and so it must not be deleted.
Status Management
This task shows you how the status of manufacturing entities is managed.
1. Select Pocketing .
The Pocketing Definition dialog box appears directly at the Geometry tab page.
The status light on the tab is red indicating that you must specify the geometry to be machined by the operation.
A symbol on the Pocketing entity in the specification tree also indicates that the operation definition is incomplete.
2.Select the required pocket geometry. The status light switches to green on the tab .
The status lights on the Strategy , Feeds and Macros tab are all green indicating that default values are already set for operation creation. You can of course modify these values. Just select the corresponding tab to access these parameters.
The status lights on the Tooling tab is orange. This indicates that, although default tooling is set for the operation, you may want to modify or change the tool or tool assembly for a more suitable one.
3. When all the status lights are green you generally have sufficient conditions to create the operation.
Just click OK to create the operation.
Remember that you should always check the operation's tool path by means of a replay.
The symbol on the Pocketing tree entity is removed when the operation definition is complete.
The operation name in the specification tree is appended with the text Computed after a replay is done on the operation.
User Parameters in PP Instructions
This task shows how to define a PP instruction that references user parameters created in the design part, and output the result in the APT source during the PP instruction processing.
1. Create PP instruction
The PP instruction created in the NC program will contain the name of the parameters to be processed. To be able to identify these parameters, there is a syntax rule.
For example, it is not easy to identify the parameters to process if the PP instruction contains:
INSERT GLengthZHeight
To be consistent with the other NC parameters, the %( characters are used to identify the beginning of the parameter and the ) character is used to identify the end of the parameter.
Refer to PP Tables and Word Syntaxes for more information.
Select PP Instruction . Enter the syntax in the Post-Processor Instruction dialog box that
appears.
Click OK to create the PP instruction in the program.
2. Generate APT source
During APT code generation, when the PP instruction is processed, the batch program will retrieve the parameters to process.
Then a search is done in the design parts related to the Part Operation being processed to find the user parameters and corresponding values. These values will be output in the APT source code.
The APT source file generated corresponding to this example (if Length is 80.5mm and Height 75.8mm) will be the following:
PPRINT OPERATION NAME : Post-Processor Instruction.1$$ Start generation of : Post-Processor Instruction.1INSERT G80.5 Z75.8$$ End of generation of : Post-Processor Instruction.1
The name of the parameter to be retrieved during the processing is the name of the parameter that is created or displayed with the f(x) function. In the case of a Product referencing several parts, the parameter Length of Part1 is identified by Part1\Length. This name will have to be used in the PP instruction definition.
The main advantage of this is that the user parameters can be added in the PP table in order to reuse them later, or in other NC commands.
Verification and SimulationThis section shows you how to use the Machining verification and simulation tools.
Replay Tool Path: Select Replay Tool Path then specify the display options for an animated tool path display of the manufacturing program of machining operation.
Simulate Material Removal in Photo Mode: Select Photo in the Tool Path Replay dialog box to run a photo simulation of the material removal.
● Simulate Material Removal in Video Mode Using Tool Path Data: Select Video in the Tool Path Replay dialog box to run a video simulation of the material removal.
● Simulate Material Removal in Video Mode Using NC Code: Double-click the Manufacturing
Program in the PPR tree to access a dialog box in order to run a video simulation of the material removal using NC code.
Check Machine Accessibility at Tool Axis Definition: Select a generic machine, define the machining axis system, then use Workpiece Automatic Mount command in the Machine Management toolbar.
Check Accessibility on a Generic Machine or a VNC Machine.
Replay a Tool Path
You can replay the tool path of a complete manufacturing program or one or more operations of a program.
This task shows you how to replay a machining operation.
Please note that a number of settings for customizing Tool Path Replay are available in the Tools > Options > Machining > General tab.
1. Select an operation in the specification tree, then select Replay Tool Path . You can also right-click
the operation and select Replay Tool Path.
The operation's tool path is computed interactively and a progress bar appears giving the status of the computation. You can interrupt the computation by clicking Cancel.
The following dialog box appears at the end of the computation. It contains a number of command icons for managing the tool path replay and material removal simulation. The name of the current operation appears in the title bar.
Information that appears in this dialog box includes:
● current feedrate
● current tool tip position (X, Y, Z) and tool axis orientation (I, J, K)
● machining time and total timeTotal time is machining time plus non-machining time (that is, time spent in transition paths and so on).
These times are displayed in hh:mm:ss format.
2. Choose the desired Replay mode by selecting one of the drop down icons:
Point to Point
Continuous
Plane by Plane:
The tool path is displayed by plane. This is suitable for multi-level operations such as Pocketing or Roughing.Note that consecutive portions of the tool path are displayed at each click on the forward (or backward) control button. All parts of the tool path on the same level may not be displayed together.
Transition paths may be displayed as you click forward (or backward).Approach and retract paths are displayed in a lower intensity.
Sectioning:
Replay by sectioning plane. This is suitable for multi-level operations such as Pocketing or Roughing.
In this mode the tool path of the operation is sectioned at each level. The program selects a suitable direction to define the normal to the sectioning planes.The replay progresses level by level along this normal at each click on the forward (or backward) control button.All the portions of the tool path are displayed in a given sectioning plane.
In Sectioning replay mode, you can choose to display the machined surface with or without the tool axes (see the Tool Visualization modes below).
Feedrate by Feedrate.
Syntax by Syntax:
The replay stops each time a PP instruction is met and the syntax of the instruction is displayed on the trajectory (for example, CYCLE/DRILL,0.000,1.000).
3. Choose the desired Tool Visualization mode by selecting one of the drop down icons:
Tool displayed at last position only
Tool axis displayed at each position
Tool displayed at each position
Machined surface is displayed in Sectioning replay mode.
Machined surface and tool axes are displayed in Sectioning replay mode.
4. Choose the desired Color mode by selecting one of the drop down icons:
Tool path displayed in same color (green by default)
Tool path displayed in different colors for different feedrates. The colors are initialized as
follows but they can be customized under the Tools > Options > Machining > General tab.
Yellow: approach or lead-in feedrateGreen: machining feedrateBlue: retract or lift-off feedrateRed: Rapid feedrateCyan: finishing feedrateMagenta: plunge feedrateCyan: chamfering feedrateMagenta: air cutting feedrate.
Please note that a transition path from operation A to operation B is represented by a dashed line whose color depends on the feedrate. This feedrate is determined as follows:
● If a clearance macro is activated operation B, the feedrate of the clearance path is used for the transition path.
● If no clearance macro is activated on operation B, the feedrate depends on the setting of the Set Rapid feedrate at start of operations option in the Generate NC Output dialog box.
❍ If the option is set, a Rapid feedrate (red) is used for the transition path
❍ If the option is not set, the first feedrate defined on operation B is used for the transition path (for example, yellow for approach or green for machining).
5. For surface machining type operations only, choose the desired Point Display mode by selecting one of the drop down icons:
Trajectory of the contact point is displayed
Trajectory of either the tool tip or the tool center point is displayed
Trajectories of the contact point and either the tool tip or the tool center point is displayed
Trajectory of either the contact point or either the tool tip or the tool center point is
displayed.
6. Choose the desired TRACUT Display mode by selecting one of the drop down icons:
TRACUT instructions are taken into account to display the tool path
TRACUT instructions are not taken into account to display the tool path.
7. You can control the tool path replay using the following control buttons and keyboard shortcuts:
or F5 key to position the tool at the operation start point
or F6 key to run the replay backward
or F4 key to request a pause in the replay
or F7 key to run the replay forward
or F8 key to go to the operation end point.
If the F7 or F6 key is kept pressed:
● for point by point, plane by plane, feedrate by feedrate, and syntax by syntax, replay steps are done continuously one after the other
● for continuous replay, the animation speed increases at each refresh.
You can customize the function keys to the replay buttons in the CATMfgReplayToolPathPanel.CATRsc resource file.
8. Click OK to quit the replay mode.
Tool Path Replay Considerations
● If the operation has been deactivated by means of the Deactivate command, it cannot be replayed. If you want to replay the operation, you must reactivate it using the Activate command.Similarly, if the manufacturing program has been deactivated, it cannot be replayed. If you want to replay the program, you must reactivate it.
● If a Profile Contouring operation was created with the cutter profile output option, both the cutter profile and tip trajectory will be displayed in the replay.
● If a user-defined tool representation is related to the operation, that tool will be displayed in the replay.
● You can also access the Replay capability directly from the machining operation editor or from the Manufacturing Program dialog box.
● You can select several machining operations in the specification tree in order to simultaneously replay the tool paths associated to these operations.
● When replaying large tool paths, you can control the animation speed using the Animation speed slider: ❍ in the first half of the slider, speed goes from one point to 10 points
❍ in the second half of the slider, speed goes from 10 points to N/10 (where N is the total number of points).
Tool Path Computation when Hidden Geometry is Present
The following rules summarize the tool path computation behavior depending on the Hide/Show status of selected elements.
● Rule 1: If you select a Body or OpenBody, and use it as Part, Check or Fixture in a machining operation, the tool path will use the Body or OpenBody, regardless of whether it is in Show or Hide status.
● Rule 2: If you select a Body or OpenBody, and use faces (which are sub-elements of this Body or OpenBody) as Part, Check or Fixture in a machining operation, then only the sub-elements which are in
Show status will be used during tool path computation. Hidden sub-elements will be ignored in the computation.
● Rule 3: If you select explicitly a set of faces and use them as Part, Check or Fixture in a machining operation, the tool path will use these faces, regardless of whether they are in Show or Hide status.
Material Removal Simulation
You can use the Photo commands to simulate the material removed by machining operations in Photo
mode (this is a P2 functionality).
You can use the Video commands to simulate the material removed by machining operations in Video
mode (this is a P2 functionality).
Machine Accessibility
You can use Check Reachability to check the accessibility of the part on a machine.
Please refer to Accessibility on a Generic Machine (this is a P2 functionality).
Start Machine Simulation
If the NC Machine Tool Simulation product is installed, you can use this icon to switch to the NC Machine Tool Simulation workbench. Please refer to the NC Machine Tool Simulation User's Guide for more information.
Photo Mode for Material Removal Simulation
This task shows you how to simulate the material removed by a machining operation in Photo mode.
For more information about this mode please refer to:
● Tools > Options > Machining > Photo/Video tab for information about the available customizing facilities
● Material Removal Simulation for information about the methodology to employ for user representation of tools, stock considerations, and so on.
Select an operation in your program, then select Tool Path Replay . You can also right-click the operation in the tree
and select Tool Path Replay. A dialog box appears for managing the replay and simulation.
1. Select Photo . The Setup Editor window switches to a window entitled Photo that shows the result of the material
removal.
If needed, you can update the program data and the display by clicking on Photo again.
At any time you can pick on the surface of the workpiece. A dialog box appears giving information about the pick point.
● The operation used for removing material.
● The normal deviation between the workpiece and the design part.
● The X, Y, and Z coordinates of the pick point.
● The tool used for machining.
2. Zoom in the rounded corner of the Photo, and right-click Closeup.
The Closeup shows a more precise Photo of the rounded corner.
Just right-click anywhere on the stock to return to the original Photo.
3. Select Analyze to analyze the result of the simulation. This is done by comparing the machined part with the design
part. The Analysis dialog box appears.
4. Select the desired fault types to be analyzed and specify the Tolerance for the comparison.
The fault filter setting permits three types of faults:
Remaining Material: areas where the tool has left behind material on the workpiece.
Gouge: areas where the tool has removed excess material from the workpiece.
Tool Clash: areas where the tool collided with the workpiece during a rapid move.
Remaining material, tool clashes and gouges will be displayed as colored zones according to the specified tolerances.
5. Click the Apply button.
The machined part is compared with the design part based on the specified settings.
Any point on the machined surface of the workpiece is considered to be part of a fault if the normal distance (normal deviation) to the design part surface is greater than the specified tolerance.
Results of the comparison are reflected on the workpiece, based on the extent of severity of the fault and the customized color settings.
The list of detected faults are listed in the Fault combo box.
The faults are ordered in such a way that Tool Clashes appear at the top of the list followed by Gouges then Remaining Material. The gouges and remaining material are in turn sorted on the basis of decreasing fault area.
On selecting a fault from the Faults combo box, the region corresponding to the fault is indicated by a "Fault Indicator" bounding box on the workpiece.
Other detailed information about the selected fault is displayed.
6. Click Cancel to quit the Analysis mode and return to the dialog box for managing the replay and simulation.
7. Click OK to quit the dialog box.
Photo Mode Considerations
Please note the following points.● Turning operations and multi-axis machining operations are not supported.
● Boring Bars and Two Sides Chamfering tools are not supported for Photo mode.
● If you select a Body (which may be in Show or Hide mode) as Stock, Design or Fixture then only sub-elements of the Body that are in Show mode will be used during material removal simulation. Hidden sub-elements will be ignored in the simulation.
● Check surfaces are not taken into account in Photo mode.
● When a Photo mode analysis is performed on vertical walls (walls parallel to the Z-axis of the Part Operation's machining axis system), the results of the analysis such as Pick Point Information, Analysis, Fault will not be accurate. This is a program limitation.
● Photo simulation is possible along any fixed axis.This means that you can simulate machining operations (MO) whose tool axis is different from the Z-axis of the Part Operation's machining axis system.
Case1: All MOs have constant identical axis not equal to Setup Z-axis.Photo simulation can be done on any one or all of these MOs.
Case 2: All MOs have constant but different axes not equal to Setup Z-axis.Photo simulation can be done on any one of these MOs.
● If a multi-axis machining operation is selected, an error message is issued indicating that these operations are not supported. The Photo simulation will be done on the first operation previous to the selected operation (going from the selected operation to the PO) that has a non-changing tool axis.
Video Mode for Material Removal Simulation Using Tool Path Data
This task shows you how to simulate the material removed by machining operations in Video mode using tool path data.
For more information about this mode please refer to:
● Tools > Options > Machining > Photo/Video tab for information about the available customizing facilities
● Material Removal Simulation for information about the methodology to employ for user representation of tools, stock considerations, and so on
● the NC Manufacturing Verification User's Guide for more information about the additional capabilities available if the NC Manufacturing Verification product is installed.
Note: It is also possible to simulate material removal in Video mode using NC code. See Video Mode for Material Removal Simulation Using NC Code.
1. Open the Processfinal.CATProcess document. The Setup Editor window appears showing the PPR tree with the Manufacturing Program.
The part is displayed held in place by fixtures. The stock is in Hide mode.
2. Right-click the Facing.1 operation in the tree, then select Tool Path Replay . The Replay dialog box
appears.
There are three Video simulation modes:
Full Video: Video simulation for complete program or part operation (depending on
setting)
Video from Last Saved Result: Video simulation from saved result of the previous Video
simulation.
Mixed Photo/Video: Photo simulation is up to the operation just before the selected
operation, then Video simulation is done on the selected operation.
The rest of the scenario illustrates how to use Full Video and Video from Last Saved Result.
3. Select Full Video . The Setup Editor window switches to a window entitled Video.
4. Select Video Options to display the Video Options dialog box.
● Select the Stop at tool change checkbox if you want the simulation to stop each time a tool change is encountered in the program.
● Select the desired Collisions detection option to either: ❍ ignore collisions during the Video simulation
❍ stop the Video simulation at the first collision
❍ continue the Video simulation even when collisions are detected. In this case, you can consult the list of collisions at the end of the simulation.
● Select the Touch is collision checkbox if you want touch (or contact) type of collision to be detected.
● Select the Video simulation in protected mode checkbox to continue the Video simulation by skipping any cuts that cause errors.
5. Press the control button to run the material removal simulation of the Facing.1 operation.
You can use the Tool animation replay buttons or keyboard shortcuts to control the material simulation Video:
or F5 key to position the tool at the start of the simulation
or F6 key to run the simulation backward
or F4 key to request a pause in the simulation
or F7 key to run the simulation forward
or F8 key to run forward up to the end of simulation. No intermediate graphics update is
made to save on rendering time. A progress indicator shows the computation progression and the final machined stock appears.
If the Replay mode is set to:
● Point to Point, the number of points value specifies the number of points to be run through at each step of the replay.
● Continuous, the slider position is taken into account for adjusting the speed of the simulation. For improved performance, intermediate graphics are not updated when the slider is used to increase simulation speed.
6. Click Associate Video Result to Machining Operation to associate the Video result to the
operation. Please note that Video results are stored in the NC Code output directory.
A check-mark appears on the Facing.1 operation in the tree.
Click OK to quit the Replay dialog box.
7. Right-click the Pocketing.2 operation, then select Tool Path Replay .
8. Select Video from Last Saved Result . A material removal is displayed starting from the previous
saved result.
The figure below shows the state of the replay at the end of the Pocketing.1 operation.
The figure below shows the state of the replay at the end of the Pocketing.2 operation.
9. Repeat the sequence of steps described above to associate the Video result to the Pocketing.2 operation.
A check-mark now appears on the Pocketing.2 operation in the tree.
Then run the simulation up to the last operation in the program.
10. Click Video Collision Report to display a dialog box showing any collisions detected during the
Video simulation.
Note that:
● the Collision detection setting must be set to Continue.
● the tool holder is taken into account during collision checking.
11. If needed, save the result of the Video simulation in a CATProduct. This result can be used as initial stock in another Part Operation or as stock in a Roughing operation.
Click Save Video Result in a CATProduct .
A dialog box appears allowing you to save the Video result in a CATProduct.
Please note the following points about this capability.
● It combines previous version Save Video Result in CGR (CATIA graphic representation) and Associate Video Result to Machining Operation (WPC information).This helps to avoid open stock problems when used in another Setup thanks to precision of the WPC data.
● Result can be saved in interactive (as shown above) or batch mode (see Generate a CATProduct in Batch Mode).
● You can add the CATProduct to the PPR tree using Insert > Existing Component or the Product Context contextual command.
12. Click OK to quit the Replay dialog box.
Video Mode Considerations
● Reduced Video simulation performance may be experienced in the following cases:
❍ When a Non cutting diameter is specified on an end mill or a face mill. To improve Video performance, if possible, try setting the value of this parameter to zero.
❍ When a user representation (CATProduct or CATPart) is associated to the tool. To improve Video performance, if possible, try running the Video without the user representation.
● The Video result may become incoherent if operations used in its creation are modified. Incoherent Video results should be removed by the user.
● The Remove Video Result contextual command allows you to remove a Video result that is associated an operation. An operation that has an associated Video result is indicated by a check-mark in the tree.
● For turning operations: ❍ Any collisions between the part and the 2D profile of the lathe insert and insert holder are
detected.
❍ For user representations of lathe tools, the insert holder does not participate in material removal (regardless of Rapid or Feed mode) and is used only in collision detection.
● Boring Bars and Two Sides Chamfering tools are not collision checked in Video mode.
● If you select a Body (which may be in Show or Hide mode) as Stock, Design or Fixture then only sub-elements of the Body that are in Show mode will be used during material removal simulation. Hidden sub-elements will be ignored in the simulation.
Video Mode for Material Removal Simulation Using NC Code
This task shows you how to simulate the material removed by machining operations in Video mode using NC code.
Note: It is also possible to simulate material removal in Video mode using tool path data. Please refer to Video Mode for Material Removal Simulation Using Tool Path Data for specific information about that operating mode and general information about Video material removal simulation.
1. Open the Processfinal.CATProcess document. The Setup Editor window appears showing the PPR tree with the Manufacturing Program.
Please note that the machine referenced in the Part Operation uses a default 3-axis machine. This type of machine is not suitable for simulating material removal in Video mode using NC code and so must be changed. It must be a CATProduct representation built using the NC Tool Machine Builder application, for example.
Select a Suitable Machine Tool and Set NC Parameters
2. Double-click Part Operation.1 in the tree, then click Machine in the Part Operation dialog box.
In the Machine Editor:
● Click then select the Mill_5axis.CATProduct machine in the
..\startup\Manufacturing\Samples\NCMachineToollib\DEVICES folder.
● Select a suitable Controller Emulator and Post Processor: Note that a Controller Emulator/Post Processor vendor must be set in the Tools > Options > Machining > Output tab.
● Select a suitable Post Processor words table: Sample PP word tables are delivered with the product in the ..\startup\manufacturing\PPTables folder.
● Select ISO (that is, NC code) as NC data type.
● Click OK to assign the machine to the Part Operation.
Position the Workpiece on the Machine3.
Position the part on the machine table using Workpiece Automatic Mount of the Machine
Management toolbar.
Note: You may also need to re-position the Machining axis system. To do this, double-click the green machining axis in the 3D view, and re-position the axis using the dedicated dialog box.
Generate Program Tool Path Data and Generate NC Code
4. Right-click Manufacturing Program.1 in the tree and select Compute Tool Path. Select the Force computation option in the pop-up that appears.
Right-click Manufacturing Program.1 in the tree and select Generate NC Code Interactively. Set the following options in the dialog box that appears.
Simulate the Program Using NC Code
5. Double-click Manufacturing Program.1 in the tree. In the Manufacturing Program dialog box, select the NC Code Based Simulation check box and select the NC code file that you generated in the previous step.
See Manufacturing Program for more information about this dialog box.
6. Select Video . The Setup Editor window switches to a window entitled Video.
Two dialog boxes appear for running the simulation:
● Replay dialog box containing tool animation control buttons and other command icons.The capabilities are described in Video Mode for Material Removal Simulation Using Tool Path Data and Replay a Tool Path.
● ISO Panel dialog box containing information about the NC code.
Click the control button to run the material removal simulation of the first machining operation
(Facing.1).
As the ISO panel highlights each line of the data while the video simulation represents the code graphically, the Machine Operation field shows the operation associated with the line of code. Conversely, you can select a single line of code, and the geometric data shows the simulation at that point in the code.
7. Continue the Video simulation for the remainder of the program using the control buttons.
The ISO Panel is displayed, It has two parts:● ISO code area, which contains the line number, a collision icon (if collision is detected), and the ISO data.
This part also has a search function and lists the machining operation associated with each ISO line number.
● Collision Information area, which gives information about any detected collisions.
Please refer to NC Machine Tool Path User's Guide for more information about this panel.
Check Machine Accessibility at Tool Axis Definition
This task shows how to check machine accessibility when defining the tool axis of a machining operation. This can be done on a generic machine with 1 or 2 rotary axis on the head.
1. Open the AccessibilityChecking.CATPart document, then select NC Manufacturing > Surface Machining from the Start menu.
2. To assign a machine the Part Operation:● Double-click the Part Operation in the tree.
● Click Machine in the Part Operation dialog box.
● In the Machine Editor dialog box, click then select the XYZCA.CATProduct machine in the
..\startup\Manufacturing\Samples\NCMachineToollib\DEVICES folder.
● Click OK in the Machine Editor dialog box.
3. In the Part Operation dialog box click Machining Axis . Select the axis system on the part as
the machining axis system.4. Click OK in the Part Operation dialog box: the machine is added to the Resource List. The machine
and the part are displayed together in the 3D window.
5.Select the Workpiece Automatic Mount in the Machine Management toolbar. The part snaps
onto the machine table as follows.
Note that you can use the contextual menu in the 3D window to hide parts of the machine (for example, to display the machine head only).
6. Select Sweeping . In the Sweeping dialog box that appears, select the Strategy tab page
. Click on the tool axis symbol in the sensitive icon.
The Tool Axis dialog box appears. 7. Select the Manual mode and activate the Machine rotary axis checkbox.
Select the Display tool and Display machine checkboxes.
Click the User-defined position [...] button and select a position on the face to be machined. This is the position that the machine will try to reach.
The machine is positioned according to the current tool axis definition.
8. Enter values for the rotary axis 4 and 5 to vary the machine head position.
9. Continue to enter values for the rotary axis 4 and 5 to find the best position for machining. Note that the I, J, K components of the tool axis are updated in accordance with the entered angle values.
You can check visually that the position is collision free.
10. Click OK in the dialog box to return to the Sweeping operation editor to continue definition of the machining operation.
The machine head returns to its original position.
Generic Machine Accessibility (CATProduct)
This task shows how to check accessibility on a generic machine. This involves:
● loading part and opening the desired NC workbench
● using the command of the Machine Management toolbar for automatically mounting the part on the machine
● checking accessibility at the current tool position by means of a replay.
1. Open the AccessibilityChecking.CATPart document, then select NC Manufacturing > Prismatic Machining from the Start menu.
2. Double-click the Part Operation in the tree.
In the Part Operation dialog box click Machine .
In the Machine Editor dialog box, click then select the Mill_5axis.CATProduct machine in the
..\startup\Manufacturing\Samples\NCMachineToollib\DEVICES folder. Click OK to assign the machine to the Part Operation.
3. In the Part Operation dialog box click Machining Axis . Select the axis system on the part as
the machining axis system.4. Click OK in the Part Operation dialog box: the machine is added to the Resource List. The machine
and the part are displayed together in the 3D window.
5.Select Workpiece Automatic Mount . The part (child object) snaps onto the machine table
(parent object) as follows.
You can use Fit All In to reframe the part in the 3D window
6. Create a machining operation (a pocketing operation, for example).7. Activate the Replay dialog box, then click Check Reachability to verify that the machine can
effectively reach the part at the current tool position.
A Check pop-up appears indicating whether the position is reachable:
● If reachable, then the tool, part and machine are displayed at that position.
● If the position is out of limits or unreachable, then the part and machine are displayed with the tool at the home position.
8. Click OK in the Check dialog box to return to the replay mode.
VNC Machine Accessibility (*.dev device)
This task shows how to check accessibility on a VNC machine. This involves:
● customizing the machine tool environment
● loading part and opening the desired NC workbench
● using the commands of the Machine Management toolbar for:
❍ importing resources
❍ positioning the part on the machine table
❍ attaching the part on the machine table
● checking accessibility at the current tool position by means of a replay.
1. Select Tools > Options from the menu bar. Select the Compatibility category in the tree to the left.
In the Root Libraries field of the DELMIA D5 tab page, enter the path of a library that will allow importing DELMIA/Deneb device files (for example, ..\startup\Manufacturing\Samples\NCMachineToollib).
Click OK to validate this choice.
2. Open the AccessibilityChecking.CATPart document, then select NC Manufacturing > Prismatic Machining from the Start menu.
3. Select the Resource Context to import a VNC machine.
In the dialog box that appears, select Files of type: (*.dev) Deneb devices then open the machine 3_2_axis.dev in the NCMachineToollib\Devices folder. This machine is added to the Resource List.
4. Double-click the Part Operation in the tree, then select Machine .
In the Machine Editor dialog box, click then select the Makino_5.1 VNC machine in the tree.
Click OK to assign the machine to the Part Operation.
5. Click OK in the Part Operation dialog box: the machine is added to the Resource List. The machine and the part are displayed together in the 3D window.
6. Select Snap then position the part on the machine table as follows.
● Select the part in the 3D window. A square symbol appears.
● Use the mouse to move the symbol and click when the square is located on the underside of the part.
● An orientation symbol and the Define Reference Plane dialog box appear. Click OK in the dialog
box.
● Select the machine table in the 3D window. A square symbol appears.
● Use the mouse to move the symbol and click when the square is located on the center of the table.
● An orientation symbol and the Define Reference Plane dialog box appear. Click OK in the dialog
box. The part is then snapped onto the table.
● Click Select to exit the Snap command.
7. Select Attach then attach the part and the machine as follows.
● Select the table (parent object) then the part (child object).
● Click OK in the Child Selection dialog box.
You can use Fit All In to reframe the part in the 3D window.
8. Create a machining operation (a pocketing operation, for example).
9. Activate the Replay dialog box, then click Check Reachability to verify that the machine can
effectively reach the part at the current tool position.
A Check pop-up appears indicating whether the position is reachable:
● If reachable, then the tool, part and machine are displayed at that position.
● If the position is out of limits or unreachable, then the part and machine are displayed with the tool at the home position.
10. Click OK in the Check dialog box to return to the replay mode.
Program OutputThis section shows you how to use the various tools provided with Machining Solutions for producing output data.
Generate NC Output in Interactive Mode: Select Generate NC Code Interactively then select the manufacturing program to be processed and define processing options.
● Generate APT Source Code in Batch Mode: Select Generate NC Output in Batch Mode then select the manufacturing program to be processed and define the APT source processing options.
● Generate Clfile Code in Batch Mode: Select Generate NC Output in Batch Mode then select the manufacturing program to be processed and define the Clfile processing options.
● Generate NC Code in Batch Mode: Select Generate NC Output in Batch Mode then select the manufacturing program to be processed and define the NC code processing options.
● Generate a CATProduct In-Process Model in Batch Mode: Select Generate NC Code in Batch Mode then select the manufacturing program to be processed and specify the processing options for generating a CATProduct in-process model.
● MfgBatch utility program that allows you to generate NC data files from a manufacturing
program by means of an executable program under Windows or a shell under UNIX.
Batch Queue Management: Manage tool path computation outside the interactive CATIA session, with the possibility of scheduling the execution of several batch jobs.
Generate NC Documentation: Select Generate Documentation to produce shop floor documentation in HTML format.
Import an APT Source into the Program: Select the APT Import contextual command to insert an existing APT source into the current manufacturing program.
Batch Mode Commands and Shareable Licenses
Please note that it is not possible to use batch mode commands with product licenses that are shareable.
Therefore, it is not possible to generate a tool path using the Manage Batch Queue or Generate NC Code in Batch Mode command if the product license is shareable.
Generate NC Output Interactively
This task shows you how to generate NC data from the program in interactive mode.
For best results, you should first verify the operations of your program by means of a replay or simulation. There should be no operations to be updated or in an undefined state.
The procedure for generating NC data in interactive mode is the same as in batch mode.
However, in interactive mode:
● it is the current CATProcess document that is processed
● Save input CATProcess means Save As
● Lock operations checkbox can be set even if Save document is not activated.
1. Select the Manufacturing Program entity in the tree, then select Generate NC Code Interactively
. You can also use the right mouse key on the Manufacturing Program entity to select
Generate NC Code Interactively.
The Generate NC Output Interactively dialog box appears.
You can choose to process one part operation or one or more machining programs in the current CATProcess document.
2. Depending on the desired NC data type the procedure is the same as that described in:● Generate APT Source Code in Batch Mode
● Generate Clfile Code in Batch Mode
● Generate NC Code in Batch Mode
● Generate a CATProduct in Batch Mode.
3. Click the Output File [...] button to select the folder where you want the file to be saved and specify the name of the file.
4. Click Execute to generate the NC data.
Generate APT Source File in Batch Mode
This task shows you how to generate NC code in APT format from the manufacturing program or part operation in batch mode.
For best results, you should first verify the machining operations of your program by means of a replay or simulation. There should be no operations to be updated or in an undefined state.
Always save your program modifications before generating the NC code.
1. Select Generate NC Code in Batch Mode in the NC Output Management toolbar.
The following dialog box appears.
In the In/Out tab page...
2. Select the manufacturing document to be processed using the Input CATProcess [...] button. The current document is proposed by default.
3. Select the type of NC entity to be processed.● Part Operations: Select one part operation in the input CATProcess. In this case all the
manufacturing programs of the selected part operation will be processed.
● Manufacturing Programs: Select one or more manufacturing programs in the input CATProcess.
4. Select APT as the NC data type that you want to generate.
5. Select the desired One file... option.● For all selected programs to generate a single APT source for all the selected
manufacturing programs.
● By program to generate a single APT source for each selected manufacturing program.
● By Machining operation to generate a single APT source for each machining operation in the selected manufacturing programs.Note that this option is not supported in programs containing Copy or Tracut Operators.
6. To store the resulting NC data file at the same location as the input CATProcess, select the Store at same location as the CATProcess check box.
Otherwise, specify the Output file where you want the NC data to be written using the [...] button.
A default name is proposed for the output file (for example, Process1_Manufacturing_Program_1.aptsource). This name can be modified directly in the Output File text field.
7. To authorize overwriting an existing like-named APT source, select the Replace like-named file check box.
8. To write the CATProcess document after processing, select the Save Input CATProcess check box. Specify where you want to save this document using the [...] button.
9. To authorize overwriting an existing like-named CATProcess document, select the Replace like-named CATProcess check box.
10. To attach the generated output file to the first selected manufacturing program, select the Associate output NC file to the program check box.
To access the output file, right-click the manufacturing program and select Display NC File.
11. Select the Lock operations check box to lock all the machining operations after processing. Refer to Locked Machining Operations for more information.
In the Tool Motions tab page...
12. Specify the options to be used for processing the tool motions.
Some of these options can be set to take machine characteristics into account: set the option to From Machine.
Refer to NC Data Options for more information.
In the Formatting tab page...
13. Specify the formatting options. These options determine how information is to be presented on the output file (for example, general information statements to be presented with the PPRINT syntax).
Refer to NC Data Options for more information.
14. Click Execute to generate the APT source file.
Refer to Syntax of Generated APT Instructions for more information about the NC data output.
A log file is also generated in the resulting NC data folder. It contains machining time information similar to that obtained during the interactive tool path replay.
Generate Clfile Code in Batch Mode
This task shows you how to generate NC code in Clfile format from the program in batch mode.
Always save your program modifications before generating the NC code.
For best results, you should first verify the operations of your program by means of a replay or simulation. There should be no operations to be updated or in an undefined state.
In order to generate clfile output, the PP table associated to the machine must be accessible in read mode. Otherwise an error message is issued in the log file.
1. Select Generate NC Code in Batch Mode . The following dialog box appears.
In the In/Out tab page...
2. Select the manufacturing document to be processed using the Input CATProcess [...] button. The current document is proposed by default.
Select the type of NC entity to be processed. This can be:
● one part operation in the input CATProcess. In this case all the manufacturing programs of the selected part operation will be processed.
● one or more manufacturing programs in the input CATProcess.
3. Select CLF as the NC data type that you want to generate.
4. Select the desired One file... option to generate a single clfile:● for all the selected manufacturing programs
● for each selected manufacturing program
● or for each machining operation in the selected manufacturing programs.Please note that this option is not supported in programs containing Copy or Tracut Operators.
5. To store the resulting NC data file at the same location as the input CATProcess, just select the Store at same location as the CATProcess checkbox.
Otherwise, specify the Output file where you want the NC data to be written using the [...] button.
A default name is proposed for the output file (for example, Process1_Manufacturing_Program_1.clfile). This name can be modified directly in the Output File text field.
6. Select the Replace like-named file checkbox if you want to authorize overwriting an existing like-named clfile.
7. If needed, you can choose to write the CATProcess document after processing. Just select the Save Input CATProcess checkbox and specify where you want to save it using the [...] button.
8. Select the Replace like-named CATProcess checkbox if you want to authorize overwriting an existing like-named CATProcess document.
9. You can attach the generated output file to the first selected manufacturing program by selecting the Associate output NC file to the program checkbox.
The output file can be accessed by right-clicking the manufacturing program and selecting Display NC File.
10. You can select the Lock operations checkbox to lock all the machining operations after processing. Please refer to Locked Machining Operations for more information.
In the Tool Motions tab page...
11. Specify the options to be used in the processing.
Some of these options take machine characteristics into account (for example, Circular Interpolation).
Please refer to NC Data Options for more information.
In the Formatting tab page...
12. Specify the formatting options. These options determine how information is to be presented on the output file (for example, information statements to be presented with the PPRINT syntax).
Please refer to NC Data Options for more information.
13. Click Execute to request computation of the Clfile code.
Please refer to Clfile Formats for more information about the NC data output.
A log file is also generated in the resulting NC data folder. It contains machining time information similar to that obtained during the interactive tool path replay.
Generate NC Code in Batch Mode
This task shows you how to generate NC code from the manufacturing program or part operation in batch mode.
Post Processors are provided by Cenit, Intelligent Manufacturing Software (IMS), and ICAM Technologies Corporation.
For information about how to acquire Post Processor parameters files that provide machine specific NC code output, please contact your IBM representative.
Select the type of Post Processor solution using Tools > Options > Machining > Output tab. If the output option is set to None, you will not be able to generate NC code.
Cenit Post-Processor Solution
Sample Cenit Post Processor parameter files are delivered with the product in the folder\Startup\Manufacturing\PPParwhich provides NC output for various machine types. To execute your own PP you must copy it into this folder.
You can use PPs that include external macros. In this case, you should define them in the PP in:
Modify postprocessor // Define NC-blocks // Index : MACRO APT WORDS
and then copy these macros in the same folder as the PP.
IMS Post-Processor Solution
Sample IMS Post Processor parameter files are delivered with the product in the folder\Startup\Manufacturing\IMSParwhich provides NC output for various machine types. To execute your own PP you must copy it into this folder.
The IMSPar folder must be accessible in Read/Write mode.
ICAM Post-Processor Solution
Sample ICAM Post Processor parameter files are delivered with the product in the folder\Startup\Manufacturing\ICAMParwhich provides NC output for various machine types. To execute your own PP you must copy it into this folder.
Always save your program modifications before generating NC code.
For best results, you should first verify the operations of your program by means of a replay or simulation. There should be no operations to be updated or in an undefined state.
1. Select Generate NC Code in Batch Mode . The following dialog box appears.
In the In/Out tab page...
2. Select the manufacturing document to be processed using the Input CATProcess [...] button. The current document is proposed by default.
Select the type of NC entity to be processed. This can be:
● one part operation in the input CATProcess. In this case all the manufacturing programs of the selected part operation will be processed.
● one or more manufacturing programs in the input CATProcess.
3. Select NC Code as the NC data type that you want to generate.
4. Select the desired One file... option to generate a single NC code file:● for all the selected manufacturing programs
● for each selected manufacturing program
● or for each machining operation in the selected manufacturing programs.Please note that this option is not supported in programs containing Copy or Tracut Operators.
5. To store the resulting NC data file at the same location as the input CATProcess, just select the Store at same location as the CATProcess checkbox.
Otherwise, specify the Output file where you want the NC data to be written using the [...] button.
A default name is proposed for the output file (for example, Process1_Manufacturing_Program_1.CATNCCode). This name can be modified directly in the Output File text field.
6. Select the Replace like-named file checkbox if you want to authorize overwriting an existing like-named NC code file.
7. If needed, you can choose to write the CATProcess document after processing. Just select the Save Input CATProcess checkbox and specify where you want to save it using the [...] button.
8. Select the Replace like-named CATProcess checkbox if you want to authorize overwriting an existing like-named CATProcess document.
9. You can attach the generated output file to the first selected manufacturing program by selecting the Associate output NC file to the program checkbox.
The output file can be accessed by right-clicking the manufacturing program and selecting Display NC File.
10. You can select the Lock operations checkbox to lock all the machining operations after processing. Please refer to Locked Machining Operations for more information.
In the Tool Motions and Formatting tab pages...
Certain option settings may have an influence on the generated NC code. Please refer to NC Data Options for more information.
In the NC Code tab page...
11. Use the combo to select the desired Post Processor parameters file.
12. Click Execute to request computation of the NC code.
Generate a CATProduct In-Process Model in Batch Mode
This task shows you how to generate a CATProduct in-process model from the program in batch mode.
Always save your program modifications before running a batch execution.
For best results, you should first verify the operations of your program by means of a replay or simulation. There should be no operations to be updated or in an undefined state.
The batch report includes a log file. In Tools > Options > Machining > Photo/Video, if Collision Detection is set to Continue, the log file will contain the list of detected collisions. For example:
Collision number 1
Dynamic Solid : T1 End Mill D 10.CUTStatic Solid : StockCollision Point 23.388212 7.778961 15.000000 Machining Operation :Pocketing.2
The CATProduct can be useful when the result of a previous process is to be used as the stock of the next process.
1. Select the Manufacturing Program entity in the tree, then select Generate NC Code in Batch
Mode . The following dialog box appears.
In the In/Out tab page...
2. Select the manufacturing document to be processed using the Input CATProcess [...] button. The current document is proposed by default.
Select the type of NC entity to be processed. This can be:
● one part operation in the input CATProcess. In this case all the manufacturing programs of the selected part operation will be processed.
● one or more manufacturing programs in the input CATProcess.
3. Select In Process Model (CATProduct) as the NC data type that you want to generate.
4. Select the desired One file... option to generate a single CATProduct:● for all the selected manufacturing programs
● or for each selected manufacturing program. Please note that this option is not supported in programs containing Copy or Tracut Operators.
5. To store the resulting NC data file at the same location as the input CATProcess, just select the Store at same location as the CATProcess checkbox.
Otherwise, specify the Output file where you want the NC data to be written using the [...] button.
A default name is proposed for the output file (for example, Process1_Manufacturing_Program_1.CATProduct). This name can be modified directly in the Output File text field.
6. Select the Replace like-named file checkbox if you want to authorize overwriting an existing like-named CATProduct.
7. If needed, you can choose to write the CATProcess document after processing. Just select the Save Input CATProcess checkbox and specify where you want to save it using the [...] button.
8. Select the Replace like-named CATProcess checkbox if you want to authorize overwriting an existing like-named CATProcess document.
9. You can select the Lock operations checkbox to lock all the machining operations after processing. Please refer to Locked Machining Operations for more information.
In the Tool Motions and Formatting tab pages...
Certain option settings may have an influence on the generated CATProduct. Please refer to NC Data Options for more information.
The NC Code tab page is not useful for generating CATProducts.
10. Click Execute to request computation of the CATProduct.
MfgBatch Utility for Generating NC Data
MfgBatch is a utility program that allows you to generate NC data files from a manufacturing program referenced by a CATProcess.
You can run this program using one of the Generate NC Data commands in your NC workbench. This is described in the following user tasks:
● Generate APT Source Code in Batch Mode
● Generate Clfile Code in Batch Mode
● Generate NC Code in Batch Mode
● Generate APT Source Code in Interactive Mode.
You can also run MfgBatch as an executable program under Windows or a shell under UNIX. In this case MfgBatch uses an input text file called FT05 containing a set of keywords similar to the keywords of the equivalent Version 4 utility.
This document describes how to define the FT05 input file and run MfgBatch.
1. Defining the FT05 file
MfgBatch uses an input text file containing keywords that describe the processing to be done. It is largely derived from the CATIA Version 4 FT05 file. The available keywords are described below.
Sample FT05 for generating an APT file:
*REA E:\tmp*MOD Processinfra1.CATProcess*PRG Manufacturing Program.1*WRI E:\tmp*MEM aptcub1.aptsource*APT 1*REP Y*PPR 3*RUN
Sample FT05 for generating an NC Code file:
*REA E:\tmp*MOD Processinfra1.CATProcess*PRG Manufacturing Program.1*WRI E:\*MEM test1.CATNCCode*ISO CNT*REP Y*PPR 3*PPN NUM1060_5X*STX N*RUN
Do not use the character $ in path names, as this character may be interpreted as an environment variable.
2. Running MfgBatch
A CATIA V5 environment is needed in order to run MfgBatch. The entry point is the MfgBatch.exe executable program (under Windows) or MfgBatchCmd.sh shell (under UNIX).
You should create a RunMfgBatch.bat file under Windows or a RunMfgBatch.sh file under UNIX. The three arguments required for running the utility are:
environment name: -env environment_nameenvironment directory or folder: -direnv environment_locationfull name of the FT05 file: -ft05 file_name
Running MfgBatch under Windows
Here is an example of the RunMfgBatch.bat file you need to create. It must be accessible in your user path.
"C:\Program Files\Dassault Systemes\B15\intel_a\code\bin\mfgbatch.exe" -env CATIA.V5R16.B16 -direnv "C:\Program Files\Dassault Systemes\B16\CATEnv" -ft05 %1
In this example, CATIA Version 5 is installed at C:\Program Files\Dassault Systemes\B15.You will find this information in the Properties menu of the icon that is used to start CATIA.
The executable program is run by specifying the required arguments. The %1 parameter represents the FT05 file name.
How to use it:
RunMfgBatch FT05_file_name
Example:
RunMfgBatch e:\users\myself\Drilling_1_ft05.txt
Running MfgBatch under UNIX
Here is an example of the RunMfgBatch.sh file you need to create. It must be accessible in your user path.
#!/bin/kshset -x/home/data/TESTR9164/aix_a/code/command/catstart -env CATIA_P1.V5R16.B16 -direnv /CATEnv -run "MfgBatchCmd.sh -ft05 $1"
In this example, CATIA Version 5 is installed at /home/data/TESTR9164. This is followed by a reference to the Operating System which can be:
● aix_a
● hpux_a
● irix_a
● solaris_a.
You will find this information in the /CATEnv directory in the environment_name.txt files.
The shell is run by specifying the required arguments. The $1 parameter represents the FT05 file name.
How to use it:
RunMfgBatch.sh FT05_file_name
Example:
RunMfgBatch.sh /u/users/myself/Drilling_1_ft05.txt
3. Results
For the command:
RunMfgBatch d:\dir\fichierFT05.txt
with:
*WRI E:\tmp*MEM aptcub1.aptsource
results are:
● a first LOG file: d:\dir\fichierFT05.txt.LOG
● a result file: E:\tmp\aptcub1.aptsource
● a second LOG file: E:\tmp\aptcub1.LOG
If an error occurs, you should first look at the LOG files which give a diagnostic about the problem encountered (for example, syntax error or file not found).
The following keywords can be used in the FT05 file. Note that, compared with a CATIA Version 4 FT05 file, only 3 letter keywords can be used in Version 5.
Please refer to NC Data Options for more information about these keywords.
APT output:
*REA CATProcess read directory (required keyword).
*MOD CATProcess name (required keyword).
*PRG Manufacturing program to be processed (required keyword).
*WRI Write directory for the generated file.
*MEM Generated file name.
*APT 1 Generate APT source. Copy and/or Tracut instructions will not be processed. In this case there will be Copy or Tracut statements remaining in the generated APT source.
*APT 2 Generate APT source. Copy and/or Tracut instructions will be processed. In this case there will be no Copy or Tracut statements remaining in the generated APT source.
*REP If output file already exists with same name, allows replacing it (Y/N)
*PPR nor*PPR nnn
Display mode for general information (such as tool names), Part operation comments, and Machining operation names (1: PPRINT, 2: no comments, 3: $$).
For example:*PPR 1 will give general information, Part operation comments, and Machining operation names as PPRINT*PPR 121 will give general information, and Machining operation names as PPRINT and Part operation comments as $$*PPR 333 will give general information, Part operation comments, and Machining operation names as $$.
*RUN Command to start processing (required keyword).
Clfile, NC code or CATProduct output:
*CLF Generate Clfile (replaces *APT)
*ISO Generate NC code (replaces *APT)
*CGR Generate CATProduct in-process model (replaces *APT).In previous releases, a CGR in-process model is generated with this keyword.
Possibility to write CATProcess after processing:
*FLW CATProcess write directory.
*MDW CATProcess name.
*MRP If CATProcess already exists with same name, allows replacing it (Y/N).
*AOF Associates the NC output file with the CATProcess after processing (Y/N).
Other keywords:
*CIR Circular interpolation mode (0: no circle, 1: CIRCLE only, 2: CIRCLE or CYLINDR).
*FGO 3 axis or 5 axis (POINT/AXIS)
*PPN Post-processor name
*STX Syntax to be used or not for Cycles (Y/N)
*TPS Compute only, no generation of APT, NC code or Clfile.
*FCP Force compute.
*TOM Tool Output Management (1: Tip, 2:Tool center).
*FOM File Operation Management (1: output one file per program, 2: output one file per operation, 3: output one file for all programs).
*HPM Home Point Management (2: write home point of the machine in FROM or GOTO according to the machine parameter).
*LCK Lock operations.
*SRP 1 Rapid feedrate at start of each operation.
*RAP 1 Rapid defined according to the value defined on the machine feedrate.
*RMT 1 No GOTO statement is to be included before each tool change.
*GBC 1 Remove GOTO statements before axial machining operations.
*PAC 1 Remove double points after PP commands.
*ALP 1 Remove aligned points.
*SPC Split circle into two circular arcs.
0: No split.1: If the circle angle is greater than 179 degrees, it is split into two equal circular arcs (this is known as the V5 mode).2: If the circle angle between 179 and 181 degrees, or between 359 and 361 degrees, it is split into two circular arcs.The first arc has an angle of 90 degrees, the second has an angle of "circle angle-90" degrees (this is known as the V4 mode).
If the keyword if not used, the circle is not split.
*NDX N.D Format for point coordinatesN=total number of digits for each point coordinateD=number of digits after the decimal point for each point coordinate.
*NDI N.D Format for axial componentsN=total number of digits for tool axis vector componentD=the number of digits after the decimal point for tool axis vector component.
Manage Batch Queue
This task shows how to use the batch queue management functionality.
You have the possibility of managing tool path computation outside the interactive session, with the possibility of scheduling the execution of several batch jobs.
Capabilities include:
● possibility to select machining operation, manufacturing program or Part Operation
● immediate or differed execution mode
● management and edition of the list of computations to be done
● batch monitoring during execution
● possibility to an output NC file (APT, clfile, or NC code) with your job.
Always save your program modifications before computing NC data.
For best results, you should first verify the operations of your program by means of a replay or simulation. There should be no operations to be updated or in an undefined state.
1. Click Manage Batch Queue .
The NC Batch Management dialog box appears.
2. Click Create a Job .
The Job Definition dialog box appears allowing you to select either a program or part operation in the Process List by means of the [...] button.
Two options are possible:
● Compute tool path and synchronize:Click OK to add the defined job to the list in the NC Batch Management dialog box.Only the tool path will be computed.
● File generation: Click the File Generation button. This allows you to request an output NC file (APT, clfile, or NC code) with your job. The NC file parameters are defined in a similar way to that described in Generate APT Source File in Batch Mode. A different output type can be requested for each job.
The figure below shows the NC Batch Management dialog box when two programs have been selected for processing. Note that an APT output file has been requested for each job. The status column shows that the two programs are waiting to be computed.
Properties allows you to modify the selected job.
Delete Current Job allows you to delete the selected job
Move Up and Move Down allow you to move the selected job up or down in the list.
Delete All allows you to delete all the jobs in the list.
3. Select the desired batch mode: ● Deferred: the computation will start at the designated time
● Immediate: the computation will start as soon as you click the Activate button.
4. Click the [...] button to specify the desired location of the log file.
5. When the job list is defined, click Activate to execute the jobs in the specified order.
When a job is finished, you can click Synchronize to synchronize the computed tool path with the CATProcess.
Clicking the Stop button stops the execution of the job list.
A job may have one of the following statuses: Waiting, Started, Computed or Synchronized. To know the status of the jobs, just select a job in the list.
In the figure below the status column shows that the first program has been computed.
The second program has also been computed and the resulting tool path is synchronized with the CATProcess. The operations in the program now have Computed status in the specification tree:
6. You can consult the log file using the Log button.
7. Click OK to quit the NC Batch Management dialog box.
Generate NC Documentation
This task shows how to generate NC documentation in HTML format.
You can use the following scripting languages, depending on the platform you are running on: ● BasicScript 2.2 SDK for UNIX (BasicScript is a registered trademark of Summit Software Company)
● VBScript, short for Visual Basic Scripting Edition, for Windows (Visual Basic is a registered trademark of Microsoft Corporation).
Users on Windows must have Windows Scripting Host installed.
You should have previously customized a CATScript file that defines the layout of the document you want to generate. Samples are delivered with the product in \Startup\Manufacturing\Documentation.
1. Select Generate Documentation .
The Process Documentation dialog box appears.
2. Select the CATScript file by clicking the Browse button on the right of the Script field.
In this version, just leave Process as the Process name.
3. Specify the folder and file where the documentation is to be generated by clicking the Browse button on the right of the Path field.
4. Click OK to generate your documentation.
An extract from a Sample Shop Floor Documentation delivered with this User's Guide is given below.
Please note that the documentation can include machining times for machining operations and manufacturing programs.
Import APT Source File
You can import an existing NC data file into a manufacturing program. This task shows how to import an APT source file. This creates an ordered sequence of operations in the program from information in the imported file.
For more information about importing NC data files, please refer to:
● Syntaxes Interpreted by APT Import
● NC Data Import to Support Legacy Data.
1. Right-click the Manufacturing Program entity in the specification tree and select Import APT, Clfile or NC Code File.
The NC File Import dialog box appears allowing you to select the type of NC data file to be imported:
● APT
● Clfile
● NC code.Note that in this case the Post Processor type must be set in the Tools > Options > Machining > Output tab.
Select APT using the combo, then click the Input File button.
If the selected NC data type is NC Code, a combo field appears in the dialog box for selecting the desired Post Processor file.
2. The Read NC File dialog box appears.
Navigate to the desired APT file and click the Open button.
3. The NC File Import dialog box is updated with the selected input file. Click OK to import this file in the program.
The PPR tree is updated with the machining information of the imported file.
NC data objects appear in the Manufacturing Program for each tool change in the imported file. A Tool path object is associated to each computed APT Import entity.
All necessary PP instructions are added to the program. Typical content is shown below:
● Post-Processor Instruction.1:
$$ -----------------------------------------------------------------$$ Generated on Monday, December 13, 2004 05:39:06 PM$$ CATIA APT VERSION 1.0$$ -----------------------------------------------------------------$$ Manufacturing Program.1$$ Part Operation.1
● Post-Processor Instruction.2:
PARTNO PART TO BE MACHINEDCOOLNT/ONCUTCOM/OFF
● Post-Processor Instruction.3:
$$ Start generation of : Tool Change.1
● Post-Processor Instruction.4:
TOOLNO/1, 10.000000TPRINT/T1 End Mill D 10LOADTL/1$$ End of generation of : Tool Change.1
All tools referenced in the imported NC file appear in the Resources List.
Please note the following points:● You can import an NC file anywhere in the Manufacturing program:
❍ If you select a machining operation, the file will be imported just after the operation.
❍ If you select the Manufacturing Program, the file will be imported at the start of the program.
● You can right-click the APT Import entity in the tree to access a contextual menu that allows you to:
❍ replay the APT source
❍ replace the associated tool
❍ rename or assign a comment to the APT source file.
● The machining time displayed after replaying an imported APT source may not be the exact value. This is because there is no distinction between machining and transition feedrates in the APT source. For an imported APT source, machining time is computed by taking the smallest feedrate value as machining feedrate and bigger feedrate values as transition feedrates. If this is the case for the APT source under consideration, the machining time will be correct.
● Limitation for turning operations processed on a milling center machine.When you import an APT source file (or clfile) generated from a program containing turning operations processed on a milling center machine, data concerning axial and radial axes for the turning operations is missing from the imported file. The imported NC data will not be correctly replayed or simulated in Video mode because the turning tool cannot be correctly oriented.Note that a milling center machine is any machine different from a lathe machine or multi-turret machine.
Workbench DescriptionThis section contains the description of the menu commands and toolbars that are common to the Machining products. The Advanced Machining workbench below is shown as an example.
Menu BarToolbars
Specification Tree
NC Manufacturing Menu Bar The various menus and menu commands that are common to NC Manufacturing products are described below.
Start File Edit View Insert Tools Window Help
Tasks corresponding to general menu commands are described in the Version 5 Infrastructure User's Guide.
Edit Menu
Please note that most of the commands in the Edit menu are common facilities offered by the Version 5 Infrastructure. The NC Manufacturing edit commands available depend on the type of object being edited: Manufacturing Program or other entity.
Edit > Manufacturing Program.x object
Note that you can access the same menu contextually by right-clicking the object in the PPR tree.
Command... Description... Definition Opens the Manufacturing
Program dialog box for consultation, edition, replay or simulation.
Deactivate/Activate Deactivates the program for replay or NC output. It can be made active again with Activate.
Hide/Show Children Hides the child nodes of the program. They can be visualized again with Show.
Start Video Simulation using NC Code
Allows direct access to Video material removal simulation using NC code.
Simulate Machine using NC Code
If the NC Machine Tool Simulation product is installed, you can simulate the machine using NC code. See NC Machine Tool Simulation User's Guide for more information.
Replay Tool Path See Replay the Tool Path.
Start Video Simulation using Tool Path
Allows direct access to Video material removal simulation using tool path data.
Simulate Machine using Tool Path
If the NC Machine Tool Simulation product is installed, you can simulate the machine using tool path data. See NC Machine Tool Simulation User's Guide for more information.
Compute Tool Path Allows you to choose a tool path computation mode for the program: either compute if not already done or force computation even when tool path exists.
Remove Tool Path Removes computed tool paths from the program.
Lock/Unlock Children Locks all the machining operations of a program. Locked operations can be unlocked with Unlock Children.
Lock/Unlock Tool Path Locks all the tool paths of a program. Locked tool paths can be unlocked with Unlock Tool Path.
Remove Video Result Removes all saved material simulation Videos from the program.
Generate NC Code Interactively
See Generate NC Code for the Program.
Display NC FileIf an NC file is associated to the program, allows the display of that file. See Display NC File.
Generate Tool Changes See Tool Change.
Delete Generated Tool Changes
See Tool Change.
Generate Machine Rotations
See Machine Rotation.
Delete Generated Machine Rotations
See Machine Rotation.
Import APT, Clfile or NC Code File
See Import an APT file.
Delete Unused Indices Deletes indices not used by a Copy operator.
Process Table See Process Table.
Expand tree to machining operations
Expands the PPR tree down to MO level.
Edit > Part Operation.x object
Note that you can access the same menu contextually by right-clicking the object in the PPR tree.
Command... Description... Definition Opens the Part Operation dialog
box for consultation or edition.Activate/Deactivate Deactivates the Part Operation.
It can be made active again.Show/Hide Children Hides the child nodes of the
part operation. They can be shown again.
Assign Machine from File Allows assigning a generic machine (CATProduct) to the Part Operation.
Assign Machine from PPR
Allows assigning a machine from the Resource List to the Part Operation.
Process Table See Process Table.
Expand tree to tool changes
Expands the PPR tree down to tool change level.
Edit > Machining Operation.x object
Note that you can access the same menu contextually by right-clicking the object in the PPR tree.
Command... Description... Definition Accesses the operation's
definition dialog box.Deactivate/Activate Deactivates the operation for
replay or NC output. It can be made active again.
Hide/Show Children Hides the child nodes of the operation. They can be shown again.
Replace Tool Allows replacing a tool on an operation.
Replay Tool Path See Replay the Tool Path.
Compute Tool Path Allows you to choose a tool path computation mode for the operation: either compute if not already done or force computation even when tool path exists.
Remove Tool Path Removes computed tool paths from the operation.
Pack/Unpack Tool Path Allows compressing an operation's tool path information in an external tpl-suffixed file. Unpacking is also possible.
Several operations can be selected for packing. In this case, one tpl file is created for each operation. In the PPR tree, a mask symbol on the operation indicates that it is packed.
Lock/Unlock Locks the computed machining operation. It can be unlocked using Unlock.
Lock/Unlock Tool Path Locks the tool path of a computed machining operation. It can be unlocked using Unlock Tool Path.
Remove Video Result Removes a saved material simulation Video from the operation.
Starts Machine Simulation
If the NC Machine Tool Simulation product is installed, you can switch from the Machining workbench to the NC Machine Tool Simulation workbench by clicking this command.
Import APT, Clfile or NC Code File
See Import an APT file.
Start Video Simulation Run full Video from last Video result.
Edit > Manufacturing View.x object
Note that you can access the same menu contextually by right-clicking the object in the Manufacturing View.
Command... Description... Sort by Features Sorts the view by features.Sort by Patterns Sorts the view by patterns.Sort by Operations Sorts the view by operations.Sort by Tooling Sorts the view by tooling criteria.Sort by Machining Features
Sorts the view by machining features.
Delete Unused Deletes unused machining features. You can delete either all unused machining features or all unused machining features of a given type.
View > Machining MenuCommand... Description...
Process Table See Process Table.
Manufacturing View See Manufacturing View.
Machining Process View See Machining Process View.
Machining Gantt Chart
The Machining Gantt Chart can be used to review machining operations on multi-turret machines. Please refer to the Multi-Slide Lathe Machining User's Guide for more information.
Insert MenuCommand... Description...
Machining Operations
Creates Machining Operations in the program. This is described in the User's Guides of the various NC products.
Auxiliary Operations See Insert > Auxiliary Operations, below.
Machining Features See Insert > Machining Features, below.
Insert > Auxiliary OperationsCommand... Description...Tool Change Creates a Tool Change.
Machine Rotation Creates a Machine Rotation.
Machine Instruction Available if NC Machine Tool Simulation is installed.See NC Machine Tool Simulation User's Guide for more information.
Machining Axis Change Creates a Machining Axis Change.
Post-Processor Instruction
Creates a PP Instruction.
COPY Operator Creates a COPY Operator.
TRACUT Operator Creates a TRACUT Operator.
Copy Transformation Instruction
Creates a Copy Transformation Instruction.
Insert > Machining Features
Command... Description...Milling Features Creates Milling type Machining
Features in the program. This is described in the User's Guides of the relevant NC products.
Machining Pattern See Machining Pattern.
Machining Axis System Creates a Machining Axis System feature, which is referenced in the Machining Axis Change auxiliary operation.
Tools Menu
Please note that most of the commands available in the Tools menu are common facilities offered by the Version 5 Infrastructure. Specific Machining commands are described in the present document.
Command... Description...
Formula Allows editing parameters and formula.
Image Allows capturing images.
Macro Allows recording, running and editing macros.
Utility Allows access to batch utilities.
Customize Allows customizing the workbench.
Visualization Filters
Allows management of visualization filters.
Options See Customizing Settings for Machining.
Standards Allows access to standards (general, drafting, and so on).
Conferencing Allows access to the Conferencing capability.
Machining Tools > Isolate Process Data
Allows creating a Process Template.
NC Manufacturing Toolbars The NC Manufacturing Infrastructure provides a number of toolbars that are common to all the NC machining products. These are described below.
Manufacturing Program ToolbarsAuxiliary Operations Toolbar
Transition Path Management ToolbarNC Output Management Toolbar
Machining Features ToolbarAuxiliary Commands Toolbar
Edge and Face Selection ToolbarsMachining Process Toolbars
Manufacturing Program Optimization ToolbarMachine Management Toolbar
Measure Toolbar
Manufacturing Program ToolbarThe Manufacturing Program toolbar contains the following commands for creating manufacturing program and part operation entities.
See Part Operation
See Manufacturing Program
Auxiliary Operations Toolbar This toolbar contains commands for creating auxiliary operations in the program.
See Machine Rotation
Machine Instruction, available if NC Machine Tool Simulation is installed.
Manages machine axes motion and/or lock machine axes in the machining program.External/Peripheral axis position and/or lock.Lock parallel axis.Example: NC Machine with W axis.
Capability to influence machine simulation by positioning rotary axes at user defined positions.Control over machine configuration.Example: NC machine with 2 head positions.
Integration with Automatic Transition Path generation.
See NC Machine Tool Simulation User's Guide for more information.
See Machine Rotation
See Post-Processor Instruction
See COPY Operator.
See TRACUT Operator.
See Copy-Transformation Instruction.
Opposite Hand Machining Options. See Opposite Hand Machining.
Reverse Machining Conditions. See Opposite Hand Machining.
Reorder Operations List. See Opposite Hand Machining.
Inverse Macros. See Opposite Hand Machining.
The following toolbar is accessed from the drop-down icon in the Auxiliary Operations toolbar.
It contains icons for creating and editing Tool Change operations as follows. Please note that the icon representing a Tool
Change operation in the tree looks like this: .
See Drill tool for more information about this resource
See Tap tool for more information about this resource
See Thread Mill tool for more information about this resource
See Countersink tool for more information about this resource
See Reamer tool for more information about this resource
See Spot Drill tool for more information about this resource
See Center Drill tool for more information about this resource
See Multi-Diameter Drill tool for more information about this resource
See Boring and Chamfering tool for more information about this resource
See Two-Sides Chamfering tool for more information about this resource
See Boring Bar tool for more information about this resource
See Counterbore Mill tool for more information about this resource
See End Mill tool for more information about this resource
See Face Mill tool for more information about this resource
See Conical Mill tool for more information about this resource
See T-Slotter tool for more information about this resource.
Transition Path Management ToolbarThis toolbar contains the commands for automatically creating all necessary transition paths in the program according to user-defined transition planes and necessary machine rotations.
See Generate Transition Paths in a Program.
Generate Transition Paths
Remove Transition Paths
Update Transition Paths.
NC Output Management Toolbar This toolbar contains the following tools to help you validate the tool path and generate NC output.
See Replay Tool Path
See Generate NC Code in Batch Mode
See Generate NC Code Interactively
See Manage Batch Queue
See Generate NC Documentation
Screen capture for associating a JPEG image to an activity (that is, part operation, manufacturing program, machining operation, and so on).
During NC Documentation generation, an IDL interface can be called in order to read the image associated to the activity. A URL link must be made from the HTML documentation to the image in order to retrieve it in the generated HTML documentation.Starts Machine SimulationThis icon is added to the toolbar if the NC Machine Tool Simulation product is installed. You can use this icon to switch from a Machining workbench to the NC Machine Tool Simulation workbench. Please refer to the NC Machine Tool Simulation User's Guide for more information.
Machining Features Toolbar This toolbar contains commands for managing machining features. The commands available depend on the Machining workbench (the figure below illustrates the toolbar for Prismatic Machining).
The commands that are common to all workbenches are:
See Machining Patterns
Machining Axis System
See Manufacturing View.
Commands that are specific to a Machining workbench are described in the user's guide of the corresponding product.
Auxiliary Commands Toolbar This toolbar contains a number of auxiliary commands.
Open Catalog.See procedure for Applying machining processes.
Import/List Tools. See procedure for searching tools described in Select or Create a Tool.
Replace Tools.See procedure described in Replace Tools.
The Activity Selection sub-toolbar offers a choice between:
No Display of Tool path or Geometry of selected operation
Display Tool Path of selected operation
Display Geometry of selected operation.
Display Status of Selected Activities.Allows display of activity status in tree. This command is available when the Update Activity Status Automatically checkbox is not selected in the Tools > Options > Machining > General tab.
Synchronize Process.See methodology dealing with NC Synchronization in Manufacturing Hub Context.
Process Table.See procedure dealing with Process Table.
NC Gantt ChartThis command is available for machines that have multiple turrets. For more information, please refer to the Multi-Slide Lathe Machining User's Guide.
For machining operations that use part and check surfaces, you can now choose to show or hide that geometry using commands of the Hide/Show Geometry as follows:
Hide/Show part elements
Hide/Show check elements
Edge and Face Selection ToolbarsA number of geometry selection commands are available for selecting parts, check surfaces, drives, and so on. Please note that any hidden geometry selected using these commands is not taken into account in subsequent tool path computations. For more information, please refer to the rules described in Tool Path Computation when Hidden Geometry is Present.
Edge Selection Toolbar
The Edge Selection toolbar contains commands to help you select edges of contours when specifying geometry in machining operations. Please note that only some of the following commands and options are available for some operations (5-axis Flank Contouring, for example).
Display options panel allows you access to the following dialog box for specifying Link types, propagation domains, and propagation parameters.
Link types: You can apply a global link type for managing gaps during contour selection by choosing one of the following:
● Automatic: contour selection is propagated up to a selected edge
● No link: gaps are not filled
● Line insert: a line segment is used to fill a gap
● Linear extrapolation: two extrapolated line segments are used to fill a gap
● Radial axial: for geometry in turning operations, a radial-axial transition is inserted
● Axial radial: for geometry in turning operations, an axial-radial transition is inserted.
Reverse Propagation: During edge selection, you can click this button to reverse the direction in which the following edges are to be selected.
Propagation Domains: By default, only the edges included in the current Body (or OpenBody) can be selected. You can add other bodies by clicking the Add button and selecting new bodies in the 3D viewer. You can remove selected bodies by right-clicking the Propagation Domains area and selecting Reset.
During automatic propagation, if there are more that one possible edges for selection, the best candidate is selected according to the following criteria:
● the gap between the last selected edge and the candidate edge must be less than the Maximum gap
● the angle between the tangent of the candidate edge and the tangent to the last selected edges must be less than the Maximum angle. If there still more that one candidates, the one that makes the smallest angle is preferred.
Max Steps forward: When navigating on a belt of edges, propagation stops when the number of steps (or edges) forward is reached. In this case the label Next? appears at the end of the last selected edge to prompt a user action.
Steps Back: When resetting previous edge selections, this parameter specifies the number of edges (or steps) that will be reset. Navigate on Belt of Edges allows you to select all edges that are tangent to the one you have selected.
● Select an edge and then click the icon.
Navigate on Edges Until an Edge allows you to select all edges that are tangent between start edges and a stop edge.
● Select two edges that are tangent (to give the direction of selection) and then click the icon.
● Select a third edge where you want selection to end.
Close Contour with Line. ● Select a contour or series of lines to form a contour and click on this icon. A straight
line is inserted from the beginning of the contour to the end of it.
Insert Lines on Gaps allows you to create a line between two points. ● Click the icon then select one point as the beginning of the line and then select a
second point for the end of the line.
Reset Selection to Step Back resets the previous edge selections. The number of edges that are reset is determined by the number of Steps Back given in the Options dialog box.
Reset Selection to Stop Edge resets the last edge selections up to the last stop edge.
Reset All Selections resets all selections made with the Edge Selection toolbar.
Accept Geometry Selections allows you to accept selected geometry and exit the selection mode.Cancel Geometry Selections allows you to refuse any selected geometry and exit selection mode.
Face Selection
The Face Selection toolbar and Tools Palette appear when face selection is necessary for machining operations.
Face Selection Toolbar
The Face Selection toolbar contains commands to help you select faces when specifying geometry in machining operations.
Navigate on Belt of Faces allows you to select all faces that are adjacent to the one you have selected.
● Select two adjacent faces and click the icon. All adjacent face are selected.
Navigate on Faces Until a Face allows you to select all faces that are adjacent between start faces and a stop face.
● Select two faces that are adjacent (to give the direction of selection) and then click the icon.
● Select a third face where you want selection to end.
Navigate on Faces allows you to select all faces which are tangent to a selected face. ● Select a face and then click this icon.
Preview the Contour allows you to highlight the contour of selected faces.
Select Faces in a Polygon Trap allows you to select all faces that are situated entirely within a polygon.
● Select the icon.
● Click the places in the viewer where you want the corners of the polygon to be. Double-click to end corner definition.
Select Normal Faces lets you select faces that are: ● normal to a main axis.
● parallel or perpendicular to a face that you select as reference.
The Define Normal Faces dialog box appears when you click the icon.
The By Axis tab allows you to select all of the flat faces that are normal to a main axis.
● The Reference body is No selection. Make sure it is selected (as in the image) and click on the part to machine in the viewer.
● Choose an axis then click OK.The faces normal to the axis you chose in the viewer are selected.
● Click OK in the Face Selection toolbar to confirm your selection.
The By Face tab allows you to select flat faces with reference to a face that you choose.
● Select a part as the Reference body.
● Click in the Reference face box the select the face on the part that you want to use as reference.
● Choose whether you want to select faces that are perpendicular or parallel to that face.
● Click OK to select these faces.
● Click OK in the Face Selection toolbar to confirm your selection.
Retrieve Faces of Same Color allows you to select all faces of a given color. ● Select a face of a given color and then click the icon. All faces of that color are
selected.
Note that you can define the color of a face via the Edit/Properties menu item when the face is selected.Selection Sets allows you to select faces belonging to previously created selection sets. This action is a shortcut to the Selection Sets item in the Edit menu.
● Click on the icon and select the selection set you want to use in the displayed dialog box.
● Press Close.
Reset All Selections. ● Click the icon to reset all selections made with the Face Selection toolbar.
Accept Geometry Selections allows you to accept selected geometry and exit selection mode.Cancel Geometry Selections allows you to refuse any already geometry and exit selection mode.
Tools Palette
The Tools Palette toolbar contains commands to help you multi-select face elements.
Select enables you to select elements or deselect elements in the 3D geometry or in the specification tree. Use the Ctrl key to select several elements, and the Shift key to deselect already selected elements.
Selection Trap enables you to select elements by drawing a trap.Elements must be entirely located inside the trap to be selected.
Intersecting Trap enables you to select elements by drawing a trap.Elements can either be located inside the trap or be intersected by the trap to be selected.
Polygon Trap enables you to select elements by drawing a closed polygon.Any element inside the polygon will be selected.
Paint Stroke Trap enables you to select elements by drawing a paint stroke across them.
Outside Trap Selection enables you to select elements outside the trap.Any object strictly outside the trap will be selected.
Intersecting Outside Trap Selection enables you to select elements outside the trap.Any object strictly outside or partially outside the trap will be selected.
Interruption Feedback
In some cases when automatic propagation is interrupted, a label appears at the extremity of the last selected edge. For example:
● Next?This means that the maximum number of steps forward has been reached.
● AngleThis means that the maximum angle is not respected or there is an ambiguity.
● ToleranceThis means that the maximum gap is not respected.
● Closed LoopThis means that the contour is closed.
Machining Process Toolbars The Machining Process toolbar is available for P2 products and contains the following tools for creating and viewing machining processes.
Displays the Machining Process View. See procedure described in Create a Machining Process.
See Create a Machining Process.
The Standard Machining Processes toolbar contains the following commands.
Machining Processes Application:Applies all the machining processes of a catalog on a set of selected features.Standard Drilling:Inserts a Drilling operation in the program with a pre-selected tool according to the selected geometry.
Axial Process for Design HolesApplies a generic drilling process dedicated to all design holes with operations according to the hole type.Standard Multi-Axis Flank Contouring:Inserts a Multi-Axis Flank Contouring operation in the program with a pre-selected tool according to the selected geometry.
Manufacturing Program Optimization ToolbarThis toolbar contains the commands for optimizing the order of operations in the program according to pre-defined sequencing rules.
See Auto-sequence operations of a program according to pre-defined rules.
Machine Management Toolbar This toolbar is available for P2 products and contains the following tools for checking accessibility on the NC machine.
Resource Context.Imports resources such as an NC machine. Workpiece Automatic Mount.Automatically mounts the workpiece on the machine for current part operation.Snap.Snaps resources together.Align on Machine commands.Aligns objects using various methods:
● Align Side: aligns the side of a selected object with respect to a reference plane.
● Align Center: aligns the center of a selected object with respect to a reference plane.
● Distribute: evenly distributes 3 or more elements with respect to a reference line or plane.
● Rotate to Align: rotates a selected object with respect to a reference plane.
Attach.Attaches selected objects together and creates Child/Parent link between them.
Measure Toolbar This toolbar contains the following tools for measuring.
Measure Between measures between two elements. For more information please refer to the procedure described in Measuring Properties.
Measure measures an element. For more information please refer to the procedure described in Measuring Distances and Angles between Geometrical Entities.
Specification TreeThe Process Product Resources (PPR) specification tree is the same for all Machining workbenches.
Process List
Process List starts with a Root process node. It gives all the machining operations, associated tools, and auxiliary operations that are required to transform a part from a rough to a finished state.
● Part Operation defines the manufacturing resources and the reference data.
● Manufacturing Program is the list of all of the operations and tool changes performed. The example above shows that:
❍ Drilling.1 is complete and the tool path has not been computed
❍ Drilling.2 is complete and the tool path has been computed
❍ Drilling.3 does not have all of the necessary data (indicated by the Exclamation mask )
❍ Drilling.4 has been deactivated by the user (indicated by the Inactive mask )
❍ Drilling.5 has been modified and needs to be recomputed (indicated by the Update mask ).
Product List
Product List gives all of the parts to machine as well as CATPart documents containing complementary geometry.
Resources List
Resources List gives all of the resources such as machines, tools, and tool assemblies that can be used in the process. Contextual commands are available by right-clicking in the Resources List.
You can edit a tool or tool assembly by means of the Edit NC Resources contextual command. Note that a resource in the list cannot be edited by double-clicking it.
You can save a tool or tool assembly in a catalog by means of the Save in Catalog contextual command.
You can assign a user-defined representation (CATPart or CATProduct) to the tool or tool assembly by means of the Add User Representation contextual command.
You can delete unused resources from the list by:
● selecting all the resources of the same type (all the tools, for example)
● right-clicking and selecting the Delete Unused Resources contextual command.
You can duplicate a resource in the list using the Duplicate Resources contextual command. A name of the duplicated resource is suffixed with '_n', where n is a number.
Expanding the Tree
The following behavior is aimed at improving performance:
● Only Part Operations and Programs are shown when you open your document.
● You can expand the tree level by level: ❍ Programs are shown when you expand the Part Operation level
❍ Tool changes are shown when you expand the Program level.
● You can expand the tree as follows using contextual menus: ❍ Expand Tree from Part Operation to Tool changes
❍ Expand Tree from Manufacturing Program to Machining operations
❍ Expand Tree from Tool Change to Tool paths.
The View > Tree Expansion menu provides a number of standard commands (such as expanding or collapsing the entire tree).
CustomizingThe tasks in this section describe ways in which you can customize your NC Manufacturing environment.
MachiningBuild a Tools Catalog
Access External Tool CatalogsPP Word SyntaxesNC Documentation
Workbenches and Tool Bars
Customizing Settings for Machining
This section describes how to customize settings for Machining.
Before you start your first working session, you can customize the settings to suit your working habits. Your customized settings are stored in permanent setting files: they will not be lost at the end of your session.
1. Select Tools > Options from the menu bar: the Options dialog box appears.
2. Select the Machining category in the tree to the left. The options for Machining settings appear, organized in tab pages.
3. Select the tab corresponding to the parameters to be customized.
Parameters in this tab... Allow you to customize...
General general settings for all Machining products
Resources tooling, feeds&speeds and resource files
Operation machining operations
Output PP files and NC data output
Program manufacturing programs (sequencing, and so on)
Photo/Video material removal simulation
4. Set these options according to your needs.
5. Click OK to save the settings and quit the Options dialog box.
General
This document explains how to customize general settings for Machining products.
Select the General tab, which is divided up into areas.
Parameters in this area... Allow you to customize...
Performance settings for optimized performance
Tree Display display of the specification tree
Color and Highlight colors of displayed geometry and parameters
Tool Path Replay tool display during tool path replay
Complementary Geometry handling of geometry necessary for manufacturing
Design Changes use of the Smart NC mode and enhanced detection of design changes.
Performance
Click the Optimize button in order to automatically set a number of the Machining options for optimized performance. These options are listed in the Information dialog box that appears:
If you click Yes, these options will be set as described in the dialog box. Note that, if needed, you may locally reset any of these options.If you click No, the options will remain with their current settings.
The Information box also lists some recommendations for manually setting other options that have an influence on performance.
Tree Display
● Select the check box if you want the status of activities in the tree to be updated automatically.
● If this check box is not selected, you can display the status of one or more selected activities in the tree using Display
Status of Selected Activities in the Auxiliary Commands toolbar.
If this check box is not selected, performance is improved.
By default, the check box is not selected.
Color and Highlight
● Select the colors to be used for identifying the various manufacturing entities by means of the combos. Note that for Geometry that is not found or not up to date, you can select the colors used to display the valuated parameters in the corresponding Operation or Feature dialog boxes.
● For certain entities, you can select the corresponding check box to use highlighting. Performance is improved when all the Highlight check boxes are selected.
Tool Path Replay
Display tool near cursor position on tool path
Select this check box if you want to display the tool near your cursor position on the trajectory during a tool path replay.
You can display the tool at a specific point by clicking on the tool path. The tool will then be positioned on the nearest computed point on the trajectory. To remove the tool from that position, just click anywhere on the tool or tool path.Please note that, as from Release 15, this positioning capability is available even when the check box is not selected.
Display tool center instead of tool tip
Select this check box if you want to display the tool center point instead of the tool tip during a tool path replay.
Display circles
Select this check box if you want to display each circular trajectory as a circular arc instead of a set of discretization points. The extremities of the circular arc are indicated by means of 'O' symbols.This allows better control of the Point by Point replay mode, where it is necessary to make several interactions to replay a circle (because of its representation by a set of points). With the graphic representation as a circle, only one interaction is necessary to perform the replay.
By default, these check boxes are not selected.
Color of feedrates
Select the colors to be used for identifying the various feedrate types by means of the combos. The selected colors will be displayed in the Different colors replay mode.
Complementary Geometry
Select the check box to create a CATPart dedicated to manufacturing-specific geometry in the Product List of the PPR tree.
By default, the check box is not selected.
Design Changes
Smart NC mode
Select this check box to activate the Smart NC mode. In this mode, an image of the geometry selected in machining operations is kept to allow analysis of design changes.Performance is improved when this check box is not selected.
Optimized detection of design changes
Select this check box to enable a geometrical comparison mode for detecting design changes.This mode determines with more precision the design change status of machining operations when a product is replaced in the Part Operation (using either the Part Operation editor or the Edit Links capability). This option has no effect on all other design change methods such as direct modification in the Part.
By default, these check boxes are not selected.
Resources
This document explains how to customize resource settings for Machining products.
Select the Resources tab, which is divided up into areas.
Parameters in this area... Allow you to customize...
Catalogs and Files the path name for resource files
Tool Selection the selection of tools
Automatic Compute from Tool Feeds and Speeds
the update of feeds and speeds according to tooling data
Tool Query Mode in Machining Processes Instantiation
tool queries in machining processes
Catalogs and Files
Enter the path of the folder containing tool catalogs, PP tables, macros, and machining processes. You can choose a folder by clicking the [...] button.
You can concatenate paths using:
● a semi colon (;) character for Windows platforms
● a colon (:) character for UNIX platforms.
For example, if the concatenated folders E:\DownloadOfCXR12rel\intel_a\startup and e:\users\jmn\NC in the figure above contain PP tables, then those PP tables will be available for selection in the Part Operation's Machine Editor dialog box.
Please note that:
● PP tables must be contained in folders named Manufacturing\PPTables
● tools must be contained in folders named Manufacturing\Tools.
Tool Selection
Automatic query after modification
Select this check box if you want to to activate an automatic query after each modification of a tool parameter. Performance is improved when this check box is not selected.
Tool preview after selection
Select this check box if you want to preview the tool after selection.
By default, these check boxes are selected.
Automatic Compute from Tool Feeds and Speeds
Feedrate attributes of the operation
Select this check box if you want the Automatic Update of Feedrates option to be set by default in the Feeds and Speeds tab page of machining operations.This option allows feedrates of operations to be automatically updated whenever feedrate information on the tool is modified.
Spindle attributes of the operation
Select this check box if you want the Automatic Update of Speeds option to be set by default in the Feeds and Speeds tab page of machining operations.This option allows spindle speeds of operations to be automatically updated whenever speed information on the tool is modified.
By default, these check boxes are selected.
Tool Query mode in Machining Processes Instantiation
Select the type of Tool Query to be executed when a Machining Process is instantiated:
● automatically computed Tool Query
● interactively defined Tool Selection in case of multiple results
● interactively defined Tool Selection if no tool is found.
Depending on the selected option, the Advanced tab page of the Search Tool dialog box shows the solved Tool Query for each operation in the Machining Process.
By default, the Automatic Tool Query option is selected.
In the example below, you can choose one of the tools found in the ToolsSampleMP, or use the Look in combo to select a tool from the current document or another tool catalog.
Operation
This document explains how to customize machining operation settings for Machining products.
Select the Operation tab, which is divided up into areas.
Parameters in this area... Allow you to customize...
Default Values the use of default values
After Creation or Machining Process (MP) Instantiation
what happens after creating machining operations or machining processes
When Copying the duplication of geometry links
Display tool path displays of operations
User Interface dialog boxes of 3-axis surface machining operations
Start Feedrate the feedrate at the start of operation.
Default Values
Select the check box if you want operations to be created with the values used in the current program. The values and units of attributes at the creation step of an operation are set to the values and units of the last edited and validated operation whatever its type (that is, exit the operation definition dialog box using OK).
Otherwise the default settings delivered with the application are used.
By default, this check box is selected.
After Creation or Machining Process (MP) Instantiation
Select the desired check boxes to specify conditions to be applied when you create machining operations or machining processes.
Sequence machining operation
Machining operations are automatically sequenced in the current program after creation. Otherwise, sequencing can be managed in the feature view.
Search compatible tool in previous operations
When creating an operation, if a compatible tool exists in a previous operation of the current program, it will be set in the new operation. Otherwise, the operation will be incomplete.
Use a default tool
When creating an operation, a search is done in the document to find a compatible tool. If no compatible tool exists, a default one is created in the document and set in the created operation.If check box is not selected, no tool will be defined on the operation.
Start edit mode (not available for machining processes)
When creating a machining operation, Edit mode is automatically started to allow modifying parameters of the created operation.Otherwise, the operation is added to the program but the machining operation editor is not started.
MP instantiation: keep the absolute position of the tool axis
When a machining process is instantiated, the tool axes of the activities in the MP keep their absolute positions. Otherwise, if the check box is not selected, these positions are changed in order to keep the relative components of the tool axis.
By default, these check boxes are selected.
When Copying
Select the check box if you want geometry links to be duplicated in a copied operation.
Otherwise the geometry must be defined for the copied operation. Performance is improved when this check box is not selected.
By default, this check box is selected.
Display
Select the check box if you want to display tool paths of operations in the current Part Operation.
By default, this check box is not selected.
User Interface
Select the check box if you want to have the possibility of simplifying the dialog boxes of machining operations (that is, you can display the minimum number of parameters necessary for a correct tool path). This setting is available for 3-axis surface machining operations only.
By default, this check box is not selected.
Start Feedrate
If the checkbox is selected, the following paragraphs illustrate the expected behaviour.Otherwise, the behaviour is the same as for V5R13 level.
If a clearance macro is defined and active on machining operation B (see figure below), the feedrate at the start of operation B is the feedrate of the transition path in the plane of the clearance macro.
If there is no clearance macro defined on operation B (or if a clearance macro is defined but inactive), the feedrate at the start of operation B in the figure below is:
● either rapid feedrate if the Set rapid feedrate at start of operations NC output option is set
● or the first feedrate of operation B (this may be the feedrate of the approach macro of operation B, for example).
By default, this check box is selected.
Output
This document explains how to customize data output settings for Machining products.
Select the Output tab, which is divided up into areas.
Parameters in this area... Allow you to customize...
Post Processor and Controller Emulator Folder
the type of Post Processor and Controller Emulator files to be used for generating and simulating NC code and the path where these files are located
Tool Path Storage the tool path storage capability
Tool Path Edition the tool path edition capability
During Tool Path Computation contact point storage
Tool Output Point type of tool output point
Tool Output Files ... Location default paths for NC output files storage.
Post Processor and Controller Emulator Folder
Select the desired option:
● None: no Post Processor or Controller Emulator is defined. NC code output is not possible in this case
● Cenit: you can choose from among the Post Processor and Controller Emulator parameter files proposed by Cenit to generate and simulate your NC code
● IMS: you can choose from among the Post Processor and Controller Emulator parameter files proposed by Intelligent Manufacturing Software (IMS) to generate and simulate your NC code
● ICAM: you can choose from among the Post Processor and Controller Emulator parameter files proposed by ICAM Technologies Corporation (ICAM) to generate and simulate your NC code.
Enter the path of the folder containing Post processors and Controller Emulators. You can choose a folder by clicking the [...] button. File concatenation is possible.
By default, the None option is selected.
Tool Path Storage
Select the desired option to store tool path data either in the current document or in an external file (as a tpl file).
For operations with large tool paths (more than 100 000 points), tool path storage in an external file is recommended.
By default, the Store tool path in the current document option is selected.
Tool Path Edition
Select the check box if you want to be able to edit tool paths even when the operation is locked.
This capability is available only for activities with a tool path node in the specification tree.
By default, this check box is selected.
During Tool Path Computation
Select the check box if you want to store contact points in the tool path.
Performance is improved when this check box is not selected.
By default, this check box is selected.
Tool Output Point
Select the desired option to select one of the following as output point:
● tool tip
● tool center point
● tool center point for ball end tools (that is, any tool with the Ball-end tool attribute selected or an end mill whose nominal diameter is equal to twice the corner radius).
Performance is better when the Tool Tip option is selected.
By default, the Tool Tip option is selected.
Default File Locations
Specify default locations for storing Tool Path files, NC Documentation, and NC Code output.
You can store tool paths files (tpl files) in the same folder as the CATProcess by selecting the check box. This allows you to store these files according to your CATProcess context. Otherwise, you can choose another location by clicking the [...] button.
For NC Documentation, and NC Code output you can choose a folder easily by clicking the [...] button.
You can customize the extension to be used for NC Code output (by default, the suffix used is CATNCCode).
Please note that Video results are stored in the NC Code output directory. This is done by using Associate Video Result to
Machining Operation in the Replay Tool Path dialog box.
By default, the Tool path: Store at same location as the CATProcess check box is not selected.
Program
This document explains how to customize manufacturing program settings for Machining products.
Select the Program tab to customize program auto-sequencing rules and priorities. These settings are mainly intended for the administrator.
Make sure that the document in the sequencing rules path (AllSequencingRules.CATProduct in the example below) is accessible in Read/Write.
Auto Sequencing
Access to sequencing rules settings
Select the Access to sequencing rules settings check box to authorize user access to sequencing rules.
You can then specify the path for the rules base You can choose a rules base easily by clicking the [...] button.
By default, this check box is selected.
Display sequencing rules and priorities
Select the Display sequencing rules and priorities check box to authorize the display of sequencing rules and priorities in the user's view. In this case two more check boxes can be selected in order to:
● allow the user to filter rules
● allow the user to modify rule priorities.
By default, these check boxes are selected.
Photo/Video
This document explains how to customize material removal simulation settings for Machining products.
Select the Photo/Video tab, which is divided up into areas.
Parameters in this area... Allow you to customize...
Simulation at material removal simulation at program of Part Operation level
Video Video material removal simulation options
Photo Photo material removal simulation options
Performance settings that influence performance
Color color during material removal simulation
Positioning Move allowed tool axis variation between two operations
Simulation at
Select the desired option to perform material removal simulation at either Program or Part Operation level. Depending on the selected level, simulation begins either from the start of the manufacturing program or from the start of the Part Operation. Best performance is obtained with Program level.
By default, the Program level option is selected.
Video
Stop at tool change
Select the Stop at tool change check box if you want the Video simulation to stop each time a tool change is encountered in the program.
By default, this check box is not selected.
Collision detection
Select the desired Collisions detection option to:
● ignore collisions during the Video simulation
● stop the Video simulation at the first collision
● continue the Video simulation even when collisions are detected. In this case, you can consult the list of collisions at any time during the simulation.
Best performance is obtained when collisions are ignored.
By default, the Ignore option is selected.
Touch is collision
Select the Touch is collision check box if you want touch (or contact) type of collision to be detected.
By default, this check box is selected.
Multiple Video result on program
Select the Multiple Video result on program check box if you want to store video results on more than one operation in the program.
By default, this check box is not selected.
Photo
Select the desired Fault box type for examining remaining material or gouges:
● Transparent: to display a transparent bounding box
● Wireframe: to display a wireframe bounding box
● None: if no bounding box is required.
By default, the Wireframe option is selected.
Select the check box to compute all information at the picked point.
By default, this check box is not selected.
Best performance is obtained when Fault box is set to None and the Compute all information at picked point check box is not selected.
Performance
Tool and faceting
There are three methods of tool faceting used in Video simulation: Standard, Smaller and Larger. The number of facets for a tool representation is determined by the chord deviation that is set for the tool diameter (0.005% of the tool diameter).
● Smaller: The picture shows a rough approximation of a tool with six facets. Note that the chord deviation is always inside the actual circle, and that the points are always on the circle (accurate).
This is the most accurate method for the Arc through Three Points command.
● Standard: The picture shows a rough approximation of a tool with six facets. Note that the chord deviation is partly inside and partly outside the actual circle, and that the points are not always on the circle.
This is the best method for material removal simulation. However, this is not suitable for the Arc through Three Points command.
● Larger: The picture shows a rough approximation of a tool with six facets. Note that the chord deviation is outside the actual circle, and that the points are not on the circle.
This is not suitable for the Arc through Three Points command.However, it can be useful for gouge detection.
By default, the Standard option is selected.
Photo resolution
Best performance is obtained when the Photo resolution is set to 0. In this case, a detailed simulation of a portion of the part can be obtained using the Closeup command.Increasing the resolution improves machining accuracy and gives a very detailed simulation. However, this requires increased memory and computation time.
By default, this resolution is set to 0.
Tool axis interpolation angle (5-axis only)
Specify the maximum angle that the tool axis is allowed to vary between two consecutive points. Best performance is obtained for an angle of 10 degrees. Decreasing the angle improves the precision of the simulation. However, this requires increased memory and computation time.
By default, this angle is set to 1degree.
Optimized rendering for Video
Select the Optimized rendering for Video check box to obtain an optimized rendering that improves Video simulation performance.Otherwise, more realistic colors are obtained with a slightly degraded performance. Milling, drilling, and turning operations are supported .
By default, this check box is selected.
Color
Set the tool (and associated machined area) color to be the same as or different from the last tool, or have different colors for all tools. Best performance is obtained with same colored tools.
By default, the All different option is selected.
Assign colors to the different tools using the associated color combo.
Assign colors to tool holders, parts, and fixtures using the associated color combos.
Positioning Move
Set the Maximum tool axis variation that is to be allowed between the end point of an operation and the start point of the next operation. If the tool axis varies by an amount greater than the specified value, then the tool is positioned at the start of the following operation.
By default, this angle is set to 1degree.
Build a Tools Catalog
This task shows you how to build a customized tools catalog.
You will have to customize an Excel file and a VB macro file in order to build your tools catalog.
1. Edit an Excel file with the desired tool descriptions.
The characteristic attributes of each tool type are described in Tools.
You can include user-defined tool representations in your catalog. You do this by associating a CATPart document containing this representation to the desired tool in the last column of the Excel file.
The user-defined tool representation will be displayed in the tool path replay.
2. Save the tool descriptions as a csv type file.
3. Edit the VB macro file to specify the input and output files. An example is shown below:
'''''''''''''''''''''''''''''''''''''''''''''''''''''''''''' VBScript for Manufacturing Tools catalog generation.''''''''''''''''''''''''''''''''''''''''''''''''''''''''''
Language="VBSCRIPT"
Sub CATMain()csvFile ="MyCatalog.csv"catalogFile ="MyCatalog.catalog"
'Get the outputDir and inputDir environment variablesinputDir = "HOME\Catalog"outputDir = "HOME\Catalog"
'Creates a catalog documentDim Catlg As DocumentSet Catlg=CATIA.Documents.Add("CatalogDocument")
InitData1=inputDir & "\" & csvFileNewcata1=outputDir & "\" & catalogFile
'Calls CreateCatalogFromcsv method on Catlg (ENDCHAPTER)
Catlg.CreateCatalogFromcsv InitData1 , Newcata1
Catlg.Close
End Sub
4. In your Version 5 session, select Tool > Macro > Macros.
The Macro dialog box is displayed.
5. Select the VB macro file that you edited previously, then click Run.
The tools catalog is created (MyCatalog.catalog) along with a report file (MyCatalog.report).
You can check this in the Search Tool dialog box.
Access to External Tool Catalogs
This task shows you how to customize access to the following external tool catalogs: ● CATIA Version 4 Manufacturing database under ORACLE or DB2/6000
● TDM (Tool Data Management) database under ORACLE .
CATIA Version 4 Manufacturing relational database (ORACLE)
Please note that the V4 database must be used as the server and the V5 session must be running in client mode.
1. Declare the UNIX server on the client machine.
The client machine should have a client ORACLE installation (for example, on Windows it may be installed on c:\orant).
The Unix server machine should be declared on the client machine, the tnsnames.ora file (for example, in c:\orant\net80\admin) should be modified.
● The string MACHINE_NAME should be replaced by the name of the Unix server machine where V4 database is installed.
● The string SID_NAME should be replaced by the name of the ORACLE SID name of V4 database installation.
● The string PORT_NUMBER should be replaced by the port number used for the ORACLE installation.
Please contact the ORACLE administrator to locate the file.
Example:
MACHINE_NAME.SID_NAME = (DESCRIPTION = (ADDRESS_LIST = (ADDRESS = (PROTOCOL = TCP) (PORT = PORT_NUMBER ) (HOST = MACHINE_NAME) ) ) (CONNECT_DATA = (SID = SID_NAME) ) )
2. Customize the ...\intel_a\startup\Manufacturing\Database\CATIAV4NC.ini file of your CATIA V5 installation to define the default values for the connection.
● The string DatabaseType should be set to ORACLE.
● The string DatabaseName should be set to MACHINE_NAME.SID_NAME declared in the tnsnames.ora file.
● The string User should be set to the Unix user who has access rights to the V4 database
● The string Password should be set to the password of the Unix user who has access rights to the V4 database.
● The string ProjectName should be set to the name of the V4 database project to be connected.
● The string CDMADictionary should be set to the name of the CDMA dictionary used for the V4 database installation.
Example:
DatabaseType = ORACLEDataBaseName =diva.AIXUser =catadmPassword =db2admProjectName =MfgResourcesCDMADictionary =CATIA
CATIA Version 4 Manufacturing relational database (DB2/6000)
Please note that the V4 database must be used as the server and the V5 session must be running in client mode.
1. Declare the UNIX server on the client machine.
The client machine should have a DB2/6000 client installation. The UNIX server machine should be declared on the client machine. The following commands have to be executed by the db2 administrator of the client machine:
CATALOG TCPIP NODE nodename REMOTE hostname
CATALOG DATABASE database_name at NODE nodename AUTHENTICATION SERVER
nodename can be the name of the UNIX machine where server installation is done
hostname is the name of the UNIX machine where server installation is done
database_name is the name of the database on which the V4 database is installed.
2. Customize the ...\intel_a\startup\Manufacturing\Database\CATIAV4NC.ini file of your CATIA V5 installation to define the default values for the connection.
● The string DatabaseType should be set to DB2.
● The string DatabaseName should be set to the name of the DB2 database used for the V4 database installation.
● The string User should be set to the UNIX user who has access rights to the V4 database.
● The string Password should be set to the password of the UNIX user who has access rights to the V4 database.
● The string ProjectName should be set to the name of the V4 database project to be connected.
● The string CDMADictionary should be set to the name of the CDMA dictionary used for the V4 database installation.
Example:
DatabaseType = DB2DataBaseName =SAMPLEUser =catadmPassword =db2admProjectName =MfgResourcesCDMADictionary =CATIA
TDM (Tool Data Management) relational database (Oracle)
Please note that the TDM database must be installed and used as the server and the V5 session must be running in client mode.
1. Declare the UNIX server on the client machine.
The client machine should have a client ORACLE installation (for example, on Windows it may be installed on c:\orant).
The UNIX server machine should be declared on the client machine, the tnsnames.ora file (for example, in c:\orant\net80\admin) should be modified.
● The string MACHINE_NAME should be replaced by the name of the UNIX server machine where the TDM database is installed.
● The string SID_NAME should be replaced by the ORACLE SID name of the TDM database installation.
● The string PORT_NUMBER should be replaced by the port number used for the ORACLE installation.
Please contact the ORACLE administrator to locate the file.
Example:
MACHINE_NAME.SID_NAME = (DESCRIPTION = (ADDRESS_LIST =
(ADDRESS = (PROTOCOL = TCP) (PORT = PORT_NUMBER ) (HOST = MACHINE_NAME) ) ) (CONNECT_DATA = (SID = SID_NAME) ) )
2. Customize the ...\intel_a\startup\Manufacturing\Database\TDM.ini file of your CATIA V5 installation to define the default values for the connection.
● The string DatabaseName should be set to MACHINE_NAME.SID_NAME declared in the tnsnames.ora file.
● The strings User and Password should be set to catia.
Example:
User =catiaPassword =catiaDatabaseName =tdm.world
PP Word Syntaxes
This section shows you how to customize the following types of syntaxes in your PP word table: ● syntaxes associated to NC commands
● sequences of PP word syntaxes associated to NC instructions.
The Machining product will resolve the parameters of these syntaxes and syntax sequences and generate the corresponding statements in the APT output.
A sample PP word table is delivered with the product in \Startup\Manufacturing\PPTables\PPTableSample.pptable
It can be used as a basis for creating user-defined tables.
Please refer to PP Tables and Word Syntaxes for more information.
Some NC commands and NC instructions have default values. See NC Commands and NC Instructions for syntaxes and default values.
Please note that this default value is output even when the NC command or NC instruction is not present in the PP table.
The example below shows an NC command with explicit definition:
*START_NC_COMMAND NC_CHANGE_REF_PTSWITCH/%MFG_QUADRANT*END
If this output is not required, you must define an empty NC command or NC instruction.
For example:
*START_NC_COMMAND NC_CHANGE_REF_PT*END
1. NC Commands
You can define for a given machine tool (i.e. post-processor) PP word syntaxes associated to particular NC commands.
An NC command is a machine function such as feedrate declaration (NC_FEEDRATE) or spindle activation (NC_SPINDLE_START).
A syntax comprises a major word and one or more syntax elements such as minor words, numerical values, list values and parameters.
A syntax that includes lists or parameters is a parameterized syntax (see example below):
*START_NC_COMMAND NC_FEEDRATEFEDRAT/%MFG_FEED_VALUE,&MFG_FEED_UNIT*END
Note that the `&' character indicates a list and the `%' character indicates a parameter.
You can define only one syntax for each NC command.
The following example shows how the NC command NC_DELAY could be used in a Drilling Dwell Delay operation.
2. Make sure that the PP word table is referenced by the machine used in the Part Operation and the syntax associated with the NC_DELAY command is already created as follows:
*START_NC_COMMAND NC_DELAYDELAY/&MFG_DELAY_UNIT,%MFG_DELAY_VALUE*END
3. Create a Drilling Dwell Delay operation.
4. In the dialog box showing the available options, set the Dwell mode to Revolutions and enter a numerical dwell value of `5'.
In this case the statement generated in the resulting APT source will be:DELAY/REV,5.000
If the operation was created with the Dwell mode set to Time Units and a dwell value of `5', the statement generated in the resulting APT source would be:
DELAY/5.000
1. NC Instructions
You can define for a given machine tool (i.e. post-processor) sequences of PP word syntaxes associated to particular NC instructions.
NC instructions are either axial machining operations or auxiliary commands.
A syntax comprises a major word and one or more syntax elements such as minor words, numerical values and standard parameters. A set of standard parameters is associated to each NC instruction. Parameters may be combined in arithmetical expressions.
A syntax that includes parameters is a parameterized syntax (see example below):
*START_NC_INSTRUCTION NC_TOOL_CHANGE*START_SEQUENCETOOLNO/%MFG_TOOL_NUMBER,%MFG_NOMINAL_DIAMTPRINT/%MFG_TOOL_NAMELOADTL/%MFG_TOOL_NUMBER*END*END
Note that the `%' character indicates a parameter.
You can define one or more syntax sequences for each NC instruction.
The following example shows how the NC instruction NC_DRILLING_DWELL_DELAY could be used to generate a specific NC data output.
2. Make sure that the PP word table is referenced by the machine used in the Part Operation and the syntax associated with NC_DRILLING_DWELL_DELAY instruction is already created as follows:
*START_NC_INSTRUCTION NC_TOOL_CHANGE*START_SEQUENCECYCLE / DRILL, %MFG_TOTAL_DEPTH, %MFG_FEED_MACH_VALUE, &MFG_FEED_UNIT, %MFG_CLEAR_TIP, DWELL, %MFG_DWELL_REVOL*END*END
3. Create a Drilling Dwell Delay operation.
4. In the dialog box showing the available options, set: ● hole depth to 25.0
● feedrate to 500.0
● approach clearance to 5.0
● Dwell mode to Revolutions and enter a numerical dwell value of `3'.
In this case the NC data output is as follows:
CYCLE/DRILL, 25.000000, 500.000000, MMPM, 5.000000, DWELL, 3
The PP word table is updated with your syntaxes when you save the file.
NC Documentation
This task shows you how to generate customized NC documentation.
You will have to customize a VBScript macro file according to the document that you want to generate.
You can use the following scripting languages, depending on the platform you are running on: ● BasicScript 2.2 SDK for UNIX (BasicScript is a registered trademark of Summit Software Company)
● VBScript, short for Visual Basic Scripting Edition, for Windows (Visual Basic is a registered trademark of Microsoft Corporation).
Users on Windows must have Windows Scripting Host installed.
1. Open a sample delivered with the product from \Startup\Manufacturing\Documentation.
2. Open the document delivered with the product in \Startup\Manufacturing\Documentation\NCDocumentationReadMe.htm.
This document describes the interfaces to help you to produce NC manufacturing documentation.
3. Modify the sample according to the type of document you want.
4. Generate the documentation as described in Generate NC Documentation.
Workbenches and Tool Bars
This task shows how to customize workbenches and tool bars from Machining Processes managed in catalog files.
You can define your own toolbars to create one or more operations in your program from the Machining Process instantiation window.
1. In your catalog document (containing external feature links toward Machining Processes), select a component (an external link).
2. Select Publish Catalog Object in the contextual menu (right-click) in the Keywords tab page.
3. The Publishing Catalog Alias window appears. Enter your Alias name.
Repeat this sequence for all Machining process links you want to use in a toolbar, then close your catalog document.
4. In your Machining workbench, select Tools > Customize.
The Customize window is appears.
If necessary, select the Toolbars tab page and create your toolbar.
5. In the Commands tab page, select Catalogs in the Categories list.
6. Select your command (corresponding to the Alias name) that you want to add in your toolbar.
7. Select the icon that you want to associate to the command (Hide/Show Properties button).
8. Drag and Drop the selected command line onto your toolbar.
Now you can use the command through its toolbar whenever necessary.
Reference InformationThis section provides essential reference information on the following topics.
Machining ResourcesNC Macros
Transition Path ManagementPP Tables and PP Word Syntaxes
Feeds and SpeedsNC Data Options
APT FormatsClfile Formats
NC Data Import to Support Legacy DataFeature Attributes for Tool Queries, Checks and Formula
PLM Integration
Machining ResourcesAll supported Machining resources are presented in this section:
● Machine tools:
❍ 3-axis machine
❍ 3-axis machine with table rotation
❍ 5-axis machine
❍ Horizontal lathe
❍ Vertical lathe
● Tool assemblies
❍ Mill and drill assembly
❍ Lathe assembly
● Tools for milling and drilling operations:
❍ Face Mill
❍ End Mill
❍ Center Drill
❍ Spot Drill
❍ Drill
❍ Countersink
❍ Reamer
❍ Boring Bar
❍ Tap
❍ T-Slotter
❍ Multi-Diameter Drill
❍ Two Sides Chamfering Tool
❍ Boring and Chamfering Tool
❍ Conical Mill
❍ Thread Mill
❍ Counterbore Mill
● Tools (that is, insert holders) for turning operations:
❍ External Insert Holder
❍ Internal Insert Holder
❍ External Groove Insert Holder
❍ Frontal Groove Insert Holder
❍ Internal Groove Insert Holder
❍ External Thread Insert Holder
❍ Internal Thread Insert Holder
● Inserts for turning operations:
❍ Diamond Insert
❍ Square Insert
❍ Triangular Insert
❍ Round Insert
❍ Trigon Insert
❍ Groove Insert
❍ Thread Insert
The described attributes are particularly useful for tasks such as Building a catalog of tools.
Tools for Milling and Drilling Operations
Face Mill
The MFG_NAME_BAS attribute for this tool is MfgFaceMillTool
This tool type has only one compensation site P1, which is located at the extremity of the tool.
Manufacturing geometry attributes used in this resource are:
Nominal Diameter (D) MFG_NOMINAL_DIAM
Outside Diameter (Da) MFG_OUTSIDE_DIAM
Overall Length (L) MFG_OVERALL_LGTH
Length (l) MFG_LENGTH
Cutting Length (lc) MFG_CUT_LENGTH
Corner Radius (Rc) MFG_CORNER_RAD
Body Diameter (Db) MFG_BODY_DIAM
Cutting Angle (A) MFG_CUT_ANGLE
Non Cutting Diameter MFG_TOOL_CORE_DIAMETER
More information about the Geometry, Technology and Cutting Conditions attributes of this resource is available in the Tool Resources section.
End Mill
The MFG_NAME_BAS attribute for this tool is MfgEndMillTool
This tool type has only one compensation site P1, which is located at the extremity of the tool.
Manufacturing geometry attributes used in this resource are:
Nominal Diameter (D) MFG_NOMINAL_DIAM
Overall Length (L) MFG_OVERALL_LGTH
Length (l) MFG_LENGTH
Cutting Length (lc) MFG_CUT_LENGTH
Corner Radius (Rc) MFG_CORNER_RAD
Body Diameter (Db) MFG_BODY_DIAM
Non Cutting Diameter MFG_TOOL_CORE_DIAMETER
More information about the Geometry, Technology and Cutting Conditions attributes of this resource is available in the Tool Resources section.
Center Drill
The MFG_NAME_BAS attribute for this tool is MfgCenterDrillTool.
This tool type has six compensation sites P1 to P6, which are located on the tool as shown below.
Manufacturing geometry attributes used in this resource are:
Nominal Diameter (D) MFG_NOMINAL_DIAM
Overall Length (L) MFG_OVERALL_LGTH
Length (l) MFG_LENGTH
Cutting Length (lc) MFG_CUT_LENGTH
Body Diameter (Db) MFG_BODY_DIAM
Cutting Angle (a1) MFG_CUT_ANGLE
Taper Angle (Ach) MFG_TAPER_ANGLE
More information about the Geometry, Technology and Cutting Conditions attributes of this resource is available in the Tool Resources section.
Spot Drill
The MFG_NAME_BAS attribute for this tool is MfgSpotDrillTool
This tool type has three compensation sites P1 to P3, which are located on the tool as shown below.
Manufacturing geometry attributes used in this resource are:
Nominal Diameter (D) MFG_NOMINAL_DIAM
Overall Length (L) MFG_OVERALL_LGTH
Length (l) MFG_LENGTH
Body Diameter (Db) MFG_BODY_DIAM
Cutting Angle (a) MFG_CUT_ANGLE
More information about the Geometry, Technology and Cutting Conditions attributes of this resource is available in the Tool Resources section.
Drill
The MFG_NAME_BAS attribute for this tool is MfgDrillTool
This tool type has three compensation sites P1 to P3, which are located on the tool as shown below.
Manufacturing geometry attributes used in this resource are:
Nominal Diameter (D) MFG_NOMINAL_DIAM
Overall Length (L) MFG_OVERALL_LGTH
Length (l) MFG_LENGTH
Cutting Length (lc) MFG_CUT_LENGTH
Tool Tip Length (ld) MFG_TL_TIP_LGTH
Body Diameter (Db) MFG_BODY_DIAM
Cutting Angle (a) MFG_CUT_ANGLE
More information about the Geometry, Technology and Cutting Conditions attributes of this resource is available in the Tool Resources section.
Countersink
The MFG_NAME_BAS attribute for this tool is MfgCountersinkTool
This tool type has three compensation sites P1 to P3, which are located on the tool as shown below.
Manufacturing geometry attributes used in this resource are:
Nominal Diameter (D) MFG_NOMINAL_DIAM
Outside Diameter (Da) MFG_OUTSIDE_DIAM
Overall Length (L) MFG_OVERALL_LGTH
Length (l) MFG_LENGTH
Cutting Length (lc) MFG_CUT_LENGTH
Entry Diameter (d) MFG_ENTRY_DIAM
Body Diameter (Db) MFG_BODY_DIAM
Cutting Angle (a) MFG_CUT_ANGLE
Corner radius (Rc) MFG_CORNER_RAD
More information about the Geometry, Technology and Cutting Conditions attributes of this resource is available in the Tool Resources section.
Reamer
The MFG_NAME_BAS attribute for this tool is MfgReamerTool
This tool type has only one compensation site P1, which is located at the extremity of the tool.
Manufacturing geometry attributes used in this resource are:
Nominal Diameter (D) MFG_NOMINAL_DIAM
Overall Length (L) MFG_OVERALL_LGTH
Length (l) MFG_LENGTH
Cutting Length (lc) MFG_CUT_LENGTH
Tool Tip Length (ld) MFG_TL_TIP_LGTH
Entry Diameter (d) MFG_ENTRY_DIAM
Body Diameter (Db) MFG_BODY_DIAM
More information about the Geometry, Technology and Cutting Conditions attributes of this resource is available in the Tool Resources section.
Boring Bar
The MFG_NAME_BAS attribute for this tool is MfgBoringBarTool
This tool type has three compensation sites P1, P2 and P3.
P1 is the most external point of the cutting flange projected onto the tool axis.
P2 is the lower edge of the cutting flange (Boring Bars) projected onto the tool axis.
P3 is the upper edge of the cutting flange (Back Boring Bars) projected onto the tool axis.
Manufacturing geometry attributes used in this resource are:
Nominal Diameter (D) MFG_NOMINAL_DIAM
Overall Length (L) MFG_OVERALL_LGTH
Length (l) MFG_LENGTH
Cutting Length (lc) MFG_CUT_LENGTH
Body Diameter (Db) MFG_BODY_DIAM
Cutting Angle (A) MFG_CUT_ANGLE
Non Cut Diameter (dn) MFG_NON_CUT_DIAM
Tip Length (lt) MFG_TIP_LENGTH
Tip Angle (E) MFG_TIP_ANGLE
Tip Radius (Re) MFG_TIP_RADIUS
Tool Angle (B) MFG_TOOL_ANGLE
Tool Tip Length (ld) MFG_TL_TIP_LGTH
Minimum Diameter MFG_MIN_DIAMETER
Maximum Diameter MFG_MAX_DIAMETER
More information about the Geometry, Technology and Cutting Conditions attributes of this resource is available in the Tool Resources section.
Tap
The MFG_NAME_BAS attribute for this tool is MfgTapTool.
This tool type has only one compensation site P1, which is located at the extremity of the tool.
Manufacturing geometry attributes used in this resource are:
Nominal Diameter (D) MFG_NOMINAL_DIAM
Overall Length (L) MFG_OVERALL_LGTH
Length (l) MFG_LENGTH
Cutting Length (lc) MFG_CUT_LENGTH
Tool Tip Length (ld) MFG_TL_TIP_LGTH
Body Diameter (Db) MFG_BODY_DIAM
Entry Diameter (d) MFG_ENTRY_DIAM
Taper Angle (Ach) MFG_TAPER_ANGLE
Nominal Diameter Location (Lnd) MFG_LENGTH_NOM_DIAM
Taps can have a tapered or straight flank. More information about the Geometry, Technology and Cutting Conditions attributes of this resource is available in the Tool Resources section.
T-Slotter
The MFG_NAME_BAS attribute for this tool is MfgTSlotterTool.
This tool type has two compensation sites P1 and P2, which are located on the tool as shown below.
Manufacturing geometry attributes used in this resource are:
Nominal Diameter (D) MFG_NOMINAL_DIAM
Overall Length (L) MFG_OVERALL_LGTH
Length (l) MFG_LENGTH
Corner Radius (Rc) MFG_CORNER_RAD
Upper corner Radius (Rc2) MFG_CORNER_RAD_2
Body Diameter (Db) MFG_BODY_DIAM
More information about the Geometry, Technology and Cutting Conditions attributes of this resource is available in the Tool Resources section.
Multi-Diameter Drill
The MFG_NAME_BAS attribute for this tool is MfgMultiDiamDrillTool
This tool type has nine compensation sites P1 to P9, which are located on the tool as shown below.
Manufacturing geometry attributes used in this resource are:
Nominal Diameter (D) MFG_NOMINAL_DIAM
Overall Length (L) MFG_OVERALL_LGTH
Length (l) MFG_LENGTH
Length (l1) MFG_LENGTH_1
Length (l2) MFG_LENGTH_2
Cutting Length (lc) MFG_CUT_LENGTH
Tool Tip Length (ld) MFG_TL_TIP_LGTH
Body Diameter (Db) MFG_BODY_DIAM
Cutting Angle (a1) MFG_CUT_ANGLE
Cutting Angle 2 (a2) MFG_ANGLE2
Taper Angle (Ach) MFG_TAPER_ANGLE
Chamfer Diameter 1 (Dc) MFG_CHAMFR_DIAM1
Chamfer Diameter 2 (Dc2) MFG_CHAMFR_DIAM2
More information about the Geometry, Technology and Cutting Conditions attributes of this resource is
available in the Tool Resources section.
Two Sides Chamfering Tool
The MFG_NAME_BAS attribute for this tool is MfgTwoSidesChamferingTool
This tool type has seven compensation sites P1 to P7, which are located on the tool as shown below.
Manufacturing geometry attributes used in this resource are:
Nominal Diameter (D) MFG_NOMINAL_DIAM
Entry Diameter (d) MFG_ENTRY_DIAM
Overall Length (L) MFG_OVERALL_LGTH
Length (l) MFG_LENGTH
Cutting Length (lc) MFG_CUT_LENGTH
Tool Tip Length (ld) MFG_TL_TIP_LGTH
Body Diameter (Db) MFG_BODY_DIAM
Cutting Angle (a1) MFG_CUT_ANGLE
Cutting Angle (a2) MFG_ANGLE2
More information about the Geometry, Technology and Cutting Conditions attributes of this resource is available in the Tool Resources section.
Boring and Chamfering Tool
The MFG_NAME_BAS attribute for this tool is MfgBoringAndChamferingTool
This tool type has four compensation sites P1 to P4, which are located on the tool as shown below.
Manufacturing geometry attributes used in this resource are:
Nominal Diameter (D) MFG_NOMINAL_DIAM
Chamfer Diameter (Dc) MFG_CHAMFR_DIAM1
Overall Length (L) MFG_OVERALL_LGTH
Length (l) MFG_LENGTH
Length 1 (l1) MFG_LENGTH_1
Cutting Length (lc) MFG_CUT_LENGTH
Body Diameter (Db) MFG_BODY_DIAM
Taper Angle (Ach) MFG_TAPER_ANGLE
Corner Radius (Rc) MFG_CORNER_RAD
More information about the Geometry, Technology and Cutting Conditions attributes of this resource is available in the Tool Resources section.
Conical Mill
The MFG_NAME_BAS attribute for this tool is MfgConicalMillTool
This tool type has three compensation sites P1 to P3, which are located on the tool as shown below.
Manufacturing geometry attributes used in this resource are:
Nominal Diameter (D) MFG_NOMINAL_DIAM
Entry Diameter (d) MFG_ENTRY_DIAM
Overall Length (L) MFG_OVERALL_LGTH
Length (l) MFG_LENGTH
Cutting Length (lc) MFG_CUT_LENGTH
Corner Radius (Rc) MFG_CORNER_RAD
Body Diameter (Db) MFG_BODY_DIAM
Cutting Angle (a) MFG_CUT_ANGLE
More information about the Geometry, Technology and Cutting Conditions attributes of this resource is available in the Tool Resources section.
Thread Mill
The MFG_NAME_BAS attribute for this tool is MfgThreadMillTool
This tool type has only one compensation site P1, which is located at the extremity of the tool.
Manufacturing geometry attributes used in this resource are:
Nominal Diameter (D) MFG_NOMINAL_DIAM
Overall Length (L) MFG_OVERALL_LGTH
Length (l) MFG_LENGTH
Cutting Length (lc) MFG_CUT_LENGTH
Outside Diameter (Da) MFG_OUTSIDE_DIAM
Body Diameter (Db) MFG_BODY_DIAM
Length 1 (l1) MFG_LENGTH_1
Taper Angle (Ach) MFG_TAPER_ANGLE
More information about the Geometry, Technology and Cutting Conditions attributes of this resource is available in the Tool Resources section.
Counterbore Mill
The MFG_NAME_BAS attribute for this tool is MfgCounterboreMillTool
This tool type has only one compensation site P1, which is located on the tool as shown below.
Manufacturing geometry attributes used in this resource are:
Nominal Diameter (D) MFG_NOMINAL_DIAM
Overall Length (L) MFG_OVERALL_LGTH
Length (l) MFG_LENGTH
Cutting Length (lc) MFG_CUT_LENGTH
Entry Diameter (d) MFG_ENTRY_DIAM
Body Diameter (Db) MFG_BODY_DIAM
Tool Tip Length (ld) MFG_TL_TIP_LGTH
More information about the Geometry, Technology and Cutting Conditions attributes of this resource is available in the Tool Resources section.
Tools for Turning Operations
External Insert Holder
The MFG_NAME_BAS attribute for this tool isMfgExternalTool.
The main Manufacturing geometry attributes used in this resource are:
MFG_SHANK_HEIGHT: h
MFG_SHANK_WIDTH: b
MFG_SHK_LENGTH_1: l1
MFG_SHK_LENGTH_2: l2
MFG_SHK_CUT_WDTH: f
MFG_KAPPA_R: Kr
More information about the Geometry and Technology attributes of this resource is available in the Tool Resources section.
Internal Insert Holder
The MFG_NAME_BAS attribute for this tool isMfgInternalTool.
The main Manufacturing geometry attributes used in this resource are:
MFG_BODY_DIAM: db
MFG_BAR_LENGTH_1: l1
MFG_BAR_LENGTH_2: l2
MFG_BAR_CUT_RAD: f
MFG_KAPPA_R: Kr
More information about the Geometry and Technology attributes of this resource is available in the Tool Resources section.
External Groove Insert Holder
The MFG_NAME_BAS attribute for this tool isMfgGrooveExternalTool.
The main Manufacturing geometry attributes used in this resource are:
MFG_SHANK_HEIGHT: h
MFG_SHANK_WIDTH: b
MFG_SHK_LENGTH_1: l1
MFG_SHK_LENGTH_2: l2
MFG_SHK_CUT_WDTH: f
More information about the Geometry and Technology attributes of this resource is available in the Tool Resources section.
Frontal Groove Insert Holder
The MFG_NAME_BAS attribute for this tool isMfgGrooveFrontalTool
The main Manufacturing geometry attributes used in this resource are:
MFG_SHANK_HEIGHT: h
MFG_SHANK_WIDTH: b
MFG_SHK_LENGTH_1: l1
MFG_SHK_LENGTH_2: l2
MFG_SHK_CUT_WDTH: f
More information about the Geometry and Technology attributes of this resource is available in the Tool Resources section.
Internal Groove Insert Holder
The MFG_NAME_BAS attribute for this tool isMfgGrooveInternalTool
The main Manufacturing geometry attributes used in this resource are:
MFG_BODY_DIAM: db
MFG_BAR_LENGTH_1: l1
MFG_BAR_LENGTH_2: l2
MFG_BAR_CUT_RAD: f
More information about the Geometry and Technology attributes of this resource is available in the Tool Resources section.
External Thread Insert Holder
The MFG_NAME_BAS attribute for this tool isMfgThreadExternalTool
The main Manufacturing geometry attributes used in this resource are:
MFG_SHANK_HEIGHT: h
MFG_SHANK_WIDTH: b
MFG_SHK_LENGTH_1: l1
MFG_SHK_LENGTH_2: l2
MFG_SHK_CUT_WDTH: f
More information about the Geometry and Technology attributes of this resource is available in the Tool Resources section.
Internal Thread Insert Holder
The MFG_NAME_BAS attribute for this tool isMfgThreadInternalTool
The main Manufacturing geometry attributes used in this resource are:
MFG_BODY_DIAM: db
MFG_BAR_LENGTH_1: l1
MFG_BAR_LENGTH_2: l2
MFG_BAR_CUT_RAD: f
More information about the Geometry and Technology attributes of this resource is available in the Tool Resources section.
Lathe Inserts
Diamond Insert
The MFG_NAME_BAS attribute for this insert isMfgDiamondInsert
The main Manufacturing geometry attributes used in this resource are:
MFG_INSCRIB_DIAM: IC
MFG_INSERT_LGTH: l
MFG_INSERT_THICK: s
MFG_NOSE_RADIUS: r
MFG_INSERT_ANGL: a
More information about the Geometry, Technology and Cutting Conditions attributes of this resource is available in the Inserts section.
Square Insert
The MFG_NAME_BAS attribute for this insert isMfgSquareInsert
The main Manufacturing geometry attributes used in this resource are:
MFG_INSCRIB_DIAM: IC
MFG_INSERT_LGTH: l
MFG_INSERT_THICK: s
MFG_NOSE_RADIUS: r
More information about the Geometry, Technology and Cutting Conditions attributes of this resource is available in the Inserts section.
Triangular Insert
The MFG_NAME_BAS attribute for this insert isMfgTriangularInsert
The main Manufacturing geometry attributes used in this resource are:
MFG_INSCRIB_DIAM: IC
MFG_INSERT_LGTH: l
MFG_INSERT_THICK: s
MFG_NOSE_RADIUS: r
More information about the Geometry, Technology and Cutting Conditions attributes of this resource is available in the Inserts section.
Round Insert
The MFG_NAME_BAS attribute for this insert isMfgRoundInsert
The main Manufacturing geometry attributes used in this resource are:
MFG_NOSE_RADIUS: r
MFG_INSERT_THICK: s
More information about the Geometry, Technology and Cutting Conditions attributes of this resource is available in the Inserts section.
Trigon Insert
The MFG_NAME_BAS attribute for this insert isMfgTrigonInsert
The main Manufacturing geometry attributes used in this resource are:
MFG_INSCRIB_DIAM: IC
MFG_INSERT_LGTH: l
MFG_INSERT_THICK: s
MFG_NOSE_RADIUS: r
More information about the Geometry, Technology and Cutting Conditions attributes of this resource is available in the Inserts section.
Groove Insert
The MFG_NAME_BAS attribute for this insert isMfgGrooveInsert
The main Manufacturing geometry attributes used in this resource are:
MFG_INSERT_LGTH: l
MFG_INSERT_THICK
MFG_INSERT_WIDTH: la
MFG_NOSE_RAD_1: r1
MFG_NOSE_RAD_2: r2
MFG_BOTTOM_ANGLE: b
MFG_FLANK_ANG_1: a1
MFG_FLANK_ANG_2: a2
MFG_CUT_LENGTH: l1
More information about the Geometry, Technology and Cutting Conditions attributes of this resource is available in the Inserts section.
Thread Insert
The MFG_NAME_BAS attribute for this insert isMfgThreadInsert
The main Manufacturing geometry attributes used in this resource are:
MFG_INSERT_LGTH: l
MFG_INSERT_THICK
MFG_NOSE_RADIUS
MFG_THREAD_ANGLE
MFG_TOOTH_X
MFG_TOOTH_Z
MFG_TOOTH_H
More information about the Geometry, Technology and Cutting Conditions attributes of this resource is available in the Inserts section.
Machine Tool ResourcesAll supported NC Machine resources are presented in this section:
● NC machines
❍ 3-axis machine
❍ 3-axis machine with table rotation
❍ 5-axis machine
❍ Horizontal lathe
❍ Vertical lathe
Mfg3AxisMachine (3-axis Machine)
Description
Describes the Mfg3AxisMachine resource attributes that are available in Machining workbenches.
Base Attributes
These attributes provide general information.
MFG_NAME (Name)Type: StringSpecifies the name of the resource. MFG_COMMENT (Comment)Type: StringAssociates a comment to the resource.
Numerical Control Attributes
These attributes characterize the machine controller and have an impact on the output format.
MFG_PP_WORD_TBL (Post Processor words table)Type: StringSpecifies the name of the PP words table which is used for creating Post Processor word syntaxes.
MFG_OUTPUT_TYPE (NC data type)Type: StringPossible values:APTCLF-3000CLF-15000ISOSpecifies the type of NC data output by the application. It can take the following values: APT (APT source, this is the default), CLF-3000 (clfile record types 3000 and 5000 are output), CLF-15000 (clfile record type 15000 is output), ISO. MFG_OUTPUT_FRMT (NC data format)Type: StringPossible values:POINT (Point (X,Y,Z))AXIS (Axis (X,Y,Z,I,J,K))Specifies the format of the NC data output. It can take the following values: POINT (X,Y,Z point coordinates, by default), AXIS (X,Y,Z,I,J,K point coordinates and tool axis components). MFG_STRT_PT_SYNT (Home point strategy)Type: StringPossible values:FROM (FROM)GOTO (GOTO)Specifies the type of trajectory on the start point: GOTO or FROM MFG_MAX_FEEDRATE (Max machining feedrate)Type: RealSpecifies the maximum machining feedrate. This is used in NC Manufacturing Verification product. Errors (tool collision with the stock) will be reported if the feedrate exceeds this value.MFG_RAPID_FEED (Rapid feedrate)Type: RealSpecifies the rapid feedrate. This is used to compute the total machining time and may replace the RAPID instruction in output APT files.MFG_AXIAL_RADIAL_MOVE (Axial/Radial movement)Type: Boolean (Yes/No)Specifies the ability to generate automatically axial and radial movements to avoid collisions in axial operations MFG_INT_LIN_3D (3D linear interpol.)Type: Boolean (Yes/No)Specifies if the machine is able to make a 3D linear interpolation between 2 points. MFG_INT_CIRC_2D (2D circular interpol.)Type: Boolean (Yes/No)Specifies if the machine is able to make a 2D circular interpolation between 2 points. MFG_INT_CIRC_3D (3D circular interpol.)Type: Boolean (Yes/No)Specifies if the machine is able to make a 3D circular interpolation between 2 points. MFG_R_MIN_CIRC (Min interpol. radius)Type: RealSpecifies the minimum radius of circular interpolation that the machine is able to achieve. MFG_R_MAX_CIRC (Max interpol. radius)Type: RealSpecifies the maximum radius of circular interpolation that the machine is able to achieve.
MFG_MIN_DISC (Min discretization step)Type: RealSpecifies the minimum distance between two consecutive points that the machine is able to achieve.
Note:The application compares the minimum discretization step and the machining tolerance. The larger of the two values is taken to be the minimum distance between two points.
When you generate NC data, any points that are spaced at a distance less than this value are eliminated from the output file.MFG_MIN_ANGLE (Min discretization angle)Type: RealSpecifies minimum angle between tool axis at two consecutive points that the machine is able to achieve. The application eliminates points whose tool axis orientation does not meet this criteria. MFG_NURBS_OUTPUT (3D Nurbs interpolation)Type: Boolean (Yes/No)Specifies the ability to generate NURBS data in an APT output file.
Spindle Attributes
These attributes provide information on the spindle definition.
MFG_X_HOME_POS (Home point X)Type: RealDefines the X coordinate of the home point with respect to the reference machining axis system. Note that this point is taken into account when replaying a table rotation if this rotation is located at the first position of the program. MFG_Y_HOME_POS (Home point Y)Type: RealDefines the Y coordinate of the home point with respect to the reference machining axis system. Note that this point is taken into account when replaying a table rotation if this rotation is located at the first position of the program. MFG_Z_HOME_POS (Home point Z)Type: RealDefines the Z coordinate of the home point with respect to the reference machining axis system. Note that this point is taken into account when replaying a table rotation if this rotation is located at the first position of the program. MFG_X_INIT_SPNDL (Orientation I)Type: RealSpecifies the I component of the initial spindle orientation with respect to the reference machining axis system. MFG_Y_INIT_SPNDL (Orientation J)Type: RealSpecifies the J component of the initial spindle orientation with respect to the reference machining axis system. MFG_Z_INIT_SPNDL (Orientation K)Type: RealSpecifies the K component of the initial spindle orientation with respect to the reference machining axis system.
Mfg3AxisWithTableRotationMachine (3-axis With Rotary Table Machine)
Description
Describes the Mfg3AxisWithTableRotationMachine resource attributes that are available in Machining workbenches.
Base Attributes
These attributes provide general information.
MFG_NAME (Name)Type: StringSpecifies the name of the resource. MFG_COMMENT (Comment)Type: StringAssociates a comment to the resource.
Numerical Control Attributes
These attributes characterize the machine controller and have an impact on the output format.
MFG_PP_WORD_TBL (Post Processor words table)Type: StringSpecifies the name of the PP words table which is used for creating Post Processor word syntaxes. MFG_OUTPUT_TYPE (NC data type)Type: StringPossible values:APTCLF-3000CLF-15000ISOSpecifies the type of NC data output by the application. It can take the following values: APT (APT source, this is the default), CLF-3000 (clfile record types 3000 and 5000 are output), CLF-15000 (clfile record type 15000 is output), ISO. MFG_OUTPUT_FRMT (NC data format)Type: StringPossible values:POINT (Point (X,Y,Z))AXIS (Axis (X,Y,Z,I,J,K))Specifies the format of the NC data output. It can take the following values: POINT (X,Y,Z point coordinates, by default), AXIS (X,Y,Z,I,J,K point coordinates and tool axis components). MFG_STRT_PT_SYNT (Home point strategy)Type: StringPossible values:FROM (FROM)GOTO (GOTO)Specifies the type of trajectory on the start point: GOTO or FROM MFG_MAX_FEEDRATE (Max machining feedrate)Type: RealSpecifies the maximum machining feedrate. This is used in NC Manufacturing Verification product. Errors (tool collision with the stock) will be reported if the feedrate exceeds this value
MFG_RAPID_FEED (Rapid feedrate)Type: RealSpecifies the rapid feedrate. This is used to compute the total machining time and may replace the RAPID instruction in output APT files.MFG_AXIAL_RADIAL_MOVE (Axial/Radial movement)Type: Boolean (Yes/No)Specifies the ability to generate automatically axial and radial movements to avoid collisions in axial operations MFG_INT_LIN_3D (3D linear interpol.)Type: Boolean (Yes/No)Specifies if the machine is able to make a 3D linear interpolation between 2 points. MFG_INT_CIRC_2D (2D circular interpol.)Type: Boolean (Yes/No)Specifies if the machine is able to make a 2D circular interpolation between 2 points. MFG_INT_CIRC_3D (3D circular interpol.)Type: Boolean (Yes/No)Specifies if the machine is able to make a 3D circular interpolation between 2 points. MFG_R_MIN_CIRC (Min interpol. radius)Type: RealSpecifies the minimum radius of circular interpolation that the machine is able to achieve. MFG_R_MAX_CIRC (Max interpol. radius)Type: RealSpecifies the maximum radius of circular interpolation that the machine is able to achieve. MFG_MIN_DISC (Min discretization step)Type: RealSpecifies the minimum distance between two consecutive points that the machine is able to achieve.
Note:The application compares the minimum discretization step and the machining tolerance. The larger of the two values is taken to be the minimum distance between two points.
When you generate NC data, any points that are spaced at a distance less than this value are eliminated from the output file.MFG_MIN_ANGLE (Min discretization angle)Type: RealSpecifies minimum angle between tool axis at two consecutive points that the machine is able to achieve. The application eliminates points whose tool axis orientation does not meet this criteria. MFG_NURBS_OUTPUT (3D Nurbs interpolation)Type: Boolean (Yes/No)Specifies the ability to generate NURBS data in an APT output file.MFG_ROTABL_OUTPUT (Rotabl output in cycle)Type: Boolean (Yes/No)Specifies the ability to output Rotabl statement inside Axial operation cycle statement
Rotary Table Attributes
These attributes provide information on the rotary table and have an impact on table rotation capabilities.
MFG_X_ROT_CENTER (Center point X)Type: RealDefines the X coordinate of the center of rotation of the rotary table with respect to the reference machining axis system.
MFG_Y_ROT_CENTER (Center point Y)Type: RealDefines the Y coordinate of the center of rotation of the rotary table with respect to the reference machining axis system. MFG_Z_ROT_CENTER (Center point Z)Type: RealDefines the Z coordinate of the center of rotation of the rotary table with respect to the reference machining axis system. MFG_INIT_ROT_POS (Initial position)Type: RealIf the machine has a rotary table, specifies the initial angular position of the rotary table. MFG_ROTARY_ANGLE (Rotary angle)Type: RealIf the machine has a rotary table, specifies the rotary angle. MFG_ROTARY_AXIS (Rotary axis)Type: StringPossible values:ABCIf the machine has a rotary table, specifies which axis (A, B or C) of the reference machining axis system is parallel to the rotary axis. MFG_ROT_DIR (Rotary direction)Type: StringPossible values:CLW (Clockwise)CCLW (Counter-clockwise)BOTH (Shortest)Defines the rotary direction that the machine can accept: Clockwise, Counterclockwise, or Shortest. MFG_ROT_TYP (Rotary type)Type: StringPossible values:ABS (Absolute)Defines the rotary angle as absolute. This is the only option available in the current version.
Spindle Attributes
These attributes provide information on the spindle definition.
MFG_X_HOME_POS (Home point X)Type: RealDefines the X coordinate of the home point with respect to the reference machining axis system. Note that this point is taken into account when replaying a table rotation if this rotation is located at the first position of the program. MFG_Y_HOME_POS (Home point Y)Type: RealDefines the Y coordinate of the home point with respect to the reference machining axis system. Note that this point is taken into account when replaying a table rotation if this rotation is located at the first position of the program. MFG_Z_HOME_POS (Home point Z)Type: RealDefines the Z coordinate of the home point with respect to the reference machining axis system. Note that this point is taken into account when replaying a table rotation if this rotation is located at the first position of the program.
MFG_X_INIT_SPNDL (Orientation I)Type: RealSpecifies the I component of the initial spindle orientation with respect to the reference machining axis system. MFG_Y_INIT_SPNDL (Orientation J)Type: RealSpecifies the J component of the initial spindle orientation with respect to the reference machining axis system. MFG_Z_INIT_SPNDL (Orientation K)Type: RealSpecifies the K component of the initial spindle orientation with respect to the reference machining axis system.
Mfg5AxisMachine (5-axis Machine)
Description
Describes the Mfg5AxisMachine resource attributes that are available in Machining workbenches.
Base Attributes
These attributes provide general information.
MFG_NAME (Name)Type: StringSpecifies the name of the resource. MFG_COMMENT (Comment)Type: StringAssociates a comment to the resource.
Numerical Control Attributes
These attributes characterize the machine controller and have an impact on the output format.
MFG_PP_WORD_TBL (Post Processor words table)Type: StringSpecifies the name of the PP words table which is used for creating Post Processor word syntaxes. MFG_OUTPUT_TYPE (NC data type)Type: StringPossible values:APTCLF-3000CLF-15000ISOSpecifies the type of NC data output by the application. It can take the following values: APT (APT source, this is the default), CLF-3000 (clfile record types 3000 and 5000 are output), CLF-15000 (clfile record type 15000 is output), ISO.
MFG_OUTPUT_FRMT (NC data format)Type: StringPossible values:POINT (Point (X,Y,Z))AXIS (Axis (X,Y,Z,I,J,K))Specifies the format of the NC data output. It can take the following values: POINT (X,Y,Z point coordinates, by default), AXIS (X,Y,Z,I,J,K point coordinates and tool axis components). MFG_STRT_PT_SYNT (Home point strategy)Type: StringPossible values:FROM (FROM)GOTO (GOTO)Specifies the type of trajectory on the start point: GOTO or FROM MFG_MAX_FEEDRATE (Max machining feedrate)Type: RealSpecifies the maximum machining feedrate. This is used in NC Manufacturing Verification product. Errors (tool collision with the stock) will be reported if the feedrate exceeds this value MFG_RAPID_FEED (Rapid feedrate)Type: RealSpecifies the rapid feedrate. This is used to compute the total machining time and may replace the RAPID instruction in output APT files.MFG_AXIAL_RADIAL_MOVE (Axial/Radial movement)Type: Boolean (Yes/No)Specifies the ability to generate automatically axial and radial movements to avoid collisions in axial operations MFG_INT_LIN_3D (3D linear interpol.)Type: Boolean (Yes/No)Specifies if the machine is able to make a 3D linear interpolation between 2 points. MFG_INT_CIRC_2D (2D circular interpol.)Type: Boolean (Yes/No)Specifies if the machine is able to make a 2D circular interpolation between 2 points. MFG_INT_CIRC_3D (3D circular interpol.)Type: Boolean (Yes/No)Specifies if the machine is able to make a 3D circular interpolation between 2 points. MFG_R_MIN_CIRC (Min interpol. radius)Type: RealSpecifies the minimum radius of circular interpolation that the machine is able to achieve. MFG_R_MAX_CIRC (Max interpol. radius)Type: RealSpecifies the maximum radius of circular interpolation that the machine is able to achieve. MFG_MIN_DISC (Min discretization step)Type: RealSpecifies the minimum distance between two consecutive points that the machine is able to achieve.
Note:The application compares the minimum discretization step and the machining tolerance. The larger of the two values is taken to be the minimum distance between two points.
When you generate NC data, any points that are spaced at a distance less than this value are eliminated from the output file.MFG_MIN_ANGLE (Min discretization angle)Type: RealSpecifies minimum angle between tool axis at two consecutive points that the machine is able to achieve. The application eliminates points whose tool axis orientation does not meet this criteria.
MFG_NURBS_OUTPUT (3D Nurbs interpolation)Type: Boolean (Yes/No)Specifies the ability to generate NURBS data in an APT output file.
Spindle Attributes
These attributes provide information on the spindle definition.
MFG_X_HOME_POS (Home point X)Type: RealDefines the X coordinate of the home point with respect to the reference machining axis system. Note that this point is taken into account when replaying a table rotation if this rotation is located at the first position of the program. MFG_Y_HOME_POS (Home point Y)Type: RealDefines the Y coordinate of the home point with respect to the reference machining axis system. Note that this point is taken into account when replaying a table rotation if this rotation is located at the first position of the program. MFG_Z_HOME_POS (Home point Z)Type: RealDefines the Z coordinate of the home point with respect to the reference machining axis system. Note that this point is taken into account when replaying a table rotation if this rotation is located at the first position of the program. MFG_X_INIT_SPNDL (Orientation I)Type: RealSpecifies the I component of the initial spindle orientation with respect to the reference machining axis system. MFG_Y_INIT_SPNDL (Orientation J)Type: RealSpecifies the J component of the initial spindle orientation with respect to the reference machining axis system. MFG_Z_INIT_SPNDL (Orientation K)Type: RealSpecifies the K component of the initial spindle orientation with respect to the reference machining axis system.
MfgHorizontalLatheMachine (Horizontal Lathe Machine)
Description
Describes the MfgHorizontalLatheMachine resource attributes that are available in Machining workbenches.
Base Attributes
These attributes provide general information.
MFG_NAME (Name)Type: StringSpecifies the name of the resource.
MFG_COMMENT (Comment)Type: StringAssociates a comment to the resource.
Numerical Control Attributes
These attributes characterize the machine controller and have an impact on the output format.
MFG_PP_WORD_TBL (Post Processor words table)Type: StringSpecifies the name of the PP words table which is used for creating Post Processor word syntaxes. MFG_OUTPUT_TYPE (NC data type)Type: StringPossible values:APTCLF-3000CLF-15000ISOSpecifies the type of NC data output by the application. It can take the following values: APT (APT source, this is the default), CLF-3000 (clfile record types 3000 and 5000 are output), CLF-15000 (clfile record type 15000 is output), ISO. MFG_OUTPUT_FRMT (NC data format)Type: StringPossible values:POINT (Point (X,Y,Z))AXIS (Axis (X,Y,Z,I,J,K))Specifies the format of the NC data output. It can take the following values: POINT (X,Y,Z point coordinates, by default), AXIS (X,Y,Z,I,J,K point coordinates and tool axis components). MFG_STRT_PT_SYNT (Home point strategy)Type: StringPossible values:FROM (FROM)GOTO (GOTO)Specifies the type of trajectory on the start point: GOTO or FROM MFG_MAX_FEEDRATE (Max machining feedrate)Type: RealSpecifies the maximum machining feedrate. This is used in NC Manufacturing Verification product. Errors (tool collision with the stock) will be reported if the feedrate exceeds this value MFG_RAPID_FEED (Rapid feedrate)Type: RealSpecifies the rapid feedrate. This is used to compute the total machining time and may replace the RAPID instruction in output APT files.MFG_AXIAL_RADIAL_MOVE (Axial/Radial movement)Type: Boolean (Yes/No)Specifies the ability to generate automatically axial and radial movements to avoid collisions in axial operations MFG_INT_LIN_3D (3D linear interpol.)Type: Boolean (Yes/No)Specifies if the machine is able to make a 3D linear interpolation between 2 points. MFG_INT_CIRC_2D (2D circular interpol.)Type: Boolean (Yes/No)Specifies if the machine is able to make a 2D circular interpolation between 2 points.
MFG_INT_CIRC_3D (3D circular interpol.)Type: Boolean (Yes/No)Specifies if the machine is able to make a 3D circular interpolation between 2 points. MFG_R_MIN_CIRC (Min interpol. radius)Type: RealSpecifies the minimum radius of circular interpolation that the machine is able to achieve. MFG_R_MAX_CIRC (Max interpol. radius)Type: RealSpecifies the maximum radius of circular interpolation that the machine is able to achieve. MFG_MIN_DISC (Min discretization step)Type: RealSpecifies the minimum distance between two consecutive points that the machine is able to achieve.
Note:The application compares the minimum discretization step and the machining tolerance. The larger of the two values is taken to be the minimum distance between two points.
When you generate NC data, any points that are spaced at a distance less than this value are eliminated from the output file.MFG_MIN_ANGLE (Min discretization angle)Type: RealSpecifies minimum angle between tool axis at two consecutive points that the machine is able to achieve. The application eliminates points whose tool axis orientation does not meet this criteria.
Spindle Attributes
These attributes provide information on the spindle and have an impact on spindle capabilities.
MFG_X_ROT_CENTER (Center point X)Type: RealDefines the X coordinate of the center of rotation of the rotary table with respect to the reference machining axis system. MFG_Y_ROT_CENTER (Center point Y)Type: RealDefines the Y coordinate of the center of rotation of the rotary table with respect to the reference machining axis system. MFG_Z_ROT_CENTER (Center point Z)Type: RealDefines the Z coordinate of the center of rotation of the rotary table with respect to the reference machining axis system. MFG_INIT_ROT_POS (Initial position)Type: RealIf the machine has a rotary table, specifies the initial angular position of the rotary table. MFG_ROTARY_ANGLE (Rotary angle)Type: RealIf the machine has a rotary table, specifies the rotary angle.
MFG_ROT_DIR (Rotary direction)Type: StringPossible values:CLW (Clockwise)CCLW (Counter-clockwise)BOTH (Shortest)Defines the rotary direction that the machine can accept: Clockwise, Counterclockwise, or Shortest. MFG_ROT_TYP (Rotary type)Type: StringPossible values:ABS (Absolute)Defines the rotary angle as absolute. This is the only option available in the current version. MFG_LATHE_RAD_AX (Radial axis)Type: StringPossible values:XYZDefines the radial axis (X, Y or Z) MFG_LATHE_SPN_AX (Spindle axis)Type: StringPossible values:XYZDefines the spindle axis (X, Y or Z)
Turret Attributes
These attributes provide information on the turret definition.
MFG_X_HOME_POS (Home point X)Type: RealDefines the X coordinate of the home point with respect to the reference machining axis system. Note that this point is taken into account when replaying a table rotation if this rotation is located at the first position of the program. MFG_Y_HOME_POS (Home point Y)Type: RealDefines the Y coordinate of the home point with respect to the reference machining axis system. Note that this point is taken into account when replaying a table rotation if this rotation is located at the first position of the program. MFG_Z_HOME_POS (Home point Z)Type: RealDefines the Z coordinate of the home point with respect to the reference machining axis system. Note that this point is taken into account when replaying a table rotation if this rotation is located at the first position of the program. MFG_X_INIT_SPNDL (Orientation I)Type: RealSpecifies the I component of the initial spindle orientation with respect to the reference machining axis system. MFG_Y_INIT_SPNDL (Orientation J)Type: RealSpecifies the J component of the initial spindle orientation with respect to the reference machining axis system.
MFG_Z_INIT_SPNDL (Orientation K)Type: RealSpecifies the K component of the initial spindle orientation with respect to the reference machining axis system.
MfgVerticalLatheMachine (Vertical Lathe Machine)
Description
Describes the MfgVerticalLatheMachine resource attributes that are available in Machining workbenches.
Base Attributes
These attributes provide general information.
MFG_NAME (Name)Type: StringSpecifies the name of the resource. MFG_COMMENT (Comment)Type: StringAssociates a comment to the resource.
Numerical Control Attributes
These attributes characterize the machine controller and have an impact on the output format.
MFG_PP_WORD_TBL (Post Processor words table)Type: StringSpecifies the name of the PP words table which is used for creating Post Processor word syntaxes. MFG_OUTPUT_TYPE (NC data type)Type: StringPossible values:APTCLF-3000CLF-15000ISOSpecifies the type of NC data output by the application. It can take the following values: APT (APT source, this is the default), CLF-3000 (clfile record types 3000 and 5000 are output), CLF-15000 (clfile record type 15000 is output), ISO. MFG_OUTPUT_FRMT (NC data format)Type: StringPossible values:POINT (Point (X,Y,Z))AXIS (Axis (X,Y,Z,I,J,K))Specifies the format of the NC data output. It can take the following values: POINT (X,Y,Z point coordinates, by default), AXIS (X,Y,Z,I,J,K point coordinates and tool axis components).
MFG_STRT_PT_SYNT (Home point strategy)Type: StringPossible values:FROM (FROM)GOTO (GOTO)Specifies the type of trajectory on the start point: GOTO or FROM MFG_MAX_FEEDRATE (Max machining feedrate)Type: RealSpecifies the maximum machining feedrate. This is used in NC Manufacturing Verification product. Errors (tool collision with the stock) will be reported if the feedrate exceeds this value MFG_RAPID_FEED (Rapid feedrate)Type: RealSpecifies the rapid feedrate. This is used to compute the total machining time and may replace the RAPID instruction in output APT files.MFG_AXIAL_RADIAL_MOVE (Axial/Radial movement)Type: Boolean (Yes/No)Specifies the ability to generate automatically axial and radial movements to avoid collisions in axial operations MFG_INT_LIN_3D (3D linear interpol.)Type: Boolean (Yes/No)Specifies if the machine is able to make a 3D linear interpolation between 2 points. MFG_INT_CIRC_2D (2D circular interpol.)Type: Boolean (Yes/No)Specifies if the machine is able to make a 2D circular interpolation between 2 points. MFG_INT_CIRC_3D (3D circular interpol.)Type: Boolean (Yes/No)Specifies if the machine is able to make a 3D circular interpolation between 2 points. MFG_R_MIN_CIRC (Min interpol. radius)Type: RealSpecifies the minimum radius of circular interpolation that the machine is able to achieve. MFG_R_MAX_CIRC (Max interpol. radius)Type: RealSpecifies the maximum radius of circular interpolation that the machine is able to achieve. MFG_MIN_DISC (Min discretization step)Type: RealSpecifies the minimum distance between two consecutive points that the machine is able to achieve.
Note:The application compares the minimum discretization step and the machining tolerance. The larger of the two values is taken to be the minimum distance between two points.
When you generate NC data, any points that are spaced at a distance less than this value are eliminated from the output file.MFG_MIN_ANGLE (Min discretization angle)Type: RealSpecifies minimum angle between tool axis at two consecutive points that the machine is able to achieve. The application eliminates points whose tool axis orientation does not meet this criteria.
Spindle Attributes
These attributes provide information on the spindle and have an impact on spindle capabilities.
MFG_X_ROT_CENTER (Center point X)Type: RealDefines the X coordinate of the center of rotation of the rotary table with respect to the reference machining axis system. MFG_Y_ROT_CENTER (Center point Y)Type: RealDefines the Y coordinate of the center of rotation of the rotary table with respect to the reference machining axis system. MFG_Z_ROT_CENTER (Center point Z)Type: RealDefines the Z coordinate of the center of rotation of the rotary table with respect to the reference machining axis system. MFG_INIT_ROT_POS (Initial position)Type: RealIf the machine has a rotary table, specifies the initial angular position of the rotary table. MFG_ROTARY_ANGLE (Rotary angle)Type: RealIf the machine has a rotary table, specifies the rotary angle. MFG_ROT_DIR (Rotary direction)Type: StringPossible values:CLW (Clockwise)CCLW (Counter-clockwise)BOTH (Shortest)Defines the rotary direction that the machine can accept: Clockwise, Counterclockwise, or Shortest. MFG_ROT_TYP (Rotary type)Type: StringPossible values:ABS (Absolute)Defines the rotary angle as absolute. This is the only option available in the current version. MFG_LATHE_RAD_AX (Radial axis)Type: StringPossible values:XYZDefines the radial axis (X, Y or Z) MFG_LATHE_SPN_AX (Spindle axis)Type: StringPossible values:XYZDefines the spindle axis (X, Y or Z)
Turret Attributes
These attributes provide information on the turret definition and have an impact on turret capabilities.
MFG_X_HOME_POS (Home point X)Type: RealDefines the X coordinate of the home point with respect to the reference machining axis system. Note that this point is taken into account when replaying a table rotation if this rotation is located at the first position of the program.
MFG_Y_HOME_POS (Home point Y)Type: RealDefines the Y coordinate of the home point with respect to the reference machining axis system. Note that this point is taken into account when replaying a table rotation if this rotation is located at the first position of the program. MFG_Z_HOME_POS (Home point Z)Type: RealDefines the Z coordinate of the home point with respect to the reference machining axis system. Note that this point is taken into account when replaying a table rotation if this rotation is located at the first position of the program. MFG_X_INIT_SPNDL (Orientation I)Type: RealSpecifies the I component of the initial spindle orientation with respect to the reference machining axis system. MFG_Y_INIT_SPNDL (Orientation J)Type: RealSpecifies the J component of the initial spindle orientation with respect to the reference machining axis system. MFG_Z_INIT_SPNDL (Orientation K)Type: RealSpecifies the K component of the initial spindle orientation with respect to the reference machining axis system.
Traverser Attributes
These attributes provide information on the lathe traverser definition.
MFG_TRAVERSE_NB (Traverse number)Type: IntegerDefines the number of traverse MFG_TRAV_PITCH (Traverse pitch)Type: RealDefines the pitch between two traverses
Tool Assembly ResourcesAll supported Tool Assembly resources are presented in this section:
● Lathe assembly
● Mill and drill assembly.
MfgLatheToolAssembly (Lathe Assembly)
Description
Describes the MfgLatheToolAssembly resource attributes that are available in Machining workbenches.
Base Attributes
These attributes provide general information.
MFG_NAME (Name)Type: StringSpecifies the name of the resource. MFG_COMMENT (Comment)Type: StringAssociates a comment to the resource. MFG_TOOL_NUMBER (Tool number)Type: IntegerDefines the tool number. The manufacturing attribute is MFG_TOOL_NUMBER. MFG_TL_SETUP_ANG (Setup angle)Type: RealDefines the tool assembly setup angle. The manufacturing attribute is MFG_TL_SETUP_ANG.
Geometry Attributes
These attributes characterize the assembly shape and have an impact on the collision detection capability.
MFG_TL_SET_X (Set X)Type: RealSpecifies the X component of the total set length of the tool assembly. The manufacturing attribute is MFG_TL_SET_X. MFG_TL_SET_Y (Set Y)Type: RealSpecifies the Y component of the total set length of the tool assembly. The manufacturing attribute is MFG_TL_SET_Y. MFG_TL_SET_Z (Set Z)Type: RealSpecifies the Z component of the total set length of the tool assembly. The manufacturing attribute is MFG_TL_SET_Z.
MFG_TOOL_INVERT (Tool inverted)Type: Boolean (Yes/No)Defines if the tool has been inverted. The manufacturing attribute is MFG_TOOL_INVERT.
Technology Attributes
These attributes provide technological information without any impact on the tool path computation.
MFG_NB_OF_COMP (Number of components)Type: IntegerSpecifies the number of components of the tool assembly. The manufacturing attribute is MFG_NB_OF_COMP. MFG_OUTP_PREF_1 (Pref. output point 1)Type: StringPossible values:MfgNone (None)P1P2P3P4P5P6P7P8P9P9RDefines the first preferred output point. The manufacturing attribute is MFG_OUTP_PREF_1. MFG_OUTP_PREF_2 (Pref. output point 2)Type: StringPossible values:MfgNone (None)P1P2P3P4P5P6P7P8P9P9RDefines the second preferred output point. The manufacturing attribute is MFG_OUTP_PREF_2.
MFG_OUTP_PREF_3 (Pref. output point 3)Type: StringPossible values:MfgNone (None)P1P2P3P4P5P6P7P8P9P9RDefines the third preferred output point. The manufacturing attribute is MFG_OUTP_PREF_3.
MfgMillAndDrillToolAssembly (Milling Assembly)
Description
Describes the MfgMillAndDrillToolAssembly resource attributes that are available in Machining workbenches.
Base Attributes
These attributes provide general information.
MFG_NAME (Name)Type: StringSpecifies the name of the resource. MFG_COMMENT (Comment)Type: StringAssociates a comment to the resource. MFG_TOOL_NUMBER (Tool number)Type: IntegerDefines the tool number. The manufacturing attribute is MFG_TOOL_NUMBER.
Geometry Attributes
These attributes characterize the assembly shape and have an impact on the collision detection capability.
MFG_DIAMETER_1 (Diameter 1 : D1)Type: RealSpecifies the maximum diameter of the tool. The manufacturing attribute is MFG_DIAMETER_1. MFG_DIAMETER_2 (Diameter 2 : D2)Type: RealSpecifies the maximum diameter of the adapter or holder depending on the number of components on the tool assembly. The manufacturing attribute is MFG_DIAMETER_2. MFG_DIAMETER_3 (Diameter 3 : D3)Type: RealSpecifies the maximum diameter of the tool assembly holder. It is valuated only if the number of components is 3. The manufacturing attribute is MFG_DIAMETER_3.
MFG_TL_SET_LGTH (Total set length : ST)Type: RealSpecifies the total set length of the tool assembly. The manufacturing attribute is MFG_TL_SET_LGTH. MFG_TL_SET_X (Set X)Type: RealSpecifies the X component of the total set length of the tool assembly. The manufacturing attribute is MFG_TL_SET_X. MFG_TL_SET_Y (Set Y)Type: RealSpecifies the Y component of the total set length of the tool assembly. The manufacturing attribute is MFG_TL_SET_Y. MFG_TL_SET_Z (Set Z)Type: RealSpecifies the Z component of the total set length of the tool assembly. The manufacturing attribute is MFG_TL_SET_Z. MFG_ORIENT_ANGLE (Orientation)Type: RealIf a boring bar is used, defines the angle between the boring bar and the tool assembly reference. The manufacturing attribute is MFG_ORIENT_ANGLE.
Technology Attributes
These attributes provide technological information without any impact on the tool path computation.
MFG_NB_OF_COMP (Number of components)Type: IntegerSpecifies the number of components of the tool assembly. The manufacturing attribute is MFG_NB_OF_COMP. MFG_ASS_GAGE_1 (Gage 1 : G1)Type: RealSpecifies the assembly gage between the tool and adapter or the tool and holder depending on the number of components on the tool assembly. The manufacturing attribute is MFG_ASS_GAGE_1. MFG_ASS_GAGE_2 (Gage 2 : G2)Type: RealSpecifies the assembly gage between the adapter and holder, if there are three components on the tool assembly. The manufacturing attribute is MFG_ASS_GAGE_2. MFG_TOOL_ASS_POWER (Power)Type: StringPossible values:MFG_FIXED (Fixed)MFG_POWERED (Powered)Defines whether the tool assembly is powered or fixed: Powered means that the tool turns and the part is fixed, Fixed means that the tool is fixed and the part turns. The manufacturing attribute is MFG_TOOL_ASS_POWER.
Tool and Insert Holder ResourcesAll supported Tool resources are presented in this section:
● Tools for milling and drilling operations:
❍ Drill
❍ Center Drill
❍ Spot Drill
❍ Face Mill
❍ End Mill
❍ Countersink
❍ Reamer
❍ Boring Bar
❍ Tap
❍ T-Slotter
❍ Multi-Diameter Drill
❍ Two Sides Chamfering Tool
❍ Boring and Chamfering Tool
❍ Conical Mill
❍ Thread Mill
❍ Counterbore Mill.
● Tools (that is, insert holders) for turning operations:
❍ External Insert Holder
❍ Internal Insert Holder
❍ External Groove Insert Holder
❍ Frontal Groove Insert Holder
❍ Internal Groove Insert Holder
❍ External Thread Insert Holder
❍ Internal Thread Insert Holder.
MfgDrillTool (Drill)
Description
Describes the MfgDrillTool resource attributes that are available in Machining workbenches.
Base Attributes
These attributes provide general information.
MFG_NAME (Name)Type: StringSpecifies the name of the resource. MFG_COMMENT (Comment)Type: StringAssociates a comment to the resource. MFG_TOOL_NUMBER (Tool number)Type: IntegerDefines the tool number. The manufacturing attribute is MFG_TOOL_NUMBER.
Geometry Attributes
These attributes characterize the tool shape and have an impact on the tool path computation.
MFG_NOMINAL_DIAM (Nominal diameter : D)Type: RealDefines the cutting diameter of the tool. The manufacturing attribute is MFG_NOMINAL_DIAM. MFG_OVERALL_LGTH (Overall length : L)Type: RealDefines the total length of the tool. The manufacturing attribute is MFG_OVERALL_LGTH. MFG_CUT_LENGTH (Cutting length : Lc)Type: RealDefines the effective cutting length available on the tool's active part. The manufacturing attribute is MFG_CUT_LENGTH. MFG_LENGTH (Length : l)Type: RealDefines the length of the external envelope of the tool's active part. The manufacturing attribute is MFG_LENGTH. MFG_BODY_DIAM (Body diameter : db)Type: RealDefines the diameter of the external envelope of the non-active part of the tool. The manufacturing attribute is MFG_BODY_DIAM. MFG_CUT_ANGLE (Cutting angle : A)Type: RealDefines the cutting angle of the tool. The manufacturing attribute is MFG_CUT_ANGLE. MFG_TL_TIP_LGTH (Tool tip length : ld)Type: RealDefines the part of the tool that cannot be used for cutting material at the correct diameter (non-functional part of the tool). The manufacturing attribute is MFG_TL_TIP_LGTH.
Technology Attributes
These attributes provide technological information without any impact on the tool path computation.
MFG_NB_OF_FLUTES (Number of flutes)Type: IntegerDefines the number of flutes on the tool. In case of tools with separate inserts, this is the number of inserts The manufacturing attribute is MFG_NB_OF_FLUTES. MFG_WAY_OF_ROT (Way of rotation)Type: StringPossible values:RIGHT_HAND (Right hand)LEFT_HAND (Left hand)Defines the flutes orientation. It should be compatible with spindle rotation orientation. The manufacturing attribute is MFG_WAY_OF_ROT with possible value RIGHT_HAND or LEFT_HAND MFG_MACH_QUALITY (Machining quality)Type: StringPossible values:ROUGH (Rough)FINISH (Finish)EITHER (Either)Defines the tool's ability to machine in roughing or finishing mode. The manufacturing attribute is MFG_MACH_QUALITY with possible value ROUGH, FINISH or EITHER. MFG_TOOTH_MAT (Tooth material)Type: StringPossible values:HIGH_SPEED_STEEL (High speed steel)COATED_HIGH_SPEED_STEEL (Coated high speed steel)CARBIDE (Carbide)COATED_CARBIDE (Coated carbide)OTHER (Other)Defines the tooth material type. The manufacturing attribute is MFG_TOOTH_MAT with possible value: HIGH_SPEED_STEEL, COATED_HIGH_SPEED_STEEL, CARBIDE, COATED_CARBIDE, OTHER. MFG_TOOTH_DES (Tooth description)Type: StringAllows the user to specify the tooth nature as a comment. For example, it could be the supplier reference of the insert. The manufacturing attribute is MFG_TOOTH_DES. MFG_TOOTH_MATDES (Tooth material desc.)Type: StringAllows the user to specify the tooth material by means of a comment. For example, it could be the ISO designation for cutting materials or the reference of the coating material. The manufacturing attribute is MFG_TOOTH_MATDES. MFG_TL_RAKE_ANG (Tool rake angle )Type: RealDefines the tool rake angle. The manufacturing attribute is MFG_TL_RAKE_ANG. MFG_MAX_MIL_LENGTH (Max machining length)Type: RealSpecifies the tool life in length units. The manufacturing attribute is MFG_MAX_MIL_LENGTH. MFG_MAX_MIL_TIME (Max life time)Type: RealSpecifies the tool life in time units. The manufacturing attribute is MFG_MAX_MIL_TIME. MFG_COOLNT_SNTX (Coolant syntax)Type: StringSpecifies the coolant supply syntax. The manufacturing attribute is MFG_COOLNT_SNTX. MFG_WEIGHT_SNTX (Weight syntax)Type: StringSpecifies the tool weight syntax. The manufacturing attribute is MFG_WEIGHT_SNTX.
Cutting Conditions Attributes
These attributes are used for feeds and speeds computation on the operation.
MFG_VC (Cutting speed)Type: RealDefines the Cutting speed of the tool. The manufacturing attribute is MFG_VC. MFG_SZ (Feedrate)Type: RealDefines the Feedrate of the tool. The manufacturing attribute is MFG_SZ. MFG_PP (Depth of cut)Type: RealDefines the Depth of cut of the tool. The manufacturing attribute is MFG_PP.
MfgTapTool (Tap)
Description
Describes the MfgTapTool resource attributes that are available in Machining workbenches.
Base Attributes
These attributes provide general information.
MFG_NAME (Name)Type: StringSpecifies the name of the resource. MFG_COMMENT (Comment)Type: StringAssociates a comment to the resource. MFG_TOOL_NUMBER (Tool number)Type: IntegerDefines the tool number. The manufacturing attribute is MFG_TOOL_NUMBER.
Geometry Attributes
These attributes characterize the tool shape and have an impact on the tool path computation.
MFG_NOMINAL_DIAM (Nominal diameter : D)Type: RealDefines the cutting diameter of the tool. The manufacturing attribute is MFG_NOMINAL_DIAM. MFG_OVERALL_LGTH (Overall length : L)Type: RealDefines the total length of the tool. The manufacturing attribute is MFG_OVERALL_LGTH. MFG_CUT_LENGTH (Cutting length : Lc)Type: RealDefines the effective cutting length available on the tool's active part. The manufacturing attribute is MFG_CUT_LENGTH.
MFG_LENGTH (Length : l)Type: RealDefines the length of the external envelope of the tool's active part. The manufacturing attribute is MFG_LENGTH. MFG_BODY_DIAM (Body diameter : db)Type: RealDefines the diameter of the external envelope of the non-active part of the tool. The manufacturing attribute is MFG_BODY_DIAM. MFG_ENTRY_DIAM (Entry diameter : d)Type: RealDefines the smallest diameter of the head of the tool. The manufacturing attribute is MFG_ENTRY_DIAM. MFG_TL_TIP_LGTH (Tool tip length : ld)Type: RealDefines the part of the tool that cannot be used for cutting material at the correct diameter (non-functional part of the tool). The manufacturing attribute is MFG_TL_TIP_LGTH. MFG_TAPER_ANGLE (Taper angle : Ach)Type: RealDefines the taper angle on the tool. The manufacturing attribute is MFG_TAPER_ANGLE. MFG_NOMINAL_DIAM (Nominal diameter location : Lnd)Type: RealDefines where the nominal diameter of the tool is measured from. The manufacturing attribute is MFG_NOMINAL_DIAM.
Technology Attributes
These attributes provide technological information without any impact on the tool path computation.
MFG_NB_OF_FLUTES (Number of flutes)Type: IntegerDefines the number of flutes on the tool. In case of tools with separate inserts, this is the number of inserts The manufacturing attribute is MFG_NB_OF_FLUTES. MFG_WAY_OF_ROT (Way of rotation)Type: StringPossible values:RIGHT_HAND (Right hand)LEFT_HAND (Left hand)Defines the flutes orientation. It should be compatible with spindle rotation orientation. The manufacturing attribute is MFG_WAY_OF_ROT with possible value RIGHT_HAND or LEFT_HAND MFG_TOOTH_MAT (Tooth material)Type: StringPossible values:HIGH_SPEED_STEEL (High speed steel)COATED_HIGH_SPEED_STEEL (Coated high speed steel)CARBIDE (Carbide)COATED_CARBIDE (Coated carbide)OTHER (Other)Defines the tooth material type. The manufacturing attribute is MFG_TOOTH_MAT with possible value: HIGH_SPEED_STEEL, COATED_HIGH_SPEED_STEEL, CARBIDE, COATED_CARBIDE, OTHER. MFG_TOOTH_DES (Tooth description)Type: StringAllows the user to specify the tooth nature as a comment. For example, it could be the supplier reference of the insert. The manufacturing attribute is MFG_TOOTH_DES.
MFG_TOOTH_MATDES (Tooth material desc.)Type: StringAllows the user to specify the tooth material by means of a comment. For example, it could be the ISO designation for cutting materials or the reference of the coating material. The manufacturing attribute is MFG_TOOTH_MATDES. MFG_THREAD_FORM (Thread form)Type: StringPossible values:METRIC (Metric)INCH (Inch)OTHER (Other)Defines the standard of the thread used on a tap. The manufacturing attribute is MFG_THREAD_FORM with possible value METRIC, INCH or OTHER. MFG_THREAD_CLASS (Thread class)Type: StringPossible values:1B2B3B5H6H7HOTHER (Other)Defines the dimensional tolerances of the thread and can take the following values: 1B (consistent with INCH thread form), 2B (consistent with INCH thread form), 3B (consistent with INCH thread form), 5H (consistent with METRIC thread form), 6H (consistent with METRIC thread form), 7H (consistent with METRIC thread form), OTHER The manufacturing attribute is MFG_THREAD_CLASS. MFG_THD_FRM_DESC (Thread form desc.)Type: StringSpecifies the thread form as a comment. For example, it could be some other thread form like Round thread. The manufacturing attribute is MFG_THD_FRM_DESC. MFG_THD_CLS_DESC (Thread class desc.)Type: StringSpecifies the thread class as a comment. The manufacturing attribute is MFG_THD_CLS_DESC. MFG_PITCH_OF_THREAD (Pitch of thread)Type: RealDescribes the thread pitch. The manufacturing attribute is MFG_PITCH_OF_THREAD. MFG_MAX_MIL_LENGTH (Max machining length)Type: RealSpecifies the tool life in length units. The manufacturing attribute is MFG_MAX_MIL_LENGTH. MFG_MAX_MIL_TIME (Max life time)Type: RealSpecifies the tool life in time units. The manufacturing attribute is MFG_MAX_MIL_TIME. MFG_COOLNT_SNTX (Coolant syntax)Type: StringSpecifies the coolant supply syntax. The manufacturing attribute is MFG_COOLNT_SNTX. MFG_WEIGHT_SNTX (Weight syntax)Type: StringSpecifies the tool weight syntax. The manufacturing attribute is MFG_WEIGHT_SNTX.
Cutting Conditions Attributes
These attributes are used for feeds and speeds computation on the operation.
MFG_VC (Cutting speed)Type: RealDefines the Cutting speed of the tool. The manufacturing attribute is MFG_VC. MFG_SZ (Feedrate)Type: RealDefines the Feedrate of the tool. The manufacturing attribute is MFG_SZ. MFG_PP (Depth of cut)Type: RealDefines the Depth of cut of the tool. The manufacturing attribute is MFG_PP.
MfgThreadMillTool (Thread Mill)
Description
Describes the MfgThreadMillTool resource attributes that are available in Machining workbenches.
Base Attributes
These attributes provide general information.
MFG_NAME (Name)Type: StringSpecifies the name of the resource. MFG_COMMENT (Comment)Type: StringAssociates a comment to the resource. MFG_TOOL_NUMBER (Tool number)Type: IntegerDefines the tool number. The manufacturing attribute is MFG_TOOL_NUMBER.
Geometry Attributes
These attributes characterize the tool shape and have an impact on the tool path computation.
MFG_NOMINAL_DIAM (Nominal diameter : D)Type: RealDefines the cutting diameter of the tool. The manufacturing attribute is MFG_NOMINAL_DIAM. MFG_OVERALL_LGTH (Overall length : L)Type: RealDefines the total length of the tool. The manufacturing attribute is MFG_OVERALL_LGTH. MFG_CUT_LENGTH (Cutting length : Lc)Type: RealDefines the effective cutting length available on the tool's active part. The manufacturing attribute is MFG_CUT_LENGTH. MFG_LENGTH (Length : l)Type: RealDefines the length of the external envelope of the tool's active part. The manufacturing attribute is MFG_LENGTH.
MFG_BODY_DIAM (Body diameter : db)Type: RealDefines the diameter of the external envelope of the non-active part of the tool. The manufacturing attribute is MFG_BODY_DIAM. MFG_OUTSIDE_DIAM (Outside diameter : Da)Type: RealDefines the diameter of the external envelope of the tool's active part for tools such as face mills, countersinks and thread mills. The manufacturing attribute is MFG_OUTSIDE_DIAM. MFG_LENGTH_1 (Length 1 : l1)Type: RealDefines the length of the first active part for tools such as multi-diameter tool, bore-and-chamfer tool and thread mill. The manufacturing attribute is MFG_LENGTH_1. MFG_TAPER_ANGLE (Taper angle : Ach)Type: RealDefines the taper angle on the tool. The manufacturing attribute is MFG_TAPER_ANGLE.
Technology Attributes
These attributes provide technological information without any impact on the tool path computation.
MFG_NB_OF_FLUTES (Number of flutes)Type: IntegerDefines the number of flutes on the tool. In case of tools with separate inserts, this is the number of inserts The manufacturing attribute is MFG_NB_OF_FLUTES. MFG_WAY_OF_ROT (Way of rotation)Type: StringPossible values:RIGHT_HAND (Right hand)LEFT_HAND (Left hand)Defines the flutes orientation. It should be compatible with spindle rotation orientation. The manufacturing attribute is MFG_WAY_OF_ROT with possible value RIGHT_HAND or LEFT_HAND MFG_TOOTH_MAT (Tooth material)Type: StringPossible values:HIGH_SPEED_STEEL (High speed steel)COATED_HIGH_SPEED_STEEL (Coated high speed steel)CARBIDE (Carbide)COATED_CARBIDE (Coated carbide)OTHER (Other)Defines the tooth material type. The manufacturing attribute is MFG_TOOTH_MAT with possible value: HIGH_SPEED_STEEL, COATED_HIGH_SPEED_STEEL, CARBIDE, COATED_CARBIDE, OTHER. MFG_TOOTH_DES (Tooth description)Type: StringAllows the user to specify the tooth nature as a comment. For example, it could be the supplier reference of the insert. The manufacturing attribute is MFG_TOOTH_DES. MFG_TOOTH_MATDES (Tooth material desc.)Type: StringAllows the user to specify the tooth material by means of a comment. For example, it could be the ISO designation for cutting materials or the reference of the coating material. The manufacturing attribute is MFG_TOOTH_MATDES.
MFG_THREAD_FORM (Thread form)Type: StringPossible values:METRIC (Metric)INCH (Inch)OTHER (Other)Defines the standard of the thread used on a tap. The manufacturing attribute is MFG_THREAD_FORM with possible value METRIC, INCH or OTHER. MFG_THREAD_CLASS (Thread class)Type: StringPossible values:1B2B3B5H6H7HOTHER (Other)Defines the dimensional tolerances of the thread and can take the following values: 1B (consistent with INCH thread form), 2B (consistent with INCH thread form), 3B (consistent with INCH thread form), 5H (consistent with METRIC thread form), 6H (consistent with METRIC thread form), 7H (consistent with METRIC thread form), OTHER The manufacturing attribute is MFG_THREAD_CLASS. MFG_THD_FRM_DESC (Thread form desc.)Type: StringSpecifies the thread form as a comment. For example, it could be some other thread form like Round thread. The manufacturing attribute is MFG_THD_FRM_DESC. MFG_THD_CLS_DESC (Thread class desc.)Type: StringSpecifies the thread class as a comment. The manufacturing attribute is MFG_THD_CLS_DESC. MFG_PITCH_OF_THREAD (Pitch of thread)Type: RealDescribes the thread pitch. The manufacturing attribute is MFG_PITCH_OF_THREAD. MFG_MAX_MIL_LENGTH (Max machining length)Type: RealSpecifies the tool life in length units. The manufacturing attribute is MFG_MAX_MIL_LENGTH. MFG_MAX_MIL_TIME (Max life time)Type: RealSpecifies the tool life in time units. The manufacturing attribute is MFG_MAX_MIL_TIME. MFG_COOLNT_SNTX (Coolant syntax)Type: StringSpecifies the coolant supply syntax. The manufacturing attribute is MFG_COOLNT_SNTX. MFG_WEIGHT_SNTX (Weight syntax)Type: StringSpecifies the tool weight syntax. The manufacturing attribute is MFG_WEIGHT_SNTX.
Cutting Conditions Attributes
These attributes are used for feeds and speeds computation on the operation.
MFG_VC (Cutting speed)Type: RealDefines the Cutting speed of the tool. The manufacturing attribute is MFG_VC.
MFG_SZ (Feedrate)Type: RealDefines the Feedrate of the tool. The manufacturing attribute is MFG_SZ. MFG_PP (Depth of cut)Type: RealDefines the Depth of cut of the tool. The manufacturing attribute is MFG_PP.
MfgCountersinkTool (Countersink)
Description
Describes the MfgCountersinkTool resource attributes that are available in Machining workbenches.
Base Attributes
These attributes provide general information.
MFG_NAME (Name)Type: StringSpecifies the name of the resource. MFG_COMMENT (Comment)Type: StringAssociates a comment to the resource. MFG_TOOL_NUMBER (Tool number)Type: IntegerDefines the tool number. The manufacturing attribute is MFG_TOOL_NUMBER.
Geometry Attributes
These attributes characterize the tool shape and have an impact on the tool path computation.
MFG_NOMINAL_DIAM (Nominal diameter : D)Type: RealDefines the cutting diameter of the tool. The manufacturing attribute is MFG_NOMINAL_DIAM. MFG_CORNER_RAD (Corner radius : Rc)Type: RealDefines the radius of the cutting shape of the tool. The manufacturing attribute is MFG_CORNER_RAD. MFG_OVERALL_LGTH (Overall length : L)Type: RealDefines the total length of the tool. The manufacturing attribute is MFG_OVERALL_LGTH. MFG_CUT_LENGTH (Cutting length : Lc)Type: RealDefines the effective cutting length available on the tool's active part. The manufacturing attribute is MFG_CUT_LENGTH. MFG_LENGTH (Length : l)Type: RealDefines the length of the external envelope of the tool's active part. The manufacturing attribute is MFG_LENGTH.
MFG_BODY_DIAM (Body diameter : db)Type: RealDefines the diameter of the external envelope of the non-active part of the tool. The manufacturing attribute is MFG_BODY_DIAM. MFG_ENTRY_DIAM (Entry diameter : d)Type: RealDefines the smallest diameter of the head of the tool. The manufacturing attribute is MFG_ENTRY_DIAM. MFG_OUTSIDE_DIAM (Outside diameter : Da)Type: RealDefines the diameter of the external envelope of the tool's active part for tools such as face mills, countersinks and thread mills. The manufacturing attribute is MFG_OUTSIDE_DIAM. MFG_CUT_ANGLE (Cutting angle : A)Type: RealDefines the cutting angle of the tool. The manufacturing attribute is MFG_CUT_ANGLE.
Technology Attributes
These attributes provide technological information without any impact on the tool path computation.
MFG_NB_OF_FLUTES (Number of flutes)Type: IntegerDefines the number of flutes on the tool. In case of tools with separate inserts, this is the number of inserts The manufacturing attribute is MFG_NB_OF_FLUTES. MFG_WAY_OF_ROT (Way of rotation)Type: StringPossible values:RIGHT_HAND (Right hand)LEFT_HAND (Left hand)Defines the flutes orientation. It should be compatible with spindle rotation orientation. The manufacturing attribute is MFG_WAY_OF_ROT with possible value RIGHT_HAND or LEFT_HAND MFG_MACH_QUALITY (Machining quality)Type: StringPossible values:ROUGH (Rough)FINISH (Finish)EITHER (Either)Defines the tool's ability to machine in roughing or finishing mode. The manufacturing attribute is MFG_MACH_QUALITY with possible value ROUGH, FINISH or EITHER. MFG_TOOTH_MAT (Tooth material)Type: StringPossible values:HIGH_SPEED_STEEL (High speed steel)COATED_HIGH_SPEED_STEEL (Coated high speed steel)CARBIDE (Carbide)COATED_CARBIDE (Coated carbide)OTHER (Other)Defines the tooth material type. The manufacturing attribute is MFG_TOOTH_MAT with possible value: HIGH_SPEED_STEEL, COATED_HIGH_SPEED_STEEL, CARBIDE, COATED_CARBIDE, OTHER. MFG_TOOTH_DES (Tooth description)Type: StringAllows the user to specify the tooth nature as a comment. For example, it could be the supplier reference of the insert. The manufacturing attribute is MFG_TOOTH_DES.
MFG_TOOTH_MATDES (Tooth material desc.)Type: StringAllows the user to specify the tooth material by means of a comment. For example, it could be the ISO designation for cutting materials or the reference of the coating material. The manufacturing attribute is MFG_TOOTH_MATDES. MFG_TL_RAKE_ANG (Tool rake angle )Type: RealDefines the tool rake angle. The manufacturing attribute is MFG_TL_RAKE_ANG. MFG_MAX_MIL_LENGTH (Max machining length)Type: RealSpecifies the tool life in length units. The manufacturing attribute is MFG_MAX_MIL_LENGTH. MFG_MAX_MIL_TIME (Max life time)Type: RealSpecifies the tool life in time units. The manufacturing attribute is MFG_MAX_MIL_TIME. MFG_COOLNT_SNTX (Coolant syntax)Type: StringSpecifies the coolant supply syntax. The manufacturing attribute is MFG_COOLNT_SNTX. MFG_WEIGHT_SNTX (Weight syntax)Type: StringSpecifies the tool weight syntax. The manufacturing attribute is MFG_WEIGHT_SNTX.
Cutting Conditions Attributes
These attributes are used for feeds and speeds computation on the operation.
MFG_VC (Cutting speed)Type: RealDefines the Cutting speed of the tool. The manufacturing attribute is MFG_VC. MFG_SZ (Feedrate)Type: RealDefines the Feedrate of the tool. The manufacturing attribute is MFG_SZ. MFG_PP (Depth of cut)Type: RealDefines the Depth of cut of the tool. The manufacturing attribute is MFG_PP.
MfgReamerTool (Reamer)
Description
Describes the MfgReamerTool resource attributes that are available in Machining workbenches.
Base Attributes
These attributes provide general information.
MFG_NAME (Name)Type: StringSpecifies the name of the resource.
MFG_COMMENT (Comment)Type: StringAssociates a comment to the resource. MFG_TOOL_NUMBER (Tool number)Type: IntegerDefines the tool number. The manufacturing attribute is MFG_TOOL_NUMBER.
Geometry Attributes
These attributes characterize the tool shape and have an impact on the tool path computation.
MFG_NOMINAL_DIAM (Nominal diameter : D)Type: RealDefines the cutting diameter of the tool. The manufacturing attribute is MFG_NOMINAL_DIAM. MFG_OVERALL_LGTH (Overall length : L)Type: RealDefines the total length of the tool. The manufacturing attribute is MFG_OVERALL_LGTH. MFG_CUT_LENGTH (Cutting length : Lc)Type: RealDefines the effective cutting length available on the tool's active part. The manufacturing attribute is MFG_CUT_LENGTH. MFG_LENGTH (Length : l)Type: RealDefines the length of the external envelope of the tool's active part. The manufacturing attribute is MFG_LENGTH. MFG_BODY_DIAM (Body diameter : db)Type: RealDefines the diameter of the external envelope of the non-active part of the tool. The manufacturing attribute is MFG_BODY_DIAM. MFG_ENTRY_DIAM (Entry diameter : d)Type: RealDefines the smallest diameter of the head of the tool. The manufacturing attribute is MFG_ENTRY_DIAM. MFG_TL_TIP_LGTH (Tool tip length : ld)Type: RealDefines the part of the tool that cannot be used for cutting material at the correct diameter (non-functional part of the tool). The manufacturing attribute is MFG_TL_TIP_LGTH.
Technology Attributes
These attributes provide technological information without any impact on the tool path computation.
MFG_NB_OF_FLUTES (Number of flutes)Type: IntegerDefines the number of flutes on the tool. In case of tools with separate inserts, this is the number of inserts The manufacturing attribute is MFG_NB_OF_FLUTES. MFG_WAY_OF_ROT (Way of rotation)Type: StringPossible values:RIGHT_HAND (Right hand)LEFT_HAND (Left hand)Defines the flutes orientation. It should be compatible with spindle rotation orientation. The manufacturing attribute is MFG_WAY_OF_ROT with possible value RIGHT_HAND or LEFT_HAND
MFG_TOOTH_MAT (Tooth material)Type: StringPossible values:HIGH_SPEED_STEEL (High speed steel)COATED_HIGH_SPEED_STEEL (Coated high speed steel)CARBIDE (Carbide)COATED_CARBIDE (Coated carbide)OTHER (Other)Defines the tooth material type. The manufacturing attribute is MFG_TOOTH_MAT with possible value: HIGH_SPEED_STEEL, COATED_HIGH_SPEED_STEEL, CARBIDE, COATED_CARBIDE, OTHER. MFG_TOOTH_DES (Tooth description)Type: StringAllows the user to specify the tooth nature as a comment. For example, it could be the supplier reference of the insert. The manufacturing attribute is MFG_TOOTH_DES. MFG_TOOTH_MATDES (Tooth material desc.)Type: StringAllows the user to specify the tooth material by means of a comment. For example, it could be the ISO designation for cutting materials or the reference of the coating material. The manufacturing attribute is MFG_TOOTH_MATDES. MFG_TL_RAKE_ANG (Tool rake angle )Type: RealDefines the tool rake angle. The manufacturing attribute is MFG_TL_RAKE_ANG. MFG_MAX_MIL_LENGTH (Max machining length)Type: RealSpecifies the tool life in length units. The manufacturing attribute is MFG_MAX_MIL_LENGTH. MFG_MAX_MIL_TIME (Max life time)Type: RealSpecifies the tool life in time units. The manufacturing attribute is MFG_MAX_MIL_TIME. MFG_COOLNT_SNTX (Coolant syntax)Type: StringSpecifies the coolant supply syntax. The manufacturing attribute is MFG_COOLNT_SNTX. MFG_WEIGHT_SNTX (Weight syntax)Type: StringSpecifies the tool weight syntax. The manufacturing attribute is MFG_WEIGHT_SNTX.
Cutting Conditions Attributes
These attributes are used for feeds and speeds computation on the operation.
MFG_VC (Cutting speed)Type: RealDefines the Cutting speed of the tool. The manufacturing attribute is MFG_VC. MFG_SZ (Feedrate)Type: RealDefines the Feedrate of the tool. The manufacturing attribute is MFG_SZ. MFG_PP (Depth of cut)Type: RealDefines the Depth of cut of the tool. The manufacturing attribute is MFG_PP.
MfgSpotDrillTool (Spot Drill)
Description
Describes the MfgSpotDrillTool resource attributes that are available in Machining workbenches.
Base Attributes
These attributes provide general information.
MFG_NAME (Name)Type: StringSpecifies the name of the resource. MFG_COMMENT (Comment)Type: StringAssociates a comment to the resource. MFG_TOOL_NUMBER (Tool number)Type: IntegerDefines the tool number. The manufacturing attribute is MFG_TOOL_NUMBER.
Geometry Attributes
These attributes characterize the tool shape and have an impact on the tool path computation.
MFG_NOMINAL_DIAM (Nominal diameter : D)Type: RealDefines the cutting diameter of the tool. The manufacturing attribute is MFG_NOMINAL_DIAM. MFG_OVERALL_LGTH (Overall length : L)Type: RealDefines the total length of the tool. The manufacturing attribute is MFG_OVERALL_LGTH. MFG_LENGTH (Length : l)Type: RealDefines the length of the external envelope of the tool's active part. The manufacturing attribute is MFG_LENGTH. MFG_BODY_DIAM (Body diameter : db)Type: RealDefines the diameter of the external envelope of the non-active part of the tool. The manufacturing attribute is MFG_BODY_DIAM. MFG_CUT_ANGLE (Cutting angle : A)Type: RealDefines the cutting angle of the tool. The manufacturing attribute is MFG_CUT_ANGLE.
Technology Attributes
These attributes provide technological information without any impact on the tool path computation.
MFG_NB_OF_FLUTES (Number of flutes)Type: IntegerDefines the number of flutes on the tool. In case of tools with separate inserts, this is the number of inserts The manufacturing attribute is MFG_NB_OF_FLUTES.
MFG_WAY_OF_ROT (Way of rotation)Type: StringPossible values:RIGHT_HAND (Right hand)LEFT_HAND (Left hand)Defines the flutes orientation. It should be compatible with spindle rotation orientation. The manufacturing attribute is MFG_WAY_OF_ROT with possible value RIGHT_HAND or LEFT_HAND MFG_TOOTH_MAT (Tooth material)Type: StringPossible values:HIGH_SPEED_STEEL (High speed steel)COATED_HIGH_SPEED_STEEL (Coated high speed steel)CARBIDE (Carbide)COATED_CARBIDE (Coated carbide)OTHER (Other)Defines the tooth material type. The manufacturing attribute is MFG_TOOTH_MAT with possible value: HIGH_SPEED_STEEL, COATED_HIGH_SPEED_STEEL, CARBIDE, COATED_CARBIDE, OTHER. MFG_TOOTH_DES (Tooth description)Type: StringAllows the user to specify the tooth nature as a comment. For example, it could be the supplier reference of the insert. The manufacturing attribute is MFG_TOOTH_DES. MFG_TOOTH_MATDES (Tooth material desc.)Type: StringAllows the user to specify the tooth material by means of a comment. For example, it could be the ISO designation for cutting materials or the reference of the coating material. The manufacturing attribute is MFG_TOOTH_MATDES. MFG_TL_RAKE_ANG (Tool rake angle )Type: RealDefines the tool rake angle. The manufacturing attribute is MFG_TL_RAKE_ANG. MFG_MAX_MIL_LENGTH (Max machining length)Type: RealSpecifies the tool life in length units. The manufacturing attribute is MFG_MAX_MIL_LENGTH. MFG_MAX_MIL_TIME (Max life time)Type: RealSpecifies the tool life in time units. The manufacturing attribute is MFG_MAX_MIL_TIME. MFG_COOLNT_SNTX (Coolant syntax)Type: StringSpecifies the coolant supply syntax. The manufacturing attribute is MFG_COOLNT_SNTX. MFG_WEIGHT_SNTX (Weight syntax)Type: StringSpecifies the tool weight syntax. The manufacturing attribute is MFG_WEIGHT_SNTX.
Cutting Conditions Attributes
These attributes are used for feeds and speeds computation on the operation.
MFG_VC (Cutting speed)Type: RealDefines the Cutting speed of the tool. The manufacturing attribute is MFG_VC. MFG_SZ (Feedrate)Type: RealDefines the Feedrate of the tool. The manufacturing attribute is MFG_SZ.
MFG_PP (Depth of cut)Type: RealDefines the Depth of cut of the tool. The manufacturing attribute is MFG_PP.
MfgCenterDrillTool (Center Drill)
Description
Describes the MfgCenterDrillTool resource attributes that are available in Machining workbenches.
Base Attributes
These attributes provide general information.
MFG_NAME (Name)Type: StringSpecifies the name of the resource. MFG_COMMENT (Comment)Type: StringAssociates a comment to the resource. MFG_TOOL_NUMBER (Tool number)Type: IntegerDefines the tool number. The manufacturing attribute is MFG_TOOL_NUMBER.
Geometry Attributes
These attributes characterize the tool shape and have an impact on the tool path computation.
MFG_NOMINAL_DIAM (Nominal diameter : D)Type: RealDefines the cutting diameter of the tool. The manufacturing attribute is MFG_NOMINAL_DIAM. MFG_OVERALL_LGTH (Overall length : L)Type: RealDefines the total length of the tool. The manufacturing attribute is MFG_OVERALL_LGTH. MFG_CUT_LENGTH (Cutting length : Lc)Type: RealDefines the effective cutting length available on the tool's active part. The manufacturing attribute is MFG_CUT_LENGTH. MFG_LENGTH (Length : l)Type: RealDefines the length of the external envelope of the tool's active part. The manufacturing attribute is MFG_LENGTH. MFG_BODY_DIAM (Body diameter : db)Type: RealDefines the diameter of the external envelope of the non-active part of the tool. The manufacturing attribute is MFG_BODY_DIAM. MFG_CUT_ANGLE (Cutting angle : A)Type: RealDefines the cutting angle of the tool. The manufacturing attribute is MFG_CUT_ANGLE.
MFG_TAPER_ANGLE (Taper angle : Ach)Type: RealDefines the taper angle on the tool. The manufacturing attribute is MFG_TAPER_ANGLE.
Technology Attributes
These attributes provide technological information without any impact on the tool path computation.
MFG_MAX_MIL_LENGTH (Max machining length)Type: RealSpecifies the tool life in length units. The manufacturing attribute is MFG_MAX_MIL_LENGTH. MFG_MAX_MIL_TIME (Max life time)Type: RealSpecifies the tool life in time units. The manufacturing attribute is MFG_MAX_MIL_TIME. MFG_COOLNT_SNTX (Coolant syntax)Type: StringSpecifies the coolant supply syntax. The manufacturing attribute is MFG_COOLNT_SNTX. MFG_WEIGHT_SNTX (Weight syntax)Type: StringSpecifies the tool weight syntax. The manufacturing attribute is MFG_WEIGHT_SNTX.
Cutting Conditions Attributes
These attributes are used for feeds and speeds computation on the operation.
MFG_VC (Cutting speed)Type: RealDefines the Cutting speed of the tool. The manufacturing attribute is MFG_VC. MFG_SZ (Feedrate)Type: RealDefines the Feedrate of the tool. The manufacturing attribute is MFG_SZ. MFG_PP (Depth of cut)Type: RealDefines the Depth of cut of the tool. The manufacturing attribute is MFG_PP.
MfgMultiDiamDrillTool (Multi Diameter Drill)
Description
Describes the MfgMultiDiamDrillTool resource attributes that are available in Machining workbenches.
Base Attributes
These attributes provide general information.
MFG_NAME (Name)Type: StringSpecifies the name of the resource.
MFG_COMMENT (Comment)Type: StringAssociates a comment to the resource. MFG_TOOL_NUMBER (Tool number)Type: IntegerDefines the tool number. The manufacturing attribute is MFG_TOOL_NUMBER. MFG_NB_OF_STAGES (Number of stages)Type: IntegerDefines the number of stages of a multi-diameter drill. The manufacturing attribute is MFG_NB_OF_STAGES.
Geometry Attributes
These attributes characterize the tool shape and have an impact on the tool path computation.
MFG_NOMINAL_DIAM (Nominal diameter : D)Type: RealDefines the cutting diameter of the tool. The manufacturing attribute is MFG_NOMINAL_DIAM. MFG_OVERALL_LGTH (Overall length : L)Type: RealDefines the total length of the tool. The manufacturing attribute is MFG_OVERALL_LGTH. MFG_CUT_LENGTH (Cutting length : Lc)Type: RealDefines the effective cutting length available on the tool's active part. The manufacturing attribute is MFG_CUT_LENGTH. MFG_LENGTH (Length : l)Type: RealDefines the length of the external envelope of the tool's active part. The manufacturing attribute is MFG_LENGTH. MFG_BODY_DIAM (Body diameter : db)Type: RealDefines the diameter of the external envelope of the non-active part of the tool. The manufacturing attribute is MFG_BODY_DIAM. MFG_CUT_ANGLE (Cutting angle : A)Type: RealDefines the cutting angle of the tool. The manufacturing attribute is MFG_CUT_ANGLE. MFG_TL_TIP_LGTH (Tool tip length : ld)Type: RealDefines the part of the tool that cannot be used for cutting material at the correct diameter (non-functional part of the tool). The manufacturing attribute is MFG_TL_TIP_LGTH. MFG_CHAMFR_DIAM1 (Chamfer diameter 1 : d1)Type: RealDefines the diameter of the second part of a multi-diameter tool or bore-and-chamfer tool. The manufacturing attribute is MFG_CHAMFR_DIAM1. MFG_LENGTH_1 (Length 1 : l1)Type: RealDefines the length of the first active part for tools such as multi-diameter tool, bore-and-chamfer tool and thread mill. The manufacturing attribute is MFG_LENGTH_1. MFG_TAPER_ANGLE (Taper angle : Ach)Type: RealDefines the taper angle on the tool. The manufacturing attribute is MFG_TAPER_ANGLE.
MFG_CHAMFR_DIAM2 (Chamfer diameter 2 : d2)Type: RealDefines the diameter of the third active part of a multi-diameter tool. The manufacturing attribute is MFG_CHAMFR_DIAM2. MFG_LENGTH_2 (Length 2 : l2)Type: RealDefines the length of the second active part of a multi-diameter tool. The manufacturing attribute is MFG_LENGTH_2. MFG_ANGLE2 (Cutting angle 2 : A2)Type: RealDefines the second cutting angle of the active part of a multi-diameter tool or two-sides chamfering tool. The manufacturing attribute is MFG_ANGLE2.
Technology Attributes
These attributes provide technological information without any impact on the tool path computation.
MFG_NB_OF_FLUTES (Number of flutes)Type: IntegerDefines the number of flutes on the tool. In case of tools with separate inserts, this is the number of inserts The manufacturing attribute is MFG_NB_OF_FLUTES. MFG_WAY_OF_ROT (Way of rotation)Type: StringPossible values:RIGHT_HAND (Right hand)LEFT_HAND (Left hand)Defines the flutes orientation. It should be compatible with spindle rotation orientation. The manufacturing attribute is MFG_WAY_OF_ROT with possible value RIGHT_HAND or LEFT_HAND MFG_MACH_QUALITY (Machining quality)Type: StringPossible values:ROUGH (Rough)FINISH (Finish)EITHER (Either)Defines the tool's ability to machine in roughing or finishing mode. The manufacturing attribute is MFG_MACH_QUALITY with possible value ROUGH, FINISH or EITHER. MFG_TOOTH_MAT (Tooth material)Type: StringPossible values:HIGH_SPEED_STEEL (High speed steel)COATED_HIGH_SPEED_STEEL (Coated high speed steel)CARBIDE (Carbide)COATED_CARBIDE (Coated carbide)OTHER (Other)Defines the tooth material type. The manufacturing attribute is MFG_TOOTH_MAT with possible value: HIGH_SPEED_STEEL, COATED_HIGH_SPEED_STEEL, CARBIDE, COATED_CARBIDE, OTHER. MFG_TOOTH_DES (Tooth description)Type: StringAllows the user to specify the tooth nature as a comment. For example, it could be the supplier reference of the insert. The manufacturing attribute is MFG_TOOTH_DES.
MFG_TOOTH_MATDES (Tooth material desc.)Type: StringAllows the user to specify the tooth material by means of a comment. For example, it could be the ISO designation for cutting materials or the reference of the coating material. The manufacturing attribute is MFG_TOOTH_MATDES. MFG_TL_RAKE_ANG (Tool rake angle )Type: RealDefines the tool rake angle. The manufacturing attribute is MFG_TL_RAKE_ANG. MFG_MAX_MIL_LENGTH (Max machining length)Type: RealSpecifies the tool life in length units. The manufacturing attribute is MFG_MAX_MIL_LENGTH. MFG_MAX_MIL_TIME (Max life time)Type: RealSpecifies the tool life in time units. The manufacturing attribute is MFG_MAX_MIL_TIME. MFG_COOLNT_SNTX (Coolant syntax)Type: StringSpecifies the coolant supply syntax. The manufacturing attribute is MFG_COOLNT_SNTX. MFG_WEIGHT_SNTX (Weight syntax)Type: StringSpecifies the tool weight syntax. The manufacturing attribute is MFG_WEIGHT_SNTX.
Cutting Conditions Attributes
These attributes are used for feeds and speeds computation on the operation.
MFG_VC (Cutting speed)Type: RealDefines the Cutting speed of the tool. The manufacturing attribute is MFG_VC. MFG_SZ (Feedrate)Type: RealDefines the Feedrate of the tool. The manufacturing attribute is MFG_SZ. MFG_PP (Depth of cut)Type: RealDefines the Depth of cut of the tool. The manufacturing attribute is MFG_PP.
MfgBoringAndChamferingTool (Boring and Chamfering Tool)
Description
Describes the MfgBoringAndChamferingTool resource attributes that are available in Machining workbenches.
Base Attributes
These attributes provide general information.
MFG_NAME (Name)Type: StringSpecifies the name of the resource.
MFG_COMMENT (Comment)Type: StringAssociates a comment to the resource. MFG_TOOL_NUMBER (Tool number)Type: IntegerDefines the tool number. The manufacturing attribute is MFG_TOOL_NUMBER.
Geometry Attributes
These attributes characterize the tool shape and have an impact on the tool path computation.
MFG_NOMINAL_DIAM (Nominal diameter : D)Type: RealDefines the cutting diameter of the tool. The manufacturing attribute is MFG_NOMINAL_DIAM. MFG_CORNER_RAD (Corner radius : Rc)Type: RealDefines the radius of the cutting shape of the tool. The manufacturing attribute is MFG_CORNER_RAD. MFG_OVERALL_LGTH (Overall length : L)Type: RealDefines the total length of the tool. The manufacturing attribute is MFG_OVERALL_LGTH. MFG_CUT_LENGTH (Cutting length : Lc)Type: RealDefines the effective cutting length available on the tool's active part. The manufacturing attribute is MFG_CUT_LENGTH. MFG_LENGTH (Length : l)Type: RealDefines the length of the external envelope of the tool's active part. The manufacturing attribute is MFG_LENGTH. MFG_BODY_DIAM (Body diameter : db)Type: RealDefines the diameter of the external envelope of the non-active part of the tool. The manufacturing attribute is MFG_BODY_DIAM. MFG_CHAMFR_DIAM1 (Chamfer diameter 1 : d1)Type: RealDefines the diameter of the second part of a multi-diameter tool or bore-and-chamfer tool. The manufacturing attribute is MFG_CHAMFR_DIAM1. MFG_LENGTH_1 (Length 1 : l1)Type: RealDefines the length of the first active part for tools such as multi-diameter tool, bore-and-chamfer tool and thread mill. The manufacturing attribute is MFG_LENGTH_1. MFG_TAPER_ANGLE (Taper angle : Ach)Type: RealDefines the taper angle on the tool. The manufacturing attribute is MFG_TAPER_ANGLE.
Technology Attributes
These attributes provide technological information without any impact on the tool path computation.
MFG_NB_OF_FLUTES (Number of flutes)Type: IntegerDefines the number of flutes on the tool. In case of tools with separate inserts, this is the number of inserts The manufacturing attribute is MFG_NB_OF_FLUTES.
MFG_WAY_OF_ROT (Way of rotation)Type: StringPossible values:RIGHT_HAND (Right hand)LEFT_HAND (Left hand)Defines the flutes orientation. It should be compatible with spindle rotation orientation. The manufacturing attribute is MFG_WAY_OF_ROT with possible value RIGHT_HAND or LEFT_HAND MFG_MACH_QUALITY (Machining quality)Type: StringPossible values:ROUGH (Rough)FINISH (Finish)EITHER (Either)Defines the tool's ability to machine in roughing or finishing mode. The manufacturing attribute is MFG_MACH_QUALITY with possible value ROUGH, FINISH or EITHER. MFG_TOOTH_MAT (Tooth material)Type: StringPossible values:HIGH_SPEED_STEEL (High speed steel)COATED_HIGH_SPEED_STEEL (Coated high speed steel)CARBIDE (Carbide)COATED_CARBIDE (Coated carbide)OTHER (Other)Defines the tooth material type. The manufacturing attribute is MFG_TOOTH_MAT with possible value: HIGH_SPEED_STEEL, COATED_HIGH_SPEED_STEEL, CARBIDE, COATED_CARBIDE, OTHER. MFG_TOOTH_DES (Tooth description)Type: StringAllows the user to specify the tooth nature as a comment. For example, it could be the supplier reference of the insert. The manufacturing attribute is MFG_TOOTH_DES. MFG_TOOTH_MATDES (Tooth material desc.)Type: StringAllows the user to specify the tooth material by means of a comment. For example, it could be the ISO designation for cutting materials or the reference of the coating material. The manufacturing attribute is MFG_TOOTH_MATDES. MFG_TL_RAKE_ANG (Tool rake angle )Type: RealDefines the tool rake angle. The manufacturing attribute is MFG_TL_RAKE_ANG. MFG_MAX_MIL_LENGTH (Max machining length)Type: RealSpecifies the tool life in length units. The manufacturing attribute is MFG_MAX_MIL_LENGTH. MFG_MAX_MIL_TIME (Max life time)Type: RealSpecifies the tool life in time units. The manufacturing attribute is MFG_MAX_MIL_TIME. MFG_COOLNT_SNTX (Coolant syntax)Type: StringSpecifies the coolant supply syntax. The manufacturing attribute is MFG_COOLNT_SNTX. MFG_WEIGHT_SNTX (Weight syntax)Type: StringSpecifies the tool weight syntax. The manufacturing attribute is MFG_WEIGHT_SNTX.
Cutting Conditions Attributes
These attributes are used for feeds and speeds computation on the operation.
MFG_VC (Cutting speed)Type: RealDefines the Cutting speed of the tool. The manufacturing attribute is MFG_VC. MFG_SZ (Feedrate)Type: RealDefines the Feedrate of the tool. The manufacturing attribute is MFG_SZ. MFG_PP (Depth of cut)Type: RealDefines the Depth of cut of the tool. The manufacturing attribute is MFG_PP.
MfgTwoSidesChamferingTool (Two Sides Chamfering Tool)
Description
Describes the MfgTwoSidesChamferingTool resource attributes that are available in Machining workbenches.
Base Attributes
These attributes provide general information.
MFG_NAME (Name)Type: StringSpecifies the name of the resource. MFG_COMMENT (Comment)Type: StringAssociates a comment to the resource. MFG_TOOL_NUMBER (Tool number)Type: IntegerDefines the tool number. The manufacturing attribute is MFG_TOOL_NUMBER.
Geometry Attributes
These attributes characterize the tool shape and have an impact on the tool path computation.
MFG_NOMINAL_DIAM (Nominal diameter : D)Type: RealDefines the cutting diameter of the tool. The manufacturing attribute is MFG_NOMINAL_DIAM. MFG_OVERALL_LGTH (Overall length : L)Type: RealDefines the total length of the tool. The manufacturing attribute is MFG_OVERALL_LGTH. MFG_CUT_LENGTH (Cutting length : Lc)Type: RealDefines the effective cutting length available on the tool's active part. The manufacturing attribute is MFG_CUT_LENGTH. MFG_LENGTH (Length : l)Type: RealDefines the length of the external envelope of the tool's active part. The manufacturing attribute is MFG_LENGTH.
MFG_BODY_DIAM (Body diameter : db)Type: RealDefines the diameter of the external envelope of the non-active part of the tool. The manufacturing attribute is MFG_BODY_DIAM. MFG_ENTRY_DIAM (Entry diameter : d)Type: RealDefines the smallest diameter of the head of the tool. The manufacturing attribute is MFG_ENTRY_DIAM. MFG_CUT_ANGLE (Cutting angle : A)Type: RealDefines the cutting angle of the tool. The manufacturing attribute is MFG_CUT_ANGLE. MFG_TL_TIP_LGTH (Tool tip length : ld)Type: RealDefines the part of the tool that cannot be used for cutting material at the correct diameter (non-functional part of the tool). The manufacturing attribute is MFG_TL_TIP_LGTH. MFG_ANGLE2 (Cutting angle 2 : A2)Type: RealDefines the second cutting angle of the active part of a multi-diameter tool or two-sides chamfering tool. The manufacturing attribute is MFG_ANGLE2.
Technology Attributes
These attributes provide technological information without any impact on the tool path computation.
MFG_NB_OF_FLUTES (Number of flutes)Type: IntegerDefines the number of flutes on the tool. In case of tools with separate inserts, this is the number of inserts The manufacturing attribute is MFG_NB_OF_FLUTES. MFG_WAY_OF_ROT (Way of rotation)Type: StringPossible values:RIGHT_HAND (Right hand)LEFT_HAND (Left hand)Defines the flutes orientation. It should be compatible with spindle rotation orientation. The manufacturing attribute is MFG_WAY_OF_ROT with possible value RIGHT_HAND or LEFT_HAND MFG_TOOTH_MAT (Tooth material)Type: StringPossible values:HIGH_SPEED_STEEL (High speed steel)COATED_HIGH_SPEED_STEEL (Coated high speed steel)CARBIDE (Carbide)COATED_CARBIDE (Coated carbide)OTHER (Other)Defines the tooth material type. The manufacturing attribute is MFG_TOOTH_MAT with possible value: HIGH_SPEED_STEEL, COATED_HIGH_SPEED_STEEL, CARBIDE, COATED_CARBIDE, OTHER. MFG_TOOTH_DES (Tooth description)Type: StringAllows the user to specify the tooth nature as a comment. For example, it could be the supplier reference of the insert. The manufacturing attribute is MFG_TOOTH_DES. MFG_TOOTH_MATDES (Tooth material desc.)Type: StringAllows the user to specify the tooth material by means of a comment. For example, it could be the ISO designation for cutting materials or the reference of the coating material. The manufacturing attribute is MFG_TOOTH_MATDES.
MFG_TL_RAKE_ANG (Tool rake angle )Type: RealDefines the tool rake angle. The manufacturing attribute is MFG_TL_RAKE_ANG. MFG_MAX_MIL_LENGTH (Max machining length)Type: RealSpecifies the tool life in length units. The manufacturing attribute is MFG_MAX_MIL_LENGTH. MFG_MAX_MIL_TIME (Max life time)Type: RealSpecifies the tool life in time units. The manufacturing attribute is MFG_MAX_MIL_TIME. MFG_COOLNT_SNTX (Coolant syntax)Type: StringSpecifies the coolant supply syntax. The manufacturing attribute is MFG_COOLNT_SNTX. MFG_WEIGHT_SNTX (Weight syntax)Type: StringSpecifies the tool weight syntax. The manufacturing attribute is MFG_WEIGHT_SNTX.
Cutting Conditions Attributes
These attributes are used for feeds and speeds computation on the operation.
MFG_VC (Cutting speed)Type: RealDefines the Cutting speed of the tool. The manufacturing attribute is MFG_VC. MFG_SZ (Feedrate)Type: RealDefines the Feedrate of the tool. The manufacturing attribute is MFG_SZ. MFG_PP (Depth of cut)Type: RealDefines the Depth of cut of the tool. The manufacturing attribute is MFG_PP.
MfgCounterboreMillTool (Counterbore Mill)
Description
Describes the MfgCounterboreMillTool resource attributes that are available in Machining workbenches.
Base Attributes
These attributes provide general information.
MFG_NAME (Name)Type: StringSpecifies the name of the resource. MFG_COMMENT (Comment)Type: StringAssociates a comment to the resource. MFG_TOOL_NUMBER (Tool number)Type: IntegerDefines the tool number. The manufacturing attribute is MFG_TOOL_NUMBER.
Geometry Attributes
These attributes characterize the tool shape and have an impact on the tool path computation.
MFG_NOMINAL_DIAM (Nominal diameter : D)Type: RealDefines the cutting diameter of the tool. The manufacturing attribute is MFG_NOMINAL_DIAM. MFG_OVERALL_LGTH (Overall length : L)Type: RealDefines the total length of the tool. The manufacturing attribute is MFG_OVERALL_LGTH. MFG_CUT_LENGTH (Cutting length : Lc)Type: RealDefines the effective cutting length available on the tool's active part. The manufacturing attribute is MFG_CUT_LENGTH. MFG_LENGTH (Length : l)Type: RealDefines the length of the external envelope of the tool's active part. The manufacturing attribute is MFG_LENGTH. MFG_BODY_DIAM (Body diameter : db)Type: RealDefines the diameter of the external envelope of the non-active part of the tool. The manufacturing attribute is MFG_BODY_DIAM. MFG_ENTRY_DIAM (Entry diameter : d)Type: RealDefines the smallest diameter of the head of the tool. The manufacturing attribute is MFG_ENTRY_DIAM. MFG_TL_TIP_LGTH (Tool tip length : ld)Type: RealDefines the part of the tool that cannot be used for cutting material at the correct diameter (non-functional part of the tool). The manufacturing attribute is MFG_TL_TIP_LGTH.
Technology Attributes
These attributes provide technological information without any impact on the tool path computation.
MFG_NB_OF_FLUTES (Number of flutes)Type: IntegerDefines the number of flutes on the tool. In case of tools with separate inserts, this is the number of inserts The manufacturing attribute is MFG_NB_OF_FLUTES. MFG_WAY_OF_ROT (Way of rotation)Type: StringPossible values:RIGHT_HAND (Right hand)LEFT_HAND (Left hand)Defines the flutes orientation. It should be compatible with spindle rotation orientation. The manufacturing attribute is MFG_WAY_OF_ROT with possible value RIGHT_HAND or LEFT_HAND
MFG_MACH_QUALITY (Machining quality)Type: StringPossible values:ROUGH (Rough)FINISH (Finish)EITHER (Either)Defines the tool's ability to machine in roughing or finishing mode. The manufacturing attribute is MFG_MACH_QUALITY with possible value ROUGH, FINISH or EITHER. MFG_COMPOSITION (Composition)Type: StringPossible values:ONE_PIECE (One piece)INSERT_HOLDER (Insert holder)Specifies if the tool is an inserted one. The manufacturing attribute is MFG_COMPOSITION with possible value ONE_PIECE or INSERT_HOLDER. MFG_TOOTH_MAT (Tooth material)Type: StringPossible values:HIGH_SPEED_STEEL (High speed steel)COATED_HIGH_SPEED_STEEL (Coated high speed steel)CARBIDE (Carbide)COATED_CARBIDE (Coated carbide)OTHER (Other)Defines the tooth material type. The manufacturing attribute is MFG_TOOTH_MAT with possible value: HIGH_SPEED_STEEL, COATED_HIGH_SPEED_STEEL, CARBIDE, COATED_CARBIDE, OTHER. MFG_TL_RAKE_ANG (Tool rake angle )Type: RealDefines the tool rake angle. The manufacturing attribute is MFG_TL_RAKE_ANG. MFG_MAX_PLNG_ANG (Max plunge angle)Type: RealDefines the plunge ability of the tool. When the tool is able to plunge along its axis, the maximum plunge angle is equal to 90 degrees. The manufacturing attribute is MFG_MAX_PLNG_ANG. MFG_MAX_MIL_LENGTH (Max machining length)Type: RealSpecifies the tool life in length units. The manufacturing attribute is MFG_MAX_MIL_LENGTH. MFG_MAX_MIL_TIME (Max life time)Type: RealSpecifies the tool life in time units. The manufacturing attribute is MFG_MAX_MIL_TIME. MFG_COOLNT_SNTX (Coolant syntax)Type: StringSpecifies the coolant supply syntax. The manufacturing attribute is MFG_COOLNT_SNTX. MFG_WEIGHT_SNTX (Weight syntax)Type: StringSpecifies the tool weight syntax. The manufacturing attribute is MFG_WEIGHT_SNTX.
Cutting Conditions Attributes
These attributes are used for feeds and speeds computation on the operation.
MFG_VC (Cutting speed)Type: RealDefines the Cutting speed of the tool. The manufacturing attribute is MFG_VC.
MFG_SZ (Feedrate)Type: RealDefines the Feedrate of the tool. The manufacturing attribute is MFG_SZ. MFG_PP (Depth of cut)Type: RealDefines the Depth of cut of the tool. The manufacturing attribute is MFG_PP.
MfgEndMillTool (End Mill)
Description
Describes the MfgEndMillTool resource attributes that are available in Machining workbenches.
Base Attributes
These attributes provide general information.
MFG_NAME (Name)Type: StringSpecifies the name of the resource. MFG_COMMENT (Comment)Type: StringAssociates a comment to the resource. MFG_TOOL_NUMBER (Tool number)Type: IntegerDefines the tool number. The manufacturing attribute is MFG_TOOL_NUMBER. MFG_BALL_TYPE (Ball-end tool)Type: Boolean (Yes/No)Defines the tool as being ball-end. The manufacturing attribute is MFG_BALL_TYPE.
Geometry Attributes
These attributes characterize the tool shape and have an impact on the tool path computation.
MFG_NOMINAL_DIAM (Nominal diameter : D)Type: RealDefines the cutting diameter of the tool. The manufacturing attribute is MFG_NOMINAL_DIAM. MFG_CORNER_RAD (Corner radius : Rc)Type: RealDefines the radius of the cutting shape of the tool. The manufacturing attribute is MFG_CORNER_RAD. MFG_OVERALL_LGTH (Overall length : L)Type: RealDefines the total length of the tool. The manufacturing attribute is MFG_OVERALL_LGTH. MFG_CUT_LENGTH (Cutting length : Lc)Type: RealDefines the effective cutting length available on the tool's active part. The manufacturing attribute is MFG_CUT_LENGTH.
MFG_LENGTH (Length : l)Type: RealDefines the length of the external envelope of the tool's active part. The manufacturing attribute is MFG_LENGTH. MFG_BODY_DIAM (Body diameter : db)Type: RealDefines the diameter of the external envelope of the non-active part of the tool. The manufacturing attribute is MFG_BODY_DIAM. MFG_TOOL_CORE_DIAMETER (Non cutting diameter)Type: RealDefines the diameter of the non-cutting part (core) of the tool. This can be useful in operations such as Roughing, Pocketing, and Multi-Axis Helix Machining. The manufacturing attribute is MFG_TOOL_CORE_DIAMETER.
Technology Attributes
These attributes provide technological information without any impact on the tool path computation.
MFG_NB_OF_FLUTES (Number of flutes)Type: IntegerDefines the number of flutes on the tool. In case of tools with separate inserts, this is the number of inserts The manufacturing attribute is MFG_NB_OF_FLUTES. MFG_WAY_OF_ROT (Way of rotation)Type: StringPossible values:RIGHT_HAND (Right hand)LEFT_HAND (Left hand)Defines the flutes orientation. It should be compatible with spindle rotation orientation. The manufacturing attribute is MFG_WAY_OF_ROT with possible value RIGHT_HAND or LEFT_HAND MFG_MACH_QUALITY (Machining quality)Type: StringPossible values:ROUGH (Rough)FINISH (Finish)EITHER (Either)Defines the tool's ability to machine in roughing or finishing mode. The manufacturing attribute is MFG_MACH_QUALITY with possible value ROUGH, FINISH or EITHER. MFG_COMPOSITION (Composition)Type: StringPossible values:ONE_PIECE (One piece)INSERT_HOLDER (Insert holder)Specifies if the tool is an inserted one. The manufacturing attribute is MFG_COMPOSITION with possible value ONE_PIECE or INSERT_HOLDER. MFG_TOOTH_MAT (Tooth material)Type: StringPossible values:HIGH_SPEED_STEEL (High speed steel)COATED_HIGH_SPEED_STEEL (Coated high speed steel)CARBIDE (Carbide)COATED_CARBIDE (Coated carbide)OTHER (Other)Defines the tooth material type. The manufacturing attribute is MFG_TOOTH_MAT with possible value: HIGH_SPEED_STEEL, COATED_HIGH_SPEED_STEEL, CARBIDE, COATED_CARBIDE, OTHER.
MFG_TOOTH_DESC (Tooth description)Type: StringAllows the user to specify the tooth nature as a comment. For example, it could be the supplier reference of the insert. The manufacturing attribute is MFG_TOOTH_DESC. MFG_TOOTH_MATDESC (Tooth material desc.)Type: StringAllows the user to specify the tooth material by means of a comment. For example, it could be the ISO designation for cutting materials or the reference of the coating material. The manufacturing attribute is MFG_TOOTH_MATDESC. MFG_TL_RAKE_ANG (Tool rake angle )Type: RealDefines the tool rake angle. The manufacturing attribute is MFG_TL_RAKE_ANG. MFG_MAX_PLNG_ANG (Max plunge angle)Type: RealDefines the plunge ability of the tool. When the tool is able to plunge along its axis, the maximum plunge angle is equal to 90 degrees. The manufacturing attribute is MFG_MAX_PLNG_ANG. MFG_MAX_MIL_LENGTH (Max machining length)Type: RealSpecifies the tool life in length units. The manufacturing attribute is MFG_MAX_MIL_LENGTH. MFG_MAX_MIL_TIME (Max life time)Type: RealSpecifies the tool life in time units. The manufacturing attribute is MFG_MAX_MIL_TIME. MFG_COOLNT_SNTX (Coolant syntax)Type: StringSpecifies the coolant supply syntax. The manufacturing attribute is MFG_COOLNT_SNTX. MFG_WEIGHT_SNTX (Weight syntax)Type: StringSpecifies the tool weight syntax. The manufacturing attribute is MFG_WEIGHT_SNTX.
Cutting Conditions Attributes
These attributes are used for feeds and speeds computation on the operation.
MFG_VC_FINISH (Finishing cutting speed)Type: RealDefines the Finishing cutting speed of the tool. The manufacturing attribute is MFG_VC_FINISH. MFG_SZ_FINISH (Finishing feedrate per tooth)Type: RealDefines the Finishing feedrate per tooth of the tool. The manufacturing attribute is MFG_SZ_FINISH. MFG_AA_FINISH (Axial depth of cut for finish)Type: RealDefines the Axial depth of cut for finish of the tool. The manufacturing attribute is MFG_AA_FINISH. MFG_AR_FINISH (Radial depth of cut for finish)Type: RealDefines the Radial depth of cut for finish of the tool. The manufacturing attribute is MFG_AR_FINISH. MFG_VC_ROUGH (Roughing cutting speed)Type: RealDefines the Roughing cutting speed of the tool. The manufacturing attribute is MFG_VC_ROUGH. MFG_SZ_ROUGH (Roughing feedrate per tooth)Type: RealDefines the Roughing feedrate per tooth of the tool. The manufacturing attribute is MFG_SZ_ROUGH.
MFG_AA_ROUGH (Axial depth of cut for rough)Type: RealDefines the Axial depth of cut for rough of the tool. The manufacturing attribute is MFG_AA_ROUGH. MFG_AR_ROUGH (Radial depth of cut for rough)Type: RealDefines the Radial depth of cut for rough of the tool. The manufacturing attribute is MFG_AR_ROUGH.
MfgFaceMillTool (Face Mill)
Description
Describes the MfgFaceMillTool resource attributes that are available in Machining workbenches.
Base Attributes
These attributes provide general information.
MFG_NAME (Name)Type: StringSpecifies the name of the resource. MFG_COMMENT (Comment)Type: StringAssociates a comment to the resource. MFG_TOOL_NUMBER (Tool number)Type: IntegerDefines the tool number. The manufacturing attribute is MFG_TOOL_NUMBER.
Geometry Attributes
These attributes characterize the tool shape and have an impact on the tool path computation.
MFG_NOMINAL_DIAM (Nominal diameter : D)Type: RealDefines the cutting diameter of the tool. The manufacturing attribute is MFG_NOMINAL_DIAM. MFG_CORNER_RAD (Corner radius : Rc)Type: RealDefines the radius of the cutting shape of the tool. The manufacturing attribute is MFG_CORNER_RAD. MFG_OVERALL_LGTH (Overall length : L)Type: RealDefines the total length of the tool. The manufacturing attribute is MFG_OVERALL_LGTH. MFG_CUT_LENGTH (Cutting length : Lc)Type: RealDefines the effective cutting length available on the tool's active part. The manufacturing attribute is MFG_CUT_LENGTH. MFG_LENGTH (Length : l)Type: RealDefines the length of the external envelope of the tool's active part. The manufacturing attribute is MFG_LENGTH.
MFG_BODY_DIAM (Body diameter : db)Type: RealDefines the diameter of the external envelope of the non-active part of the tool. The manufacturing attribute is MFG_BODY_DIAM. MFG_OUTSIDE_DIAM (Outside diameter : Da)Type: RealDefines the diameter of the external envelope of the tool's active part for tools such as face mills, countersinks and thread mills. The manufacturing attribute is MFG_OUTSIDE_DIAM. MFG_CUT_ANGLE (Cutting angle : A)Type: RealDefines the cutting angle of the tool. The manufacturing attribute is MFG_CUT_ANGLE. MFG_TOOL_CORE_DIAMETER (Non cutting diameter)Type: RealDefines the diameter of the non-cutting part (core) of the tool. This can be useful in operations such as Roughing, Pocketing, and Multi-Axis Helix Machining. The manufacturing attribute is MFG_TOOL_CORE_DIAMETER.
Technology Attributes
These attributes provide technological information without any impact on the tool path computation.
MFG_NB_OF_FLUTES (Number of flutes)Type: IntegerDefines the number of flutes on the tool. In case of tools with separate inserts, this is the number of inserts The manufacturing attribute is MFG_NB_OF_FLUTES. MFG_WAY_OF_ROT (Way of rotation)Type: StringPossible values:RIGHT_HAND (Right hand)LEFT_HAND (Left hand)Defines the flutes orientation. It should be compatible with spindle rotation orientation. The manufacturing attribute is MFG_WAY_OF_ROT with possible value RIGHT_HAND or LEFT_HAND MFG_MACH_QUALITY (Machining quality)Type: StringPossible values:ROUGH (Rough)FINISH (Finish)EITHER (Either)Defines the tool's ability to machine in roughing or finishing mode. The manufacturing attribute is MFG_MACH_QUALITY with possible value ROUGH, FINISH or EITHER. MFG_COMPOSITION (Composition)Type: StringPossible values:ONE_PIECE (One piece)INSERT_HOLDER (Insert holder)Specifies if the tool is an inserted one. The manufacturing attribute is MFG_COMPOSITION with possible value ONE_PIECE or INSERT_HOLDER.
MFG_TOOTH_MAT (Tooth material)Type: StringPossible values:HIGH_SPEED_STEEL (High speed steel)COATED_HIGH_SPEED_STEEL (Coated high speed steel)CARBIDE (Carbide)COATED_CARBIDE (Coated carbide)OTHER (Other)Defines the tooth material type. The manufacturing attribute is MFG_TOOTH_MAT with possible value: HIGH_SPEED_STEEL, COATED_HIGH_SPEED_STEEL, CARBIDE, COATED_CARBIDE, OTHER. MFG_TOOTH_DES (Tooth description)Type: StringAllows the user to specify the tooth nature as a comment. For example, it could be the supplier reference of the insert. The manufacturing attribute is MFG_TOOTH_DES. MFG_TOOTH_MATDES (Tooth material desc.)Type: StringAllows the user to specify the tooth material by means of a comment. For example, it could be the ISO designation for cutting materials or the reference of the coating material. The manufacturing attribute is MFG_TOOTH_MATDES. MFG_TL_RAKE_ANG (Tool rake angle )Type: IntegerDefines the tool rake angle. The manufacturing attribute is MFG_TL_RAKE_ANG. MFG_MAX_PLNG_ANG (Max plunge angle)Type: IntegerDefines the plunge ability of the tool. When the tool is able to plunge along its axis, the maximum plunge angle is equal to 90 degrees. The manufacturing attribute is MFG_MAX_PLNG_ANG. MFG_MAX_MIL_LENGTH (Max machining length)Type: RealSpecifies the tool life in length units. The manufacturing attribute is MFG_MAX_MIL_LENGTH. MFG_MAX_MIL_TIME (Max life time)Type: RealSpecifies the tool life in time units. The manufacturing attribute is MFG_MAX_MIL_TIME. MFG_COOLNT_SNTX (Coolant syntax)Type: StringSpecifies the coolant supply syntax. The manufacturing attribute is MFG_COOLNT_SNTX. MFG_WEIGHT_SNTX (Weight syntax)Type: StringSpecifies the tool weight syntax. The manufacturing attribute is MFG_WEIGHT_SNTX.
Cutting Conditions Attributes
These attributes are used for feeds and speeds computation on the operation.
MFG_VC_FINISH (Finishing cutting speed)Type: RealDefines the Finishing cutting speed of the tool. The manufacturing attribute is MFG_VC_FINISH. MFG_SZ_FINISH (Finishing feedrate per tooth)Type: RealDefines the Finishing feedrate per tooth of the tool. The manufacturing attribute is MFG_SZ_FINISH. MFG_AA_FINISH (Axial depth of cut for finish)Type: RealDefines the Axial depth of cut for finish of the tool. The manufacturing attribute is MFG_AA_FINISH.
MFG_AR_FINISH (Radial depth of cut for finish)Type: RealDefines the Radial depth of cut for finish of the tool. The manufacturing attribute is MFG_AR_FINISH. MFG_VC_ROUGH (Roughing cutting speed)Type: RealDefines the Roughing cutting speed of the tool. The manufacturing attribute is MFG_VC_ROUGH. MFG_SZ_ROUGH (Roughing feedrate per tooth)Type: RealDefines the Roughing feedrate per tooth of the tool. The manufacturing attribute is MFG_SZ_ROUGH. MFG_AA_ROUGH (Axial depth of cut for rough)Type: RealDefines the Axial depth of cut for rough of the tool. The manufacturing attribute is MFG_AA_ROUGH. MFG_AR_ROUGH (Radial depth of cut for rough)Type: RealDefines the Radial depth of cut for rough of the tool. The manufacturing attribute is MFG_AR_ROUGH.
MfgConicalMillTool (Conical Mill)
Description
Describes the MfgConicalMillTool resource attributes that are available in Machining workbenches.
Base Attributes
These attributes provide general information.
MFG_NAME (Name)Type: StringSpecifies the name of the resource. MFG_COMMENT (Comment)Type: StringAssociates a comment to the resource. MFG_TOOL_NUMBER (Tool number)Type: IntegerDefines the tool number. The manufacturing attribute is MFG_TOOL_NUMBER. MFG_BALL_TYPE (Ball-end tool)Type: Boolean (Yes/No)Defines the tool as being ball-end. The manufacturing attribute is MFG_BALL_TYPE.
Geometry Attributes
These attributes characterize the tool shape and have an impact on the tool path computation.
MFG_NOMINAL_DIAM (Nominal diameter : D)Type: RealDefines the cutting diameter of the tool. The manufacturing attribute is MFG_NOMINAL_DIAM. MFG_CORNER_RAD (Corner radius : Rc)Type: RealDefines the radius of the cutting shape of the tool. The manufacturing attribute is MFG_CORNER_RAD.
MFG_OVERALL_LGTH (Overall length : L)Type: RealDefines the total length of the tool. The manufacturing attribute is MFG_OVERALL_LGTH. MFG_CUT_LENGTH (Cutting length : Lc)Type: RealDefines the effective cutting length available on the tool's active part. The manufacturing attribute is MFG_CUT_LENGTH. MFG_LENGTH (Length : l)Type: RealDefines the length of the external envelope of the tool's active part. The manufacturing attribute is MFG_LENGTH. MFG_BODY_DIAM (Body diameter : db)Type: RealDefines the diameter of the external envelope of the non-active part of the tool. The manufacturing attribute is MFG_BODY_DIAM. MFG_ENTRY_DIAM (Entry diameter : d)Type: RealDefines the smallest diameter of the head of the tool. The manufacturing attribute is MFG_ENTRY_DIAM. MFG_CUT_ANGLE (Cutting angle : A)Type: RealDefines the cutting angle of the tool. The manufacturing attribute is MFG_CUT_ANGLE.
Technology Attributes
These attributes provide technological information without any impact on the tool path computation.
MFG_NB_OF_FLUTES (Number of flutes)Type: IntegerDefines the number of flutes on the tool. In case of tools with separate inserts, this is the number of inserts The manufacturing attribute is MFG_NB_OF_FLUTES. MFG_WAY_OF_ROT (Way of rotation)Type: StringPossible values:RIGHT_HAND (Right hand)LEFT_HAND (Left hand)Defines the flutes orientation. It should be compatible with spindle rotation orientation. The manufacturing attribute is MFG_WAY_OF_ROT with possible value RIGHT_HAND or LEFT_HAND MFG_MACH_QUALITY (Machining quality)Type: StringPossible values:ROUGH (Rough)FINISH (Finish)EITHER (Either)Defines the tool's ability to machine in roughing or finishing mode. The manufacturing attribute is MFG_MACH_QUALITY with possible value ROUGH, FINISH or EITHER. MFG_COMPOSITION (Composition)Type: StringPossible values:ONE_PIECE (One piece)INSERT_HOLDER (Insert holder)Specifies if the tool is an inserted one. The manufacturing attribute is MFG_COMPOSITION with possible value ONE_PIECE or INSERT_HOLDER.
MFG_TOOTH_MAT (Tooth material)Type: StringPossible values:HIGH_SPEED_STEEL (High speed steel)COATED_HIGH_SPEED_STEEL (Coated high speed steel)CARBIDE (Carbide)COATED_CARBIDE (Coated carbide)OTHER (Other)Defines the tooth material type. The manufacturing attribute is MFG_TOOTH_MAT with possible value: HIGH_SPEED_STEEL, COATED_HIGH_SPEED_STEEL, CARBIDE, COATED_CARBIDE, OTHER. MFG_TOOTH_DES (Tooth description)Type: StringAllows the user to specify the tooth nature as a comment. For example, it could be the supplier reference of the insert. The manufacturing attribute is MFG_TOOTH_DES. MFG_TOOTH_MATDES (Tooth material desc.)Type: StringAllows the user to specify the tooth material by means of a comment. For example, it could be the ISO designation for cutting materials or the reference of the coating material. The manufacturing attribute is MFG_TOOTH_MATDES. MFG_TL_RAKE_ANG (Tool rake angle )Type: RealDefines the tool rake angle. The manufacturing attribute is MFG_TL_RAKE_ANG. MFG_MAX_PLNG_ANG (Max plunge angle)Type: RealDefines the plunge ability of the tool. When the tool is able to plunge along its axis, the maximum plunge angle is equal to 90 degrees. The manufacturing attribute is MFG_MAX_PLNG_ANG. MFG_MAX_MIL_LENGTH (Max machining length)Type: RealSpecifies the tool life in length units. The manufacturing attribute is MFG_MAX_MIL_LENGTH. MFG_MAX_MIL_TIME (Max life time)Type: RealSpecifies the tool life in time units. The manufacturing attribute is MFG_MAX_MIL_TIME. MFG_COOLNT_SNTX (Coolant syntax)Type: StringSpecifies the coolant supply syntax. The manufacturing attribute is MFG_COOLNT_SNTX. MFG_WEIGHT_SNTX (Weight syntax)Type: StringSpecifies the tool weight syntax. The manufacturing attribute is MFG_WEIGHT_SNTX.
Cutting Conditions Attributes
These attributes are used for feeds and speeds computation on the operation.
MFG_VC_FINISH (Finishing cutting speed)Type: RealDefines the Finishing cutting speed of the tool. The manufacturing attribute is MFG_VC_FINISH. MFG_SZ_FINISH (Finishing feedrate per tooth)Type: RealDefines the Finishing feedrate per tooth of the tool. The manufacturing attribute is MFG_SZ_FINISH. MFG_AA_FINISH (Axial depth of cut for finish)Type: RealDefines the Axial depth of cut for finish of the tool. The manufacturing attribute is MFG_AA_FINISH.
MFG_AR_FINISH (Radial depth of cut for finish)Type: RealDefines the Radial depth of cut for finish of the tool. The manufacturing attribute is MFG_AR_FINISH. MFG_VC_ROUGH (Roughing cutting speed)Type: RealDefines the Roughing cutting speed of the tool. The manufacturing attribute is MFG_VC_ROUGH. MFG_SZ_ROUGH (Roughing feedrate per tooth)Type: RealDefines the Roughing feedrate per tooth of the tool. The manufacturing attribute is MFG_SZ_ROUGH. MFG_AA_ROUGH (Axial depth of cut for rough)Type: RealDefines the Axial depth of cut for rough of the tool. The manufacturing attribute is MFG_AA_ROUGH. MFG_AR_ROUGH (Radial depth of cut for rough)Type: RealDefines the Radial depth of cut for rough of the tool. The manufacturing attribute is MFG_AR_ROUGH.
MfgTSlotterTool (T-Slotter)
Description
Describes the MfgTSlotterTool resource attributes that are available in Machining workbenches.
Base Attributes
These attributes provide general information.
MFG_NAME (Name)Type: StringSpecifies the name of the resource. MFG_COMMENT (Comment)Type: StringAssociates a comment to the resource. MFG_TOOL_NUMBER (Tool number)Type: IntegerDefines the tool number. The manufacturing attribute is MFG_TOOL_NUMBER. MFG_BALL_TYPE (Ball-end tool)Type: Boolean (Yes/No)Defines the tool as being ball-end. The manufacturing attribute is MFG_BALL_TYPE.
Geometry Attributes
These attributes characterize the tool shape and have an impact on the tool path computation.
MFG_NOMINAL_DIAM (Nominal diameter : D)Type: RealDefines the cutting diameter of the tool. The manufacturing attribute is MFG_NOMINAL_DIAM. MFG_CORNER_RAD (Corner radius : Rc)Type: RealDefines the radius of the cutting shape of the tool. The manufacturing attribute is MFG_CORNER_RAD.
MFG_CORNER_RAD_2 (Upper corner radius : Rc2)Type: RealDefines the upper radius of the cutting shape of the tool. The manufacturing attribute is MFG_CORNER_RAD_2. MFG_OVERALL_LGTH (Overall length : L)Type: RealDefines the total length of the tool. The manufacturing attribute is MFG_OVERALL_LGTH. MFG_LENGTH (Length : l)Type: RealDefines the length of the external envelope of the tool's active part. The manufacturing attribute is MFG_LENGTH. MFG_BODY_DIAM (Body diameter : db)Type: RealDefines the diameter of the external envelope of the non-active part of the tool. The manufacturing attribute is MFG_BODY_DIAM.
Technology Attributes
These attributes provide technological information without any impact on the tool path computation.
MFG_NB_OF_FLUTES (Number of flutes)Type: IntegerDefines the number of flutes on the tool. In case of tools with separate inserts, this is the number of inserts The manufacturing attribute is MFG_NB_OF_FLUTES. MFG_WAY_OF_ROT (Way of rotation)Type: StringPossible values:RIGHT_HAND (Right hand)LEFT_HAND (Left hand)Defines the flutes orientation. It should be compatible with spindle rotation orientation. The manufacturing attribute is MFG_WAY_OF_ROT with possible value RIGHT_HAND or LEFT_HAND MFG_MACH_QUALITY (Machining quality)Type: StringPossible values:ROUGH (Rough)FINISH (Finish)EITHER (Either)Defines the tool's ability to machine in roughing or finishing mode. The manufacturing attribute is MFG_MACH_QUALITY with possible value ROUGH, FINISH or EITHER. MFG_COMPOSITION (Composition)Type: StringPossible values:ONE_PIECE (One piece)INSERT_HOLDER (Insert holder)Specifies if the tool is an inserted one. The manufacturing attribute is MFG_COMPOSITION with possible value ONE_PIECE or INSERT_HOLDER.
MFG_TOOTH_MAT (Tooth material)Type: StringPossible values:HIGH_SPEED_STEEL (High speed steel)COATED_HIGH_SPEED_STEEL (Coated high speed steel)CARBIDE (Carbide)COATED_CARBIDE (Coated carbide)OTHER (Other)Defines the tooth material type. The manufacturing attribute is MFG_TOOTH_MAT with possible value: HIGH_SPEED_STEEL, COATED_HIGH_SPEED_STEEL, CARBIDE, COATED_CARBIDE, OTHER. MFG_TOOTH_DES (Tooth description)Type: StringAllows the user to specify the tooth nature as a comment. For example, it could be the supplier reference of the insert. The manufacturing attribute is MFG_TOOTH_DES. MFG_TOOTH_MATDES (Tooth material desc.)Type: StringAllows the user to specify the tooth material by means of a comment. For example, it could be the ISO designation for cutting materials or the reference of the coating material. The manufacturing attribute is MFG_TOOTH_MATDES. MFG_TL_RAKE_ANG (Tool rake angle )Type: RealDefines the tool rake angle. The manufacturing attribute is MFG_TL_RAKE_ANG. MFG_MAX_MIL_LENGTH (Max machining length)Type: RealSpecifies the tool life in length units. The manufacturing attribute is MFG_MAX_MIL_LENGTH. MFG_MAX_MIL_TIME (Max life time)Type: RealSpecifies the tool life in time units. The manufacturing attribute is MFG_MAX_MIL_TIME. MFG_COOLNT_SNTX (Coolant syntax)Type: StringSpecifies the coolant supply syntax. The manufacturing attribute is MFG_COOLNT_SNTX. MFG_WEIGHT_SNTX (Weight syntax)Type: StringSpecifies the tool weight syntax. The manufacturing attribute is MFG_WEIGHT_SNTX.
Cutting Conditions Attributes
These attributes are used for feeds and speeds computation on the operation.
MFG_VC_FINISH (Finishing cutting speed)Type: RealDefines the Finishing cutting speed of the tool. The manufacturing attribute is MFG_VC_FINISH. MFG_SZ_FINISH (Finishing feedrate per tooth)Type: RealDefines the Finishing feedrate per tooth of the tool. The manufacturing attribute is MFG_SZ_FINISH. MFG_AA_FINISH (Axial depth of cut for finish)Type: RealDefines the Axial depth of cut for finish of the tool. The manufacturing attribute is MFG_AA_FINISH. MFG_AR_FINISH (Radial depth of cut for finish)Type: RealDefines the Radial depth of cut for finish of the tool. The manufacturing attribute is MFG_AR_FINISH.
MFG_VC_ROUGH (Roughing cutting speed)Type: RealDefines the Roughing cutting speed of the tool. The manufacturing attribute is MFG_VC_ROUGH. MFG_SZ_ROUGH (Roughing feedrate per tooth)Type: RealDefines the Roughing feedrate per tooth of the tool. The manufacturing attribute is MFG_SZ_ROUGH. MFG_AA_ROUGH (Axial depth of cut for rough)Type: RealDefines the Axial depth of cut for rough of the tool. The manufacturing attribute is MFG_AA_ROUGH. MFG_AR_ROUGH (Radial depth of cut for rough)Type: RealDefines the Radial depth of cut for rough of the tool. The manufacturing attribute is MFG_AR_ROUGH.
MfgExternalTool (External Insert Holder)
Description
Describes the MfgExternalTool resource attributes that are available in Machining workbenches.
Base Attributes
These attributes provide general information.
MFG_NAME (Name)Type: StringSpecifies the name of the resource. MFG_COMMENT (Comment)Type: StringAssociates a comment to the resource.
Geometry Attributes
These attributes characterize the tool shape and have an impact on the tool path computation.
MFG_HAND_STYLE (Hand style)Type: StringPossible values:RIGHT_HAND (Right hand)LEFT_HAND (Left hand)NEUTRALDefines the tool's hand style. The manufacturing attribute is MFG_HAND_STYLE with possible value RIGHT_HAND, LEFT_HAND or NEUTRAL. MFG_HOLDER_CAPAB (Holder capability)Type: StringPossible values:SURFACETRAVERSEBOTH (Shortest)Defines the holder capability. The manufacturing attribute is MFG_HOLDER_CAPAB with possible value SURFACE, TRAVERSE or BOTH.
MFG_KAPPA_R (Cutting edge angle : Kr)Type: RealDefines the cutting edge angle of the tool. The manufacturing attribute is MFG_KAPPA_R. MFG_INSERT_ANGLE (Insert angle : a)Type: RealDefines the angle of the insert mounted on the tool. The manufacturing attribute is MFG_INSERT_ANGLE. MFG_INSERT_LGTH (Insert length : l)Type: RealDefines the cutting edge length of an insert. The manufacturing attribute is MFG_INSERT_LGTH. MFG_CLEAR_ANGLE (Clearance angle)Type: RealDefines the clearance angle. The manufacturing attribute is MFG_CLEAR_ANGLE. MFG_SHK_CUT_WDTH (Shank cut width : f)Type: RealDefines the cutting width of the tool. The manufacturing attribute is MFG_SHK_CUT_WDTH. MFG_SHANK_HEIGHT (Shank height : h)Type: RealDefines the height of the shank. The manufacturing attribute is MFG_SHANK_HEIGHT. MFG_SHK_LENGTH_1 (Shank length 1 : l1)Type: RealDefines the overall length of the tool. The manufacturing attribute is MFG_LENGTH_1. MFG_SHK_LENGTH_2 (Shank length 2 : l2)Type: RealDefines the length of the external envelope of the tool's active part. The manufacturing attribute is MFG_SHK_LENGTH_2. MFG_SHANK_WIDTH (Shank width : b)Type: RealDefines the width of the shank. The manufacturing attribute is MFG_SHANK_WIDTH.
Technology Attributes
These attributes provide technological information without any impact on the tool path computation.
MFG_MAX_MIL_LENGTH (Max machining length)Type: RealSpecifies the tool life in length units. The manufacturing attribute is MFG_MAX_MIL_LENGTH. MFG_MAX_MIL_TIME (Max life time)Type: RealSpecifies the tool life in time units. The manufacturing attribute is MFG_MAX_MIL_TIME. MFG_COOLNT_SNTX (Coolant syntax)Type: StringSpecifies the coolant supply syntax. The manufacturing attribute is MFG_COOLNT_SNTX. MFG_WEIGHT_SNTX (Weight syntax)Type: StringSpecifies the tool weight syntax. The manufacturing attribute is MFG_WEIGHT_SNTX. MFG_TRAILING_ANG (Trailing angle)Type: RealDefines the trailing angle of the tool. If the trailing angle is set to 0, insert angle is used for the trailing angle. The manufacturing attribute is MFG_TRAILING_ANG. MFG_LEADING_ANG (Leading angle)Type: RealDefines the leading angle of the tool. If the leading angle is set to 0, insert angle is used for the leading angle. The manufacturing attribute is MFG_LEADING_ANG.
MFG_MAX_REC_DPTH (Max recessing depth)Type: RealDefines the maximum recessing depth. The manufacturing attribute is MFG_MAX_REC_DPTH.
MfgInternalTool (Internal Insert Holder)
Description
Describes the MfgInternalTool resource attributes that are available in Machining workbenches.
Base Attributes
These attributes provide general information.
MFG_NAME (Name)Type: StringSpecifies the name of the resource. MFG_COMMENT (Comment)Type: StringAssociates a comment to the resource.
Geometry Attributes
These attributes characterize the tool shape and have an impact on the tool path computation.
MFG_HAND_STYLE (Hand style)Type: StringPossible values:RIGHT_HAND (Right hand)LEFT_HAND (Left hand)NEUTRALDefines the tool's hand style. The manufacturing attribute is MFG_HAND_STYLE with possible value RIGHT_HAND, LEFT_HAND or NEUTRAL. MFG_BODY_DIAM (Body diameter : db)Type: RealDefines the diameter of the external envelope of the non-active part of the tool. The manufacturing attribute is MFG_BODY_DIAM. MFG_KAPPA_R (Cutting edge angle : Kr)Type: RealDefines the cutting edge angle of the tool. The manufacturing attribute is MFG_KAPPA_R. MFG_INSERT_ANGLE (Insert angle : a)Type: RealDefines the angle of the insert mounted on the tool. The manufacturing attribute is MFG_INSERT_ANGLE. MFG_INSERT_LGTH (Insert length : l)Type: RealDefines the cutting edge length of an insert. The manufacturing attribute is MFG_INSERT_LGTH. MFG_CLEAR_ANGLE (Clearance angle)Type: RealDefines the clearance angle. The manufacturing attribute is MFG_CLEAR_ANGLE.
MFG_BAR_LENGTH_1 (Bar length 1 : l1)Type: RealDefines the overall length of the tool. The manufacturing attribute is MFG_BAR_LENGTH_1. MFG_BAR_LENGTH_2 (Bar length 2 : l2)Type: RealDefines the length of the external envelope of the tool's active part. The manufacturing attribute is MFG_BAR_LENGTH_2. MFG_BAR_CUT_RAD (Bar cut radius : f)Type: RealDefines the cutting radius of the tool. The manufacturing attribute is MFG_BAR_CUT_RAD.
Technology Attributes
These attributes provide technological information without any impact on the tool path computation.
MFG_MAX_MIL_LENGTH (Max machining length)Type: RealSpecifies the tool life in length units. The manufacturing attribute is MFG_MAX_MIL_LENGTH. MFG_MAX_MIL_TIME (Max life time)Type: RealSpecifies the tool life in time units. The manufacturing attribute is MFG_MAX_MIL_TIME. MFG_COOLNT_SNTX (Coolant syntax)Type: StringSpecifies the coolant supply syntax. The manufacturing attribute is MFG_COOLNT_SNTX. MFG_WEIGHT_SNTX (Weight syntax)Type: StringSpecifies the tool weight syntax. The manufacturing attribute is MFG_WEIGHT_SNTX. MFG_TRAILING_ANG (Trailing angle)Type: RealDefines the trailing angle of the tool. If the trailing angle is set to 0, insert angle is used for the trailing angle. The manufacturing attribute is MFG_TRAILING_ANG. MFG_LEADING_ANG (Leading angle)Type: RealDefines the leading angle of the tool. If the leading angle is set to 0, insert angle is used for the leading angle. The manufacturing attribute is MFG_LEADING_ANG. MFG_MAX_REC_DPTH (Max recessing depth)Type: RealDefines the maximum recessing depth. The manufacturing attribute is MFG_MAX_REC_DPTH. MFG_MAX_BOR_DPTH (Max boring depth)Type: RealDefines the maximum boring depth. The manufacturing attribute is MFG_MAX_BOR_DPTH. MFG_MIN_DIAM (Min diameter)Type: RealDefines the minimum diameter which can be cut. The manufacturing attribute is MFG_MIN_DIAM.
MfgGrooveExternalTool (External Groove Insert Holder)
Description
Describes the MfgGrooveExternalTool resource attributes that are available in Machining workbenches.
Base Attributes
These attributes provide general information.
MFG_NAME (Name)Type: StringSpecifies the name of the resource. MFG_COMMENT (Comment)Type: StringAssociates a comment to the resource.
Geometry Attributes
These attributes characterize the tool shape and have an impact on the tool path computation.
MFG_HAND_STYLE (Hand style)Type: StringPossible values:RIGHT_HAND (Right hand)LEFT_HAND (Left hand)NEUTRALDefines the tool's hand style. The manufacturing attribute is MFG_HAND_STYLE with possible value RIGHT_HAND, LEFT_HAND or NEUTRAL. MFG_HAND_ANGLE (Hand angle)Type: RealDefines the hand angle. The manufacturing attribute is MFG_HAND_ANGLE. MFG_INSERT_WIDTH (Insert width : la)Type: RealDefines the insert width. The manufacturing attribute is MFG_INSERT_WIDTH. MFG_CLEAR_ANGLE (Clearance angle)Type: RealDefines the clearance angle. The manufacturing attribute is MFG_CLEAR_ANGLE. MFG_SHK_CUT_WDTH (Shank cut width : f)Type: RealDefines the cutting width of the tool. The manufacturing attribute is MFG_SHK_CUT_WDTH. MFG_SHANK_HEIGHT (Shank height : h)Type: RealDefines the height of the shank. The manufacturing attribute is MFG_SHANK_HEIGHT. MFG_SHK_LENGTH_1 (Shank length 1 : l1)Type: RealDefines the overall length of the tool. The manufacturing attribute is MFG_LENGTH_1. MFG_SHK_LENGTH_2 (Shank length 2 : l2)Type: RealDefines the length of the external envelope of the tool's active part. The manufacturing attribute is MFG_SHK_LENGTH_2. MFG_SHANK_WIDTH (Shank width : b)Type: RealDefines the width of the shank. The manufacturing attribute is MFG_SHANK_WIDTH.
Technology Attributes
These attributes provide technological information without any impact on the tool path computation.
MFG_MAX_MIL_LENGTH (Max machining length)Type: RealSpecifies the tool life in length units. The manufacturing attribute is MFG_MAX_MIL_LENGTH. MFG_MAX_MIL_TIME (Max life time)Type: RealSpecifies the tool life in time units. The manufacturing attribute is MFG_MAX_MIL_TIME. MFG_COOLNT_SNTX (Coolant syntax)Type: StringSpecifies the coolant supply syntax. The manufacturing attribute is MFG_COOLNT_SNTX. MFG_WEIGHT_SNTX (Weight syntax)Type: StringSpecifies the tool weight syntax. The manufacturing attribute is MFG_WEIGHT_SNTX. MFG_MAX_CUT_DPTH (Max cut depth : ar)Type: RealDefines the maximum cut depth. The manufacturing attribute is MFG_MAX_CUT_DPTH. MFG_MAX_CUT_WDTH (Max cut width)Type: RealDefines the maximum cut width. The manufacturing attribute is MFG_MAX_CUT_WDTH. MFG_GAUGING_ANG (Gouging angle)Type: RealDefines the gouging angle. The manufacturing attribute is MFG_GAUGING_ANG.
MfgGrooveFrontalTool (Frontal Groove Insert Holder)
Description
Describes the MfgGrooveFrontalTool resource attributes that are available in Machining workbenches.
Base Attributes
These attributes provide general information.
MFG_NAME (Name)Type: StringSpecifies the name of the resource. MFG_COMMENT (Comment)Type: StringAssociates a comment to the resource.
Geometry Attributes
These attributes characterize the tool shape and have an impact on the tool path computation.
MFG_HAND_STYLE (Hand style)Type: StringPossible values:RIGHT_HAND (Right hand)LEFT_HAND (Left hand)NEUTRALDefines the tool's hand style. The manufacturing attribute is MFG_HAND_STYLE with possible value RIGHT_HAND, LEFT_HAND or NEUTRAL. MFG_INSERT_WIDTH (Insert width : la)Type: RealDefines the insert width. The manufacturing attribute is MFG_INSERT_WIDTH. MFG_CLEAR_ANGLE (Clearance angle)Type: RealDefines the clearance angle. The manufacturing attribute is MFG_CLEAR_ANGLE. MFG_SHK_CUT_WDTH (Shank cut width : f)Type: RealDefines the cutting width of the tool. The manufacturing attribute is MFG_SHK_CUT_WDTH. MFG_SHANK_HEIGHT (Shank height : h)Type: RealDefines the height of the shank. The manufacturing attribute is MFG_SHANK_HEIGHT. MFG_SHK_LENGTH_1 (Shank length 1 : l1)Type: RealDefines the overall length of the tool. The manufacturing attribute is MFG_LENGTH_1. MFG_SHK_LENGTH_2 (Shank length 2 : l2)Type: RealDefines the length of the external envelope of the tool's active part. The manufacturing attribute is MFG_SHK_LENGTH_2. MFG_SHANK_WIDTH (Shank width : b)Type: RealDefines the width of the shank. The manufacturing attribute is MFG_SHANK_WIDTH.
Technology Attributes
These attributes provide technological information without any impact on the tool path computation.
MFG_MAX_MIL_LENGTH (Max machining length)Type: RealSpecifies the tool life in length units. The manufacturing attribute is MFG_MAX_MIL_LENGTH. MFG_MAX_MIL_TIME (Max life time)Type: RealSpecifies the tool life in time units. The manufacturing attribute is MFG_MAX_MIL_TIME. MFG_COOLNT_SNTX (Coolant syntax)Type: StringSpecifies the coolant supply syntax. The manufacturing attribute is MFG_COOLNT_SNTX. MFG_WEIGHT_SNTX (Weight syntax)Type: StringSpecifies the tool weight syntax. The manufacturing attribute is MFG_WEIGHT_SNTX. MFG_MAX_CUT_DPTH (Max cut depth : ar)Type: RealDefines the maximum cut depth. The manufacturing attribute is MFG_MAX_CUT_DPTH. MFG_MAX_CUT_WDTH (Max cut width)Type: RealDefines the maximum cut width. The manufacturing attribute is MFG_MAX_CUT_WDTH.
MFG_GAUGING_ANG (Gouging angle)Type: RealDefines the gouging angle. The manufacturing attribute is MFG_GAUGING_ANG. MFG_MAX_CUT_DIAMType: RealDefines the maximum cut diameter. The manufacturing attribute is MFG_MAX_CUT_DIAM. MFG_MIN_CUT_DIAMType: RealDefines the minimum cut diameter. The manufacturing attribute is MFG_MIN_CUT_DIAM.
MfgGrooveInternalTool (Internal Groove Insert Holder)
Description
Describes the MfgGrooveInternalTool resource attributes that are available in Machining workbenches.
Base Attributes
These attributes provide general information.
MFG_NAME (Name)Type: StringSpecifies the name of the resource. MFG_COMMENT (Comment)Type: StringAssociates a comment to the resource.
Geometry Attributes
These attributes characterize the tool shape and have an impact on the tool path computation.
MFG_BODY_DIAM (Body diameter : db)Type: RealDefines the diameter of the external envelope of the non-active part of the tool. The manufacturing attribute is MFG_BODY_DIAM. MFG_HAND_STYLE (Hand style)Type: StringPossible values:RIGHT_HAND (Right hand)LEFT_HAND (Left hand)NEUTRALDefines the tool's hand style. The manufacturing attribute is MFG_HAND_STYLE with possible value RIGHT_HAND, LEFT_HAND or NEUTRAL. MFG_HAND_ANGLE (Hand angle)Type: RealDefines the hand angle. The manufacturing attribute is MFG_HAND_ANGLE. MFG_INSERT_WIDTH (Insert width : la)Type: RealDefines the insert width. The manufacturing attribute is MFG_INSERT_WIDTH.
MFG_CLEAR_ANGLE (Clearance angle)Type: RealDefines the clearance angle. The manufacturing attribute is MFG_CLEAR_ANGLE. MFG_BAR_LENGTH_1 (Bar length 1 : l1)Type: RealDefines the overall length of the tool. The manufacturing attribute is MFG_BAR_LENGTH_1. MFG_BAR_LENGTH_2 (Bar length 2 : l2)Type: RealDefines the length of the external envelope of the tool's active part. The manufacturing attribute is MFG_BAR_LENGTH_2. MFG_BAR_CUT_RAD (Bar cut radius : f)Type: RealDefines the cutting radius of the tool. The manufacturing attribute is MFG_BAR_CUT_RAD.
Technology Attributes
These attributes provide technological information without any impact on the tool path computation.
MFG_MAX_MIL_LENGTH (Max machining length)Type: RealSpecifies the tool life in length units. The manufacturing attribute is MFG_MAX_MIL_LENGTH. MFG_MAX_MIL_TIME (Max life time)Type: RealSpecifies the tool life in time units. The manufacturing attribute is MFG_MAX_MIL_TIME. MFG_COOLNT_SNTX (Coolant syntax)Type: StringSpecifies the coolant supply syntax. The manufacturing attribute is MFG_COOLNT_SNTX. MFG_WEIGHT_SNTX (Weight syntax)Type: StringSpecifies the tool weight syntax. The manufacturing attribute is MFG_WEIGHT_SNTX. MFG_MAX_CUT_DPTH (Max cut depth : ar)Type: RealDefines the maximum cut depth. The manufacturing attribute is MFG_MAX_CUT_DPTH. MFG_MAX_CUT_WDTH (Max cut width)Type: RealDefines the maximum cut width. The manufacturing attribute is MFG_MAX_CUT_WDTH. MFG_GAUGING_ANG (Gouging angle)Type: RealDefines the gouging angle. The manufacturing attribute is MFG_GAUGING_ANG. MFG_MIN_DIAM (Min diameter)Type: RealDefines the minimum diameter which can be cut. The manufacturing attribute is MFG_MIN_DIAM.
MfgThreadExternalTool (External Thread Insert Holder)
Description
Describes the MfgThreadExternalTool resource attributes that are available in Machining workbenches.
Base Attributes
These attributes provide general information.
MFG_NAME (Name)Type: StringSpecifies the name of the resource. MFG_COMMENT (Comment)Type: StringAssociates a comment to the resource.
Geometry Attributes
These attributes characterize the tool shape and have an impact on the tool path computation.
MFG_HAND_STYLE (Hand style)Type: StringPossible values:RIGHT_HAND (Right hand)LEFT_HAND (Left hand)NEUTRALDefines the tool's hand style. The manufacturing attribute is MFG_HAND_STYLE with possible value RIGHT_HAND, LEFT_HAND or NEUTRAL. MFG_INSERT_LGTH (Insert length : l)Type: RealDefines the cutting edge length of an insert. The manufacturing attribute is MFG_INSERT_LGTH. MFG_SHK_CUT_WDTH (Shank cut width : f)Type: RealDefines the cutting width of the tool. The manufacturing attribute is MFG_SHK_CUT_WDTH. MFG_SHANK_HEIGHT (Shank height : h)Type: RealDefines the height of the shank. The manufacturing attribute is MFG_SHANK_HEIGHT. MFG_SHK_LENGTH_1 (Shank length 1 : l1)Type: RealDefines the overall length of the tool. The manufacturing attribute is MFG_LENGTH_1. MFG_SHK_LENGTH_2 (Shank length 2 : l2)Type: RealDefines the length of the external envelope of the tool's active part. The manufacturing attribute is MFG_SHK_LENGTH_2. MFG_SHANK_WIDTH (Shank width : b)Type: RealDefines the width of the shank. The manufacturing attribute is MFG_SHANK_WIDTH.
Technology Attributes
These attributes provide technological information without any impact on the tool path computation.
MFG_MAX_MIL_LENGTH (Max machining length)Type: RealSpecifies the tool life in length units. The manufacturing attribute is MFG_MAX_MIL_LENGTH. MFG_MAX_MIL_TIME (Max life time)Type: RealSpecifies the tool life in time units. The manufacturing attribute is MFG_MAX_MIL_TIME.
MFG_COOLNT_SNTX (Coolant syntax)Type: StringSpecifies the coolant supply syntax. The manufacturing attribute is MFG_COOLNT_SNTX. MFG_WEIGHT_SNTX (Weight syntax)Type: StringSpecifies the tool weight syntax. The manufacturing attribute is MFG_WEIGHT_SNTX.
MfgThreadInternalTool (Internal Thread Insert Holder)
Description
Describes the MfgThreadInternalTool resource attributes that are available in Machining workbenches.
Base Attributes
These attributes provide general information.
MFG_NAME (Name)Type: StringSpecifies the name of the resource. MFG_COMMENT (Comment)Type: StringAssociates a comment to the resource.
Geometry Attributes
These attributes characterize the tool shape and have an impact on the tool path computation.
MFG_BODY_DIAM (Body diameter : db)Type: RealDefines the diameter of the external envelope of the non-active part of the tool. The manufacturing attribute is MFG_BODY_DIAM. MFG_HAND_STYLE (Hand style)Type: StringPossible values:RIGHT_HAND (Right hand)LEFT_HAND (Left hand)NEUTRALDefines the tool's hand style. The manufacturing attribute is MFG_HAND_STYLE with possible value RIGHT_HAND, LEFT_HAND or NEUTRAL. MFG_INSERT_LGTH (Insert length : l)Type: RealDefines the cutting edge length of an insert. The manufacturing attribute is MFG_INSERT_LGTH. MFG_BAR_LENGTH_1 (Bar length 1 : l1)Type: RealDefines the overall length of the tool. The manufacturing attribute is MFG_BAR_LENGTH_1. MFG_BAR_LENGTH_2 (Bar length 2 : l2)Type: RealDefines the length of the external envelope of the tool's active part. The manufacturing attribute is MFG_BAR_LENGTH_2.
MFG_BAR_CUT_RAD (Bar cut radius : f)Type: RealDefines the cutting radius of the tool. The manufacturing attribute is MFG_BAR_CUT_RAD.
Technology Attributes
These attributes provide technological information without any impact on the tool path computation.
MFG_MAX_MIL_LENGTH (Max machining length)Type: RealSpecifies the tool life in length units. The manufacturing attribute is MFG_MAX_MIL_LENGTH. MFG_MAX_MIL_TIME (Max life time)Type: RealSpecifies the tool life in time units. The manufacturing attribute is MFG_MAX_MIL_TIME. MFG_COOLNT_SNTX (Coolant syntax)Type: StringSpecifies the coolant supply syntax. The manufacturing attribute is MFG_COOLNT_SNTX. MFG_WEIGHT_SNTX (Weight syntax)Type: StringSpecifies the tool weight syntax. The manufacturing attribute is MFG_WEIGHT_SNTX. MFG_MIN_DIAM (Min diameter)Type: RealDefines the minimum diameter which can be cut. The manufacturing attribute is MFG_MIN_DIAM.
MfgBoringBarTool (Boring Bar)
Description
Describes the MfgBoringBarTool resource attributes that are available in Machining workbenches.
Base Attributes
These attributes provide general information.
MFG_NAME (Name)Type: StringSpecifies the name of the resource. MFG_COMMENT (Comment)Type: StringAssociates a comment to the resource. MFG_TOOL_NUMBER (Tool number)Type: IntegerDefines the tool number. The manufacturing attribute is MFG_TOOL_NUMBER.
Geometry Attributes
These attributes characterize the tool shape and have an impact on the tool path computation.
MFG_NOMINAL_DIAM (Nominal diameter : D)Type: RealDefines the cutting diameter of the tool. The manufacturing attribute is MFG_NOMINAL_DIAM. MFG_OVERALL_LGTH (Overall length : L)Type: RealDefines the total length of the tool. The manufacturing attribute is MFG_OVERALL_LGTH. MFG_CUT_LENGTH (Cutting length : Lc)Type: RealDefines the effective cutting length available on the tool's active part. The manufacturing attribute is MFG_CUT_LENGTH. MFG_LENGTH (Length : l)Type: RealDefines the length of the external envelope of the tool's active part. The manufacturing attribute is MFG_LENGTH. MFG_BODY_DIAM (Body diameter : db)Type: RealDefines the diameter of the external envelope of the non-active part of the tool. The manufacturing attribute is MFG_BODY_DIAM. MFG_CUT_ANGLE (Cutting angle : A)Type: RealDefines the cutting angle of the tool. The manufacturing attribute is MFG_CUT_ANGLE. MFG_TL_TIP_LGTH (Tool tip length : ld)Type: RealDefines the part of the tool that cannot be used for cutting material at the correct diameter (non-functional part of the tool). The manufacturing attribute is MFG_TL_TIP_LGTH. MFG_NON_CUT_DIAM (Non cut diameter : dn)Type: RealDefines the diameter of the non-cutting extremity of a boring bar. The manufacturing attribute is MFG_NON_CUT_DIAM. MFG_MIN_DIAMETER (Minimum diameter)Type: RealDefines the minimum diameter for an adjustable boring bar. The manufacturing attribute is MFG_MIN_DIAMETER. MFG_MAX_DIAMETER (Maximum diameter)Type: RealDefines the maximum diameter for an adjustable boring bar. The manufacturing attribute is MFG_MAX_DIAMETER. MFG_TIP_ANGLE (Tip angle : E)Type: RealDefines the tip angle of a boring bar. The manufacturing attribute is MFG_TIP_ANGLE. MFG_TIP_RADIUS (Tip radius : Re)Type: RealDefines tip radius of a boring bar. The manufacturing attribute is MFG_TIP_RADIUS. MFG_TIP_LENGTH (Tip length : lt)Type: RealDefines the position and the shape of the cutter on a boring bar. The manufacturing attribute is MFG_TIP_LENGTH. MFG_TOOL_ANGLE (Tool angle : B)Type: RealDefines the cutter orientation on a boring bar. The manufacturing attribute is MFG_TOOL_ANGLE.
Technology Attributes
These attributes provide technological information without any impact on the tool path computation.
MFG_WAY_OF_ROT (Way of rotation)Type: StringPossible values:RIGHT_HAND (Right hand)LEFT_HAND (Left hand)Defines the flutes orientation. It should be compatible with spindle rotation orientation. The manufacturing attribute is MFG_WAY_OF_ROT with possible value RIGHT_HAND or LEFT_HAND MFG_MACH_QUALITY (Machining quality)Type: StringPossible values:ROUGH (Rough)FINISH (Finish)EITHER (Either)Defines the tool's ability to machine in roughing or finishing mode. The manufacturing attribute is MFG_MACH_QUALITY with possible value ROUGH, FINISH or EITHER. MFG_COMPOSITION (Composition)Type: StringPossible values:ONE_PIECE (One piece)INSERT_HOLDER (Insert holder)Specifies if the tool is an inserted one. The manufacturing attribute is MFG_COMPOSITION with possible value ONE_PIECE or INSERT_HOLDER. MFG_TOOTH_MAT (Tooth material)Type: StringPossible values:HIGH_SPEED_STEEL (High speed steel)COATED_HIGH_SPEED_STEEL (Coated high speed steel)CARBIDE (Carbide)COATED_CARBIDE (Coated carbide)OTHER (Other)Defines the tooth material type. The manufacturing attribute is MFG_TOOTH_MAT with possible value: HIGH_SPEED_STEEL, COATED_HIGH_SPEED_STEEL, CARBIDE, COATED_CARBIDE, OTHER. MFG_TOOTH_DES (Tooth description)Type: StringAllows the user to specify the tooth nature as a comment. For example, it could be the supplier reference of the insert. The manufacturing attribute is MFG_TOOTH_DES. MFG_TOOTH_MATDES (Tooth material desc.)Type: StringAllows the user to specify the tooth material by means of a comment. For example, it could be the ISO designation for cutting materials or the reference of the coating material. The manufacturing attribute is MFG_TOOTH_MATDES.
MFG_BORE_ABILITY (Boring ability)Type: StringPossible values:THROUGHEITHERDetermines whether a boring bar can be used for through or blind holes according to its tip configuration. It can take the following values:
● THROUGH: implies cutting angle < 90 degrees and tool tip length > 0
● EITHER: implies cutting angle > 90 degrees and tool tip length = 0.
The manufacturing attribute is MFG_BORE_ABILITY. MFG_TL_RAKE_ANG (Tool rake angle )Type: RealDefines the tool rake angle. The manufacturing attribute is MFG_TL_RAKE_ANG. MFG_MAX_MIL_LENGTH (Max machining length)Type: RealSpecifies the tool life in length units. The manufacturing attribute is MFG_MAX_MIL_LENGTH. MFG_MAX_MIL_TIME (Max life time)Type: RealSpecifies the tool life in time units. The manufacturing attribute is MFG_MAX_MIL_TIME. MFG_COOLNT_SNTX (Coolant syntax)Type: StringSpecifies the coolant supply syntax. The manufacturing attribute is MFG_COOLNT_SNTX. MFG_WEIGHT_SNTX (Weight syntax)Type: StringSpecifies the tool weight syntax. The manufacturing attribute is MFG_WEIGHT_SNTX.
Cutting Conditions Attributes
These attributes are used for feeds and speeds computation on the operation.
MFG_VC (Cutting speed)Type: RealDefines the Cutting speed of the tool. The manufacturing attribute is MFG_VC. MFG_SZ (Feedrate)Type: RealDefines the Feedrate of the tool. The manufacturing attribute is MFG_SZ. MFG_PP (Depth of cut)Type: RealDefines the Depth of cut of the tool. The manufacturing attribute is MFG_PP.
Insert ResourcesAll supported Insert resources are presented in this section:
● Round Insert
● Diamond Insert
● Square Insert
● Triangular Insert
● Trigon Insert
● Groove Insert
● Thread Insert.
MfgRoundInsert (Round Insert)
Description
Describes the MfgRoundInsert resource attributes that are available in Machining workbenches.
Base Attributes
These attributes provide general information.
MFG_NAME (Name)Type: StringSpecifies the name of the resource. MFG_COMMENT (Comment)Type: StringAssociates a comment to the resource. MFG_DESC_CODE (Description code)Type: StringPossible values:ANSIISONoCodeDefines the Description code: ISO or ANSI. The manufacturing attribute is MFG_DESC_CODE.
Geometry Attributes
These attributes characterize the insert shape and have an impact on the tool path computation.
MFG_NOSE_RADIUS (Nose radius : r)Type: RealSpecifies the nose radius of the insert. The manufacturing attribute is MFG_NOSE_RADIUS.
MFG_INSERT_THICK (Thickness)Type: RealSpecifies the thickness of the insert. The manufacturing attribute is MFG_INSERT_THICK. MFG_CLEAR_ANGLE (Clearance angle)Type: RealDefines the clearance angle. The manufacturing attribute is MFG_CLEAR_ANGLE.
Technology Attributes
These attributes provide technological information without any impact on the tool path computation.
MFG_MACH_QUALITY (Machining quality)Type: StringPossible values:ROUGH (Rough)FINISH (Finish)EITHER (Either)Defines the tool's ability to machine in roughing or finishing mode. The manufacturing attribute is MFG_MACH_QUALITY with possible value ROUGH, FINISH or EITHER. MFG_INSERT_MAT (Material)Type: StringPossible values:COATED_CARBIDE (Coated carbide)CERMETS (Cermets)CERAMICS (Ceramics)CUBIDE_BORON_NITRIDE (Cubide Boron Nitride)OTHER (Other)Specifies the material of the insert. The manufacturing attribute is MFG_INSERT_MAT. MFG_LIFE_TIME (Life time)Type: RealSpecifies the life time of the insert. The manufacturing attribute is MFG_LIFE_TIME.
Cutting Conditions Attributes
These attributes are used for feeds and speeds computation on the operation.
MFG_VC_FINISH (Finishing cutting speed)Type: RealDefines the Finishing cutting speed of the tool. The manufacturing attribute is MFG_VC_FINISH. MFG_SZ_FINISH (Finishing feedrate per tooth)Type: RealDefines the Finishing feedrate per tooth of the tool. The manufacturing attribute is MFG_SZ_FINISH. MFG_VC_ROUGH (Roughing cutting speed)Type: RealDefines the Roughing cutting speed of the tool. The manufacturing attribute is MFG_VC_ROUGH. MFG_SZ_ROUGH (Roughing feedrate per tooth)Type: RealDefines the Roughing feedrate per tooth of the tool. The manufacturing attribute is MFG_SZ_ROUGH.
MfgGrooveInsert (Groove Insert)
Description
Describes the MfgGrooveInsert resource attributes that are available in Machining workbenches.
Base Attributes
These attributes provide general information.
MFG_NAME (Name)Type: StringSpecifies the name of the resource. MFG_COMMENT (Comment)Type: StringAssociates a comment to the resource. MFG_GROOVE_TYPE (Type)Type: StringPossible values:CUTOFF (Cut Off)GROOVE (Groove)Specifies the grooving capability of the insert. The manufacturing attribute is MFG_GROOVE_TYPE.
Geometry Attributes
These attributes characterize the insert shape and have an impact on the tool path computation.
MFG_INSERT_HEIGH (Height : l)Type: RealSpecifies the height of the insert. The manufacturing attribute is MFG_INSERT_HEIGH. MFG_INSERT_WIDTH (Insert width : la)Type: RealDefines the insert width. The manufacturing attribute is MFG_INSERT_WIDTH. MFG_BOTTOM_ANGLE (Bottom angle)Type: RealSpecifies the bottom angle of the insert. The manufacturing attribute is MFG_BOTTOM_ANGLE. MFG_FLANK_ANG_1 (Left flank angle)Type: RealSpecifies the left flank angle of the insert. The manufacturing attribute is MFG_FLANK_ANG_1. MFG_FLANK_ANG_2 (Right flank angle)Type: RealSpecifies the right flank angle of the insert. The manufacturing attribute is MFG_FLANK_ANG_2. MFG_NOSE_RAD_1 (Left nose radius : r1)Type: RealSpecifies the left nose radius of the insert. The manufacturing attribute is MFG_NOSE_RAD_1. MFG_NOSE_RAD_2 (Right nose radius : r2)Type: RealSpecifies the right nose radius of the insert. The manufacturing attribute is MFG_NOSE_RAD_2. MFG_INSERT_THICK (Thickness)Type: RealSpecifies the thickness of the insert. The manufacturing attribute is MFG_INSERT_THICK. MFG_CLEAR_ANGLE (Clearance angle)Type: RealDefines the clearance angle. The manufacturing attribute is MFG_CLEAR_ANGLE.
Technology Attributes
These attributes provide technological information without any impact on the tool path computation.
MFG_MACH_QUALITY (Machining quality)Type: StringPossible values:ROUGH (Rough)FINISH (Finish)EITHER (Either)Defines the tool's ability to machine in roughing or finishing mode. The manufacturing attribute is MFG_MACH_QUALITY with possible value ROUGH, FINISH or EITHER. MFG_INSERT_MAT (Material)Type: StringPossible values:COATED_CARBIDE (Coated carbide)CERMETS (Cermets)CERAMICS (Ceramics)CUBIDE_BORON_NITRIDE (Cubide Boron Nitride)OTHER (Other)Specifies the material of the insert. The manufacturing attribute is MFG_INSERT_MAT. MFG_CUT_LENGTH (Cutting length : Lc)Type: RealDefines the effective cutting length available on the tool's active part. The manufacturing attribute is MFG_CUT_LENGTH.
Cutting Conditions Attributes
These attributes are used for feeds and speeds computation on the operation.
MFG_VC_FINISH (Finishing cutting speed)Type: RealDefines the Finishing cutting speed of the tool. The manufacturing attribute is MFG_VC_FINISH. MFG_SZ_FINISH (Finishing feedrate per tooth)Type: RealDefines the Finishing feedrate per tooth of the tool. The manufacturing attribute is MFG_SZ_FINISH. MFG_VC_ROUGH (Roughing cutting speed)Type: RealDefines the Roughing cutting speed of the tool. The manufacturing attribute is MFG_VC_ROUGH. MFG_SZ_ROUGH (Roughing feedrate per tooth)Type: RealDefines the Roughing feedrate per tooth of the tool. The manufacturing attribute is MFG_SZ_ROUGH.
MfgThreadInsert (Thread Insert)
Description
Describes the MfgThreadInsert resource attributes that are available in Machining workbenches.
Base Attributes
These attributes provide general information.
MFG_NAME (Name)Type: StringSpecifies the name of the resource. MFG_COMMENT (Comment)Type: StringAssociates a comment to the resource. MFG_MACH_TYPE (Machining type)Type: StringPossible values:MfgExternalMfgInternalSpecifies internal or external machining type. The manufacturing attribute is MFG_MACH_TYPE.
Geometry Attributes
These attributes characterize the insert shape and have an impact on the tool path computation.
MFG_THREAD_PROF (Thread profile)Type: StringPossible values:MfgTrapezoidalMfgISOMfgUNCMfgGazOTHER (Other)Specifies the thread profile of the insert. The manufacturing attribute is MFG_THREAD_PROF. MFG_THREAD_DEF (Thread definition)Type: StringPossible values:MfgPitchMfgThreadPerInchSpecifies the thread definition of the insert. The manufacturing attribute is MFG_THREAD_DEF. MFG_PITCH_OF_THREAD (Pitch of thread)Type: RealDescribes the thread pitch. The manufacturing attribute is MFG_PITCH_OF_THREAD. MFG_PITCH_NUMBER (Pitch)Type: RealSpecifies the pitch number of the insert. The manufacturing attribute is MFG_PITCH_NUMBER. MFG_INSERT_LGTH (Insert length : l)Type: RealDefines the cutting edge length of an insert. The manufacturing attribute is MFG_INSERT_LGTH. MFG_THREAD_ANGLE (Thread angle)Type: RealSpecifies the thread angle of the insert. The manufacturing attribute is MFG_THREAD_ANGLE.
MFG_HAND_STYLE (Hand style)Type: StringPossible values:RIGHT_HAND (Right hand)LEFT_HAND (Left hand)NEUTRALDefines the tool's hand style. The manufacturing attribute is MFG_HAND_STYLE with possible value RIGHT_HAND, LEFT_HAND or NEUTRAL. MFG_TOOTH_X (Tooth X)Type: RealSpecifies the X position of end of the insert tooth. The manufacturing attribute is MFG_TOOTH_X. MFG_TOOTH_Z (Tooth Z)Type: RealSpecifies the Z position of end of the insert tooth. The manufacturing attribute is MFG_TOOTH_Z. MFG_TOOTH_H (Tooth Y)Type: RealSpecifies the height of the insert tooth. The manufacturing attribute is MFG_TOOTH_H. MFG_NOSE_RADIUS (Nose radius : r)Type: RealSpecifies the nose radius of the insert. The manufacturing attribute is MFG_NOSE_RADIUS. MFG_INSERT_THICK (Thickness)Type: RealSpecifies the thickness of the insert. The manufacturing attribute is MFG_INSERT_THICK.
Technology Attributes
These attributes provide technological information without any impact on the tool path computation.
MFG_MACH_QUALITY (Machining quality)Type: StringPossible values:ROUGH (Rough)FINISH (Finish)EITHER (Either)Defines the tool's ability to machine in roughing or finishing mode. The manufacturing attribute is MFG_MACH_QUALITY with possible value ROUGH, FINISH or EITHER. MFG_INSERT_MAT (Material)Type: StringPossible values:COATED_CARBIDE (Coated carbide)CERMETS (Cermets)CERAMICS (Ceramics)CUBIDE_BORON_NITRIDE (Cubide Boron Nitride)OTHER (Other)Specifies the material of the insert. The manufacturing attribute is MFG_INSERT_MAT. MFG_LIFE_TIME (Life time)Type: RealSpecifies the life time of the insert. The manufacturing attribute is MFG_LIFE_TIME.
Cutting Conditions Attributes
These attributes are used for feeds and speeds computation on the operation.
MFG_VC_FINISH (Finishing cutting speed)Type: RealDefines the Finishing cutting speed of the tool. The manufacturing attribute is MFG_VC_FINISH. MFG_SZ_FINISH (Finishing feedrate per tooth)Type: RealDefines the Finishing feedrate per tooth of the tool. The manufacturing attribute is MFG_SZ_FINISH. MFG_VC_ROUGH (Roughing cutting speed)Type: RealDefines the Roughing cutting speed of the tool. The manufacturing attribute is MFG_VC_ROUGH. MFG_SZ_ROUGH (Roughing feedrate per tooth)Type: RealDefines the Roughing feedrate per tooth of the tool. The manufacturing attribute is MFG_SZ_ROUGH.
MfgDiamondInsert (Diamond Insert)
Description
Describes the MfgDiamondInsert resource attributes that are available in Machining workbenches.
Base Attributes
These attributes provide general information.
MFG_NAME (Name)Type: StringSpecifies the name of the resource. MFG_COMMENT (Comment)Type: StringAssociates a comment to the resource. MFG_DESC_CODE (Description code)Type: StringPossible values:ANSIISONoCodeDefines the Description code: ISO or ANSI. The manufacturing attribute is MFG_DESC_CODE.
Geometry Attributes
These attributes characterize the insert shape and have an impact on the tool path computation.
MFG_NOSE_RADIUS (Nose radius : r)Type: RealSpecifies the nose radius of the insert. The manufacturing attribute is MFG_NOSE_RADIUS. MFG_INSERT_ANGLE (Insert angle : a)Type: RealDefines the angle of the insert mounted on the tool. The manufacturing attribute is MFG_INSERT_ANGLE. MFG_INSERT_LGTH (Insert length : l)Type: RealDefines the cutting edge length of an insert. The manufacturing attribute is MFG_INSERT_LGTH.
MFG_INSCRIB_DIAM (Inscribed diameter : iC)Type: RealSpecifies the diameter of the inscribed circle of the insert. The manufacturing attribute is MFG_INSCRIB_DIAM. MFG_INSERT_THICK (Thickness)Type: RealSpecifies the thickness of the insert. The manufacturing attribute is MFG_INSERT_THICK. MFG_CLEAR_ANGLE (Clearance angle)Type: RealDefines the clearance angle. The manufacturing attribute is MFG_CLEAR_ANGLE.
Technology Attributes
These attributes provide technological information without any impact on the tool path computation.
MFG_MACH_QUALITY (Machining quality)Type: StringPossible values:ROUGH (Rough)FINISH (Finish)EITHER (Either)Defines the tool's ability to machine in roughing or finishing mode. The manufacturing attribute is MFG_MACH_QUALITY with possible value ROUGH, FINISH or EITHER. MFG_INSERT_MAT (Material)Type: StringPossible values:COATED_CARBIDE (Coated carbide)CERMETS (Cermets)CERAMICS (Ceramics)CUBIDE_BORON_NITRIDE (Cubide Boron Nitride)OTHER (Other)Specifies the material of the insert. The manufacturing attribute is MFG_INSERT_MAT. MFG_LIFE_TIME (Life time)Type: RealSpecifies the life time of the insert. The manufacturing attribute is MFG_LIFE_TIME.
Cutting Conditions Attributes
These attributes are used for feeds and speeds computation on the operation.
MFG_VC_FINISH (Finishing cutting speed)Type: RealDefines the Finishing cutting speed of the tool. The manufacturing attribute is MFG_VC_FINISH. MFG_SZ_FINISH (Finishing feedrate per tooth)Type: RealDefines the Finishing feedrate per tooth of the tool. The manufacturing attribute is MFG_SZ_FINISH. MFG_VC_ROUGH (Roughing cutting speed)Type: RealDefines the Roughing cutting speed of the tool. The manufacturing attribute is MFG_VC_ROUGH. MFG_SZ_ROUGH (Roughing feedrate per tooth)Type: RealDefines the Roughing feedrate per tooth of the tool. The manufacturing attribute is MFG_SZ_ROUGH.
MfgSquareInsert (Square Insert)
Description
Describes the MfgSquareInsert resource attributes that are available in Machining workbenches.
Base Attributes
These attributes provide general information.
MFG_NAME (Name)Type: StringSpecifies the name of the resource. MFG_COMMENT (Comment)Type: StringAssociates a comment to the resource. MFG_DESC_CODE (Description code)Type: StringPossible values:ANSIISONoCodeDefines the Description code: ISO or ANSI. The manufacturing attribute is MFG_DESC_CODE.
Geometry Attributes
These attributes characterize the insert shape and have an impact on the tool path computation.
MFG_NOSE_RADIUS (Nose radius : r)Type: RealSpecifies the nose radius of the insert. The manufacturing attribute is MFG_NOSE_RADIUS. MFG_INSERT_LGTH (Insert length : l)Type: RealDefines the cutting edge length of an insert. The manufacturing attribute is MFG_INSERT_LGTH. MFG_INSCRIB_DIAM (Inscribed diameter : iC)Type: RealSpecifies the diameter of the inscribed circle of the insert. The manufacturing attribute is MFG_INSCRIB_DIAM. MFG_INSERT_THICK (Thickness)Type: RealSpecifies the thickness of the insert. The manufacturing attribute is MFG_INSERT_THICK. MFG_CLEAR_ANGLE (Clearance angle)Type: RealDefines the clearance angle. The manufacturing attribute is MFG_CLEAR_ANGLE.
Technology Attributes
These attributes provide technological information without any impact on the tool path computation.
MFG_MACH_QUALITY (Machining quality)Type: StringPossible values:ROUGH (Rough)FINISH (Finish)EITHER (Either)Defines the tool's ability to machine in roughing or finishing mode. The manufacturing attribute is MFG_MACH_QUALITY with possible value ROUGH, FINISH or EITHER. MFG_INSERT_MAT (Material)Type: StringPossible values:COATED_CARBIDE (Coated carbide)CERMETS (Cermets)CERAMICS (Ceramics)CUBIDE_BORON_NITRIDE (Cubide Boron Nitride)OTHER (Other)Specifies the material of the insert. The manufacturing attribute is MFG_INSERT_MAT. MFG_LIFE_TIME (Life time)Type: RealSpecifies the life time of the insert. The manufacturing attribute is MFG_LIFE_TIME.
Cutting Conditions Attributes
These attributes are used for feeds and speeds computation on the operation.
MFG_VC_FINISH (Finishing cutting speed)Type: RealDefines the Finishing cutting speed of the tool. The manufacturing attribute is MFG_VC_FINISH. MFG_SZ_FINISH (Finishing feedrate per tooth)Type: RealDefines the Finishing feedrate per tooth of the tool. The manufacturing attribute is MFG_SZ_FINISH. MFG_VC_ROUGH (Roughing cutting speed)Type: RealDefines the Roughing cutting speed of the tool. The manufacturing attribute is MFG_VC_ROUGH. MFG_SZ_ROUGH (Roughing feedrate per tooth)Type: RealDefines the Roughing feedrate per tooth of the tool. The manufacturing attribute is MFG_SZ_ROUGH.
MfgTriangularInsert (Triangular Insert)
Description
Describes the MfgTriangularInsert resource attributes that are available in Machining workbenches.
Base Attributes
These attributes provide general information.
MFG_NAME (Name)Type: StringSpecifies the name of the resource.
MFG_COMMENT (Comment)Type: StringAssociates a comment to the resource. MFG_DESC_CODE (Description code)Type: StringPossible values:ANSIISONoCodeDefines the Description code: ISO or ANSI. The manufacturing attribute is MFG_DESC_CODE.
Geometry Attributes
These attributes characterize the insert shape and have an impact on the tool path computation.
MFG_NOSE_RADIUS (Nose radius : r)Type: RealSpecifies the nose radius of the insert. The manufacturing attribute is MFG_NOSE_RADIUS. MFG_INSERT_LGTH (Insert length : l)Type: RealDefines the cutting edge length of an insert. The manufacturing attribute is MFG_INSERT_LGTH. MFG_INSCRIB_DIAM (Inscribed diameter : iC)Type: RealSpecifies the diameter of the inscribed circle of the insert. The manufacturing attribute is MFG_INSCRIB_DIAM. MFG_INSERT_THICK (Thickness)Type: RealSpecifies the thickness of the insert. The manufacturing attribute is MFG_INSERT_THICK. MFG_CLEAR_ANGLE (Clearance angle)Type: RealDefines the clearance angle. The manufacturing attribute is MFG_CLEAR_ANGLE.
Technology Attributes
These attributes provide technological information without any impact on the tool path computation.
MFG_MACH_QUALITY (Machining quality)Type: StringPossible values:ROUGH (Rough)FINISH (Finish)EITHER (Either)Defines the tool's ability to machine in roughing or finishing mode. The manufacturing attribute is MFG_MACH_QUALITY with possible value ROUGH, FINISH or EITHER. MFG_INSERT_MAT (Material)Type: StringPossible values:COATED_CARBIDE (Coated carbide)CERMETS (Cermets)CERAMICS (Ceramics)CUBIDE_BORON_NITRIDE (Cubide Boron Nitride)OTHER (Other)Specifies the material of the insert. The manufacturing attribute is MFG_INSERT_MAT.
MFG_LIFE_TIME (Life time)Type: RealSpecifies the life time of the insert. The manufacturing attribute is MFG_LIFE_TIME.
Cutting Conditions Attributes
These attributes are used for feeds and speeds computation on the operation.
MFG_VC_FINISH (Finishing cutting speed)Type: RealDefines the Finishing cutting speed of the tool. The manufacturing attribute is MFG_VC_FINISH. MFG_SZ_FINISH (Finishing feedrate per tooth)Type: RealDefines the Finishing feedrate per tooth of the tool. The manufacturing attribute is MFG_SZ_FINISH. MFG_VC_ROUGH (Roughing cutting speed)Type: RealDefines the Roughing cutting speed of the tool. The manufacturing attribute is MFG_VC_ROUGH. MFG_SZ_ROUGH (Roughing feedrate per tooth)Type: RealDefines the Roughing feedrate per tooth of the tool. The manufacturing attribute is MFG_SZ_ROUGH.
MfgTrigonInsert (Trigon Insert)
Description
Describes the MfgTrigonInsert resource attributes that are available in Machining workbenches.
Base Attributes
These attributes provide general information.
MFG_NAME (Name)Type: StringSpecifies the name of the resource. MFG_COMMENT (Comment)Type: StringAssociates a comment to the resource. MFG_DESC_CODE (Description code)Type: StringPossible values:ANSIISONoCodeDefines the Description code: ISO or ANSI. The manufacturing attribute is MFG_DESC_CODE.
Geometry Attributes
These attributes characterize the insert shape and have an impact on the tool path computation.
MFG_NOSE_RADIUS (Nose radius : r)Type: RealSpecifies the nose radius of the insert. The manufacturing attribute is MFG_NOSE_RADIUS. MFG_INSERT_LGTH (Insert length : l)Type: RealDefines the cutting edge length of an insert. The manufacturing attribute is MFG_INSERT_LGTH. MFG_INSCRIB_DIAM (Inscribed diameter : iC)Type: RealSpecifies the diameter of the inscribed circle of the insert. The manufacturing attribute is MFG_INSCRIB_DIAM. MFG_INSERT_THICK (Thickness)Type: RealSpecifies the thickness of the insert. The manufacturing attribute is MFG_INSERT_THICK. MFG_CLEAR_ANGLE (Clearance angle)Type: RealDefines the clearance angle. The manufacturing attribute is MFG_CLEAR_ANGLE.
Technology Attributes
These attributes provide technological information without any impact on the tool path computation.
MFG_MACH_QUALITY (Machining quality)Type: StringPossible values:ROUGH (Rough)FINISH (Finish)EITHER (Either)Defines the tool's ability to machine in roughing or finishing mode. The manufacturing attribute is MFG_MACH_QUALITY with possible value ROUGH, FINISH or EITHER. MFG_INSERT_MAT (Material)Type: StringPossible values:COATED_CARBIDE (Coated carbide)CERMETS (Cermets)CERAMICS (Ceramics)CUBIDE_BORON_NITRIDE (Cubide Boron Nitride)OTHER (Other)Specifies the material of the insert. The manufacturing attribute is MFG_INSERT_MAT. MFG_LIFE_TIME (Life time)Type: RealSpecifies the life time of the insert. The manufacturing attribute is MFG_LIFE_TIME.
Cutting Conditions Attributes
These attributes are used for feeds and speeds computation on the operation.
MFG_VC_FINISH (Finishing cutting speed)Type: RealDefines the Finishing cutting speed of the tool. The manufacturing attribute is MFG_VC_FINISH. MFG_SZ_FINISH (Finishing feedrate per tooth)Type: RealDefines the Finishing feedrate per tooth of the tool. The manufacturing attribute is MFG_SZ_FINISH.
MFG_VC_ROUGH (Roughing cutting speed)Type: RealDefines the Roughing cutting speed of the tool. The manufacturing attribute is MFG_VC_ROUGH. MFG_SZ_ROUGH (Roughing feedrate per tooth)Type: RealDefines the Roughing feedrate per tooth of the tool. The manufacturing attribute is MFG_SZ_ROUGH.
NC Macros
NC Macros in Machining Operations
You can define transition paths in your machining operations by means of NC Macros. These transition paths are useful for providing approach, retract and linking motion in the tool path.
You build the macros using the interface provided under the Macros tab page in the Machining Operation Definition dialog box.
Predefined Macros
You can use predefined macros. These are made up from one or more paths in a specific order. Just select the desired mode in the Current Macro Toolbox of the Macros page. You can then adjust parameters of the macro (such as path length and feedrate).
User-Built Macros
You can also build your own macros using the Build by user mode.
Depending on the context, you can use the following icons to specify macro paths:
tangent motion
normal motion
axial motion
circular motion
ramping motion
PP word
motion perpendicular to a plane
axial motion to a plane
motion perpendicular to a line
distance along a given direction
tool axis motion
motion to a point.
Successive PP Words
If the current macro ends with a PP word, PP word becomes inactive and so you cannot add another successive PP word. For example in the following sequence of macro paths ending with PPword.2:
...-TangentMotion-PPWord.1-CircularMotion-PPWord.2
you cannot add another PP word directly after PPword.2.However, you can edit and complete PPWord.2.
Elementary Motions After an Axial Path
If the current macro ends with an axial path (Axial, Axial to a plane, Axial perpendicular to a plane), the following icons become inactive:
Tangent motion, Circular motion, Normal motion, Ramping motion.This is because there is insufficient information about conditions such as tangency or normal to the axial path.Note that this behavior is not applied to 3-axis surface machining operations (the icons remain active).
Defining Motion Perpendicular to a Line
This type of motion is available for most prismatic and axial machining operations.
Select Motion perpendicular to a line .
The motion is symbolized in the Current Macro Tool box by a linear path going to a Line symbol.
Select the Line symbol to display the following dialog box.
Select the desired method to specify the line orientation using the combo:
● Manual. In this case, choose one of the following: ❍ Components to define the orientation by means of I, J and K components
❍ Angles to define the orientation by means of a rotation specified by means of one or two angles:Angle 1 about X, Angle 2 about YAngle 1 about Z, Angle 2 about XAngle 1 about Y, Angle 2 about Z
● Selection. In this case just select a line or linear edge to define the orientation.
Just click OK to accept the specified orientation.
Example:Motion starts and ends at the same linear location for each machining level.
Approach Macro
An Approach macro is used to approach the operation start point. It is available for all machining operation types.
Retract Macro
A Retract macro is used to retract from the operation end point. It is available for all machining operation types.
Linking Macro
A Linking macro may be used in several cases, for example:
● to avoid islands in Pocketing operations
● to link two non consecutive paths
● to access finish and spring passes in Pocketing and Contouring operations
● to link points of a pattern in an axial machining operation.
You could specify a Linking macro to do the following:
1. Retract along the tool axis at machining or finishing feedrate up to a safety plane defined by the top plane plus an approach clearance.
2. Approach next path along the tool axis with approach feedrate.3. The clearance motion between the retract and approach is along a line in the safety plane at rapid
feedrate.
Return on Same Level Macro
A Return on Same Level macro is used in a multi-path operation to link two consecutive paths in a given level.
For example, you could define a Return on Same Level macro on a Profile Contouring operation in One Way mode to do the following :
1. Retract along the tool axis at machining feedrate up to a safety plane defined by the top plane plus an approach clearance.
2. Approach next path along the tool axis with approach feedrate.3. The clearance motion between the retract and approach is along a line in the safety plane at rapid
feedrate.
Note that no Return on Same Level macro is needed on a Profile Contouring operation in Zig Zag mode. The motion between two paths is done at machining feedrate by following the profile of the boundary.
Return between Levels Macro
A Return between Levels macro is used in a multi-level machining operation to go to the next level.
You could define a Return between Levels macro to do the following:
1. Retract along the tool axis at machining feedrate up to a safety plane defined by the top plane plus an approach clearance.
2. Approach the next level along the tool axis at approach feedrate.3. The clearance motion between the retract and approach is along a line in the safety plane at rapid
feedrate.
Return to Finish Pass Macro
A Return to Finish Pass macro is used in a machining operation to go to the finish pass.
For example, you could define a Return to Finish Pass macro to do the following:
1. Retract along the tool axis at machining feedrate up to a safety plane defined by the top plane plus an approach clearance.
2. Approach the finish pass level along the tool axis at approach feedrate.3. The clearance motion between the retract and approach is along a line in the safety plane at rapid
feedrate.
Clearance Macro
A Clearance macro can be used in a machining operation to avoid a fixture, for example.
You could define a Clearance macro to do the following:
1. Retract along the tool axis at machining feedrate up to a safety plane.2. Approach the finish pass level along the tool axis at approach feedrate.3. The clearance motion between the retract and approach is along a line in the safety plane at rapid
feedrate.
Angular Orientation Conventions in NC Macros
These conventions concern both Circular and Tangent motions.
For Circular motions , position of the circle is defined by the Angular orientation parameter.
For Tangent motion , direction of the motion is defined by the Horizontal angle parameter.
The following types of operation are concerned.
Operations without consistent material side definition
This concerns the following operations:Isoparametric machiningMulti Axis SweepingMulti Axis Contour Driven.
For these operations, convention is simple:For Circular motion:Angular Orientation = 0.0 deg => Circle on the right sideAngular Orientation = 90 deg => Vertical CircleAngular Orientation = 180 deg => Circle on the left sideFor Tangent motion:Horizontal Angle = -90 deg => Motion on the left side.Horizontal Angle = 0.0 deg => Motion along TangentHorizontal Angle = 90 deg => Motion on the right side
Operations with material side defined by the flank
This concerns the following operations:Profile ContouringPocketingMulti Axis Flank ContouringMulti Axis Curve Machining in Side or Tip mode (between two curves or between curve and surface).
For Circular motion:Angular Orientation = 0.0 deg => Circle on the free side of the flankAngular Orientation = 90 deg => Vertical CircleAngular Orientation = 180 deg => Circle on side to the flankFor Tangent motion:Horizontal Angle = -90 deg => Motion on the free side of the flank.Horizontal Angle = 0.0 deg => Motion along TangentHorizontal Angle = 90 deg => Motion on side to the flank
Operations with material side defined by the bottom
This concerns the following operations:Isoparametric MachiningMulti Axis SweepingMulti Axis Contour DrivenMulti Axis Curve Machining in Contact mode.
For Circular motion:Angular Orientation = 0.0 deg => Circle on the free side of the bottomAngular Orientation = 90 deg => Vertical CircleAngular Orientation = 180 deg => Circle on side to the bottomFor Tangent motion:Horizontal Angle = -90 deg => Motion on the free side of the bottom.Horizontal Angle = 0.0 deg => Motion along TangentHorizontal Angle = 90 deg => Motion on side to the bottom.
Transition Path ManagementThis document describes the Transition Path Management capability. Transition paths can be generated between operations in a program. This is done by taking the following parameters into account:
● the machine's kinematic characteristics
● specified transition planes
● selected transition path options.
A transition path can include one or more linear transitions and machine rotations.
Transition paths can be created, deleted and updated using the commands of the Transition Path Management toolbar.
Generate Transition Paths
Remove Transition Paths
Update Transition Paths.
Machine
In order to use Transition Path Management, a generic machine must be defined on the Part Operation. This is done using the Part Operation's Machine Editor.
Available machine types are:
● 3-axis machine with no rotary axis
● 3-axis machine with 1 rotary axis on table
● 3-axis machine with 2 rotary axes on table
● 3-axis machine with 1 rotary axis on table and 1 rotary axis on head
● 3-axis machine with 1 rotary axis on head
● 3-axis machine with 2 rotary axes on head
● 5-axis continuous machine (without generation of machine rotations).
Each machine contains all the necessary NC parameters and kinematic definition data for the Part Operation.
Transition Planes
Transition Path Management takes into account the following planes defined in the Part Operation:
● Traverse box planes to create linear tool path motions (5 planes representing a box are needed)
● Transition planes to create linear tool path motions
● Rotary planes to create machine rotations:❍ between machining operations
❍ between tool change and machining operation.
The Safety plane is not taken into account for the generation of transition paths.
Transition Path Options
When Generate Transition Paths is selected, the Transition Paths dialog box appears. You must select the manufacturing
program to be processed and set the desired options.
Transition Path Creation: specifies where transition paths are to be added in the program:
● To Machining Operation: transition paths are generated before each machining operation. If there is a machining axis before a machining operation, the transition path is added before the machining axis.
● To Tool Change: transition paths are added before each tool change.
Machine Rotation Creation: allows creation of Rotary motion embedded in the transition path with:
● generation of machine rotation instructions in the output file (for example, ROTABL and ROTHED)
● automatic checking of machine reachability for rotary motion.
Priority Order: specifies the preferred order between Tool Change and Machine Rotation when they are both present before a machining operation.
● Priority to Tool change: the Machine Rotation is embedded in the Transition Path that is after the Tool change.
● Priority to Machine Rotation: the Machine Rotation is embedded in the Transition Path that is before the Tool change.
Retract/Approach Motion: specifies how retract and approach motions are to be done globally for all the transition paths of all selected programs:
● Perpendicular to transition (or traverse) plane
● Along tool axis.
If a specific retract or approach is required on a machining operation, it should be defined by macros on the operation.
Traverse Motion on Top: this option is taken into account only when all 5 traverse planes are defined in the Part Operation. It is useful when a transition path needs to go from one side to the opposite side of the traverse box. The intermediate plane can be any one of the three other planes. If the checkbox is selected, then the top plane is used as the intermediate plane. Otherwise, the motion will be done using the intermediate plane that gives the shortest path.
Compute axial-radial motion: if a traverse box is not defined and no transition plane is selected, selecting this checkbox authorizes 2.5 axis motion only. Tool axis direction at start and end of motion must be the same.
Return to machine home position: Generates an additional Transition Path after the last Machining Operation in order to return to the machine home position.
Transition Path Computation Overview
The general operation of Transition Path generation is outlined below. It assumes that an appropriate generic machine has been specified in the Part Operation.
Transition Paths with Table Rotation
If Table Rotation option is selected, and if a table rotation is needed, the tool retracts to the specified rotary plane and makes the table rotation. A head rotation is also done if necessary.
If Compute axial-radial motion is selected, the tool approaches the next point in 2.5 axis motion. Otherwise, the tool approaches the next point in linear motion.For a transition path with table motion, the tool approaches the next point in 2.5 axis motion after the table rotation.
Transition Paths without Table Rotation
If Table Rotation option is not selected, or if a table rotation is not needed, the Transition Path capability checks whether or not a valid traverse box is defined.
Traverse Box Defined
If a valid traverse box is defined, the traverse box motion is computed. This motion may be modified according whenever valid transition planes are specified. A head rotation are also done if necessary.
Traverse Box Not Defined
If no valid traverse box is defined, the Transition Path capability verifies whether or not valid transition planes are defined.
If valid transition planes are defined, the tool retracts to these planes.
If no valid transition planes are defined, the Transition Path capability verifies whether or not the Axial Radial option is selected.If Compute axial-radial motion is selected, the tool approaches the next point in 2.5 axis motion. Otherwise, the tool approaches the next point in linear motion.
Generation of Transition Paths without Machine Rotations
This is the case when a generic 5-axis machine is selected in the Part Operation.
Transitions Between Operations
The 5 traverse box planes defined on the Part operation delimit a traverse box.First, the transition path is computed by taken into account this traverse box.
Retract and Approach motions are automatically defined.The transitions motions are done in RAPID mode.
The Retract/Approach option can be set to define the motions type:
● Perpendicular to transition plane (the tool axis of the machining operation is kept)
● Along operation tool axis, until the transition plane.
Transition motions are done as follows:
1.Perpendicular retract (1) to the plane (with the same tool axis of the operation) or retract along the tool axis 2.Transition motion (2) through the plane (P1) until the intersection of planes (P1 and P2) 3.Tool axis modification4.Transition motion (3) through the plane (P2) until the perpendicular (or along the tool axis) of the next operation5.Approach motion (4) to the next operation (tool axis of the operation)
Note that during transition motions the tool tip is on the traverse planes.
Then transition planes are used to modify these transition motions by reducing air cuts.
Transitions Between Tool Change and Operation
First, transition motions are done as follows (respecting the traverse box):
1. Perpendicular retract (1) to the plane (with the same tool axis than the operation) or retract along the tool axis2. Transition motion (2) through the plane (P1) until the intersection of planes (P1 and P2) 3. Tool axis modification: Normal to the next plane (P2).4. Transition motion (3) through the plane (P2) until the perpendicular of the tool change5. Approach motion (4) to the tool change
Then transition planes are used to modify these transition motions by reducing air cuts.
Generation of Transition Paths with Machine Rotations
Transitions Between Operations
The transition path is done between the last point of the machining operation (last point of the retract macro) and the first point of the next machining operation (first point of the approach macro).
No control or cut of machining operation motions (including macro motions) is done outside the traverse box. The macro should be defined inside the traverse box. The transition paths are then generated up to the traverse box planes.
Transitions with Generation of Machine Table Rotation
The rotary plane is taken into account in order to define a safety distance.The rotary plane must be parallel to the machine rotary axis. Thus, if the machine as several rotary axis, several planes must be selected.
There are several cases:
● None of the selected Rotary planes are parallel to the machine rotary axis: the furthest point between the rotary axis and the last point of the previous operation or the first point of the next operation defines the radius of the rotation.
● Some of the selected Rotary planes are parallel to the machine rotary axis: the plane that defines the maximum distance with the rotary axis is taken into account.
● The last point of the previous operation or the first point of the next operation is further from the machine rotation axis than all rotary planes: the rotary planes are not taken into account.
Transitions with Generation of Machine Head Rotation
In the previous example, if machine head rotation generation is chosen, the transition path is computed the same way as for a 5 axis machine without generation of machine rotations. The tool tip path follows traverse box planes and transition planes. The difference is that for each modification of the tool axis, a machine head rotation is generated as well as tool motions take back the tool tip on the planes.
Example1:
The tool axes are different and the traverse planes are different: the head rotation is performed at the traverse plane intersection with the following behavior.
Example 2:
The tool axes are different, the traverse plane is the same: the head rotation is performed as follows.
Example 3:
The machining operations are defined at opposite sides of the traverse box.
The transition motions are generated in 3 planes: then head rotations are done at the intersection of planes.
In this case, in the intermediate plane, the tool axis is defined as being perpendicular to the plane during transition motion in this plane.
Transitions when Traverse Plane and Transition Planes are Defined
The transition planes are used to modify the transition motions respecting the traverse box plane by reducing air cuts.
Example:
A machining operation is defined at the bottom of the part.Motion mode is set to Along operation tool axis.A transition plane defines the bottom limit of the box.
Transition Motions between Tool Change and Operation
The behavior is the same as that described in Transition Between Operations.
Rotation Generation
The tool path is a circular arc for table rotation and head rotation.Transition path needs to be computed before the computation of the machine rotation tool path in order to have the start position (position 2 in the figure below).
PP Tables and PP Word Syntaxes
PP Word Tables
You can create and manage Post-Processor word tables with NC Manufacturing products.
Sample PP word tables are delivered with the product in the ..\startup\manufacturing\PPTables folder. Each PP word table is stored in a unique text file with suffix pptable. These tables can be used as a basis for creating user-defined tables.
A PP word table can be defined for a specific machine tool and used in NC applications. You can also define the general syntaxes of post-processor words. These syntaxes will be proposed when you want to create a PP instruction.
A PP word table comprises:
● major words without parameters
● major words with a text
● major words with parameters
● minor words
● word syntaxes.
You can define for a given machine tool:
● syntaxes associated to particular NC commands
● sequences of PP word syntaxes associated to particular NC instructions.
The NC Manufacturing product will resolve the parameters of these syntaxes and syntax sequences and generate the corresponding statements in the APT output.
NC Commands
You can define for a given machine tool (i.e. post-processor) PP word syntaxes associated to particular NC commands.
An NC command is a machine function such as feedrate declaration (NC_FEEDRATE) or spindle activation (NC_SPINDLE_START).
A syntax comprises a major word and one or more syntax elements such as minor words, numerical values, lists and parameters.
A syntax that includes lists or parameters is a parameterized syntax (see example below):
*START_NC_COMMAND NC_COMPENSATIONLOADTL/%MFG_TL_NUMBER,%MFG_TOOL_COMP*END
Note that the & character indicates a list and the % character indicates a parameter. A list has a finite number of values. You can define only one syntax for each NC command.
The example below shows how lists can be used to define inch units for feeds and speeds:
*START_NC_COMMAND NC_FEEDRATE*START_LIST MFG_FEED_UNIT
IPM ,IPR *END FEDRAT/%MFG_FEED_VALUE,&MFG_FEED_UNIT*END/*START_NC_COMMAND NC_SPINDLE_START*START_LIST MFG_SPNDL_UNIT RPM ,SFM *ENDSPINDL/%MFG_SPNDL_SPEED,&MFG_SPNDL_UNIT,&MFG_SPNDL_WAY*END/*START_NC_COMMAND NC_SPINDLE_LATHE*START_LIST MFG_SPNDL_UNIT RPM ,SFM *END SPINDL/%MFG_SPNDL_SPEED,&MFG_SPNDL_UNIT*END
The example below shows how lists can be used to define metric units for feeds and speeds:
*START_NC_COMMAND NC_FEEDRATE*START_LIST MFG_FEED_UNIT MMPM ,MMPR *END FEDRAT/%MFG_FEED_VALUE,&MFG_FEED_UNIT*END/*START_NC_COMMAND NC_SPINDLE_START*START_LIST MFG_SPNDL_UNIT RPM ,SMM *ENDSPINDL/%MFG_SPNDL_SPEED,&MFG_SPNDL_UNIT,&MFG_SPNDL_WAY*END/*START_NC_COMMAND NC_SPINDLE_LATHE*START_LIST MFG_SPNDL_UNIT RPM ,SMM *END SPINDL/%MFG_SPNDL_SPEED,&MFG_SPNDL_UNIT*END
For an example of how to define syntaxes in NC commands, please see PP Word Syntaxes in the Customizing section of this guide.
Arithmetic Operators
It is possible to use the following arithmetic operators in PP word syntaxes:
● addition (+)
● subtraction (-)
● multiplication (*)
● division (/).
These operators can be used:
● between word syntaxes (for example, %MFG_xxx + %MFG_yyy)
● between a value and a word syntax (for example, n + %MFG_yyy)
● between a word syntax and a value (for example, %MFG_xxx + n)
● between values (for example, n + m).
Parenthesis are not needed in expressions: they will be ignored and will not appear in NC data output. For example:
WORD/%MFG_aaa, %MFG_xxx + %MFG_yyy, %MFG_bbb/2
Operators are processed in the order they appear in the syntax. For example:
%MFG_xxx + %MFG_yyy * %MFG_zzz
This means that %MFG_xxx is added to %MFG_yyy, then this sum is multiplied by %MFG_zzz.
You should avoid using the +, -, *, / characters for other meanings. For example, you could use an underscore (_) instead of a dash (-) in the following expression to avoid any ambiguity:
PPRINT/DIAMETER-VALUE, %MFG_NOMINAL_DIAM
Syntaxes of NC Commands
NC command syntaxes that are supported in the current version are as follows:
● NC_3X_MO_START_COMMENT
● NC_5X_MO_START_COMMENT
● NC_AXIAL_MO_START_COMMENT
● NC_CHANGE_REF_PT
● NC_COMMENT
● NC_COMPENSATION
● NC_CUTCOM_LEFT
● NC_CUTCOM_OFF
● NC_CUTCOM_ON
● NC_CUTCOM_NORMDS_OFF
● NC_CUTCOM_NORMDS_ON
● NC_CUTCOM_NORMPS_OFF
● NC_CUTCOM_NORMPS_ON
● NC_CUTCOM_RIGHT
● NC_DELAY
● NC_FEEDRATE
● NC_LATHE_MO_START_COMMENT
● NC_MACHINING_AXIS
● NC_MILL_MO_START_COMMENT
● NC_MULTAX_ON
● NC_MULTAX_OFF
● NC_PITCH
● NC_SPINDLE
● NC_SPINDLE_LATHE
● NC_SPINDLE_LOCK
● NC_SPINDLE_OFF
● NC_SPINDLE_ON
● NC_SPINDLE_START
● NC_SPINDLE_STOP
● NC_THREAD_TURN
● NC_THREAD_TURN_OFF
NC_xxx_MO_START_COMMENT syntaxes allow machining operation information to be output in the APT source file. A sample PP Table (PPTableSampleMOComment.pptable) is delivered in the ..\startup\manufacturing\PPTables folder.
NC_AXIAL_MO_START_COMMENT
For axial machining operations:
*START_NC_INSTRUCTION NC_AXIAL_MO_START_COMMENT*START_SEQUENCEPPRINT NC_AXIAL_MO_START_COMMENT BEGINPPRINT MACHINE OPERATION = %MFG_MO_TYPEPPRINT OPERATION NAME = %MFG_MO_IDENTIFIERPPRINT PATTERN NAME = %MFG_PATTERN_NAMEPPRINT TOOL ASSEMBLY = %MFG_TL_ASMBLY_ID PPRINT NC_AXIAL_MO_START_COMMENT END*END*END
The following example shows the type of APT source that can be generated:
PPRINT NC_AXIAL_MO_START_COMMENT BEGINPPRINT MACHINE OPERATION = DrillingPPRINT OPERATION NAME = Drilling.1PPRINT PATTERN NAME = Hole.1PPRINT TOOL ASSEMBLY = Drill_Diam10PPRINT NC_AXIAL_MO_START_COMMENT ENDPPRINT OPERATION NAME : Drilling.1$$ Start generation of : Drilling.1LOADTL/2,1SPINDL/ 204.0000,SFM,CLWRAPIDGOTO / 130.00000, -55.00000, 2.50000CYCLE/DRILL, 52.886751, 2.500000, 0.200000,MMPRGOTO / 130.00000, -55.00000, 0.00000CYCLE/OFF
NC_3X_MO_START_COMMENT
For 3-axis milling operations:
*START_NC_INSTRUCTION NC_3X_MO_START_COMMENT*START_SEQUENCEPPRINT NC_3X_MO_START_COMMENT BEGINPPRINT MACHINE OPERATION = %MFG_MO_TYPEPPRINT OPERATION NAME = %MFG_MO_IDENTIFIERPPRINT TOOL ASSEMBLY = %MFG_TL_ASMBLY_ID
PPRINT NC_3X_MO_START_COMMENT END*END*END
NC_5X_MO_START_COMMENT
For 5-axis milling operations:
*START_NC_INSTRUCTION NC_5X_MO_START_COMMENT*START_SEQUENCEPPRINT NC_5X_MO_START_COMMENT BEGINPPRINT MACHINE OPERATION = %MFG_MO_TYPEPPRINT OPERATION NAME = %MFG_MO_IDENTIFIERPPRINT TOOL ASSEMBLY = %MFG_TL_ASMBLY_IDPPRINT NC_5X_MO_START_COMMENT END*END*END
NC_LATHE_MO_START_COMMENT
For turning operations:
*START_NC_INSTRUCTION NC_LATHE_MO_START_COMMENT*START_SEQUENCEPPRINT NC_LATHE_MO_START_COMMENT BEGINPPRINT MACHINE OPERATION = %MFG_MO_TYPEPPRINT OPERATION NAME = %MFG_MO_IDENTIFIERPPRINT TOOL ASSEMBLY = %MFG_TL_ASMBLY_IDPPRINT NC_LATHE_MO_START_COMMENT END*END*END
NC_MILL_MO_START_COMMENT
For 2.5-axis milling operations:
*START_NC_INSTRUCTION NC_MILL_MO_START_COMMENT*START_SEQUENCEPPRINT NC_MILL_MO_START_COMMENT BEGINPPRINT MACHINE OPERATION = %MFG_MO_TYPEPPRINT OPERATION NAME = %MFG_MO_IDENTIFIERPPRINT TOOL ASSEMBLY = %MFG_TL_ASMBLY_IDPPRINT NC_MILL_MO_START_COMMENT END*END*END
NC_CHANGE_REF_PT
Allows selecting the tool compensation corresponding to the desired tool output point.
MFG_QUADRANT: Number of the compensation type (for example, 2 for compensation type P2)MFG_NOSE_RADIUS: Insert nose radiusMFG_TL_SET_X: Tool assembly set length in x direction MFG_TL_SET_Y: Tool assembly set length in y direction MFG_TL_SET_Z: Tool assembly set length in z directionMFG_LGTH_COR_REG, MFG_TOOL_COMP and MFG_TL_COMP (compatibility V4): number of the correction register.
Default syntax: SWITCH/%MFG_QUADRANTSyntax example for turning operations:
SWITCH/%MFG_TL_COMP,%MFG_QUADRANT,INCR,%MFG_TL_SET_X,%MFG_TL_SET_Z,%MFG_NOSE_RADIUS
NC_COMMENT
MFG_MO_COMMENT: comment defined on machining operation.
Default syntax: %MFG_MO_COMMENT
NC_COMPENSATION
MFG_TOOL_COMP and MFG_TL_COMP (compatibility V4): value of the tool compensation lengthMFG_TL_COMP_RAD: value of the tool compensation radiusMFG_TL_NUMBER: tool number associated to the compensationMFG_TL_NAME: name of tool associated to the compensation.
Default syntax: LOADTL/%MFG_TL_NUMBER,%MFG_TL_COMP
NC_CUTCOM_ON
The syntax of this NC command is CUTCOM/ON and cannot be parameterized.
NC_CUTCOM_OFF
The syntax of this NC command is CUTCOM/OFF and cannot be parameterized.
NC_CUTCOM_NORMDS_ON
The syntax of this NC command is CUTCOM/SAME, NORMDS and cannot be parameterized.
NC_CUTCOM_NORMDS_OFF
The syntax of this NC command is CUTCOM/OFF and cannot be parameterized.
NC_CUTCOM_NORMPS_ON
The syntax of this NC command is CUTCOM/NORMPS and cannot be parameterized.
NC_CUTCOM_NORMPS_OFF
The syntax of this NC command is CUTCOM/OFF and cannot be parameterized.
NC_CUTCOM_LEFT
The syntax of this NC command is CUTCOM/LEFT and cannot be parameterized.
NC_CUTCOM_RIGHT
The syntax of this NC command is CUTCOM/RIGHT and cannot be parameterized.
NC_DELAY
MFG_DELAY_UNIT: list with two values defining the delay units.
First value: delay expressed in number of revolutions.REV is the default value.Second value: delay expressed in seconds.A blank string (represented by 8 underscore characters) is the default value. When the statement is generated by the application this string is ignored.MFG_DELAY_VALUE: numerical value of the delay.
Default syntax: DELAY/%MFG_DELAY_VALUE,&MFG_DELAY_UNIT
NC_FEEDRATE
MFG_FEED_UNIT: list with two values defining the feedrate units.First value: feedrate expressed in model units per minute. MMPM is the default value.Second value: feedrate expressed in model units per revolution. MMPR is the default value.MFG_FEED_VALUE: numerical value of the feedrate.
Default syntax: FEDRAT/%MFG_FEED_VALUE,&MFG_FEED_UNIT
NC_MACHINING_AXIS
The syntax of this NC command is as follows:
$$*CATIA0$$ %MFG_NCAXIS_IDENTIFIER$$ %MFG_NCAXIS_X_VECX %MFG_NCAXIS_X_VECY %MFG_NCAXIS_X_VECZ %MFG_NCAXIS_X_ORIG$$ %MFG_NCAXIS_Y_VECX %MFG_NCAXIS_Y_VECY %MFG_NCAXIS_Y_VECZ %MFG_NCAXIS_Y_ORIG$$ %MFG_NCAXIS_Z_VECX %MFG_NCAXIS_Z_VECY %MFG_NCAXIS_Z_VECZ %MFG_NCAXIS_Z_ORIG
The syntax of this NC command for a multi-slide lathe machine environment is as follows:
$$*CATIA0$$ %MFG_NCAXIS_IDENTIFIER, %MFG_SPINDLE_NAME, %MFG_SPINDLE_NUMBER$$ %MFG_NCAXIS_X_VECX %MFG_NCAXIS_X_VECY %MFG_NCAXIS_X_VECZ %MFG_NCAXIS_X_ORIG$$ %MFG_NCAXIS_Y_VECX %MFG_NCAXIS_Y_VECY %MFG_NCAXIS_Y_VECZ %MFG_NCAXIS_Y_ORIG$$ %MFG_NCAXIS_Z_VECX %MFG_NCAXIS_Z_VECY %MFG_NCAXIS_Z_VECZ %MFG_NCAXIS_Z_ORIG
The parameters are as follows:
MFG_NCAXIS_IDENTIFIER: manufacturing program name for the first output, otherwise name of the machining axis changeMFG_SPINDLE_NAME: name of the spindle that is linked to the originMFG_SPINDLE_NUMBER: number of the spindle that is linked to the originMFG_NCAXIS_X_ORIG, MFG_NCAXIS_Y_ORIG, MFG_NCAXIS_Z_ORIG: coordinates of the machining axis originMFG_NCAXIS_X_VECX, MFG_NCAXIS_Y_VECX, MFG_NCAXIS_Z_VECX: components of the x-axisMFG_NCAXIS_X_VECY, MFG_NCAXIS_Y_VECY, MFG_NCAXIS_Z_VECY: components of the y-axisMFG_NCAXIS_X_VECZ, MFG_NCAXIS_Y_VECZ, MFG_NCAXIS_Z_VECZ: components of the z-axis.
NC_MULTAX_ON
The syntax of this NC command is MULTAX and cannot be parameterized.
NC_MULTAX_OFF
The syntax of this NC command is MULTAX/OFF and cannot be parameterized.
NC_PITCH
MFG_THREAD_PITCH: Thread pitch
MFG_NUM_THREADS: Number of threads.
Syntax examples:PITCH/%MFG_THREAD_PITCH
PITCH/(1/%MFG_THREAD_PITCH),MULTRD,%MFG_NUM_THREADSFEDRAT/%MFG_THREAD_PITCH,MMPR
NC_SPINDLE_ON
The syntax of this NC command is SPINDL/ON and cannot be parameterized.
NC_SPINDLE_START or NC_SPINDLE
MFG_SPNDL_UNIT: list with two values defining the spindle rotation units.First value: spindle rotation expressed in revolutions per minute. RPM is the default value.Second value: spindle rotation expressed in surface meters per minute. SMM is the default value.MFG_SPNDL_WAY: list with two values defining the direction of rotation of the spindle.First value: spindle rotation processed clockwise. CLW is the default value.Second value: spindle rotation processed counter-clockwise. CCLW is the default value.MFG_SPNDL_SPEED: numerical value of the spindle speed.MFG_SPNDL_DIAMTR: diameter of the tool where the spindle speed is taken into account.
Default syntax: SPINDL/%MFG_SPNDL_SPEED,&MFG_SPNDL_UNIT,&MFG_SPNDL_WAY
NC_SPINDLE_LATHE
Note that this corresponds to the part's spindle speed.
MFG_SPNDL_UNIT: list with two values defining the spindle rotation units.First value: spindle rotation expressed in revolutions per minute. RPM is the default value.Second value: spindle rotation expressed in surface meters per minute. SMM is the default value.MFG_SPNDL_WAY: list with two values defining the direction of rotation of the spindle.First value: spindle rotation processed clockwise. CLW is the default value.Second value: spindle rotation processed counter-clockwise. CCLW is the default value.MFG_SPNDL_SPEED: numerical value of the spindle speed.
Default syntax: SPINDL/%MFG_SPNDL_SPEED,&MFG_SPNDL_UNIT
NC_SPINDLE_STOP
This NC command ensures compatibility with V4. You should use NC_SPINDLE_LOCK or NC_SPINDLE_OFF, if possible.
MFG_SPNDL_STOP: list with two values defining the action applied to the spindle.First value: de-activation of the spindle. OFF is the default value.Second value: spindle locked in an indexed position. LOCK is the default value.
NC_SPINDLE_LOCK
The syntax of this NC command is SPINDL/LOCK and cannot be parameterized.
NC_SPINDLE_OFF
The syntax of this NC command is SPINDL/OFF and cannot be parameterized.
NC_THREAD_TURN
Syntax example: THREAD/TURN
NC_THREAD_TURN_OFF
Syntax example: THREAD/OFF
NC Instructions
You can define for a given machine tool (i.e. post-processor) sequences of PP word syntaxes associated to particular NC instructions.
NC instructions are either auxiliary commands or axial machining operations.
A syntax comprises a major word and one or more syntax elements such as minor words, numerical values and standard parameters. A set of standard parameters is associated to each NC instruction. Parameters may be combined in arithmetical expressions.
A syntax that includes parameters is a parameterized syntax (see examples below):
*START_NC_INSTRUCTION NC_TOOL_CHANGE*START_SEQUENCETOOLNO/%MFG_TOOL_NUMBER,%MFG_NOMINAL_DIAMTPRINT/%MFG_TOOL_NAMELOADTL/%MFG_TOOL_NUMBER*END*END
*START_NC_INSTRUCTION NC_TAPPING*START_SEQUENCECYCLE/TAP,%MFG_TOTAL_DEPTH,%MFG_CLEAR_TIP*END*END
Note that the % character indicates a parameter.
You can define one or more syntax sequences for each NC instruction.
For an example of how to define syntax sequences in NC Instructions, please see PP Word Syntaxes in the Customizing section of this guide.
Standard Parameters for Auxiliary Command Type NC Instructions
These parameters include data that is defined on the corresponding entity or parameters that are computed according to an application method.
Auxiliary command type NC Instructions are as follows:
● NC_ACTIVITY_HEADER
● NC_END_MACRO
● NC_HEAD_ROTATION
● NC_ORIGIN
● NC_PROGRAM_HEADER
● NC_START_MACRO
● NC_TABLE_ROTATION
● NC_TOOL_CHANGE
● NC_TOOL_CHANGE_LATHE
NC_ACTIVITY_HEADER
This instruction is used to valuate parameters of an activity during the generation of APT.
Default syntax (empty): *START_NC_INSTRUCTION NC_ACTIVITY_HEADER *START_SEQUENCE *END *END
Syntax example:$$ OPERATION NAME = %MFG_MO_IDENTIFIER
NC_END_MACRO
MFG_IDENTIFIER: Part Operation identifierMFG_MACHINE_NAME: Machine name.
Default syntax: SPINDL/OFF
NC_HEAD_ROTATION
MFG_TYPE_OF_ROT: Rotation type (absolute angle in this version)MFG_DIR_OF_ROT: Rotation direction (clockwise or counterclockwise)MFG_AMOUNT_ROT: Angle of rotation about the axis of rotationMFG_AXIS_OF_ROT: Axis of rotation on machine head. MFG_ABC_AXIS: Axis of rotation on machine head to get Minor word AAXIS, BAXIS or CAXIS.
Default syntax: ROTHED/%MFG_AMOUNT_ROT,%MFG_DIR_OF_ROT
NC_ORIGIN
MFG_NCAXIS_X_ORIG, MFG_NCAXIS_Y_ORIG, MFG_NCAXIS_Z_ORIG: coordinates of the originMFG_ORIGIN_NUMBER: origin numberMFG_ORIGIN_GROUP: origin group.
Default syntax: ORIGIN/%MFG_NCAXIS_X_ORIG,%MFG_NCAXIS_Y_ORIG,%MFG_NCAXIS_Z_ORIG,$%MFG_ORIGIN_NUMBER,%MFG_ORIGIN_GROUP
NC_PROGRAM_HEADER
MFG_PROGRAM_NAME: Manufacturing Program nameMFG_CHANNEL_NUMBER: Channel number (Turret).
Default syntax (empty): *START_NC_INSTRUCTION NC_PROGRAM_HEADER *START_SEQUENCE *END *END
Syntax example:
PROG_NAME,%MFG_PROGRAM_NAME
Syntax example in a Multi-Axis Lathe machine environment:CHANNEL,%MFG_CHANNEL_NUMBER
NC_START_MACRO
MFG_IDENTIFIER: Part Operation identifierMFG_PROGRAM_NAME: Manufacturing Program nameMFG_MACHINE_NAME: Machine nameMFG_MODEL_NAME: Name of the CATProcess (with document suffix)MFG_PRODUCT_NAME: Name of the CATProduct/CATPart (with no document suffix).
Default syntax: PARTNO PART TO BE MACHINED
NC_TABLE_ROTATION
MFG_TYPE_OF_ROT: Rotation type (absolute angle in this version)MFG_DIR_OF_ROT: Rotation direction (clockwise or counterclockwise)MFG_AMOUNT_ROT: Angle of rotation about the axis of rotationMFG_AXIS_OF_ROT: Axis of rotation on machine table. MFG_ABC_AXIS: Axis of rotation on machine table to get Minor word AAXIS, BAXIS or CAXIS.
Default syntax: ROTABL/%MFG_AMOUNT_ROT,%MFG_DIR_OF_ROT
NC_TOOL_CHANGE
Please note that if tool assembly resources are not used in your process, the term 'tool assembly' means 'tool' or 'cutter' in the following description.
MFG_TL_ASMBLY_ID: Tool assembly identifier MFG_TL_SET_LGTH: Tool set lengthMFG_NOMINAL_DIAM: Nominal diameter of the toolMFG_TOOL_COMMENT: Comment associated with the toolMFG_TOOL_NUMBER: Tool assembly number MFG_ASS_COMMENT: Comment associated with the tool assemblyMFG_WEIGHT_SNTX: Tool weight syntaxMFG_COOLNT_SNTX: Coolant supply syntaxMFG_TOOTH_DES: Tooth descriptionMFG_DIAMETER_2: Diameter 2 of the tool assemblyMFG_MAX_MIL_TIME: Tool life (in time units)MFG_MAX_MIL_LGTH: Tool life (in length units)MFG_CORNER_RAD: Tool corner radiusMFG_CUT_ANGLE: Tool cutting angleMFG_LENGTH: Length of active part of the toolMFG_TL_TIP_LGTH: Tool tip lengthMFG_CUT_LENGTH: Tool cutting lengthMFG_NB_OF_FLUTES: Number of teethMFG_TOOL_NAME: Tool nameMFG_TL_SET_X: Tool set length in x directionMFG_TL_SET_Y: Tool set length in y directionMFG_WAY_OF_ROT: Computed rotation direction of tool (RIGHTHAND or LEFTHAND)MFG_TOOL_ASS_POW: Computed tool assembly power typeIf fixed the value is TURN, otherwise the value is MILLMFG_TOOL_COMP and MFG_TL_COMP (compatibility V4): value of the tool compensation lengthMFG_TOOL_COMP_2: value of the second tool compensation length
MFG_FEED_MACH: Machining feedrate (*)MFG_SPNDL_MACH: Machining spindle speed (*)MFG_FEED_UNIT: Computed feedrate unit (*)MFG_SPNDL_UNIT: Computed spindle speed unit (*)
(*) The values of these feed and speed attributes are taken from the first machining operation under the tool change.
Default syntax: TOOLNO/%MFG_TOOL_NUMBER,%MFG_NOMINAL_DIAM
NC_TOOL_CHANGE_LATHE
MFG_TL_ASMBLY_ID: Tool assembly identifier MFG_ASS_COMMENT: Comment associated with the tool assembly MFG_TOOL_NUMBER: Tool assembly number MFG_TOOL_NAME: Insert-holder name MFG_TOOL_COMMENT: Comment associated with the insert-holderMFG_INSERT_NAME: Insert nameMFG_INSERT_COMMENT: Comment associated with the insert
MFG_QUADRANT: Number of the compensation type (for example, 2 for compensation type P2)MFG_TL_SETUP_ANG: Tool assembly setup angle (value in degrees)MFG_TL_SET_X: Tool assembly set length in x direction MFG_TL_SET_Y: Tool assembly set length in y direction MFG_TL_SET_Z: Tool assembly set length in z direction
MFG_HAND_STYLE: Insert-holder style (LEFT_HAND, RIGHT_HAND or NEUTRAL)MFG_TOOL_INVERT: Tool assembly inversion. Defines if the insert-holder has been inverted with respect to the original insert-holder style. Possible values are 0 (not inverted) or 1 (inverted).MFG_TOOL_COMP and MFG_TL_COMP (compatibility V4): Value of the insert-holder compensation length
MFG_LIFE_TIME: Insert life-time (in time units). Not available for Groove inserts. MFG_NOSE_RADIUS: Insert nose radius MFG_CLEAR_ANGLE: Insert clearance angleMFG_INSERT_LGTH: Insert lengthMFG_INSCRIB_DIAM: Inscribed diameter of insert MFG_INSERT_ANGLE: Insert shape angle
MFG_SPNDL_WAY: Spindle direction MFG_FEED_MACH: Machining feedrate (*)MFG_FEED_UNIT: Feedrate unit (*)MFG_SPNDL_MACH: Machining spindle speed (*)MFG_SPNDL_UNIT: Spindle speed unit (*).
(*) The values of these feed and speed attributes are taken from the first machining operation under the tool change.
Default syntax: TOOLNO/%MFG_TOOL_NUMBER,TURN
Mill/Turn integration and the NC_TOOL_CHANGE_LATHE instruction
For a drilling operation using a non-powered Milling Tool Assembly and machining along the spindle axis, a Lathe Tool Change is created. In this case, the following Insert attributes are replaced by Tool attributes:
Insert attributesMFG_NOSE_RADIUS MFG_INSCRIB_DIAM MFG_LIFE_TIME MFG_LIFE_LGTH MFG_INSERT_LGTH MFG_CLEAR_ANGLEMFG_INSERT_ANGLE
Tool attributes MFG_NOMINAL_DIAM MFG_NOMINAL_DIAM MFG_MAX_MIL_TIME MFG_MAX_MIL_LGTH MFG_CUT_LENGTH 0 (not valuated) MFG_CUT_ANGLE
Standard Parameters for Axial Machining Operation Type NC Instructions
For axial machining operations, the standard parameters are either:
● parameters defined on the corresponding machining operation (geometrical data, machining strategy parameters, feeds and speeds, and so on)
● parameters that are calculated according to an application method.
In the figures below:
● detail depth (MFG_DETAIL_DEPTH) and total depth (MFG_TOTAL_DEPTH) are computed parameters
● breakthrough distance (MFG_BREAKTHROUGH) is a machining strategy parameter
● tool tip length is a geometric attribute of the tool (MFG_TL_TIP_LGTH).
Overall breakthrough is the breakthrough distance plus the tool tip length.
Figure 1. Total depth without breakthrough
Figure 2. Total depth with breakthrough
The figures below show Depth mode behavior on axial operations with chamfering machining:
Figure 3. Spot Drilling with Depth mode=By Tip
Figure 4. Countersinking with Depth mode=By Diameter
Axial machining operation type NC Instructions are as follows:
● NC_BACK_BORING
● NC_BORING
● NC_BORING_SPINDLE_STOP
● NC_BORING_AND_CHAMFERING
● NC_BREAK_CHIPS
● NC_CIRCULAR_MILLING
● NC_COUNTERBORING
● NC_COUNTERSINKING
● NC_DEEPHOLE
● NC_DRILLING
● NC_DRILLING_DWELL_DELAY
● NC_LATHE_THREADING
● NC_REAMING
● NC_REVERSE_THREADING
● NC_SPOT_DRILLING
● NC_T_SLOTTING
● NC_TAPPING
● NC_THREAD_WITHOUT_TAP_HEAD
● NC_THREAD_MILLING
● NC_TWO_SIDES_CHAMFERING
NC_BACK_BORING
General parameters are as follows:
MFG_MO_TYPE: Machining operation typeMFG_MO_IDENTIFIER: Machining operation name or identifierMFG_PATTERN_NAME: Machining pattern name.
Feeds and Speeds parameters are as follows:
MFG_FEED_APP_MODE: Approach feedrate mode (0: Value / 1: Rapid)MFG_FEED_APP_VALUE and MFG_FEED_APPRCH (compatibility V4): Approach feedrateMFG_FEED_PLUNGE_MODE and MFG_FEED_PL_TYPE (compatibility V4): Plunge feedrate mode (0: Value / 1: Rapid)MFG_FEED_PLUNGE_VALUE and MFG_PLUNGE_FEED (compatibility V4): Plunge feedrateMFG_FEED_MACH_VALUE and MFG_FEED_MACH (compatibility V4): Machining feedrateMFG_SPINDLE_MACH_VALUE and MFG_SPNDL_MACH (compatibility V4): Machining spindle speedMFG_FEED_RETRACT_MODE and MFG_FEED_RT_TYPE (compatibility V4): Retract feedrate mode (0: Value / 1: Rapid)MFG_FEED_RETRACT_VALUE and MFG_FEED_RETRACT (compatibility V4): Retract feedrateMFG_FEED_UNIT: Feedrate unitMFG_SPNDL_UNIT: Spindle speed unit
Machining Strategy parameters are as follows:
MFG_CLEAR_TIP: Approach clearanceMFG_CLEAR_TIP_2: Second approach clearanceMFG_DEPTH_MODE: Depth mode (1: Tip / 2: Shoulder)MFG_DWELL_MODE: Dwell mode (0: None / 1: By revolutions / 2: By time)MFG_DWELL_REVOL: Dwell delay in revolutionsMFG_DWELL_TIME: Dwell delay in time units (seconds)MFG_LIFT_MODE: Shift mode (0: None / 1: Linear coordinates / 2: Polar coordinates) MFG_XOFF: Shift along X MFG_YOFF: Shift along Y MFG_ZOFF: Shift along Z MFG_LIFT_ANGLE: Shift angle MFG_LIFT_DIST: Shift distanceMFG_RETRACT_CLEAR_TIP: retract clearance MFG_TOOL_COMP and MFG_TL_COMP (compatibility V4): Length number of current correctorMFG_TOOL_COMP_1: Length number of first correctorMFG_TOOL_COMP_DIST: Distance between the position of the current corrector and the tool tipMFG_TOOL_COMP_DIST_1: Distance between the position of the first corrector and the tool tip
Geometry parameters are as follows:
MFG_DIAMETER: Nominal diameter of the toolMFG_NOMINAL_DIAMETER: Nominal diameter of the machined featureMFG_BCK_BORE_VAL: Back bore depthMFG_JUMP_DIST: Jump distance
Computed parameters are as follows (see Figure 1 and Figure 2 above):
MFG_DETAIL_DEPTH: Hole depth that is effectively machinedMFG_TOTAL_DEPTH: Total depth machined by the operation. This includes the hole depth, breakthrough, and tool tip length.MFG_CMP_DWL_TIME: Computed dwell delay (in time units of seconds): this parameter is computed if dwell mode is set to 'revolutions'. Otherwise, the dwell time is returned as is.MFG_CMP_OFFSET: Computed offsetMFG_CMP_ANGLE: Computed angle. This parameter is computed if Shift mode is set to 'Linear coordinates'. Otherwise, the Shift angle is returned as is.
Default syntax: CYCLE/BORE,%MFG_TOTAL_DEPTH,%MFG_CLEAR_TIP
NC_BORING
General parameters are as follows:
MFG_MO_TYPE: Machining operation typeMFG_MO_IDENTIFIER: Machining operation name or identifierMFG_PATTERN_NAME: Machining pattern name.
Feeds and Speeds parameters are as follows:
MFG_FEED_APP_MODE: Approach feedrate mode (0: Value / 1: Rapid)MFG_FEED_APP_VALUE and MFG_FEED_APPRCH (compatibility V4): Approach feedrateMFG_FEED_PLUNGE_MODE and MFG_FEED_PL_TYPE (compatibility V4): Plunge feedrate mode (0: Value / 1: Rapid)MFG_FEED_PLUNGE_VALUE and MFG_PLUNGE_FEED (compatibility V4): Plunge feedrateMFG_FEED_MACH_VALUE and MFG_FEED_MACH (compatibility V4): Machining feedrateMFG_SPINDLE_MACH_VALUE and MFG_SPNDL_MACH (compatibility V4): Machining spindle speedMFG_FEED_RETRACT_MODE and MFG_FEED_RT_TYPE (compatibility V4): Retract feedrate mode (0: Value / 1: Rapid)MFG_FEED_RETRACT_VALUE and MFG_FEED_RETRACT (compatibility V4): Retract feedrateMFG_FEED_UNIT: Feedrate unitMFG_SPNDL_UNIT: Spindle speed unit
Machining Strategy parameters are as follows:
MFG_CLEAR_TIP: Approach clearanceMFG_DEPTH_MODE: Depth mode (1: Tip / 2: Shoulder)MFG_BREAKTHROUGH: Breakthrough distanceMFG_PLUNGE_MODE: Plunge mode (0: None / 1: Tip / 3: Diameter)MFG_PLUNGE_TIP: Plunge tip distanceMFG_PLUNGE_OFFST: Plunge tip offsetMFG_PLUNGE_DIAMETER: Plunge diameterMFG_DWELL_MODE: Dwell mode (0: None / 1: By revolutions / 2: By time)MFG_DWELL_REVOL: Dwell delay in revolutionsMFG_DWELL_TIME: Dwell delay in time units (seconds)MFG_TOOL_COMP and MFG_TL_COMP (compatibility V4): Length number of current correctorMFG_TOOL_COMP_1: Length number of first correctorMFG_TOOL_COMP_DIST: Distance between the position of the current corrector and the tool tipMFG_TOOL_COMP_DIST_1: Distance between the position of the first corrector and the tool tip
Geometry parameters are as follows:
MFG_DIAMETER: Nominal diameter of toolMFG_NOMINAL_DIAMETER: Nominal diameter of the machined featureMFG_JUMP_DIST: Jump distance
Computed parameters are as follows (see Figure 1 and Figure 2 above):
MFG_DETAIL_DEPTH: Hole depth that is effectively machinedMFG_TOTAL_DEPTH: Total depth machined by the operation. This includes the hole depth, breakthrough, and tool tip length.MFG_PLUNGE_DIST: Whatever the selected plunge mode (by Tip or by Diameter), this parameter returns the plunge distance. The plunge offset is taken into account in this value.MFG_CMP_DWL_TIME: Computed dwell delay (in time units of seconds): this parameter is computed if dwell mode is set to 'revolutions'. Otherwise, the dwell time is returned as is.
Default syntax: CYCLE/BORE,%MFG_TOTAL_DEPTH,%MFG_CLEAR_TIP
NC_BORING_SPINDLE_STOP
General parameters are as follows:
MFG_MO_TYPE: Machining operation typeMFG_MO_IDENTIFIER: Machining operation name or identifierMFG_PATTERN_NAME: Machining pattern name.
Feeds and Speeds parameters are as follows:
MFG_FEED_APP_MODE: Approach feedrate mode (0: Value / 1: Rapid)MFG_FEED_APP_VALUE and MFG_FEED_APPRCH (compatibility V4): Approach feedrateMFG_FEED_PLUNGE_MODE and MFG_FEED_PL_TYPE (compatibility V4): Plunge feedrate mode (0: Value / 1: Rapid)MFG_FEED_PLUNGE_VALUE and MFG_PLUNGE_FEED (compatibility V4): Plunge feedrateMFG_FEED_MACH_VALUE and MFG_FEED_MACH (compatibility V4): Machining feedrateMFG_SPINDLE_MACH_VALUE and MFG_SPNDL_MACH (compatibility V4): Machining spindle speedMFG_FEED_RETRACT_MODE and MFG_FEED_RT_TYPE (compatibility V4): Retract feedrate mode (0: Value / 1: Rapid)MFG_FEED_RETRACT_VALUE and MFG_FEED_RETRACT (compatibility V4): Retract feedrateMFG_FEED_UNIT: Feedrate unitMFG_SPNDL_UNIT: Spindle speed unit
Machining Strategy parameters are as follows:
MFG_CLEAR_TIP: Approach clearanceMFG_DEPTH_MODE: Depth mode (1: Tip / 2: Shoulder)MFG_BREAKTHROUGH: Breakthrough distanceMFG_PLUNGE_MODE: Plunge mode (0: None / 1: Tip / 3: Diameter)MFG_PLUNGE_TIP: Plunge tip distanceMFG_PLUNGE_OFFST: Plunge tip offsetMFG_PLUNGE_DIAMETER: Plunge diameterMFG_DWELL_MODE: Dwell mode (0: None / 1: By revolutions / 2: By time)MFG_DWELL_REVOL: Dwell delay in revolutionsMFG_DWELL_TIME: Dwell delay in time units (seconds)MFG_LIFT_MODE: Shift mode (0: None / 1: Linear coordinates / 2: Polar coordinates) MFG_XOFF: Shift along X MFG_YOFF: Shift along Y MFG_ZOFF: Shift along Z MFG_LIFT_ANGLE: Shift angle MFG_LIFT_DIST: Shift distanceMFG_TOOL_COMP and MFG_TL_COMP (compatibility V4): Length number of current correctorMFG_TOOL_COMP_1: Length number of first correctorMFG_TOOL_COMP_DIST: Distance between the position of the current corrector and the tool tipMFG_TOOL_COMP_DIST_1: Distance between the position of the first corrector and the tool tip.
Geometry parameters are as follows:
MFG_DIAMETER: Nominal diameter of toolMFG_NOMINAL_DIAMETER: Nominal diameter of the machined featureMFG_JUMP_DIST: Jump distance
Computed parameters are as follows (see Figure 1 and Figure 2 above):
MFG_DETAIL_DEPTH: Hole depth that is effectively machinedMFG_TOTAL_DEPTH: Total depth machined by the operation. This includes the hole depth, breakthrough, and tool tip length.MFG_PLUNGE_DIST: Whatever the selected plunge mode (by Tip or by Diameter), this parameter returns the plunge distance. The plunge offset is taken into account in this value.MFG_CMP_DWL_TIME: Computed dwell delay (in time units of seconds): this parameter is computed if dwell mode is set to 'revolutions'. Otherwise, the dwell time is returned as is.MFG_CMP_OFFSET: Computed offsetMFG_CMP_ANGLE: Computed angle. This parameter is computed if Shift mode is set to 'Linear coordinates'. Otherwise, the Shift angle is returned as is.
Default syntax: CYCLE/BORE,%MFG_TOTAL_DEPTH,%MFG_CLEAR_TIP
NC_BORING_AND_CHAMFERING
General parameters are as follows:
MFG_MO_TYPE: Machining operation typeMFG_MO_IDENTIFIER: Machining operation name or identifierMFG_PATTERN_NAME: Machining pattern name.
Feeds and Speeds parameters are as follows:
MFG_FEED_APP_MODE: Approach feedrate mode (0: Value / 1: Rapid)MFG_FEED_APP_VALUE and MFG_FEED_APPRCH (compatibility V4): Approach feedrateMFG_FEED_PLUNGE_MODE and MFG_FEED_PL_TYPE (compatibility V4): Plunge feedrate mode (0: Value / 1: Rapid)MFG_FEED_PLUNGE_VALUE and MFG_PLUNGE_FEED (compatibility V4): Plunge feedrateMFG_FEED_MACH_VALUE and MFG_FEED_MACH (compatibility V4): Machining feedrateMFG_SPINDLE_MACH_VALUE and MFG_SPNDL_MACH (compatibility V4): Machining spindle speedMFG_CHAMFER_FEED_VALUE and MFG_CHAMFER_FEED (compatibility V4): Machining feedrate for chamfering phaseMFG_CHAMFER_SPINDLE_VALUE: Machining spindle speed for chamfering phase.MFG_FEED_RETRACT_MODE and MFG_FEED_RT_TYPE (compatibility V4): Retract feedrate mode (0: Value / 1: Rapid)MFG_FEED_RETRACT_VALUE and MFG_FEED_RETRACT (compatibility V4): Retract feedrateMFG_FEED_UNIT: Feedrate unitMFG_SPNDL_UNIT: Spindle speed unit
Machining Strategy parameters are as follows:
MFG_CLEAR_TIP: Approach clearanceMFG_CLEAR_TIP_2: Second approach clearanceMFG_DEPTH_MODE: Depth mode (1: Tip / 2: Shoulder)MFG_BREAKTHROUGH: Breakthrough distanceMFG_PLUNGE_MODE: Plunge mode (0: None / 1: Tip / 3: Diameter)MFG_PLUNGE_TIP: Plunge tip distanceMFG_PLUNGE_OFFST: Plunge tip offsetMFG_PLUNGE_DIAMETER: Plunge diameterMFG_DWELL_MODE: Dwell mode (0: None / 1: By revolutions / 2: By time)MFG_DWELL_REVOL: Dwell delay in revolutionsMFG_DWELL_TIME: Dwell delay in time units (seconds)MFG_TOOL_COMP and MFG_TL_COMP (compatibility V4): Length number of current correctorMFG_TOOL_COMP_1: Length number of first correctorMFG_TOOL_COMP_2: Length number of second correctorMFG_TOOL_COMP_DIST: Distance between the position of the current corrector and the tool tipMFG_TOOL_COMP_DIST_1: Distance between the position of the first corrector and the tool tipMFG_TOOL_COMP_DIST_2: Distance between the position of the second corrector and the tool tip
Geometry parameters are as follows:
MFG_DIAMETER and MFG_CHAMFER_VAL (compatibility V4): Chamfer diameterMFG_NOMINAL_DIAMETER: Nominal diameter of the machined featureMFG_JUMP_DIST: Jump distance.
Computed parameters are as follows (see Figure 1 and Figure 2 above):
MFG_DETAIL_DEPTH: Hole depth that is effectively machined.MFG_TOTAL_DEPTH: Total depth machined by the operation. This includes the hole depth, breakthrough, and tool tip length.MFG_PLUNGE_DIST: Whatever the selected plunge mode (by Tip or by Diameter), this parameter returns the plunge distance. The plunge offset is taken into account in this value.MFG_CMP_DWL_TIME: Computed dwell delay (in time units of seconds): this parameter is computed if dwell mode is set to 'revolutions'. Otherwise, the dwell time is returned as is.
Default syntax: CYCLE/BORE,%MFG_TOTAL_DEPTH,%MFG_CLEAR_TIP
NC_BREAK_CHIPS
General parameters are as follows:
MFG_MO_TYPE: Machining operation typeMFG_MO_IDENTIFIER: Machining operation name or identifierMFG_PATTERN_NAME: Machining pattern name.
Feeds and Speeds parameters are as follows:
MFG_FEED_APP_MODE: Approach feedrate mode (0: Value / 1: Rapid)MFG_FEED_APP_VALUE and MFG_FEED_APPRCH (compatibility V4): Approach feedrateMFG_FEED_PLUNGE_MODE and MFG_FEED_PL_TYPE (compatibility V4): Plunge feedrate mode (0: Value / 1: Rapid)MFG_FEED_PLUNGE_VALUE and MFG_PLUNGE_FEED (compatibility V4): Plunge feedrateMFG_FEED_MACH_VALUE and MFG_FEED_MACH (compatibility V4): Machining feedrateMFG_SPINDLE_MACH_VALUE and MFG_SPNDL_MACH (compatibility V4): Machining spindle speedMFG_FEED_RETRACT_MODE and MFG_FEED_RT_TYPE (compatibility V4): Retract feedrate mode (0: Value / 1: Rapid)MFG_FEED_RETRACT_VALUE and MFG_FEED_RETRACT (compatibility V4): Retract feedrateMFG_FEED_UNIT: Feedrate unitMFG_SPNDL_UNIT: Spindle speed unit
Machining Strategy parameters are as follows:
MFG_CLEAR_TIP: Approach clearanceMFG_DEPTH_MODE: Depth mode (1: Tip / 2: Shoulder)MFG_BREAKTHROUGH: Breakthrough distanceMFG_AXIAL_DEPTH: Maximum depth of cutMFG_OFFSET_RET: Retract offset MFG_PLUNGE_MODE: Plunge mode (0: None / 1: Tip / 3: Diameter)MFG_PLUNGE_TIP: Plunge tip distanceMFG_PLUNGE_OFFST: Plunge tip offsetMFG_PLUNGE_DIAMETER: Plunge diameterMFG_DWELL_MODE: Dwell mode (0: None / 1: By revolutions / 2: By time)MFG_DWELL_REVOL: Dwell delay in revolutionsMFG_DWELL_TIME: Dwell delay in time units (seconds)MFG_TOOL_COMP and MFG_TL_COMP (compatibility V4): Length number of current correctorMFG_TOOL_COMP_1: Length number of first correctorMFG_TOOL_COMP_DIST: Distance between the position of the current corrector and the tool tipMFG_TOOL_COMP_DIST_1: Distance between the position of the first corrector and the tool tip
Geometry parameters are as follows:
MFG_DIAMETER: Tool nominal diameterMFG_NOMINAL_DIAMETER: Nominal diameter of the machined featureMFG_JUMP_DIST: Jump distance
Computed parameters are as follows (see Figure 1 and Figure 2 above):
MFG_DETAIL_DEPTH: Hole depth that is effectively machined.MFG_TOTAL_DEPTH: Total depth machined by the operation. This includes the hole depth, breakthrough, and tool tip length.MFG_PLUNGE_DIST: Whatever the selected plunge mode (by Tip or by Diameter), this parameter returns the plunge distance. The plunge offset is taken into account in this value.MFG_CMP_DWL_TIME: Computed dwell delay (in time units of seconds): this parameter is computed if dwell mode is set to 'revolutions'. Otherwise, the dwell time is returned as is.MFG_EFFCT_DEPTH: Effective depth (= maximum depth of cut)
Default syntax: CYCLE/BRKCHP,%MFG_TOTAL_DEPTH,%MFG_CLEAR_TIP
NC_CIRCULAR_MILLING
General parameters are as follows:
MFG_MO_TYPE: Machining operation typeMFG_MO_IDENTIFIER: Machining operation name or identifierMFG_PATTERN_NAME: Machining pattern name.
Feeds and Speeds parameters are as follows:
MFG_FEED_APP_VALUE and MFG_FEED_APPRCH (compatibility V4): Approach feedrateMFG_FEED_PLUNGE_MODE and MFG_FEED_PL_TYPE (compatibility V4): Plunge feedrate mode (0: Value / 1: Rapid)MFG_FEED_PLUNGE_VALUE and MFG_PLUNGE_FEED (compatibility V4): Plunge feedrateMFG_FEED_MACH_VALUE and MFG_FEED_MACH (compatibility V4): Machining feedrateMFG_SPINDLE_MACH_VALUE and MFG_SPNDL_MACH (compatibility V4): Machining spindle speedMFG_FEED_RETRACT_VALUE and MFG_FEED_RETRACT (compatibility V4): Retract feedrateMFG_FEED_UNIT: Feedrate unitMFG_SPNDL_UNIT: Spindle speed unit
Machining Strategy parameters are as follows:
MFG_CLEAR_TIP: Approach clearanceMFG_RADIAL_STEP: Distance between pathsMFG_RADIAL_NB: Number of pathsMFG_AXIAL_STRAT: Axial mode (1: Max depth of cut / 2: Number of levels / 3: Number of levels without top) MFG_AXIAL_DEPTH: Maximum depth of cutMFG_AXIAL_NUMBER: Number of levelsMFG_SEQUENCING_STRAT: Sequencing mode (1: Radial first / 2: Axial first)MFG_TOLER_MACH: Machining toleranceMFG_DIR_CUT: Direction of cut (1: Climb / 2: Conventional)MFG_OVERHANG: Percentage overlapMFG_DRAFT_ANGLE: Automatic draft angleMFG_CIRCULAR_MODE: Machining mode (1: Standard / 2: Helical)MFG_HELIX_MODE: Helix mode (1: By pitch / 2: By angle)MFG_HELIX_ANGLE: Helix angleMFG_PITCH: Helix pitchMFG_TOOL_COMP and MFG_TL_COMP (compatibility V4): Length number of current correctorMFG_TOOL_COMP_1: Length number of first correctorMFG_TOOL_COMP_DIST: Distance between the position of the current corrector and the tool tipMFG_TOOL_COMP_DIST_1: Distance between the position of the first corrector and the tool tip
Geometry parameters are as follows:
MFG_DIAMETER: Nominal diameter of hole (offset on contour is taken into account in this value)MFG_JUMP_DIST: Jump distance
Computed parameters are as follows (see Figure 1 and Figure 2 above):
MFG_DETAIL_DEPTH: Hole depth that is effectively machined.MFG_TOTAL_DEPTH: Total depth machined by the operation. This includes the hole depth, breakthrough, and tool tip length.
Default syntax: CYCLE/CIRCULARMILLING,%MFG_TOTAL_DEPTH,%MFG_CLEAR_TIP
NC_COUNTERBORING
General parameters are as follows:
MFG_MO_TYPE: Machining operation typeMFG_MO_IDENTIFIER: Machining operation name or identifierMFG_PATTERN_NAME: Machining pattern name.
Feeds and Speeds parameters are as follows:
MFG_FEED_APP_MODE: Approach feedrate mode (0: Value / 1: Rapid)MFG_FEED_APP_VALUE and MFG_FEED_APPRCH (compatibility V4): Approach feedrateMFG_FEED_PLUNGE_MODE and MFG_FEED_PL_TYPE (compatibility V4): Plunge feedrate mode (0: Value / 1: Rapid)MFG_FEED_PLUNGE_VALUE and MFG_PLUNGE_FEED (compatibility V4): Plunge feedrateMFG_FEED_MACH_VALUE and MFG_FEED_MACH (compatibility V4): Machining feedrateMFG_SPINDLE_MACH_VALUE and MFG_SPNDL_MACH (compatibility V4): Machining spindle speedMFG_FEED_RETRACT_MODE and MFG_FEED_RT_TYPE (compatibility V4): Retract feedrate mode (0: Value / 1: Rapid)MFG_FEED_RETRACT_VALUE and MFG_FEED_RETRACT (compatibility V4): Retract feedrateMFG_FEED_UNIT: Feedrate unitMFG_SPNDL_UNIT: Spindle speed unit
Machining Strategy parameters are as follows:
MFG_CLEAR_TIP: Approach clearanceMFG_DEPTH_MODE: Depth mode (1: Tip / 2: Shoulder)MFG_PLUNGE_MODE: Plunge mode (0: None / 1: Tip / 3: Diameter)MFG_PLUNGE_TIP: Plunge tip distanceMFG_PLUNGE_OFFST: Plunge tip offsetMFG_PLUNGE_DIAMETER: Plunge diameterMFG_DWELL_MODE: Dwell mode (0: None / 1: By revolutions / 2: By time)MFG_DWELL_REVOL: Dwell delay in revolutionsMFG_DWELL_TIME: Dwell delay in time units (seconds)MFG_TOOL_COMP and MFG_TL_COMP (compatibility V4): Length number of current correctorMFG_TOOL_COMP_1: Length number of first correctorMFG_TOOL_COMP_DIST: Distance between the position of the current corrector and the tool tipMFG_TOOL_COMP_DIST_1: Distance between the position of the first corrector and the tool tip
Geometry parameters are as follows:
MFG_DIAMETER: Nominal diameter of the toolMFG_NOMINAL_DIAMETER: Nominal diameter of the machined featureMFG_JUMP_DIST: Jump distance
Computed parameters are as follows (see Figure 1 and Figure 2 above):
MFG_DETAIL_DEPTH: Hole depth that is effectively machined.MFG_TOTAL_DEPTH: Total depth machined by the operation. This includes the hole depth, breakthrough, and tool tip length.MFG_PLUNGE_DIST: Whatever the selected plunge mode (by Tip or by Diameter), this parameter returns the plunge distance. The plunge offset is taken into account in this value.MFG_CMP_DWL_TIME: Computed dwell delay (in time units of seconds): this parameter is computed if dwell mode is set to 'revolutions'. Otherwise, the dwell time is returned as is.
Default syntax: CYCLE/BORE,%MFG_TOTAL_DEPTH,%MFG_CLEAR_TIP
NC_COUNTERSINKING
General parameters are as follows:
MFG_MO_TYPE: Machining operation type
MFG_MO_IDENTIFIER: Machining operation name or identifierMFG_PATTERN_NAME: Machining pattern name.
Feeds and Speeds parameters are as follows:
MFG_FEED_APP_MODE: Approach feedrate mode (0: Value / 1: Rapid)MFG_FEED_APP_VALUE and MFG_FEED_APPRCH (compatibility V4): Approach feedrateMFG_FEED_PLUNGE_MODE and MFG_FEED_PL_TYPE (compatibility V4): Plunge feedrate mode (0: Value / 1: Rapid)MFG_FEED_PLUNGE_VALUE and MFG_PLUNGE_FEED (compatibility V4): Plunge feedrateMFG_FEED_MACH_VALUE and MFG_FEED_MACH (compatibility V4): Machining feedrateMFG_SPINDLE_MACH_VALUE and MFG_SPNDL_MACH (compatibility V4): Machining spindle speedMFG_FEED_RETRACT_MODE and MFG_FEED_RT_TYPE (compatibility V4): Retract feedrate mode (0: Value / 1: Rapid)MFG_FEED_RETRACT_VALUE and MFG_FEED_RETRACT (compatibility V4): Retract feedrateMFG_FEED_UNIT: Feedrate unitMFG_SPNDL_UNIT: Spindle speed unit
Machining Strategy parameters are as follows:
MFG_CLEAR_TIP: Approach clearanceMFG_DEPTH_MODE: Depth mode (3: Diameter / 4: Distance). See Figure 4 above.MFG_PLUNGE_MODE: Plunge mode (0: None / 1: Tip / 3: Diameter). MFG_PLUNGE_TIP: Plunge tip distanceMFG_PLUNGE_OFFST: Plunge tip offsetMFG_PLUNGE_DIAMETER: Plunge diameterMFG_DWELL_MODE: Dwell mode (0: None / 1: By revolutions / 2: By time)MFG_DWELL_REVOL: Dwell delay in revolutionsMFG_DWELL_TIME: Dwell delay in time units (seconds)MFG_TOOL_COMP and MFG_TL_COMP (compatibility V4): Length number of current correctorMFG_TOOL_COMP_1: Length number of first correctorMFG_TOOL_COMP_DIST: Distance between the position of the current corrector and the tool tipMFG_TOOL_COMP_DIST_1: Distance between the position of the first corrector and the tool tip
Geometry parameters are as follows:
MFG_DIAMETER: Countersink diameterMFG_NOMINAL_DIAMETER: Nominal diameter of the machined featureMFG_JUMP_DIST: Jump distance
Computed parameters are as follows (see Figure 4 above):
MFG_DETAIL_DEPTH: Hole depth that is effectively machined.MFG_TOTAL_DEPTH: Total depth machined by the operation. This includes the hole depth and breakthrough.MFG_PLUNGE_DIST: Whatever the selected plunge mode (by Tip or by Diameter), this parameter returns the plunge distance. The plunge offset is taken into account in this value.MFG_CMP_DWL_TIME: Computed dwell delay (in time units of seconds): this parameter is computed if dwell mode is set to 'revolutions'. Otherwise, the dwell time is returned as is.
Default syntax: CYCLE/CSINK,%MFG_TOTAL_DEPTH,%MFG_CLEAR_TIP
NC_DEEPHOLE
General parameters are as follows:
MFG_MO_TYPE: Machining operation typeMFG_MO_IDENTIFIER: Machining operation name or identifierMFG_PATTERN_NAME: Machining pattern name.
Feeds and Speeds parameters are as follows:
MFG_FEED_APP_MODE: Approach feedrate mode (0: Value / 1: Rapid)MFG_FEED_APP_VALUE and MFG_FEED_APPRCH (compatibility V4): Approach feedrateMFG_FEED_PLUNGE_MODE and MFG_FEED_PL_TYPE (compatibility V4): Plunge feedrate mode (0: Value / 1: Rapid)MFG_FEED_PLUNGE_VALUE and MFG_PLUNGE_FEED (compatibility V4): Plunge feedrateMFG_FEED_MACH_VALUE and MFG_FEED_MACH (compatibility V4): Machining feedrateMFG_SPINDLE_MACH_VALUE and MFG_SPNDL_MACH (compatibility V4): Machining spindle speedMFG_FEED_RETRACT_MODE and MFG_FEED_RT_TYPE (compatibility V4): Retract feedrate mode (0: Value / 1: Rapid)MFG_FEED_RETRACT_VALUE and MFG_FEED_RETRACT (compatibility V4): Retract feedrateMFG_FEED_UNIT: Feedrate unitMFG_SPNDL_UNIT: Spindle speed unit
Machining Strategy parameters are as follows:
MFG_CLEAR_TIP: Approach clearanceMFG_DEPTH_MODE: Depth mode (1: Tip / 2: Shoulder)MFG_BREAKTHROUGH: Breakthrough distanceMFG_PLUNGE_MODE: Plunge mode (0: None / 1: Tip / 3: Diameter)MFG_PLUNGE_TIP: Plunge tip distanceMFG_PLUNGE_OFFST: Plunge tip offsetMFG_PLUNGE_DIAMETER: Plunge diameterMFG_DWELL_MODE: Dwell mode (0: None / 1: By revolutions / 2: By time)MFG_DWELL_REVOL: Dwell delay in revolutionsMFG_DWELL_TIME: Dwell delay in time units (seconds)MFG_AXIAL_DEPTH: Maximum depth of cutMFG_OFFSET_RET: Retract offset MFG_DEPTH_DEC: Decrement rate MFG_DEPTH_LIM: Decrement limit MFG_TOOL_COMP and MFG_TL_COMP (compatibility V4): Length number of current correctorMFG_TOOL_COMP_1: Length number of first correctorMFG_TOOL_COMP_DIST: Distance between the position of the current corrector and the tool tipMFG_TOOL_COMP_DIST_1: Distance between the position of the first corrector and the tool tip
Geometry parameters are as follows:
MFG_DIAMETER: Nominal diameter of the toolMFG_NOMINAL_DIAMETER: Nominal diameter of the machined featureMFG_JUMP_DIST: Jump distance
Computed parameters are as follows (see Figure 1 and Figure 2 above):
MFG_DETAIL_DEPTH: Hole depth that is effectively machined.MFG_TOTAL_DEPTH: Total depth machined by the operation. This includes the hole depth, breakthrough, and tool tip length.MFG_PLUNGE_DIST: Whatever the selected plunge mode (by Tip or by Diameter), this parameter returns the plunge distance. The plunge offset is taken into account in this value.MFG_CMP_DWL_TIME: Computed dwell delay (in time units of seconds): this parameter is computed if dwell mode is set to 'revolutions'. Otherwise, the dwell time is returned as is.MFG_EFFCT_DEPTH: Effective depth (= Maximum depth of cut)
Default syntax: CYCLE/DEEPHL,%MFG_TOTAL_DEPTH,%MFG_CLEAR_TIP
NC_DRILLING
General parameters are as follows:
MFG_MO_TYPE: Machining operation typeMFG_MO_IDENTIFIER: Machining operation name or identifierMFG_PATTERN_NAME: Machining pattern name.
Feeds and Speeds parameters are as follows:
MFG_FEED_APP_MODE: Approach feedrate mode (0: Value / 1: Rapid)
MFG_FEED_APP_VALUE and MFG_FEED_APPRCH (compatibility V4): Approach feedrateMFG_FEED_PLUNGE_MODE and MFG_FEED_PL_TYPE (compatibility V4): Plunge feedrate mode (0: Value / 1: Rapid)MFG_FEED_PLUNGE_VALUE and MFG_PLUNGE_FEED (compatibility V4): Plunge feedrateMFG_FEED_MACH_VALUE and MFG_FEED_MACH (compatibility V4): Machining feedrateMFG_SPINDLE_MACH_VALUE and MFG_SPNDL_MACH (compatibility V4): Machining spindle speedMFG_FEED_RETRACT_MODE and MFG_FEED_RT_TYPE (compatibility V4): Retract feedrate mode (0: Value / 1: Rapid)MFG_FEED_RETRACT_VALUE and MFG_FEED_RETRACT (compatibility V4): Retract feedrateMFG_FEED_UNIT: Feedrate unitMFG_SPNDL_UNIT: Spindle speed unit
Machining Strategy parameters are as follows:
MFG_CLEAR_TIP: Approach clearanceMFG_DEPTH_MODE: Depth mode (1: Tip / 2: Shoulder)MFG_BREAKTHROUGH: Breakthrough distanceMFG_PLUNGE_MODE: Plunge mode (0: None / 1: Tip / 3: Diameter)MFG_PLUNGE_TIP: Plunge tip distanceMFG_PLUNGE_OFFST: Plunge tip offsetMFG_PLUNGE_DIAMETER: Plunge diameterMFG_TOOL_COMP and MFG_TL_COMP (compatibility V4): Length number of current correctorMFG_TOOL_COMP_1: Length number of first correctorMFG_TOOL_COMP_DIST: Distance between the position of the current corrector and the tool tipMFG_TOOL_COMP_DIST_1: Distance between the position of the first corrector and the tool tip
Geometry parameters are as follows:
MFG_DIAMETER: Nominal diameter of the toolMFG_NOMINAL_DIAMETER: Nominal diameter of the machined featureMFG_JUMP_DIST: Jump distance
Computed parameters are as follows (see Figure 1 and Figure 2 above):
MFG_DETAIL_DEPTH: Hole depth that is effectively machined.MFG_TOTAL_DEPTH: Total depth machined by the operation. This includes the hole depth, breakthrough, and tool tip length.MFG_PLUNGE_DIST: Whatever the selected plunge mode (by Tip or by Diameter), this parameter returns the plunge distance. The plunge offset is taken into account in this value.
Default syntax: CYCLE/DRILL,%MFG_TOTAL_DEPTH,%MFG_CLEAR_TIP,%MFG_FEED_MACH,&MFG_FEED_UNIT
NC_DRILLING_DWELL_DELAY
General parameters are as follows:
MFG_MO_TYPE: Machining operation typeMFG_MO_IDENTIFIER: Machining operation name or identifierMFG_PATTERN_NAME: Machining pattern name.
Feeds and Speeds parameters are as follows:
MFG_FEED_APP_MODE: Approach feedrate mode (0: Value / 1: Rapid)MFG_FEED_APP_VALUE and MFG_FEED_APPRCH (compatibility V4): Approach feedrateMFG_FEED_PLUNGE_MODE and MFG_FEED_PL_TYPE (compatibility V4): Plunge feedrate mode (0: Value / 1: Rapid)MFG_FEED_PLUNGE_VALUE and MFG_PLUNGE_FEED (compatibility V4): Plunge feedrateMFG_FEED_MACH_VALUE and MFG_FEED_MACH (compatibility V4): Machining feedrateMFG_SPINDLE_MACH_VALUE and MFG_SPNDL_MACH (compatibility V4): Machining spindle speedMFG_FEED_RETRACT_MODE and MFG_FEED_RT_TYPE (compatibility V4): Retract feedrate mode (0: Value / 1: Rapid)MFG_FEED_RETRACT_VALUE and MFG_FEED_RETRACT (compatibility V4): Retract feedrateMFG_FEED_UNIT: Feedrate unitMFG_SPNDL_UNIT: Spindle speed unit
Machining Strategy parameters are as follows:
MFG_CLEAR_TIP: Approach clearanceMFG_DEPTH_MODE: Depth mode (1: Tip / 2: Shoulder)MFG_BREAKTHROUGH: Breakthrough distanceMFG_PLUNGE_MODE: Plunge mode (0: None / 1: Tip / 3: Diameter)MFG_PLUNGE_TIP: Plunge tip distanceMFG_PLUNGE_OFFST: Plunge tip offsetMFG_PLUNGE_DIAMETER: Plunge diameterMFG_DWELL_MODE: Dwell mode (0: None / 1: By revolutions / 2: By time)MFG_DWELL_REVOL: Dwell delay in revolutionsMFG_DWELL_TIME: Dwell delay in time units (seconds)MFG_TOOL_COMP and MFG_TL_COMP (compatibility V4): Length number of current correctorMFG_TOOL_COMP_1: Length number of first correctorMFG_TOOL_COMP_DIST: Distance between the position of the current corrector and the tool tipMFG_TOOL_COMP_DIST_1: Distance between the position of the first corrector and the tool tip
Geometry parameters are as follows:
MFG_DIAMETER: Nominal diameter of the toolMFG_NOMINAL_DIAMETER: Nominal diameter of the machined featureMFG_JUMP_DIST: Jump distance
Computed parameters are as follows (see Figure 1 and Figure 2 above):
MFG_DETAIL_DEPTH: Hole depth that is effectively machined.MFG_TOTAL_DEPTH: Total depth machined by the operation. This includes the hole depth, breakthrough, and tool tip length.MFG_PLUNGE_DIST: Whatever the selected plunge mode (by Tip or by Diameter), this parameter returns the plunge distance. The plunge offset is taken into account in this value.MFG_CMP_DWL_TIME: Computed dwell delay (in time units of seconds): this parameter is computed if dwell mode is set to 'revolutions'. Otherwise, the dwell time is returned as is.
Default syntax: CYCLE/DRILL,%MFG_TOTAL_DEPTH,%MFG_CLEAR_TIP
NC_LATHE_THREADING
General parameters are as follows:
MFG_MO_TYPE: Machining operation typeMFG_MO_IDENTIFIER: Machining operation name or identifier.
Machining Strategy parameters are as follows:
MFG_THREAD_MACHINING: Machining type (1: Constant depth / 2: Section of cut)MFG_THREAD_PENETRATION: Penetration (1: Straight / 2: Flank / 3: Alternate)MFG_THREAD_UNIT: Unit (1: Pitch / 2: Thread per inch)MFG_THREAD_PROFILE: Profile (1: ISO / 2: Trapezoidal / 3: UNC / 4: Gaz)
MFG_THREAD_PITCH: Thread pitch MFG_NUM_THREADS: Number of threads MFG_THRD_PER_UNIT: Threads per inch
MFG_FIR_PATH: Boolean for first passes (0: No / 1: Yes)MFG_LAS_PATH: Boolean for last passes (0: No / 1: Yes)MFG_SPR_PATH: Boolean for spring passes (0: No / 1: Yes)MFG_NUM_FIR_PATH: Number of first passes MFG_NUM_LAS_PATH: Number of last passesMFG_NUM_SPR_PATH: Number of spring passesMFG_FIR_SECT_CUT: Section of cut for first passes MFG_LAS_DEPT_CUT: Depth of cut for last passes MFG_FIR_SECT_RAT: Section ratio between first passes and next passes
MFG_CRES_DIA_CLR: Clearance on crest diameter MFG_ENTER_ANG: Entry angle MFG_LEAD_IN_DIST: Lead-in distance MFG_LIFT_OFF_ANG: Lift-off angle MFG_LIFT_OFF_DIS: Lift-off distance
MFG_SPNDL_UNIT: list with two values defining the spindle rotation units.First value: spindle rotation expressed in revolutions per minute. RPM is the default value.Second value: spindle rotation expressed in surface meters per minute. SMM is the default value.MFG_SPNDL_WAY: list with two values defining the direction of rotation of the spindle.First value: spindle rotation processed clockwise. CLW is the default value.Second value: spindle rotation processed counter-clockwise. CCLW is the default value.MFG_SPNDL_SPEED: numerical value of the spindle speed.
Computed parameters are as follows:
MFG_ST_THRD_AX: Axial coordinate of the start thread on the crest. MFG_ST_THRD_RAD: Radial coordinate of the start thread on the crest. MFG_END_THRD_AX: Axial coordinate of the end thread on the crest. MFG_END_THRD_RAD: Radial coordinate of the end thread on the crest. MFG_END_THRD1_AX: Axial coordinate of the end thread on the root. MFG_END_THRD1_RAD: Radial coordinate of the end thread on the root. MFG_THRD_DEL_RAD: Depth of thread according to the radial axis.MFG_THRD_ANG: Angle of the thread. If different from zero, this angle indicates a conical thread. MFG_NOM_DIAM: Nominal diameter of the thread. MFG_THRD_LENGTH: Length of the thread. MFG_NB_PATH: Number of passes. First, last and spring passes are not included. MFG_DEPTH_CUT: Depth of cut. MFG_SECTION_CUT: Section of cut for passes that follow the first passes. MFG_THREAD_DEPTH: Depth of thread.
Default syntax: CYCLE/THREAD,%MFG_THREAD_PITCH
NC_REAMING
General parameters are as follows:
MFG_MO_TYPE: Machining operation typeMFG_MO_IDENTIFIER: Machining operation name or identifierMFG_PATTERN_NAME: Machining pattern name.
Feeds and Speeds parameters are as follows:
MFG_FEED_APP_MODE: Approach feedrate mode (0: Value / 1: Rapid)MFG_FEED_APP_VALUE and MFG_FEED_APPRCH (compatibility V4): Approach feedrateMFG_FEED_PLUNGE_MODE and MFG_FEED_PL_TYPE (compatibility V4): Plunge feedrate mode (0: Value / 1: Rapid)MFG_FEED_PLUNGE_VALUE and MFG_PLUNGE_FEED (compatibility V4): Plunge feedrateMFG_FEED_MACH_VALUE and MFG_FEED_MACH (compatibility V4): Machining feedrateMFG_SPINDLE_MACH_VALUE and MFG_SPNDL_MACH (compatibility V4): Machining spindle speedMFG_FEED_RETRACT_MODE and MFG_FEED_RT_TYPE (compatibility V4): Retract feedrate mode (0: Value / 1: Rapid)MFG_FEED_RETRACT_VALUE and MFG_FEED_RETRACT (compatibility V4): Retract feedrateMFG_FEED_UNIT: Feedrate unitMFG_SPNDL_UNIT: Spindle speed unit
Machining Strategy parameters are as follows:
MFG_CLEAR_TIP: Approach clearanceMFG_DEPTH_MODE: Depth mode (1: Tip / 2: Shoulder)MFG_BREAKTHROUGH: Breakthrough distanceMFG_PLUNGE_MODE: Plunge mode (0: None / 1: Tip / 3: Diameter)MFG_PLUNGE_TIP: Plunge tip distanceMFG_PLUNGE_OFFST: Plunge tip offset
MFG_PLUNGE_DIAMETER: Plunge diameterMFG_DWELL_MODE: Dwell mode (0: None / 1: By revolutions / 2: By time)MFG_DWELL_REVOL: Dwell delay in revolutionsMFG_DWELL_TIME: Dwell delay in time units (seconds)MFG_TOOL_COMP and MFG_TL_COMP (compatibility V4): Length number of current correctorMFG_TOOL_COMP_1: Length number of first correctorMFG_TOOL_COMP_DIST: Distance between the position of the current corrector and the tool tipMFG_TOOL_COMP_DIST_1: Distance between the position of the first corrector and the tool tip
Geometry parameters are as follows:
MFG_DIAMETER: Nominal diameter of the toolMFG_NOMINAL_DIAMETER: Nominal diameter of the machined featureMFG_JUMP_DIST: Jump distance
Computed parameters are as follows (see Figure 1 and Figure 2 above):
MFG_DETAIL_DEPTH: Hole depth that is effectively machined.MFG_TOTAL_DEPTH: Total depth machined by the operation. This includes the hole depth, breakthrough, and tool tip length.MFG_PLUNGE_DIST: Whatever the selected plunge mode (by Tip or by Diameter), this parameter returns the plunge distance. The plunge offset is taken into account in this value.MFG_CMP_DWL_TIME: Computed dwell delay (in time units of seconds): this parameter is computed if dwell mode is set to 'revolutions'. Otherwise, the dwell time is returned as is.
Default syntax: CYCLE/REAM,%MFG_TOTAL_DEPTH,%MFG_CLEAR_TIP
NC_REVERSE_THREADING
General parameters are as follows:
MFG_MO_TYPE: Machining operation typeMFG_MO_IDENTIFIER: Machining operation name or identifierMFG_PATTERN_NAME: Machining pattern name.
Feeds and Speeds parameters are as follows:
MFG_FEED_APP_MODE: Approach feedrate mode (0: Value / 1: Rapid)MFG_FEED_APP_VALUE and MFG_FEED_APPRCH (compatibility V4): Approach feedrateMFG_FEED_PLUNGE_MODE and MFG_FEED_PL_TYPE (compatibility V4): Plunge feedrate mode (0: Value / 1: Rapid)MFG_FEED_PLUNGE_VALUE and MFG_PLUNGE_FEED (compatibility V4): Plunge feedrateMFG_FEED_MACH_VALUE and MFG_FEED_MACH (compatibility V4): Machining feedrateMFG_SPINDLE_MACH_VALUE and MFG_SPNDL_MACH (compatibility V4): Machining spindle speedMFG_FEED_RETRACT_MODE and MFG_FEED_RT_TYPE (compatibility V4): Retract feedrate mode (0: Value / 1: Rapid)MFG_FEED_RETRACT_VALUE and MFG_FEED_RETRACT (compatibility V4): Retract feedrateMFG_FEED_UNIT: Feedrate unitMFG_SPNDL_UNIT: Spindle speed unit
Machining Strategy parameters are as follows:
MFG_CLEAR_TIP: Approach clearanceMFG_DEPTH_MODE: Depth mode (1: Tip / 2: Shoulder)MFG_BREAKTHROUGH: Breakthrough distanceMFG_PLUNGE_MODE: Plunge mode (0: None / 1: Tip)MFG_PLUNGE_TIP: Plunge tip distanceMFG_PLUNGE_OFFST: Plunge tip offsetMFG_TOOL_COMP and MFG_TL_COMP (compatibility V4): Length number of current correctorMFG_TOOL_COMP_1: Length number of first correctorMFG_TOOL_COMP_DIST: Distance between the position of the current corrector and the tool tipMFG_TOOL_COMP_DIST_1: Distance between the position of the first corrector and the tool tip
Geometry parameters are as follows:
MFG_DIAMETER: Internal diameter of the toolMFG_THREAD_DIAMETER: Nominal diameter of the toolMFG_JUMP_DIST: Jump distance
Computed parameters are as follows (see Figure 1 and Figure 2 above):
MFG_DETAIL_DEPTH: Hole depth that is effectively machined.MFG_TOTAL_DEPTH: Total depth machined by the operation. This includes the hole depth, breakthrough, and tool tip length.MFG_PLUNGE_DIST: This parameter returns the plunge distance. The plunge offset is taken into account in this value.MFG_TOOL_PITCH: Pitch value defined on tool.
Default syntax: CYCLE/TAP,%MFG_TOTAL_DEPTH,%MFG_CLEAR_TIP
NC_SPOT_DRILLING
General parameters are as follows:
MFG_MO_TYPE: Machining operation typeMFG_MO_IDENTIFIER: Machining operation name or identifierMFG_PATTERN_NAME: Machining pattern name.
Feeds and Speeds parameters are as follows:
MFG_FEED_APP_MODE: Approach feedrate mode (0: Value / 1: Rapid)MFG_FEED_APP_VALUE and MFG_FEED_APPRCH (compatibility V4): Approach feedrateMFG_FEED_PLUNGE_MODE and MFG_FEED_PL_TYPE (compatibility V4): Plunge feedrate mode (0: Value / 1: Rapid)MFG_FEED_PLUNGE_VALUE and MFG_PLUNGE_FEED (compatibility V4): Plunge feedrateMFG_FEED_MACH_VALUE and MFG_FEED_MACH (compatibility V4): Machining feedrateMFG_SPINDLE_MACH_VALUE and MFG_SPNDL_MACH (compatibility V4): Machining spindle speedMFG_FEED_RETRACT_MODE and MFG_FEED_RT_TYPE (compatibility V4): Retract feedrate mode (0: Value / 1: Rapid)MFG_FEED_RETRACT_VALUE and MFG_FEED_RETRACT (compatibility V4): Retract feedrateMFG_FEED_UNIT: Feedrate unitMFG_SPNDL_UNIT: Spindle speed unit
Machining Strategy parameters are as follows:
MFG_CLEAR_TIP: Approach clearanceMFG_DEPTH_MODE: Depth mode (1: Tip / 2: Shoulder). See Figure 3 above.MFG_BREAKTHROUGH: Breakthrough distance MFG_PLUNGE_MODE: Plunge mode (0: None / 1: Tip / 3: Diameter). MFG_PLUNGE_TIP: Plunge tip distanceMFG_PLUNGE_OFFST: Plunge tip offsetMFG_PLUNGE_DIAMETER: Plunge diameterMFG_DWELL_MODE: Dwell mode (0: None / 1: By revolutions / 2: By time)MFG_DWELL_REVOL: Dwell delay in revolutionsMFG_DWELL_TIME: Dwell delay in time units (seconds)MFG_TOOL_COMP and MFG_TL_COMP (compatibility V4): Length number of current correctorMFG_TOOL_COMP_1: Length number of first correctorMFG_TOOL_COMP_DIST: Distance between the position of the current corrector and the tool tipMFG_TOOL_COMP_DIST_1: Distance between the position of the first corrector and the tool tip
Geometry parameters are as follows:
MFG_DIAMETER: Chamfer diameterMFG_JUMP_DIST: Jump distance
Computed parameters are as follows (see Figure 3 above):
MFG_DETAIL_DEPTH: Hole depth that is effectively machined.MFG_TOTAL_DEPTH: Total depth machined by the operation. This includes the hole depth and plunge distance.MFG_PLUNGE_DIST: Whatever the selected plunge mode (by Tip or by Diameter), this parameter returns the plunge distance. The plunge offset is taken into account in this value.MFG_CMP_DWL_TIME: Computed dwell delay (in time units of seconds): this parameter is computed if dwell mode is set to 'revolutions'. Otherwise, the dwell time is returned as is.
Default syntax: CYCLE/DRILL,%MFG_TOTAL_DEPTH,%MFG_CLEAR_TIP
NC_T_SLOTTING
General parameters are as follows:
MFG_MO_TYPE: Machining operation typeMFG_MO_IDENTIFIER: Machining operation name or identifierMFG_PATTERN_NAME: Machining pattern name.
Feeds and Speeds parameters are as follows:
MFG_FEED_APP_MODE: Approach feedrate mode (0: Value / 1: Rapid)MFG_FEED_APP_VALUE and MFG_FEED_APPRCH (compatibility V4): Approach feedrateMFG_FEED_PLUNGE_MODE and MFG_FEED_PL_TYPE (compatibility V4): Plunge feedrate mode (0: Value / 1: Rapid)MFG_FEED_PLUNGE_VALUE and MFG_PLUNGE_FEED (compatibility V4): Plunge feedrateMFG_FEED_MACH_VALUE and MFG_FEED_MACH (compatibility V4): Machining feedrateMFG_SPINDLE_MACH_VALUE and MFG_SPNDL_MACH (compatibility V4): Machining spindle speedMFG_FEED_RETRACT_MODE and MFG_FEED_RT_TYPE (compatibility V4): Retract feedrate mode (0: Value / 1: Rapid)MFG_FEED_RETRACT_VALUE and MFG_FEED_RETRACT (compatibility V4): Retract feedrateMFG_FEED_UNIT: Feedrate unitMFG_SPNDL_UNIT: Spindle speed unit
Machining Strategy parameters are as follows:
MFG_CLEAR_TIP: Approach clearanceMFG_DEPTH_MODE: Depth mode (1: Tip)MFG_DWELL_MODE: Dwell mode (0: None / 1: By revolutions / 2: By time)MFG_DWELL_REVOL: Dwell delay in revolutionsMFG_DWELL_TIME: Dwell delay in time units (seconds)MFG_TOOL_COMP and MFG_TL_COMP (compatibility V4): Length number of current correctorMFG_TOOL_COMP_1: Length number of first correctorMFG_TOOL_COMP_DIST: Distance between the position of the current corrector and the tool tipMFG_TOOL_COMP_DIST_1: Distance between the position of the first corrector and the tool tip
Geometry parameters are as follows:
MFG_DIAMETER: Slot diameterMFG_NOMINAL_DIAMETER: Nominal diameter of the machined featureMFG_LENGTH: Slot height (= Tool length, which is read on tool)MFG_JUMP_DIST: Jump distance
Computed parameters are as follows (see Figure 1 and Figure 2 above):
MFG_DETAIL_DEPTH: Hole depth that is effectively machined.MFG_TOTAL_DEPTH: Total depth machined by the operation. This includes the hole depth, breakthrough, and tool tip length.MFG_CMP_DWL_TIME: Computed dwell delay (in time units of seconds): this parameter is computed if dwell mode is set to 'revolutions'. Otherwise, the dwell time is returned as is.
Default syntax: CYCLE/TSLOT,%MFG_TOTAL_DEPTH,%MFG_CLEAR_TIP
NC_TAPPING
General parameters are as follows:
MFG_MO_TYPE: Machining operation typeMFG_MO_IDENTIFIER: Machining operation name or identifierMFG_PATTERN_NAME: Machining pattern name.
Feeds and Speeds parameters are as follows:
MFG_FEED_APP_MODE: Approach feedrate mode (0: Value / 1: Rapid)MFG_FEED_APP_VALUE and MFG_FEED_APPRCH (compatibility V4): Approach feedrateMFG_FEED_PLUNGE_MODE and MFG_FEED_PL_TYPE (compatibility V4): Plunge feedrate mode (0: Value / 1: Rapid)MFG_FEED_PLUNGE_VALUE and MFG_PLUNGE_FEED (compatibility V4): Plunge feedrateMFG_FEED_MACH_VALUE and MFG_FEED_MACH (compatibility V4): Machining feedrateMFG_SPINDLE_MACH_VALUE and MFG_SPNDL_MACH (compatibility V4): Machining spindle speedMFG_FEED_RETRACT_MODE and MFG_FEED_RT_TYPE (compatibility V4): Retract feedrate mode (0: Value / 1: Rapid)MFG_FEED_RETRACT_VALUE and MFG_FEED_RETRACT (compatibility V4): Retract feedrateMFG_FEED_UNIT: Feedrate unitMFG_SPNDL_UNIT: Spindle speed unit
Machining Strategy parameters are as follows:
MFG_CLEAR_TIP: Approach clearanceMFG_DEPTH_MODE: Depth mode (1: Tip / 2: Shoulder)MFG_BREAKTHROUGH: Breakthrough distanceMFG_PLUNGE_MODE: Plunge mode (0: None / 1: Tip)MFG_PLUNGE_TIP: Plunge tip distanceMFG_PLUNGE_OFFST: Plunge tip offsetMFG_TOOL_COMP and MFG_TL_COMP (compatibility V4): Length number of current correctorMFG_TOOL_COMP_1: Length number of first correctorMFG_TOOL_COMP_DIST: Distance between the position of the current corrector and the tool tipMFG_TOOL_COMP_DIST_1: Distance between the position of the first corrector and the tool tip
Geometry parameters are as follows:
MFG_DIAMETER: Internal diameter of the toolMFG_THREAD_DIAMETER: Nominal diameter of the toolMFG_JUMP_DIST: Jump distance
Computed parameters are as follows (see Figure 1 and Figure 2 above):
MFG_DETAIL_DEPTH: Hole depth that is effectively machined.MFG_TOTAL_DEPTH: Total depth machined by the operation. This includes the hole depth, breakthrough, and tool tip length.MFG_PLUNGE_DIST: This parameter returns the plunge distance. The plunge offset is taken into account in this value.MFG_TOOL_PITCH: Pitch value defined on tool
Default syntax: CYCLE/TAP,%MFG_TOTAL_DEPTH,%MFG_CLEAR_TIP
NC_THREAD_WITHOUT_TAP_HEAD
General parameters are as follows:
MFG_MO_TYPE: Machining operation typeMFG_MO_IDENTIFIER: Machining operation name or identifierMFG_PATTERN_NAME: Machining pattern name.
Feeds and Speeds parameters are as follows:
MFG_FEED_APP_MODE: Approach feedrate mode (0: Value / 1: Rapid)MFG_FEED_APP_VALUE and MFG_FEED_APPRCH (compatibility V4): Approach feedrateMFG_FEED_PLUNGE_MODE and MFG_FEED_PL_TYPE (compatibility V4): Plunge feedrate mode (0: Value / 1: Rapid)MFG_FEED_PLUNGE_VALUE and MFG_PLUNGE_FEED (compatibility V4): Plunge feedrateMFG_FEED_MACH_VALUE and MFG_FEED_MACH (compatibility V4): Machining feedrateMFG_SPINDLE_MACH_VALUE and MFG_SPNDL_MACH (compatibility V4): Machining spindle speedMFG_FEED_RETRACT_MODE and MFG_FEED_RT_TYPE (compatibility V4): Retract feedrate mode (0: Value / 1: Rapid)MFG_FEED_RETRACT_VALUE and MFG_FEED_RETRACT (compatibility V4): Retract feedrateMFG_FEED_UNIT: Feedrate unitMFG_SPNDL_UNIT: Spindle speed unit
Machining Strategy parameters are as follows:
MFG_CLEAR_TIP: Approach clearanceMFG_DEPTH_MODE: Depth mode (1: Tip)MFG_BREAKTHROUGH: Breakthrough distanceMFG_PLUNGE_MODE: Plunge mode (0: None / 1: Tip)MFG_PLUNGE_TIP: Plunge tip distanceMFG_PLUNGE_OFFST: Plunge tip offsetMFG_TOOL_COMP and MFG_TL_COMP (compatibility V4): Length number of current correctorMFG_TOOL_COMP_1: Length number of first correctorMFG_TOOL_COMP_DIST: Distance between the position of the current corrector and the tool tipMFG_TOOL_COMP_DIST_1: Distance between the position of the first corrector and the tool tip
Geometry parameters are as follows:
MFG_DIAMETER: Hole internal diameterMFG_THREAD_DIAMETER: Tool nominal diameterMFG_JUMP_DIST: Jump distance
Computed parameters are as follows (see Figure 1 and Figure 2 above):
MFG_DETAIL_DEPTH: Hole depth that is effectively machined.MFG_TOTAL_DEPTH: Total depth machined by the operation. This includes the hole depth, breakthrough, and tool tip length.MFG_PLUNGE_DIST: This parameter returns the plunge distance. The plunge offset is taken into account in this value.
Default syntax: CYCLE/TAP,%MFG_TOTAL_DEPTH,%MFG_CLEAR_TIP
NC_THREAD_MILLING
General parameters are as follows:
MFG_MO_TYPE: Machining operation typeMFG_MO_IDENTIFIER: Machining operation name or identifierMFG_PATTERN_NAME: Machining pattern name.
Feeds and Speeds parameters are as follows:
MFG_FEED_APP_VALUE and MFG_FEED_APPRCH (compatibility V4): Approach feedrateMFG_FEED_MACH_VALUE and MFG_FEED_MACH (compatibility V4): Machining feedrateMFG_SPINDLE_MACH_VALUE and MFG_SPNDL_MACH (compatibility V4): Machining spindle speedMFG_FEED_RETRACT_VALUE and MFG_FEED_RETRACT (compatibility V4): Retract feedrateMFG_FEED_UNIT: Feedrate unitMFG_SPNDL_UNIT: Spindle speed unit
Machining Strategy parameters are as follows:
MFG_CLEAR_TIP: Approach clearanceMFG_BREAKTHROUGH: Breakthrough distanceMFG_TOOL_COMP and MFG_TL_COMP (compatibility V4): Length number of current corrector
MFG_TOOL_COMP_1: Length number of first correctorMFG_TOOL_COMP_DIST: Distance between the position of the current corrector and the tool tipMFG_TOOL_COMP_DIST_1: Distance between the position of the first corrector and the tool tip.
Geometry parameters are as follows:
MFG_DIAMETER: Hole internal diameterMFG_THREAD_DIAMETER: Hole nominal diameterMFG_PITCH: Thread pitchMFG_PITCH_SENS or MFG_PITCH_WAY_OF_ROT: Thread direction (1: Left-hand / 2: Right-hand) MFG_JUMP_DIST: Jump distance
Computed parameters are as follows (see Figure 1 and Figure 2 above):
MFG_DETAIL_DEPTH: Hole depth that is effectively machined.MFG_TOTAL_DEPTH: Total depth machined by the operation. This includes the hole depth, breakthrough, and tool tip length.MFG_TOOL_PITCH: Pitch value defined on tool
Default syntax: CYCLE/THREADMILLING,%MFG_TOTAL_DEPTH,%MFG_CLEAR_TIP
NC_TWO_SIDES_CHAMFERING
General parameters are as follows:
MFG_MO_TYPE: Machining operation typeMFG_MO_IDENTIFIER: Machining operation name or identifierMFG_PATTERN_NAME: Machining pattern name.
Feeds and Speeds parameters are as follows:
MFG_FEED_APP_MODE: Approach feedrate mode (0: Value / 1: Rapid)MFG_FEED_APP_VALUE and MFG_FEED_APPRCH (compatibility V4): Approach feedrateMFG_FEED_PLUNGE_MODE and MFG_FEED_PL_TYPE (compatibility V4): Plunge feedrate mode (0: Value / 1: Rapid)MFG_FEED_PLUNGE_VALUE and MFG_PLUNGE_FEED (compatibility V4): Plunge feedrateMFG_FEED_MACH_VALUE and MFG_FEED_MACH (compatibility V4): Machining feedrateMFG_SPINDLE_MACH_VALUE and MFG_SPNDL_MACH (compatibility V4): Machining spindle speedMFG_FEED_RETRACT_MODE and MFG_FEED_RT_TYPE (compatibility V4): Retract feedrate mode (0: Value / 1: Rapid)MFG_FEED_RETRACT_VALUE and MFG_FEED_RETRACT (compatibility V4): Retract feedrateMFG_FEED_UNIT: Feedrate unitMFG_SPNDL_UNIT: Spindle speed unit
Machining Strategy parameters are as follows:
MFG_CLEAR_TIP: Approach clearanceMFG_CLEAR_TIP_2: Second approach clearanceMFG_DEPTH_MODE: Depth mode (1: Tip)MFG_PLUNGE_MODE: Plunge mode (0: None / 1: Tip / 3: Diameter)MFG_PLUNGE_TIP: Plunge tip distanceMFG_PLUNGE_OFFST: Plunge tip offsetMFG_PLUNGE_DIAMETER: Plunge diameterMFG_DWELL_MODE: Dwell mode (0: None / 1: By revolutions / 2: By time)MFG_DWELL_REVOL: Dwell delay in revolutionsMFG_DWELL_TIME: Dwell delay in time units (seconds)MFG_TOOL_COMP and MFG_TL_COMP (compatibility V4): Length number of current correctorMFG_TOOL_COMP_1: Length number of first correctorMFG_TOOL_COMP_2: Length number of second correctorMFG_TOOL_COMP_DIST: Distance between the position of the current corrector and the tool tipMFG_TOOL_COMP_DIST_1: Distance between the position of the first corrector and the tool tipMFG_TOOL_COMP_DIST_2: Distance between the position of the second corrector and the tool tip
Geometry parameters are as follows:
MFG_DIAMETER: Chamfer diameterMFG_NOMINAL_DIAMETER: Nominal diameter of the machined featureMFG_JUMP_DIST: Jump distance
Computed parameters are as follows (see Figure 1 and Figure 2 above):
MFG_DETAIL_DEPTH: Hole depth that is effectively machined.MFG_TOTAL_DEPTH: Total depth machined by the operation. This includes the hole depth, breakthrough, and tool tip length.MFG_PLUNGE_DIST: Whatever the selected plunge mode (by Tip or by Diameter), this parameter returns the plunge distance. The plunge offset is taken into account in this value.MFG_CMP_DWL_TIME: Computed dwell delay (in time units of seconds): this parameter is computed if dwell mode is set to 'revolutions'. Otherwise, the dwell time is returned as is.
Default syntax: CYCLE/DRILL,%MFG_TOTAL_DEPTH,%MFG_CLEAR_TIP,%MFG_FEED_MACH,&MFG_FEED_UNIT
Feeds and SpeedsCutting conditions (feed/tooth and cutting speed) can be included in a tools catalog. This data is converted into machining feedrate and spindle speed parameters to be used in machining operations by means of formula.
For an example of such a tools catalog, see FeedsAndSpeeds.xls file delivered in the .../startup/Manufacturing/Samples folder.
Cutting conditions are also available in the Feeds & Speeds tab page of the Tool Definition dialog box.
In the Feeds and Speeds tab page of milling operations, the Rough or Finish quality of the operation and the tool data are taken into account for computing the feeds and speeds.
Cutting Conditions
The following cutting conditions data are supported: cutting speed (Vc), feedrate/tooth (Sz), and depth of cut.
Cutting conditions for drilling tools:
MFG_VC: cutting speed in mm/mnMFG_SZ: feedrate/tooth in mm/revMFG_PP: Depth of cut.
Roughing and Finishing cutting conditions for milling tools:
MFG_VC_FINISH: finishing cutting speed in mm/mnMFG_SZ_FINISH: finishing feedrate/tooth in mm/rev
MFG_VC_ROUGH: roughing cutting speed in mm/mnMFG_SZ_ROUGH: roughing feedrate/tooth in mm/rev.
Roughing and Finishing cutting conditions for lathe inserts:
MFG_VC_FINISH: finishing cutting speed in mm/mnMFG_SZ_FINISH: finishing feedrate/tooth in mm/revMFG_SZ_AA_FINISH: axial depth of cut for finishingMFG_SZ_AR_FINISH: axial depth of cut for finishing
MFG_VC_ROUGH: roughing cutting speed in mm/mnMFG_SZ_ROUGH: roughing feedrate/tooth in mm/revMFG_SZ_AA_ROUGH: axial depth of cut for roughingMFG_SZ_AR_ROUGH: axial depth of cut for roughing.
When a tool is selected for an operation, spindle speed (N) and machining feedrate (Vf) are computed using the following formula:
N (in rev/mn) = Vc / (D * PI)where:
D = tool diameter for milling/drilling in mmVc = cutting speed of the tool or insert.
For turning operations, N is automatically set in mm/min with the value of the insert's cutting speed.
Vf (in mm/rev) = Sz * N * Z where:Sz = feedrate/tooth on the toolN = spindle speed in rev/min Z = number of teeth on the tool (MFG_NB_OF_FLUTES) or 1 for a lathe insert.
Finishing data is used if the operation is finishing type (for example, Lathe Profile Finishing) or if it includes a finishing feedrate.
If the tool data is set to 0 (that is, if there are no specified values in the catalog), then spindle speed N and machining feedrate Vf are not computed on the operation.
Update of Feeds and Speeds on Machining Operation
Operation with a Tool
When you modify a Feeds and Speeds attribute on the tool, the Feeds and Speeds values of the operation are not automatically updated.
Feeds & speeds of the operation will be updated according to tooling feeds and speeds:
● when you select a new tool
● by selecting the Automatic Compute checkboxes in the Feeds and Speeds tab page of the operation
● by clicking the Compute button located in the Feeds and Speeds tab page of the operation
Two checkboxes allow operation Feeds and Speeds values to be updated automatically when Feeds and Speeds values of the tool are modified.
If they are checked then the Feeds and Speeds values of the operation will be updated when the Feeds and
Speeds values of the tool are modified.These two buttons will work separately: if Feedrate is checked and not Spindle then the only the Feedrate values will be computed.If they are not selected then automatic update will not be done.
When you modify the Feeds and Speeds values on a tool, all existing operations with these checkboxes selected that use this tool (or an assembly using this tool) will be recomputed.
The Compute button allows you to force the update of the operation values if one or both checkboxes are not selected.
The feed and speed values are computed according to the Quality setting on the operation.
The computation of the Feeds and Speeds of the operation depends on the Quality setting:
● Rough: rough values of the tool are taken into account
● Finish: finish values of the tool are taken into account
● Either: no computation will be done for the operation's Feeds and Speeds.
In Tools > Options > Machining > Resources, settings are available to define how the Automatic Compute checkboxes in the Feeds and Speeds tab page are to be initialized for creating new operations.
Operation without Tool
When a tool is selected for the machining operation, the operation is updated with the new tool's feeds and speeds data.
NC Data OptionsThis section gives a summary of the options that are used when generating NC data output in the various
formats. NC Data can be generated either in interactive or batch mode .
NC Data Option APT Clfile NC Code
CATProduct
Circular Interpolation...
Circular interpolationSpecifies the type of circles to be processed if circular interpolation is required:- From machine: uses the values specified by the part operation's machine- None: circular interpolation is not required- Z-axis circles: only circles whose axis is parallel to the z-axis of the machining axis system are processed- Any axis circles: all circle types are processed.Equivalent keyword for MfgBatch is *CIR
Yes Yes Yes Frommachine
Circle radius limitsSpecifies how circles are to be processed for circular interpolation:- From machine: the values specified by the part operation's machine are used- Value: user-defined values are used for minimum and maximum radius constraints.
Yes Yes Yes No
Minimum radiusSpecifies the value to be used for the minimum radius constraint for circular interpolation.If From machine was selected for the Circular interpolation option, the minimum radius value of the part operation's machine is used.
Yes Yes Yes No
Maximum radiusSpecifies the value to be used for the maximum radius constraint for circular interpolation.If From machine was selected for the Circular interpolation option, the maximum radius value of the part operation's machine is used.
Yes Yes Yes No
Circular record typeSpecifies the type of record to be generated on the clfile if circular interpolation is requested:- 3000 and 5000- 15000.
No Yes No No
Tool motions...
Home Point strategyYou can choose to include Home Point information in the NC data output by means of this option. In this case GOTO or FROM information defined on the part operation's machine is used. Equivalent keyword for MfgBatch is *HPM
Yes Yes Yes No
Include GOTO for tool change- Checkbox selected: a GOTO statement will be included before each tool change.- Checkbox not selected: a GOTO statement will not be included before each tool change.Equivalent keyword for MfgBatch is *RMT
Yes Yes Yes No
Output CYCLE syntax- Checkbox selected: the PP word syntax specified in the PP word table will be output for axial machining operations . - Checkbox not selected: GOTO statements will be generated in the NC data output. Equivalent keyword for MfgBatch is *STX
Yes Yes Yes No
Remove GOTO before cyclesFor axial machining operations using SYNTAX output mode (CYCLE), you can now choose whether or not to output GOTO statements corresponding to Jump and Clearance motions.- Checkbox selected: the following points are removed: points that were added by the clearance approach distancepoints that were added by the jump distance.- Checkbox not selected: the points are not removed.Equivalent keyword for MfgBatch is *GBC 1
Yes Yes Yes No
Process Copy and Tracut operationsSpecifies whether any Copy or Tracut instructions in the program are to be processed.- Checkbox selected: Copy and/or Tracut instructions will be processed. In this case there will be no Copy or Tracut statements remaining in the generated APT source.Equivalent keyword for MfgBatch is *APT 2- Checkbox not selected: Copy and/or Tracut instructions will not be processed. In this case there will be Copy or Tracut statements remaining in the generated APT source.Equivalent keyword for MfgBatch is *APT 1
Yes No No No
Remove double points after PP commandsYou can choose to keep or remove points that are repeated after PP statements.- Checkbox selected: First point after PP command or user syntax is not kept if the previous one is a coincident point.- Checkbox not selected: First point after PP command or user syntax is always kept.Equivalent keyword for MfgBatch is *PAC 1
Yes Yes Yes No
Remove aligned points- Checkbox selected: one or more points that are aligned between two other points will not be output.- Checkbox not selected: one or more points that are aligned between two other points will be output.Equivalent keyword for MfgBatch is *ALP 1
Yes Yes Yes No
Feedrates...
Use rapid feedrate value instead of RAPID syntaxDefines the formatting for rapid motions. - Checkbox selected: rapid motions will be preceded by a FEEDRATE syntax whose value is the Rapid feedrate specified on the machine.- Checkbox not selected: rapid motions will be preceded by a RAPID syntax.Equivalent keyword for MfgBatch is *RAP
Yes Yes Yes No
Set Rapid feedrate at start of operations- Checkbox selected: a RAPID statement will be included at the start of each operation. However, if a Clearance macro is defined on an operation, the macro definition will be taken into account. - Checkbox not selected: a RAPID statement will not be included at the start of each operation.Equivalent keyword for MfgBatch is *SRP
Yes Yes Yes No
Statements...
Tool motion statementDefines the format describing tool motion statements on the NC data output:- From machine: the output format defined the part operation's machine is used.- Point: tool point coordinates (x,y,z) are output. A TLAXIS statement is given at the start of the generated APT source.A fixed-axis clfile record 9000 is given at the start of the generated clfile.- Axis: tool point coordinates and tool axis components (x,y,z,i,j,k) are output.A MULTAX statement is given at the start of the generated APT source.A MULTAX clfile record 9000 is given at the start of the generated clfile.Equivalent keyword for MfgBatch is *FGO
Yes Yes Yes No
General information Defines how information such as tool names and operation sequence numbers will be generated.- None: not generatedEquivalent keyword for MfgBatch is *PPR 2xx- PPRINT: generated with the PPRINT wordEquivalent keyword for MfgBatch is *PPR 1xx- $$: generated as a comment (not available for clfile).Equivalent keyword for MfgBatch is *PPR 3xxwhere x is a number between 1 and 3 depending on other desired information ( see example ).
Yes Yesexcept
$$
Yesexcept
$$
No
Part operation commentsDefines how part operation comments will be generated.- None: not generatedEquivalent keyword for MfgBatch is *PPR x2x- PPRINT: generated with the PPRINT wordEquivalent keyword for MfgBatch is *PPR x1x- $$: generated as a comment (not available for clfile)Equivalent keyword for MfgBatch is *PPR x3xwhere x is a number between 1 and 3 depending on other desired information ( see example ) .
Yes Yesexcept
$$
Yesexcept
$$
No
Machining operation namesDefines how machining operation names will be generated.- None: not generatedEquivalent keyword for MfgBatch is *PPR xx2- PPRINT: generated with the PPRINT wordEquivalent keyword for MfgBatch is *PPR xx1- $$: generated as a comment (not available for clfile)Equivalent keyword for MfgBatch is *PPR xx3where x is a number between 1 and 3 depending on other desired information ( see example ) .
Yes Yesexcept
$$
Yesexcept
$$
No
Format for point coordinates...Allows you to define other formats for NC data statements allowing better accuracy for large parts.
Number of digits (N)Specifies the total number of digits for each point coordinate.
Digits after decimal (D)Specifies the number of digits after the decimal point for each point coordinate.
Equivalent keyword for MfgBatch is *NDX N.D
Yes No Yes No
Format for axial components...
Number of digits (N)Specifies the total number of digits for tool axis vector component.
Digits after decimal (D)Specifies the number of digits after the decimal point for tool axis vector component.
Equivalent keyword for MfgBatch is *NDI N.D
Yes No Yes No
APT FormatsThis section describes formats used to write NC data on APT source files.
Generated APT SyntaxesNURBS Formats in APT Output
APT Output ModificationsSyntaxes Interpreted by APT Import
Syntax of Generated APT InstructionsSyntax of APT Instructions generated by Machining products is described below. Blank characters used for presentation comfort on file are not mentioned.
Example of format:
'AUTOPS''INDIRV/',F11.5,',',F11.5,',',F11.5''TLON,GOFWD/ (CIRCLE/',F13.5,',',F13.5,',',F13.5,',$',T73,'CIR',I5F13.5,'),ON,2,INTOF,$''(LINE/',F13.5,',',F13.5,',',F13.5,',$'F13.5,',',F13.5,',',F13.5,')'
Example of generated APT source:
AUTOPSINDIRV/ 0.00000, -1.00000, 0.00000TLON,GOFWD/ (CIRCLE/ 0.00000, 0.00000, 0.00000,$ CIR 150.00000),ON,2,INTOF,$(LINE/ 0.00000, 0.00000, 0.00000,$50.00000, 0.00000, 0.00000)
General Information
'$$',6X,'GENERATED ON ',A28,' AT ',A8 start of execution (date, time)
Operation Numbers
'PPRINT OPERATION NUMBER: ',I4
'$$ OPERATION NUMBER: ',I4
operation order number in part operation
PP or APT Word Instruction
A80 PP instruction string
NC Axis Components
'$$*CATIA0''$$ ',A70'$$ ',4(F11.5,2X)'$$ ',4(F11.5,2X)'$$ ',4(F11.5,2X)
NC axis identifier (may be blank if table rotation operation).
NC axis matrix definition in absolute axis (*axis1)
Tool Axis Definition
'TLAXIS/'F9.6,2(',',F9.6) tool axis components expressed in machining axis system.
Multi-Axis Management
'MULTAX/ON'
'MULTAX/OFF'
Manages the output format of GOTO statements in a 5-axis program that mixes pure 5-axis operations and locked axis operations.(GOTO / X, Y, Z, I, J, K for pure 5-axis motions, and GOTO / X, Y, Z for locked axis motions).See MULTAX Influence on APT Source.
Starting Point Operation
'GOTO/',F11.5,2(',',F11.5),T73,'PT ',I5
'FROM/',F11.5,2(',',F11.5),T73,'PT ',I5
tool tip coordinates, point number
tool tip coordinates, point number
Tool Information - Mill
'CUTTER/',4(F10.6,','),F10.6,',$'F10.6,',',F10.6
cutter diameter, corner radius, distance center corner to tool axis, corner radius, 0.0, beta angle, height
Tool Information - Lathe
'CUTTER/',F10.6 nose radius
Tolerances
'INTOL /',F11.5
'OUTTOL/',F11.5
machining tolerance
0.0
Feedrate Values
'FEDRAT/',F10.4
'RAPID'
feedrate value
Linear Tool Motion
'GOTO/',F11.5,2(',',F11.5),T73,'PT ',I5
'GODLTA/',F11.5,2(',',F11.5),T73,'PT ',I5
tool tip coordinates, point number
tool tip incremental move, point number
Circular Tool Motion - CIRCLE/
'AUTOPS'
'INDIRV/',F11.5,',',F11.5,',',F11.5'
'TLON,GOFWD/ (CIRCLE/',F13.5,',',F13.5,',',F13.5,',$',T73,'CIR',I5
EITHER:
F13.5,'),ON,(LINE/',F13.5,',',F13.5,',',F13.5,',$' F13.5,',',F13.5,',',F13.5,')'
OR:
F13.5,'),ON,2,INTOF,$''(LINE/',F13.5,',',F13.5,',',F13.5,',$'F13.5,',',F13.5,',',F13.5,')'
-
components of circle tangent at arc start pt
circle center coords, circle number
radius, circle center coords,arc end point coords
radius,circle center coords,arc end point coords
Circular Tool Motion - CYLNDR/
'PSIS/(PLANE/(POINT/',F11.5,2(',',F11.5),'),PERPTO,$''(VECTOR/',2(F9.6,','),F9.6,'))'
'INDIRV/',F11.5,',',F11.5,',',F11.5
'TLON,GOFWD/(CYLNDR/',2(F11.5,','),F11.5,',$',T73,'CIR',I5
tool tip coordinates,circle axis components
components of tangent at arc start point
circle center coords, circle number
EITHER:
3(F11.5,','),F11.5,'),ON,$''(PLANE/PERPTO,$''(PLANE/(POINT/',F11.5,2(',',F11.5),'),PERPTO,$''(VECTOR/',2(F9.6,','),F9.6,')),$' '(POINT/',2(F11.5,','),F11.5,'),$''(POINT/',2(F11.5,','),F11.5,'))'
circle axis components, radius,circle center coordinates, circle axis components,circle center coordinates,arc end point coordinates
OR:
3(F11.5,','),F11.5,'),ON,2,INTOF,$''(PLANE/PERPTO,$''(PLANE/(POINT/',F11.5,2(',',F11.5),'),PERPTO,$''(VECTOR/',2(F9.6,','),F9.6,')),$''(POINT/',2(F11.5,','),F11.5,'),$''(POINT/',2(F11.5,','),F11.5,'))'
circle axis components, radius,circle center coordinates,circle axis components,circle center coordinates,arc end point coordinates
MULTAX Influence on APT Output
A MULTAX statement (MULTAX, MULTAX/ON, MULTAX/OFF) may be defined anywhere in the program (for example, in a PP word statement or a macro path).
MULTAX statements found during APT generation will influence the output format.
MULTAX statements are searched and identified in any PP word statement. If a MULTAX or MULTAX/ON statement is found, the following linear motions will be written with the format: GOTO/ X, Y, Z, I, J, K
If a MULTAX/OFF statement is found, the following linear motions will be written GOTO/ X, Y, Z and the tool axis will be considered as locked. The components of the locked tool axis are the components defined on the last 5-axis position preceding the MULTAX/OFF statement. Therefore, no TLAXIS statement is generated after a MULTAX/OFF statement.
In a sequence of motions following a MULTAX/OFF statement, the tool axis orientation is checked, and as soon as it is not constant, a MULTAX/ON statement will be added, possibly with a warning message in the log file.
Example of APT source:
...PPRINT OPERATION NAME : Tool ChangePPRINT Start generation of : Tool ChangeMULTAX/ONGOTO / 0.00000, 27.16535, 20.47244, 0.000000, 0.000000, 1.000000$$ TOOLCHANGEBEGINNINGCUTTER/ 1.259843, 0.000000, 0.629921, 0.000000, 0.000000,$0.000000, 0.984250$$ TOOLCHANGEENDPPRINT End of generation of : Tool Change...MULTAX/OFF...RAPIDGOTO / 7.29167, 15.48687, 16.10080RAPIDGOTO / 7.29167, 15.48687, 15.13780...MULTAX/ON...RAPIDGOTO / 2.74137, 14.56693, 16.10080, 0.000000, 0.000000, 1.000000
RAPIDGOTO / 2.74137, 14.56693, 15.13780, 0.000000, 0.000000, 1.000000...
Please note that the behavior previous to Release 12 was that MULTAX statements had no influence on the format of GOTO statements.
Non-Modal Behavior of RAPID Statements
According to APT standard formats, all feedrate statements (except RAPID) are modal. This means that they are applied on all following points until next the feedrate statement.
However, the RAPID instruction is not modal. This means that the RAPID statement is applied only on the next GOTO motion. For example in a linking macro with rapid feedrate, a RAPID instruction is written before each of the three GOTO points of the macro.
Another APT standard format rule that is specific to the RAPID word, is to not repeat unnecessarily the current machining feedrate after the last point in RAPID. The machining feedrate will be applied natively.
In the example below, rapid feedrate only applies to the 1st GOTO point. The machining feedrate that was current before the RAPID statement applies to the 2nd GOTO point:
FEDRAT/ 300.0000,MMPMGOTO / -69.00000, 40.00000, 46.00000GOTO / -69.00000, 50.00000, 0.00000RAPIDGOTO / -80.0000, -23.0000, 16.0000GOTO / -90.0000, -21.0000, 16.0000
NURBS Formats in APT OutputIt is possible to generate NC output files containing tool motion descriptions using a format based on NURBS technology for both fixed or variable axis programs.
This format is recognized by most new generation NC controllers (such as the Siemens 840D). It supports High Speed Milling (HSM) in order to reduce machining time and improve surface quality.
Examples of Fixed Axis and Variable Axis NURBS output statements that can be found in the generated APT file are given below.
Fixed Axis NURBS example:
BEGIN NURBS_SIEMENS(D=3,F=4000,AXIS=0.00,0.00,1.00);N0,XT= 0.000,YT=0.000,ZT=0.000,DK= 0.00,W=1.0;N1,XT=10.000,YT=0.000,ZT=0.000,DK= 0.00,W=1.0;N2,XT=20.000,YT=0.000,ZT=0.000,DK=30.00,W=1.0;N3,XT=30.000,YT=0.000,ZT=0.000,DK= 0.00,W=1.0;END NURBS;
Variable Axis NURBS example:
BEGIN NURBS_SIEMENS(D=3,F=4000,AXIS=VAR,LENGTH=100.00);N0,XT= 0.000,YT=0.000,ZT=0.000,XH= 0.000, $YH=0.000,ZH=100.00,DK= 0.00,W=1.0;N1,XT=10.000,YT=0.000,ZT=0.000,XH=10.000, $ YH=0.000,ZH=100.00,DK= 0.00,W=1.0;N2,XT=20.000,YT=0.000,ZT=0.000,XH=20.000, $YH=0.000,ZH=100.00,DK=30.00,W=1.0;N3,XT=30.000,YT=0.000,ZT=0.000,XH=30.000, $YH=0.000,ZH=100.00,DK= 0.00,W=1.0;END NURBS;
These statements are supported by some of the Post-Processors proposed under Tools > Options > Machining > Output for conversion to Siemens Nurbs/Bspline statements.
CATIA Version 5 APT Output Format
The fixed and variable axis NURBS output will be included in regular APT Catia output containing other classes of 3 or 5 axis tool motion statements. The most common of these statements are:
GOTO / x, y, z
GOTO / x, y, z, i, j, k
Sample:
GOTO / 0.00000, 89.19372, 12.00000
GOTO / 0.00000, 89.19372, 12.00000, 0.000000, 0.000000, 1.000000
Syntax
A Fixed Axis Catia NURBS for Siemens Output looks like this:
BEGIN NURBS_SIEMENS (D=3,F=8000.000,AXIS= 0.000000, 0.000000, 1.000000)N0, XT= 0.00000, YT= 89.19372, ZT= 12.00000,DK=0.000,W=1.000;N1, XT= -35.25923, YT= 82.30182, ZT= 12.00000,DK=0.000,W=1.000;N2, XT= -70.67279, YT= 76.14709, ZT= 12.00000,DK=107.790,W=1.000;N3, XT= -105.90481, YT= 69.14878, ZT= 12.00000,DK=0.000,W=1.000;END NURBS
A Variable Axis Catia NURBS for Siemens Output looks like this:
BEGIN NURBS_SIEMENS (D=3,F=8000.000,AXIS=VAR,LENGTH= 50.000)N0, XT= -75.76597, YT= 71.65094, ZT= -21.94567, XH= -72.178223, YH=$62.527376, ZH= 27.083796,DK=0.000,W=1.000;N1, XT= -78.91003, YT= 71.01919, ZT= -21.77676, XH= -79.690819, YH=$61.032142, ZH= 27.416003,DK=0.000,W=1.000;N2, XT= -82.06101, YT= 70.37700, ZT= -21.56199, XH= -87.244248, YH=$59.640659, ZH= 27.190920,DK=22.998,W=1.000;N3, XT= -85.40313, YT= 69.68892, ZT= -21.29975, XH= -94.767915, YH=$58.350206, ZH= 26.488684,DK=0.000,W=1.000;END NURBS
The number of digits used for each float value is not imposed. The $ character signifies that the instruction continues on the next line.
Mathematical and Geometrical Interpretation
D=Integer value: degree on the NURBS, means order-1, in most cases degree is 3 and order is 4.F=Float value: feedrate in mm per minute (Feedrate)LENGTH=Float value: distance (constant in the NURBS) between MT and MH control points.N=Integer value: rank of the control point in the NURBS, starts at 0 for the initial point.XT, YT, ZT=Float values:coordinates of the control point of the tool tip (MT).XH, YH, ZH=Float values:coordinate of the control point of a point on the tool axis (MH).DK=Float value:increment of nodal parameter related to this node (can be null, always >= 0.00).W= Float value: weight of the control point (in most cases it is set to 1.00 for all NURBS, which is Polynomial and not Rational in this case ).
We note (DKi), (Wi), (XTi,YTi,ZTi), (XHi,YHi,ZHi) for all the values related to the control point i, for i in [0,NB]. With all this data it is possible to define a NURBS function from [0.00,Kmax] to R6.Kmax = ΣDKi , for i=0 to NB.
The nodal vector (U(I)) of the NURBS contains NB+5 Values:U(0)=0.00U(1)=0.00And for I=2 to NB+3U(I)=U(I-1)+DK(I-2) (that is, U(2)=U(1)+DK(0)=0.00)thenU(NB+4) = U(NB+3) = KmaxU(NB+5) = U(NB+4)
In Fixed Axis mode, for each value of w in [0,Kmax] this function give 3 values: X(w), Y(w), Z(w), which are the control point coordinates of the tool tip at the w parameter.
In Variable Axis mode, for each value of w in [0,Kmax] this function give 6 values: XT(w), YT(w), ZT(w), XH(w), YH(w), ZH(w) which are the control point coordinates of the points MT=(XT,YT,ZT) and MH=(XH,YH,ZH).
MT is the position of the tool tip at the w parameter.MH is the position, at the w parameter, of the point on the tool axis located a distance LENGTH from MT. This length defines the active cutting part of the tool. This means that all transformations of the tool path must respect the machining tolerance (chordal deviation) for all points between MT and MH.
The first Tool position (XYZIJK) of the NURBS is:
X=XT0Y=YT0Z=ZT0I=(XH0-XT0)/LENGTHJ=(YH0-YT0)/LENGTHK=(ZH0-ZT0)/LENGTH.
Post Processing Considerations for Siemens 840D Format
Variable Axis Syntax
The format used by 840D is the following:
BEGIN NURBS_SIEMENS(D=3,F=xxxx,AXIS=VAR,LENGTH=100.00);N0,XT=xt0,YT=yt0,ZT=zt0,XH=xh0,YH=yh0,ZH=zh0,DK=dk0,W=w0;N1,XT=xt1,YT=yt1,ZT=zt1,XH=xh1,YH=yh1,ZH=zh1,DK=dk1,W=w1;N2,XT=xt2,YT=yt2,ZT=zt2,XH=xh2,YH=yh2,ZH=zh2,DK=dk2,W=w2;
../..Nn,XT=xtn,YT=ytn,ZT=ztn,XH=xhn,YH=yhn,ZH=zhn,DK=dkn,W=wn;END NURBS;
If previous Catia block is a NURBS block: SD=3 F xxxx ; NURBS degree and feedrate Otherwise: ORIVECT G1 X Y Z A3=I B3=J C3=K ; first point of the NURBS, Control Point 0Then: ORICURVE G642 ; start of continuous motion statement BSPLINE SD=3 F xxxx ; NURBS declaration, degree and feedrate X Y Z XH YH ZH PW=W PL=DK ; Control Point 1 X Y Z XH YH ZH PW=W PL=DK ; Control Point 2 ../.. X Y Z XH YH ZH PW=W PL=DK ; Last Control Point of the NURBS.
Translation from Catia Format
All parameters are the same as the one on the corresponding Catia line (i), except for the first one. If needed it is translated by a G1 statement.
Siemens Xi= Catia XTISiemens Yi= Catia YTISiemens Zi= Catia ZTISiemens XHi= Catia XHiSiemens YHi= Catia YHiSiemens ZHi= Catia ZHiSiemens PWi= Catia WiSiemens PLi= Catia DKi
APT Sample for Variable Axis NURBS
$$ -----------------------------------------------------------------$$ Generated on Wednesday, September 25, 2002 05:24:47 PM$$ CATIA APT VERSION 1.0$$ -----------------------------------------------------------------$$ Flank Mixed Combin$$ Part Operation.1$$*CATIA0$$ Flank Mixed Combin$$ 1.00000 0.00000 0.00000 0.00000$$ 0.00000 1.00000 0.00000 0.00000$$ 0.00000 0.00000 1.00000 0.00000PARTNO Part Operation.1FROM / 0.00000, 0.00000, 100.00000, 0.000000, 0.000000, 0.000000
PPRINT OPERATION NAME : Tool Change.10$$ Start generation of : Tool Change.10MULTAX$$ TOOLCHANGEBEGINNINGCUTTER/ 8.000000, 4.000000, 0.000000, 4.000000, 0.000000,$0.000000, 50.000000TOOLNO/2,MILL, 8.000000, 4.000000,, 100.000000,$60.000000,, 50.000000,4, 8000.000000,$MMPM,15000.000000,RPM,CLW,ON,$AUTO, 0.000000,NOTETPRINT/balld8,,balld8LOADTL/2,2,2$$ End of generation of : Tool Change.10PPRINT OPERATION NAME : Multi-Axis Flank Contouring.2$$ Start generation of : Multi-Axis Flank Contouring.2FEDRAT/ 8000.0000,MMPMSPINDL/15000.0000,RPM,CLWBEGIN NURBS_SIEMENS (D=3,F=8000.000,AXIS=VAR,LENGTH= 50.000)N0, XT= 19.75656, YT= 81.42861, ZT= 20.00000, XH= 19.757763, YH=$71.623025, ZH= 69.029078,DK=0.000,W=1.000;N1, XT= 19.75625, YT= 83.94658, ZT= 7.40984, XH= 19.757454, YH=$74.140998, ZH= 56.438918,DK=0.000,W=1.000;N2, XT= 19.75594, YT= 86.46456, ZT= -5.18032, XH= 19.757144, YH=$76.658971, ZH= 43.848757,DK=38.518,W=1.000;N3, XT= 19.75563, YT= 88.98253, ZT= -17.77048, XH= 19.756835, YH=$79.176944, ZH= 31.258597,DK=0.000,W=1.000;END NURBSBEGIN NURBS_SIEMENS (D=3,F=8000.000,AXIS=VAR,LENGTH= 50.000)N0, XT= 19.75563, YT= 88.98253, ZT= -17.77048, XH= 19.756835, YH=$79.176944, ZH= 31.258597,DK=0.000,W=1.000;N1, XT= 19.38827, YT= 89.96343, ZT= -23.02431, XH= 19.389475, YH=$80.157844, ZH= 26.004770,DK=0.000,W=1.000;N2, XT= 14.20175, YT= 89.85474, ZT= -27.41283, XH= 14.202952, YH=$80.049153, ZH= 21.616250,DK=15.662,W=1.000;N3, XT= 9.00010, YT= 88.77303, ZT= -26.95061, XH= 9.001309, YH=$78.967440, ZH= 22.078468,DK=0.000,W=1.000;END NURBS
../..
BEGIN NURBS_SIEMENS (D=3,F=8000.000,AXIS=VAR,LENGTH= 50.000)N0, XT= 19.18055, YT= -42.44969, ZT= -6.28780, XH= 19.180191, YH=$-37.474471, ZH= 43.464058,DK=0.000,W=1.000;N1, XT= 19.18049, YT= -41.57342, ZT= 2.47480, XH= 19.180128, YH=$-36.598205, ZH= 52.226657,DK=0.000,W=1.000;N2, XT= 19.18042, YT= -40.69716, ZT= 11.23740, XH= 19.180065, YH=$-35.721939, ZH= 60.989257,DK=26.419,W=1.000;N3, XT= 19.18036, YT= -39.82089, ZT= 20.00000, XH= 19.180002, YH=$-34.845674, ZH= 69.751856,DK=0.000,W=1.000;END NURBS$$ End of generation of : Multi-Axis Flank Contouring.2FINI
NC Code Sample for Variable Axis NURBS
N10 ;PROGRAMME : Part Operation.1N20 ;PROGRAMMEUR: AAU
N30 ;DATE : AAUG642ffwonN40 TRAORIG57M8N50 ORIVECTN60 G0 Z100.0N70 G0 X0.0 Y0.0N80 T2 M06N90 G1 X19.75656 Y81.42861 Z20.0 A3=0.00002 B3=-0.19611 C3=0.98058N100 ORICURVEN110 G642N120 BSPLINE SD=3 F8000.000N130 X19.75625 Y83.94658 Z7.40984 XH=19.75745 YH=74.141 ZH=56.43892 PL=0.0N140 X19.75594 Y86.46456 Z-5.18032 XH=19.75714 YH=76.65897 ZH=43.84876 PL=38.518N150 X19.75563 Y88.98253 Z-17.77048 XH=19.75683 YH=79.17694 ZH=31.2586 PL=0.0N160 X19.38827 Y89.96343 Z-23.02431 XH=19.38948 YH=80.15784 ZH=26.00477 PL=0.0N170 X14.20175 Y89.85474 Z-27.41283 XH=14.20295 YH=80.04915 ZH=21.61625 PL=15.662N180 X9.0001 Y88.77303 Z-26.95061 XH=9.00131 YH=78.96744 ZH=22.07847 PL=0.0
../..
N470 X19.19914 Y-42.982 Z-11.59413 XH=19.19878 YH=-38.00679 ZH=38.15773 PL=15.662N480 X19.18055 Y-42.44969 Z-6.2878 XH=19.18019 YH=-37.47447 ZH=43.46406 PL=0.0N490 X19.18049 Y-41.57342 Z2.4748 XH=19.18013 YH=-36.59821 ZH=52.22666 PL=0.0N500 X19.18042 Y-40.69716 Z11.2374 XH=19.18007 YH=-35.72194 ZH=60.98926 PL=26.419N510 X19.18036 Y-39.82089 Z20.0 XH=19.18 YH=-34.84567 ZH=69.75186 PL=0.0N520 ORIVECTN530 TRAFOOFN540 G57N550 M5 M9N560 M30
Fixed Axis Syntax
The format used by 840D is the following: Translation Convention.
BEGIN NURBS_SIEMENS(D=3,F=xxxx,AXIS=0.00,0.00,1.00);N0,X=x0,Y=y0,Z=z0,DK=dk0,W=w0;N1,X=x1,Y=y1,Z=z1,DK=dk1,W=w1;N2,X=x2,Y=y2,Z=z2,DK=dk2,W=w2;../..Nn,X=xn,Y=yn,Z=zn,DK=dkn,W=wn;END NURBS;
If previous Catia block is a NURBS Block: SD=3 F xxxx ; NURBS degree and feedrate Otherwise: G1 X Y Z ; first point of the NURBS, Control Point 0Then: G64 ; start of continuous motion statement BSPLINE SD=3 F xxxx ; NURBS declaration, degree and feedrate X Y Z PW=W PL=DK ; Control Point 1 X Y Z PW=W PL=DK ; Control Point 2
../.. X Y Z PW=W PL=DK ; Last Control Point of the NURBS
Translation from Catia Format
All parameters are the same as the one on the corresponding Catia line (i), except for the first one. If needed it is translated by a G1 statement.
Siemens Xi= Catia XiSiemens Yi= Catia YiSiemens Zi= Catia ZiSiemens PWi= Catia WiSiemens PLi= Catia DKi
APT Sample for Fixed Axis NURBS
$$ -----------------------------------------------------------------$$ Generated on Wednesday, September 25, 2002 05:24:29 PM$$ CATIA APT VERSION 1.0$$ -----------------------------------------------------------------$$ Manufacturing Program.7$$ Part Operation.1$$*CATIA0$$ Manufacturing Program.7$$ 1.00000 0.00000 0.00000 0.00000$$ 0.00000 1.00000 0.00000 0.00000$$ 0.00000 0.00000 1.00000 0.00000PARTNO Part Operation.1FROM / 0.00000, 0.00000, 100.00000PPRINT OPERATION NAME : Tool Change.14$$ Start generation of : Tool Change.14MULTAX$$ TOOLCHANGEBEGINNINGCUTTER/ 8.000000, 4.000000, 0.000000, 4.000000, 0.000000,$0.000000, 50.000000TOOLNO/2,MILL, 8.000000, 4.000000,, 100.000000,$60.000000,, 50.000000,4, 8000.000000,$MMPM,15000.000000,RPM,CLW,ON,$AUTO, 0.000000,NOTETPRINT/balld8,,balld8LOADTL/2,2,2$$ End of generation of : Tool Change.14PPRINT OPERATION NAME : Isoparametric Machining.2$$ Start generation of : Isoparametric Machining.2FEDRAT/ 8000.0000,MMPMSPINDL/15000.0000,RPM,CLWGOTO / 9.95037, -48.78022, 20.00000GOTO / 9.95037, -48.78022, 22.00000BEGIN NURBS_SIEMENS (D=3,F=8000.000,AXIS= 0.000000, 0.000000, 1.000000)N0, XT= 9.95037, YT= -48.78022, ZT= 22.00000,DK=0.000,W=1.000;N1, XT= 10.01206, YT= -48.78639, ZT= 16.72430,DK=0.000,W=1.000;N2, XT= 5.43447, YT= -48.32863, ZT= 11.75306,DK=15.662,W=1.000;N3, XT= 0.00000, YT= -47.78518, ZT= 12.00000,DK=0.000,W=1.000;END NURBS
../..
BEGIN NURBS_SIEMENS (D=3,F=8000.000,AXIS= 0.000000, 0.000000, 1.000000)N0, XT= 0.00000, YT= -44.60573, ZT= 12.00000,DK=0.000,W=1.000;N1, XT= 5.25284, YT= -45.09640, ZT= 11.93801,DK=0.000,W=1.000;N2, XT= 10.20252, YT= -45.55876, ZT= 16.53842,DK=15.662,W=1.000;N3, XT= 9.95665, YT= -45.53580, ZT= 22.00000,DK=0.000,W=1.000;END NURBSGOTO / 9.95665, -45.53580, 22.00000GOTO / 9.95665, -45.53580, 20.00000$$ End of generation of : Isoparametric Machining.2FINI
NC Code Sample for Fixed Axis NURBS
N10 ;PROGRAMME : Part Operation.1N20 ;PROGRAMMEUR: AAUN30 ;DATE : AAUG642ffwonN40 TRAORIG57M8N50 ORIVECTN60 G0 Z100.0N70 G0 X0.0 Y0.0N80 T2 M06N90 G1 X9.95037 Y-48.78022 Z20 N100 G1 X9.95037 Y-48.78022 Z22.0N110 G64N120 BSPLINE SD=3 F8000.000N130 X10.01206 Y-48.78639 Z16.7243 PL=0.0N140 X5.43447 Y-48.32863 Z11.75306 PL=15.662N150 X0.0 Y-47.78518 Z12.0 PL=0.0
../..
N2700 X0.0 Y-44.60573 Z12.0 PL=0.0N2710 X5.25284 Y-45.0964 Z11.93801 PL=0.0N2720 X10.20252 Y-45.55876 Z16.53842 PL=15.662N2730 X9.95665 Y-45.5358 Z22.0 PL=0.0N2740 ORIVECTN2750 G1 X9.95665 Y-45.5358 Z22 N2760 Z20 N2770 TRAFOOFN2780 G57N2790 M5 M9N2800 M30
Scope and Limitations
The tool paths of the following types of machining operation can be generated in NURBS format:
Profile Contouring
SweepingContour DrivenZlevelPencil MillingFace iso-parametricMulti-Axis SweepingMulti-Axis Contour DrivenMulti-Axis Curve MachiningMulti-Axis Flank Contouring.
Note that the 3D Nurbs Interpolation check box in the Machine Editor dialog box should be set to specify the ability to generate NURBS data in an APT output file.
The NURBS output of an operation is not compatible with any compensation output format (Profile or PQR).
The NURBS output is not compatible with Center output, NURBS is always a Tip position.
The NURBS ouput is only possible in APT (not CLFile).
It is not possible to import an APT containing NURBS statements using the APT Import command.
APT Output ModificationsThe APT source generated by the V5 Manufacturing applications is regularly enhanced to:
● support new functionalities
● obtain the same level of APT source generated by the Version 4 Manufacturing applications in order to ensure upward Post-Processor compatibility.
Following information applies to customers upgrading from previous V5 levels. As the current level includes all the following changes through service packs of previous releases, this information should be read carefully in order to identify modifications compared to their current CATIA level.
Special Notice Regarding Circular InterpolationGeneral Modifications Introduced with V5R7General Modifications Introduced with V5R7 SP1General Modifications Introduced with V5R7 SP5General Modifications Introduced with V5R8 SP2General Modifications Introduced with V5R12General Modifications Introduced with V5R13 GA and V5R12 SP2Axial Operation Modifications Introduced with V5R7Axial Operation Modifications Introduced with V5R7 SP1Axial Operation Modifications Introduced with V5R7 SP5Axial Operation Modifications Introduced with V5R8 SP1Axial Operation Modifications Introduced with V5R9 SP3Lathe Machining Modifications Introduced with V5R7 SP5Lathe Machining Modifications Introduced with V5R8 SP2Lathe Machining Modifications Introduced with V5R8 SP5Lathe Machining Modifications Introduced with V5R10 SP5
Special Notice Regarding Circular Interpolation
In Part Operation (at machine tool definition stage), Minimum and Maximum Interpolation radius values are defined for the generation of circular interpolation in APT output. These two parameters are used at two different times: at toolpath computation and at the generation of output file.
The user should check and possibly modify these values before creating Machining operations. Otherwise circular interpolation may not appear in the APT source.
Please note that if value is modified after machining operation creation and generation of toolpath, then the toolpaths should be recomputed (using Right button on Program: Compute Tool Path in Force computation mode) before generation of the output file.
General Modifications
General Modifications Introduced with V5R7
1. The displacement to the tool change point is generated before the CUTTER.Note that the TLAXIS is also moved up.
2. Duplicate points (that is, consecutive points that have the same coordinates) must not be eliminated in the case of cycles for axial operations. In particular, it is necessary to keep these points when the approach clearance is equal to zero.
Previous SituationRAPIDGOTO/ 0.00000, 0.00000, 0.00000CYCLE/DRILL, 20.000000, 0.000000, 1000.000000,MMPMCYCLE/OFF
Current SituationRAPIDGOTO/ 0.00000, 0.00000, 0.00000CYCLE/DRILL, 20.000000, 0.000000, 1000.000000,MMPMGOTO/ 0.00000, 0.00000, 0.00000CYCLE/OFF
3. Version 4 Compatibility: TLAXIS before CATIA0. The TLAXIS is given in the old reference axis system before CATIA0 generation.
Previous SituationPPRINT OPERATION NAME : Machining Axis face at 0 degrees$$*CATIA0$$ $$ -1.00000 0.00000 0.00000 25.00000$$ 0.00000 0.00000 1.00000 200.00000$$ 0.00000 1.00000 0.00000 243.50000PPRINT OPERATION NAME : Tool Change.7TLAXIS/ 0.000000, 0.000000, 1.000000$$ TOOLCHANGEBEGINNINGRAPID
Current SituationPPRINT OPERATION NAME : Machining Axis face at 0 degreesTLAXIS/ 0.000000, 1.000000, 0.000000$$*CATIA0$$ $$ -1.00000 0.00000 0.00000 25.00000$$ 0.00000 0.00000 1.00000 200.00000$$ 0.00000 1.00000 0.00000 243.50000PPRINT OPERATION NAME : Tool Change.7$$ TOOLCHANGEBEGINNINGRAPID
4. Addition of CENIT Post-processor for Lathe Machining: CENIT_LATHE.pptable.
5. New version of the CENIT Post-processor by DLL.
General Modifications Introduced with V5R7 SP1
1. Cutter format is now exactly the same as in V4 (parameters are written with format f10.6 and positions of parameters and commas are consequently modified on the 2 lines of the statement).
2. The seventh parameter of the CUTTER statement is now valuated with the cutting length and not like before with the total length of the tool. Please note that if the cutting length is not valuated for a given tool, the seventh parameter of the CUTTER statement will be valuated with the total length.
3. GOTO format is modified from GOTO/ to GOTO / as in V4 (2 blank characters are added between the word GOTO and the slash).
Previous SituationPPRINT OPERATION NAME : Tool Change.1TLAXIS/ 0.000000, 0.000000, 1.000000 $$ TOOLCHANGEBEGINNINGRAPIDGOTO/ 0.00000, 0.00000, 100.00000 CUTTER/ 40.000000, 20.000000, 0.000000, 20.000000, 0.000000$ , 0.000000, 100.000000 TOOLNO/1, 40.000000 TPRINT/T1 End Mill D 10LOADTL/1 PPRINT OPERATION NAME : Profile Contouring
Current SituationPPRINT OPERATION NAME : Tool Change.1 TLAXIS/ 0.000000, 0.000000, 1.000000 $$ TOOLCHANGEBEGINNING RAPID GOTO / 0.00000, 0.00000, 100.00000 CUTTER/ 40.000000, 20.000000, 0.000000, 20.000000, 0.000000,$ 0.000000,100.000000 TOOLNO/1, 40.000000 TPRINT/T1 End Mill D 10LOADTL/1 PPRINT OPERATION NAME : Profile Contouring
4. INTOL and OUTTOL statements are written before the first circular statement definition, and before other circular statements each time the discretization tolerance is modified. The discretization tolerance used to generate the INTOL statement is read on the machining operation. The value associated to the OUTTOL statement is always equal to zero.
5. AUTOPS and PSIS statements become modal, that is, the statements are generated only if the plane containing the circle is modified.
6. The point coordinates that are used to define the PSIS statement are the those of the center of the circle, and not those of the end point of the circle, as before.
7. The Circle and Cylndr statements are written exactly as in V4 (see the example below).
INTOL / 0.02500 OUTTOL/ 0.00000 PSIS/(PLANE/(POINT/ 0.00000, 0.00000, 0.68000),PERPTO,$
(VECTOR/ 0.000000, 0.000000, 1.000000)) INDIRV/ 0.47943, 0.87758, 0.00000 TLON,GOFWD/(CYLNDR/ 0.00000, 0.00000, 0.68000,$ 0.00000, 0.00000, 1.00000, 3.79375),ON,$ (PLANE/PERPTO,$ (PLANE/(POINT/ 0.00000, 0.00000, 0.68000),PERPTO,$ (VECTOR/ 0.000000, 0.000000, 1.000000)),$ (POINT/ 0.00000, 0.00000, 0.68000),$ (POINT/ -3.32933, 1.81882, 0.68000))
8. New version of the CENIT Post-Processor.
General Modifications Introduced with V5R7 SP5
1. TLAXIS instruction
Previous SituationThe TLAXIS statement is generated for each machine rotation (between ROTABL and $$*CATIA0 statements). Coordinates of TLAXIS instruction are defined in the current axis system ($$*CATIA0).
Current Situation Coordinates of TLAXIS instruction are defined in the first axis system definition ($$*CATIA0) of the machining program. (V4 compliant) Coordinates of rotation matrix and machining axis matrix are defined in absolute axis system. (V4 compliant) The TLAXIS statement is generated only if the tool axis orientation is modified after a head rotation. This means that if the program only includes ROTABL instructions, there is only one TLAXIS statement at the beginning of the APT source file. (V4 compliant)The TLAXIS are generated if no table rotation statement is defined between machining operations with different tool axis.
2. Clearance motion (at the beginning of machining operation) If a clearance macro is defined on the machining operation, the clearance macro motion is generated before the Approach macro motions.
Previous SituationWhen no tool motion is generated by the clearance macro (example: distance motion set to 0.0), Feedrate statement (of the Clearance macro) is not generated.
Current Situation The value of Clearance feedrate (it can be set to RAPID) defined on the macro is generated at the beginning of the operation.
3. Minimum and Maximum interpolation radius defined on Machine.
Previous SituationThe minimum and maximum interpolation radius defined on the Machine are not taken into account for tool path computation of macro motions.
Current SituationThe minimum and maximum interpolation radius defined on the Machine are used for all tool
motions at the output file generation.
General Modifications Introduced with V5R8 SP2
When circular interpolation is needed (depends on the machine defined on the Part Operation and/or options set for generation of APT source) CIRCLE or CYLNDR instruction is generated according to the following rule:
● generation of CIRCLE instruction when circular motion axis is parallel to the Z axis of the machining axis system
● generation of CYLNDR instruction in the other case.
One Rule is added for the generation of circular interpolation in order to match V4 behavior.
Previous SituationCircular interpolation is possible even if the circular motion axis is not parallel to the tool axis and the above mentioned rule is applied.
Current SituationCircular interpolation is generated only when circular motion axis is parallel to the tool axis. Used syntax (CIRCLE or CYLNDR) will follow the above mentioned rule. If circular motion axis is not parallel to the tool axis, no circular interpolation is performed, only GOTO statements will be generated.
General Modifications Introduced with V5R12
1. The management of point coordinates after machine rotations has been improved for APT and NC code generation and tool path replay. For APT files, the CATIA0 matrices following ROTABL statements also benefit from these improvements.
2. Duplicated points are now eliminated according to the final coordinates of the point: any transformations are taken into account.
General Modifications Introduced with V5R13 GA and V5R12 SP2
Change made in computation of Machine Home Position parameters.
Previous Situation %MFG_X_HOME_POS, %MFG_Y_HOME_POS and %MFG_Z_HOME_POS parameters were computed in absolute axis system.
Current Situation %MFG_X_HOME_POS, %MFG_Y_HOME_POS and %MFG_Z_HOME_POS parameters are computed in current axis system (defined by last CATIA0 matrix)
Axial Operation Modifications
Axial Operation Modifications Introduced with V5R7
1. On BoringAndChamfering, Chamfering2Sides, CounterSinking and SpotDrilling operations, computation errors on MFG_DETAIL_DEPTH and MFG_TOTAL_DEPTH parameters have been corrected.
2. Previously the MFG_PLUNGE_TIP and MFG_PLUNGE_VAL parameters were output as negative are now output as positive.
3. Previously the MFG_DWELL_TIME and MFG_DELAY_VALUE parameters were output in integer format (INT) are now output in real format (REAL).
4. The rules for cycle interruptions are modified.
Previous Situation Operation broken down into several CYCLE instructions if(Entry distance at point n or Exit distance at point n-1) > Approach Clearance
Current Situation Operation broken down into several CYCLE instructions if (Entry distance at point n or Exit distance at point n-1) > Approach Clearance AND > JumpDistance
5. New Parameter for CYCLE syntaxes: MFG_JUMP_DIST (Jump Distance) accessible for all axial operations.
6. Tool compensation parameters are modified for Version 4 compatibility.
Previous Situation MFG_TL_COMP: Length number of first correctorMFG_TL_COMP_2: Length number of second correctorMFG_TOOL_COMP: Distance between position of first corrector and tool tipMFG_TOOL_COMP_2: Distance between position of second corrector and tool tip.
Current Situation MFG_TOOL_COMP and MFG_TL_COMP (compatibility V4): Length number of current correctorMFG_TOOL_COMP_1: Length number of first correctorMFG_TOOL_COMP_2: Length number of second correctorMFG_TOOL_COMP_DIST: Distance between current corrector position and tool tipMFG_TOOL_COMP_DIST_1: Distance between first corrector position and tool tipMFG_TOOL_COMP_DIST_2: Distance between second corrector position and tool tip.
7. NC compensation instructions are output in the APT file for BoringAndChamfering and Chamfering2Sides operations when the corrector length number is modified during the operation.
8. Cycle syntax can now be output for BackBoring and T-Slotting operations.
9. Linking between pattern points is now always done by horizontal paths.
10. Different Cycle syntaxes are generated when two consecutive positions do not have the same depth.
Axial Operation Modifications Introduced with V5R7 SP1
1. Machining operations using a Boring Bar tool respect the defined hole depth.
2. Tool Cutting Length is no longer used for chamfering operations (Spot Drilling, Countersinking, Boring&Chamfering, Chamfering2Sides) when Depth mode is set to 'by Diameter'. The defined diameter is now taken into account for tool path computation.
3. Correct valuation of MFG_EFFCT_DEPTH for Drilling Break Chips and Drilling Deephole operations. Note for CAA2 usage: GetEffectDepthCut method of CATIMfgAxialOperation interface returns the correct valuation.
4. New Parameters for CYCLE syntaxes:MFG_DIAMETER (Diameter of machined hole) accessible for all axial operations.MFG_THREAD_DIAMETER (thread diameter of machined hole) accessible for Tapping, Reverse Threading, Thread without Tap Head, and Thread Milling operations.MFG_BCK_BORE_VAL (Back Bore Depth) for Back Boring operation.
Axial Operation Modifications Introduced with V5R7 SP5
On Back Boring operation, tool path computation errors and invalid valuation on MFG_TOTAL_DEPTH parameter have been corrected.
Axial Operation Modifications Introduced with V5R8 SP1
1. New Parameters for CYCLE syntaxes on Circular Milling operationMFG_CIRCULAR_MODE: Circular mode (1: Standard / 2: Helical)MFG_HELIX_MODE: Helix mode (1:by Pitch / 2: by Angle)MFG_PITCH: Helix Pitch MFG_HELIX_ANGLE: Helix angle
2. New Parameter for CYCLE syntaxes on Thread Milling operationMFG_PITCH_WAY_OF_ROT: (1: Left hand / 2 Right hand). This new parameter replaces the MFG_PITCH_SENS parameter.
3. New valuation of MFG_DIAMETER and MFG_THREAD_DIAMETER for Circular Milling and Thread Milling operations. Offset on contour is now taken into account for the valuation of MFG_DIAMETER and MFG_THREAD_DIAMETER parameters.
Axial Operation Modifications Introduced with V5R9 SP3
Tool Compensation distance (between P1 and current tool compensation point) is taken into account for X, Y, Z coordinates of CYCLE location points (V4 compliant).
Lathe Machining Modifications
Lathe Machining Modifications Introduced with V5R7 SP5
The lathe context of Drilling and Point to Point operations is now fully managed. The lathe context is determined if the following conditions are satisfied:
● A lathe machine is defined on the Part Operation.
● Operation machines along the spindle axis of the lathe machine.
● Operation uses a fixed tool assembly.
As a result, some modifications have been done to integrate these cases.
1. SPINDL/OFF statement is no longer automatically output after a lathe operation.
Previous Situation PPRINT OPERATION NAME : Threading.1$$ Start generation of : Threading.1CYCLE/THREAD, 3.175000CYCLE/OFF$$ End of generation of : Threading.1SPINDL/OFF$$ ------ SPINDLE OFF END OF LATHE ------
Current Situation PPRINT OPERATION NAME : Threading.1$$ Start generation of : Threading.1CYCLE/THREAD, 3.175000CYCLE/OFF$$ End of generation of : Threading.1
2. A Lathe Tool Change is now automatically created before a lathe context operation instead of a Mill Tool Change.
Note: For programs created before V5R7 SP5, you must delete the previous Mill Tool Change to allow the automatic creation of a new Lathe one.
Previous Situation PPRINT OPERATION NAME : MILL Tool Change$$ Start generation of : MILL Tool Change$$ TOOLCHANGEBEGINNINGRAPIDGOTO / 200.00000, 0.00000, 300.00000CUTTER/ 25.400000, 0.000000, 12.700000, 7.332348, 30.000000,$0.000000,228.600000TOOLNO/4, 25.400000TPRINT/T5 drill 1.0diaLOADTL/4$$ End of generation of : MILL Tool Change
Current Situation PPRINT OPERATION NAME : LATHE Tool Change$$ Start generation of : LATHE Tool Change$$ TOOLCHANGEBEGINNINGRAPIDGOTO / 200.00000, 0.00000, 300.00000CUTTER/ 25.400000TOOLNO/4,TURN$$ End of generation of : LATHE Tool Change
3. For Drilling and Point to Point used in lathe context, the SPINDL statement output is the value of the NC_SPINDLE_LATHE NC command.
Previous Situation PPRINT OPERATION NAME : Drilling Deep Hole along the Spindle axis$$ Start generation of : Drilling Deep Hole along the Spindle axisTLAXIS/ 0.000000, 0.000000, 1.000000SPINDL/ 70.0000,RPM,CLWRAPIDGOTO / 0.00000, 0.00000, 196.98060CYCLE/DEEPHL, 199.947948, 5.000000GOTO / 0.00000, 0.00000, 191.98060CYCLE/OFF$$ End of generation of : Drilling Deep Hole along the Spindle axis
Current Situation PPRINT OPERATION NAME : Drilling Deep Hole along the Spindle axis$$ Start generation of : Drilling Deep Hole along the Spindle axisTLAXIS/ 0.000000, 0.000000, 1.000000SPINDL/ 70.0000,RPMRAPIDGOTO / 0.00000, 0.00000, 196.98060CYCLE/DEEPHL, 199.947948, 5.000000GOTO / 0.00000, 0.00000, 191.98060CYCLE/OFF$$ End of generation of : Drilling Deep Hole along the Spindle axis
4. Minimum and Maximum interpolation radius defined on Machine
Previous SituationThe minimum and maximum interpolation radius defined on the Machine, are not taken into account for tool path computation of macro motions.
Current SituationThe minimum and maximum interpolation radius defined on the Machine, are used for all tool motions at the output file generation.
Lathe Modifications Introduced with V5R8 SP2
When circular interpolation is needed (depends on the machine defined on the Part Operation and/or options set for generation of APT source) CIRCLE or CYLNDR instruction is generated according to the following rule:
generation of CIRCLE instruction when circular motion axis is parallel to the Z axis of the machining axis system generation of CYLNDR instruction in the other case.
One Rule is added for the generation of circular interpolation in order to match V4 behavior.
Previous SituationCircular interpolation is possible even if the circular motion axis is not parallel to the tool axis and the above mentioned rule is applied.
Current SituationCircular interpolation is generated only when circular motion axis is parallel to the tool axis. Used syntax (CIRCLE or CYLNDR) will follow the above mentioned rule. If circular motion axis is not parallel to the tool axis, no circular interpolation is performed, only GOTO statements will be generated.
Lathe Modifications Introduced with V5R8 SP5
1. When circular interpolation is needed, the following behavior has been modified for lathe operations to ensure compatibility with V4 behavior:
Previous Situation2D circular interpolation is requested : No CIRCLE orders are generated. 3D circular interpolation is requested : CYLNDR orders are generated if the machining working plane is ZX. Otherwise, GOTO statements will be generated.
Current Situation2D circular interpolation is requested : CIRCLE orders are generated whatever machining working plane (ZX, XY, YZ). 3D circular interpolation is requested : CIRCLE orders are generated if the machining working plane is XY. Otherwise, CYLNDR orders are generated .
Note: If machining operation is already computed, the computation must be forced to initialize the tool path.
2. TLAXIS order is no more output for lathe tool change
Previous SituationPPRINT OPERATION NAME : Lathe Tool Change.1 $$ Start generation of : Lathe Tool Change.1 TLAXIS/ 1.000000, 0.000000, 0.000000 $$ TOOLCHANGEBEGINNING RAPID GOTO / 254.00000, 0.00000, 508.00000 CUTTER/ 0.400000 TOOLNO/0,TURN $$ End of generation of : Lathe Tool Change.1
Current SituationPPRINT OPERATION NAME : Lathe Tool Change.1$$ Start generation of : Lathe Tool Change.1$$ TOOLCHANGEBEGINNINGRAPIDGOTO / 254.00000, 0.00000, 508.00000CUTTER/ 0.400000TOOLNO/0,TURN$$ End of generation of : Lathe Tool Change.1
3. TLAXIS order is no more output for lathe operations
Previous SituationPPRINT OPERATION NAME : Roughing.1$$ Start generation of : Roughing.1
TLAXIS/ 1.000000, 0.000000, 0.000000SPINDL/ 70.0000,RPMRAPIDGOTO / 159.86681, 0.00000, 234.57181
Current SituationPPRINT OPERATION NAME : Roughing.1$$ Start generation of : Roughing.1SPINDL/ 70.0000,RPMRAPIDGOTO / 159.86681, 0.00000, 234.57181
Lathe Machining Modifications Introduced with V5R10 SP5
CUTTER statement has been modified to output the diameter of the insert nose according to APT definition.
Syntaxes Interpreted by APT ImportThe purpose of the APT Import is to store a tool path created from parameters included in the imported APT file.
Listed below are the syntaxes interpreted by APT Import for enriching the stored tool path. Syntaxes that do not include recognized parameters are stored as is in the tool path and are generated as is in the APT file (for example, this is the case for PP words and comments).
Units Definition
UNITS / MinorWord
Feeds and Speeds
FEDRAT/ Value
FEDRAT/ Value , Unit
FEDRAT/ Unit , Value
Value = feed value
Unit = minor word among IPM, MMPM, PERMIN, IPR, MMPR, PERREV
RAPID Rapid feedrate
SPINDL/ Value
SPINDL/ MinorWord
SPINDL/ Value , Unit
SPINDL/ Value , Unit , Way
SPINDL/ Value , Way
SPINDL/ Value , Way , Unit
SPINDL/ Unit , Value
SPINDL/ Unit , Value , Way
SPINDL/ Unit , Way , Value
SPINDL/ Way , Value
SPINDL/ Way , Value , Unit
SPINDL/ Way , Unit , Value
Value = spindle speed
Unit = minor word among SFM, RPM, SMM
Way = minor word among CLW, CCLW
Starting Point
FROM / X , Y , Z
FROM / X , Y , Z , I , J , K
X,Y,Z = coordinates of the tool position
I,J,K = components of the tool axis
GOTO / X , Y , Z
GOTO / X , Y , Z , I , J , K
X,Y,Z = coordinates of the tool position
I,J,K = components of the tool axis
Linear Tool Motion
GOTO / X , Y , Z
GOTO / X , Y , Z , I , J , K
X,Y,Z = coordinates of the tool position
I,J,K = components of the tool axis
GODLTA/ X , Y , Z
GODLTA/ X , Y , Z , I , J , K
X,Y,Z = coordinates of the tool position
I,J,K = components of the tool axis
NC Axis Definition
ORIGIN / X , Y , Z (, XX , XY , XZ , ZX , ZY , ZZ)
X,Y,Z = coordinates of the origin of the NC axis
XX, XY, XZ = components of x-axis of the NC axis
ZX, ZY, ZZ = components of z-axis of the NC axis
$$*CATIA0$$identifier$$ a11 a12 a13 t1$$ a21 a22 a23 t2$$ a31 a32 a33 t3
Machining axis system definition (in absolute axis)
Tool Axis Definition
TLAXIS / I , J , K I,J,K = components of the tool axis expressed in the machining axis system
MULTAX
MULTAX/ON
MULTAX/OFF
Tool Information
CUTTER/ D, r, E, F, a, b, h Milling tool with D = cutter diameterr = corner radiusE = horizontal distance between radius center point and tool axisF = vertical distance between radius center point and cutter tipa = angle of cutter tipb = flank angle (beta angle)h = tool height
CUTTER/ D Lathe tool with D = nose radius
Tolerances
INTOL / X (, Y , Z) Tolerance on Part (, Drive, Check). Only X is taken into account
OUTTOL/ X (, Y , Z) Tolerance on Part (, Drive, Check). Only X is taken into account
Circular Interpolation - CIRCLE/
AUTOPS -
INDIRV/ X , Y , Z X,Y,Z = components of the tangent to the circle at the start position
TLON,GOFWD/ (CIRCLE/ Xc, Yc, Zc,$Rad),ON,(LINE/ Xc, Yc, Zc, Xe, Ye, Ze)
TLON,GOFWD/ (CIRCLE/ Xc, Yc, Zc,$Rad),ON,2,INTOF,$
(LINE/ Xc, Yc, Zc, Xe, Ye, Ze)
Xc, Yc, Zc = coordinates of the circle center
Rad = circle radius
Xe, Ye, Ze = coordinates of the circle end point
Circular Interpolation - CYLNDR/
PSIS/(PLANE/(POINT/ x, y, z),PERPTO,$(VECTOR/ u, v, w))
x, y, z = tool tip coordinates
u, v, w = circle axis components
INDIRV/ X , Y , Z X,Y,Z = components of the tangent to the circle at the start position
TLON,GOFWD/ (CYLNDR / Xc, Yc, Zc,$Ua, Va, Wa, Rad), ON,$(PLANE/PERPTO,$(PLANE/(POINT/Xc,Yc,Zc),PERPTO,$(VECTOR/Ua,Va,Wa)),$(POINT/Xc,Yc,Zc),$(POINT/Xe,Ye,Ze))
TLON,GOFWD/ (CYLNDR / Xc, Yc, Zc,$Ua, Va, Wa, Rad),ON,2,INTOF,$(PLANE/PERPTO,$(PLANE/(POINT/Xc,Yc,Zc),PERPTO,$(VECTOR/Ua,Va,Wa)),$(POINT/Xc,Yc,Zc),$(POINT/Xe,Ye,Ze))
Xc, Yc, Zc = coordinates of the circle center
Ua, Va, Wa = circle axis components
Rad = circle radius
Xe, Ye, Ze = coordinates of the end point
Table Rotation
ROTABL/ axis, value, mode, way
axis = A, B, C, AAXIS, BAXIS, or CAXIS
way = direction of rotation (CLW or CCLW)
mode = rotation mode (ATANGL or INCR)
Clfile FormatsThis section describes:
● the format and record types used to write NC Manufacturing data on Cutter Location files (clfiles)
● radial cutter compensation in clfiles (record type 10000)
● the command that allows the conversion of CATIA clfiles between Unix and Intel platforms.
CATIA Clfile Format
A clfile is a set of cldata type records. This type of record consists of a series of logic words. Record length is variable, up to a maximum of 245 words.
The general structure of a record is as follows:
W1 = record sequence number (integer)
W2 = record type (integer)
W3 to Wn = data depending on the record type.
The first three words are of the same length (4 bytes) and are integers.
The following words 4 to 245 have the same length (8 bytes) and may represent either an integer, a real number or a group of six characters.
● If the logic word represents an integer, the four right most bytes are used.
● If the logic word represents a real, all the bytes are used.
● If the logic word represents a six-character group, the left six bytes are used, the two remaining bytes are blank. If the group consists of less than six characters, it will be completed on the left by blank characters, in order to obtain the six characters needed.
Record Types Generated by the Application
The following record types are generated by the application: 1000, 2000, 3000, 5000, 6000, 9000, 10000, 14000, 15000 and 28000.
Type 1000 Record
Type 1000 gives the record sequence number.
● W1 = record sequence number (integer)
● W2 = 1000
● W3 = W1.
Type 2000 Record
Type 2000 gives the post-processor instructions.
● W1 = record sequence number (integer)
● W2 = 2000
● W3 = n (integer) code corresponding to a major word.
● W4 and the following words can contain either an integer representing a minor word code, a real number, or a character string.
Type 3000 Record
For circular interpolation, type 3000 gives the canonical form of the circle followed by the tool tip. A type 3000 record is followed by one or more type 5000 records to describe the tool path.
● W1 = record sequence number (integer)
● W2 = 3000
● W3 = 2 (integer)
● W4 = 0 (integer)
● W5 = 4 (integer) indicating a circle
● W6 = 9 (integer) number of following words that are used to defined the circle
● W7 = symbolic name (CIR) of the circle (characters)
● W8 = n (integer) number associated to the circle
● W9 = x coordinate of the circle center (real)
● W10 = y coordinate of the circle center (real)
● W11 = z coordinate of the circle center (real)
● W12 = x component of the circle axis unit vector (real)
● W13 = y component of the circle axis unit vector (real)
● W14 = z component of the circle axis unit vector (real)
● W15 = radius of the circle (real).
Type 5000 Record
● W1 = record sequence number (integer)
● W2 = 5000
● W3 = 3 for FROM, 5 for the other types of movements (for example, GOTO) and 6 for a series of movements (integer).
● W4 = symbolic name (PT) of the point (characters), if the record contains one single point.
● W5 = n (integer) number associated to the point, if the record contains one single point.
● From W6, point coordinates are given. A record can contain data on 40 or 80 points.
For 40 points, point and axis information is given:
● W6 = x coordinate of first point (real)
● W7 = y coordinate of first point (real)
● W8 = z coordinate of first point (real)
● W9 = i component of tool axis (real)
● W10 = j component of tool axis (real)
● W11 = k component of tool axis (real)
● W12 = x coordinate of second point (real)
● etc.
● W245 = z coordinate of 40th point (real).
For 80 points, only point information is given:
● W6 = x coordinate of first point (real)
● W7 = y coordinate of first point (real)
● W8 = z coordinate of first point (real)
● W9 = x coordinate of second point (real)
● etc.
● W245 = z coordinate of 80th point (real).
Type 6000 Record
Type 6000 contains either data on the tool geometry or the machining tolerances.
Machining tolerances:
● W1 = record sequence number (integer)
● W2 = 6000
● W3 = 4 for `INTOL' or 5 for `OUTTOL'
● W4 = tolerance value (real)
Tool data:
● W1 = record sequence number (integer)
● W2 = 6000
● W3 = 6 for `CUTTER'
● W4 = tool diameter (real)
● W5 = tool corner radius (real)
● W6 = horizontal distance between the tool axis and the center of the corner radius (real)
● W7 = vertical distance between the tool bottom and the center of the corner radius (real)
● W8 = 0 (real)
● W9 = angle between the flank of the tool and the vertical (real)
● W10 = height of the tool (real).
Type 9000 Record
Type 9000 indicates either tool axis orientation in the machining axis system in 3-axis mode or the multi-axis operating mode in multi-axis mode.
Multi-axis mode (multi-axis operating mode):
● W1 = record sequence number (integer)
● W2 = 9000
● W3 = 2 for `MULTAX'
● W4 = 1 for `ON'
3-axis mode (tool axis orientation):
● W1 = record sequence number (integer)
● W2 = 9000
● W3 = 1 (integer)
● W4 = 1 (integer) indicates that tool axis components follow
● W5 = blank (character)
● W6 = 0 (integer)
● W7 = x component of tool axis vector expressed in the machining axis system specified in the 28000 record (real)
● W8 = y component of tool axis vector expressed in the machining axis system specified in the 28000 record (real)
● W9 = z component of tool axis vector expressed in the machining axis system specified in the 28000 record (real)
Type 10000 Record
Used with type 5000 for specifying radial cutter compensation data. Please refer to Radial Compensation in Clfiles.
● W1 = record sequence number (integer)
● W2 = 10000
● W3 = 0 for NORM_DS, 1 for standard NORM_PS, 2 for NORM_PS without 5000 type record, and 3 for NORM_PS with 5000 type record containing 0, 0, 0, I, J, K for each tool position, where only the I, J, K vector components are useful (integer).
● W4 = 0 (real).
● W5 = 0 (real).
● From W6, compensation data is given on the W3 value.
NORM_DS in 3-axis mode:
● W6 = P component of the compensation vector (real)
● W7 = Q component of the compensation vector (real)
● W8 = R component of the compensation vector (real)
NORM_DS in 5-axis mode:
● W6 = 0 (real)
● W7 = 0 (real)
● W8 = 0 (real)
● W9 = P component of the compensation vector (real)
● W10 = Q component of the compensation vector (real)
● W11 = R component of the compensation vector (real)
NORM_PS:
● W6 = Xc coordinate of contact point (real)
● W7 = Yc coordinate of contact point (real)
● W8 = Zc coordinate of contact point (real)
● W9 = Xn component of the normal vector (real)
● W10 = Yn component of the normal vector (real)
● W11 = Zn component of the normal vector (real).
Type 14000 Record
Type 14000 indicates the end of the cldata records.
● W1 = record sequence number (integer)
● W2 = 14000.
Type 15000 Record
For circular interpolation, type 15000 specifies the unsegmented circular path followed by the tool tip.
● W1 = record sequence number (integer)
● W2 = 15000
● W3 = 3 (integer)
● W4 = 0 (integer)
● W5 = 4 (integer) indicating a circle
● W6 = 13 (integer) number of following words that are used to define the circle
● W7 = symbolic name (CIR) of the circle (characters)
● W8 = n (integer) number associated to the circle
● W9 = x coordinate of the circle center (real)
● W10 = y coordinate of the circle center (real)
● W11 = z coordinate of the circle center (real)
● W12 = x component of the circle axis unit vector (real)
● W13 = y component of the circle axis unit vector (real)
● W14 = z component of the circle axis unit vector (real)
● W15 = circle radius (real)
● W16 = oriented angle of the circular arc in degrees (real)
● W17 = x coordinate of the arc end point (real)
● W18 = y coordinate of the arc end point (real)
● W19 = z coordinate of the arc end point (real).
The direction of the path is determined by the circle axis unit vector (W12 to W14). It corresponds to an angular movement W16 which is positive if the direction is counterclockwise or negative if the direction is clockwise.
Type 28000 Record
Type 28000 specifies the components of the axis system in which the tool path is given. It is specified at the start of the clfile and at each change of machining axis system.
● W1 = record sequence number (integer)
● W2 = 28000
● W3 = 0 (integer)
● W4 to W16 = identifier of the axis system (characters)
● W17 to W28 = components of the axis system (real).
Radial Compensation in Clfiles
Radial compensation data (PLANAR, NORM_DS, and NORM_PS) is managed in clfile records.
The various compensation cases are as follows:
Where:X, Y, Z: Tip PointI, J, K: Tool Axis VectorXp, Yp, Zp: Profile PointXc, Yc, Zc: Contact PointIn, Jn, Kn: Part surface Normal VectorP, Q, R: Compensation Vector.
Tip Point, Tool Axis Vector and Profile Point data are stored in 5000 type records according to the standard.
A specific type of record, Type number 10000, allows storing Contact Point, Part surface Normal Vector and Compensation Vector data.
This 10000 record is written in the clfile just before the corresponding 5000 record when required. When continuation records need to be generated for 10000 and 5000 type records, all 10000 type records are written before all associated 5000 type records. A single 1000 type record will precede the couple of records (10000 + 5000). In case of continuation record for this couple of records, no additional 1000 record is added.
The record length of the 5000 and 10000 type records is 1948 bytes, but the 28 first bytes are used to define the type of the record. The remaining 1920 bytes allow defining data corresponding to 40 or 80 positions depending on the number of bytes used for one position.
In the table above:Cases 1 and 2: A 5000 type record is enough to store data corresponding to these cases, for up to 80 tool positions.
Cases 3 and 5:A 5000 type record allows storing tip or profile coordinates, for up to 80 tool positions.A 10000 type record (sub-type: 0) allows storing P, Q, R data for these tool positions.
Cases 4 and 6:A 5000 type record allows storing tip or profile coordinates and associates tool axis vector components, for up to 40 tool positions (48 bytes per tool position).A 10000 type record (sub-type: 0) allows storing P, Q, R data for these tool positions (48 bytes per tool position; the 3 first doubles are set to 0).
Case 7: A 10000 type record (sub-type: 1) allows storing Contact coordinates and Normal Vector components for up to 40 tool positions (48 bytes per tool position).A 5000 type record allows storing tip or profile coordinates for these tool positions.The maximum number of tool positions to be stored in both 5000 and 10000 type records is defined by the 10000 type record.
Case 8:A 5000 type record allows storing tip or profile coordinates and associates tool axis vector components, for up to 40 tool positions (48 bytes per tool position).A 10000 type record (sub-type: 1) allows storing Contact coordinates and Normal Vector components for these tool positions (48 bytes per tool position).
Case 9:A 10000 type record (sub-type: 2) allows storing Contact coordinates and Normal Vector components for up to 40 tool positions (48 bytes per tool position). Sub-type 2 is similar to sub-type 1 used in previous cases, but the sub-type value allows to define if a 5000 type record is associated to the 10000 (value 1) or not (value 2).No data needs to be stored in a 5000 type record.
Case 10:A 10000 type record (sub-type: 3) allows storing Contact coordinates and Normal Vector components for up to 40 tool positions (48 bytes per tool position). Sub-type 3 is similar to sub-type 1 used in previous cases, but the sub-type value allows to define if the following 5000 type record associated to the 10000 contains x, y, z, i, j, k information (value 1) or only tool axis vector components (value 3).A 5000 type record allows storing tool axis vector components, for these tool positions.
Converting CATIA Clfiles Between Unix and Intel Platforms
There is a Clfile coding difference between Windows and Unix stations. Clfiles generated by CATIA are always stored in Unix format. Therefore using a Clfile created by CATIA on Windows requires a conversion.
A module called MfgClfileConvExe is delivered that allows the conversion of CATIA clfiles between the Unix and Intel platforms.
The module recognizes automatically the format of the clfile and converts it into the other format.
To run the conversion, use the following command:
MfgClfileConvExe -i input_clfile [-o output_clfile] [-rep]
where:
-i input_clfile is the clfile to be converted, with access path (required)-o output_clfile is the resulting clfile, with access path (optional)If -o is not used, the resulting file will be written in the temp folder and called ConvertedClfile.clfile-rep, if present, write is done in replace mode.
The module does not generate messages, but a return code is given with the following values:
0: OK1: No input clfile (required)2: No PP words table (required)3: The input clfile does not exist4: PP words table loading problem5: Problem opening the input clfile 6: The output clfile exists but cannot be replaced7: The output clfile exists but there is no access permission8: The output clfile exists but cannot be deleted9: Problem opening the output clfile10: Problem closing the output clfile11: Problem closing the input clfile12: Internal error13: Problem reading a record of the input clfile14: Conversion direction undetermined15: Write problem on record length16: Write problem on record
NC Data Import to Support Legacy DataMachining data managed by customers (especially in aerospace) have a very long life cycle. During the product life, customers need to modify their products, and consequently associated machining data.Customers need to be able to retrieve machining data generated with CATIA V4 or other CAM systems, and modify them using Version 5 Machining products.
The NC Data Import functionality allows retrieving APT source files, clfiles, NC code.
This section describes the NC Data Import capability and its scope for reviewing and reusing data generated with CATIA V4 or other CAM systems.
NC Data Import
NC data files (generated using V5 or previous versions) may be tagged with markers (OPERATION NUMBER or OPERATION NAME, prefixed either by PPRINT or $$) that identify the start of each operation.
When an NC data file is imported, each operation identified in this way is defined as an entity in the resulting V5 program (APT Import, PP Instruction, Table Rotation, INDEX/TRACUT/COPY, and so on).
Created Operation Types
The following types of operation can be created:
● Tool Change
● Machining Axis Change
● Table Rotation
● INDEX, COPY, TRACUT
● APT Import.
Tool Change
A Version 5 Tool Change is created whenever a CUTTER statement with 7 parameters is found in the imported file. In most cases this tool change uses a V5 End Mill defined from the parameters on the CUTTER statement. In some cases a V5 Drill is used.
The parameters are tool radius, corner radius, horizontal and vertical distances from the center of the corner to the tool axis or bottom, bottom and flank angles, and tool height. Default values are applied to other parameters of the tool.
Note that:
● Tools and tool changes can be modified (edit, modify, replace).
● No unnecessary V5 tool change is created if the user replaces APT Import activities by V5 operations using the same tool in a sequence of APT Import activities.
If the CUTTER statement has 1 parameter, a turning assembly with insert-holder and inset is created. The parameter in the CUTTER statement represents the nose radius of the insert.
Machining Axis Change
A Machining Axis Change operation is created whenever the following statements appear in the APT file:
● *CATIA0
● ORIGIN
The matrix associated with the Machining Axis Change operation is generated from the parameters associated with the *CATIA0 or ORIGIN statement.
Note that the first *CATIA0 met will generate a Machining Axis Change operation only if the associated matrix parameters are different from the machining axis system referenced by the Part Operation.
Table Rotation
Each time a sequence of ROTABL statements is clearly identified in the file to be imported, a Machine rotation will be created in the Manufacturing Program to manage it.
The rotation matrix associated with the Machine rotation is generated from the parameters associated with the *CATIA0 syntax that follows the ROTABL statement.
Table rotation statements (ROTABL)
The supported forms of ROTABL/ axis, value, mode, way statements are all combinations of the following parameters:
● axis indicating the rotation axis (A, B, C, AAXIS, BAXIS, or CAXIS)
● value representing the angle value of the rotation
● mode indicating if the angle is defined in incremental (INCR) or absolute mode (ABS or ATANGL)
● way giving the direction of rotation (CLW or CCLW).
The case of 2 successive table rotations is supported by the APT Import. These rotations are followed by a single matrix definition.
Example:
ROTABL/AAXIS,...ROTABL/CAXIS,...$$CATIA0$$$$ a11 a12 a13 a14$$ a21 a22 a23 a24$$ a31 a32 a33 a34
Notes:
● The incremental mode is not supported: a statement including INCR value is considered as a simple PP word statement and not as a rotation.
● If the axis name (A, B, C, AAXIS, BAXIS, or CXAXIS) or way of rotation (CLW or CCLW) of the rotary syntax is not defined, then no Machine rotation can be created. These statements will be considered as simple PP words and not as a rotation.
● A ROTABL statement cannot be imported if the referenced machine is a generic machine (that is, machine created using the NC Machine Tool Builder product).
INDEX, COPY, TRACUT
Each time an INDEX, COPY or TRACUT statement is found during APT Import, a V5 COPY or TRACUT activity is created.
The following forms of INDEX, COPY and TRACUT statements are supported.
INDEX
INDEX/n where n is the index number
INDEX/n,NOMORE where n is the index number.
COPY
COPY/n,SAME,p where n is the index number and p is the number of copies
COPY/n,TRANSL,dx,dy,dz,p where n is the index number, dx,dy,dz are the components of the translation vector and p is the number of copies
COPY/n,XYROT,a,p where n is the index number, a is the angle value and p is the number of copies
COPY/n,YZROT,b,p where n is the index number, b is the angle value and p is the number of copies
COPY/n,ZXROT,c,p where n is the index number, c is the angle value and p is the number of copies
COPY/n,SCALE,s,p where n is the index number, s is the scale factor and p is the number of copies
COPY/n,MODIFY,$ (MATRIX/a11,a12,a13,$ a21,a22,a23,$ a31,a32,a33,$ a41,a42,a43),p where n is the index number, aij are the components of the matrix and p is the number of copies
TRACUT
TRACUT/(MATRIX/TRANSL,dx,dy,dz) where dx,dy,dz are the components of the translation vector
TRACUT/(MATRIX/XYROT,a) where a is the angle value of the rotation
TRACUT/(MATRIX/YZROT,b) where b is the angle value of the rotation
TRACUT/(MATRIX/ZXROT,c) where c is the angle value of the rotation
TRACUT/(MATRIX/SCALE,s) where s is the scale factor
TRACUT/(MATRIX/a11,a12,a13,$ a21,a22,a23,$ a31,a32,a33,$ a41,a42,a43) where aij are the components of the matrix.
TRACUT/NOMORE
APT Import
The purpose of the APT Import activity is to store a tool path created from parameters included in the APT file. The tool path comprises linear and circular displacements and PP words
APT Import entities are automatically locked during creation.This allows the tool path to be modified by means of the Tool Path Editor.
Creation Conditions for a New APT Import
A first APT Import activity (with a current tool path) is created when the APT file is opened.
A new APT Import activity is created when the following parameters are decoded in the APT file:
● CUTTER (after creation of a Tool Change operation)
● *CATIA0 or ORIGIN (after creation of a Machining Axis Change operation)
● ROTABL (after creation of a Table Rotation operation)
● FROM
● TLAXIS
● OPERATION NUMBER or OPERATION NAME type comment.
Other Interpreted Parameters
The other interpreted parameters for the created tool path are as follows:
● GOTO and GODLTA for linear displacements
● INTOL, OUTTOL, AUTOPS, PSIS, INDIRV and TLON for circular displacements
● MULTAX for 5-axis tool paths
● FEDRAT and RAPID for feedrate descriptions
● SPINDL for spindle speed descriptions
● UNITS for the current unit (mm, inch, and so on)
● TOOLCENTER, CONTACTPOINT and TOOLEND. These are descriptions of the tool's center point, contact point, and end point (or tip).
Syntaxes that do not include recognized parameters are stored as is in the tool path and are generated as is in the APT file (for example, this is the case for PP words and comments).
Each time a sequence of PP word statements is clearly identified (with PPRINT OPERATION NUMBER) in the NC data file, a V5 Post-Processor instruction will be created in the Manufacturing Program. The created PP instruction can be edited.
Note that PP word statements defined in macros of a machining operation remain embedded in the tool path of the operation.
PQR Cutter Compensation
You can import an APT file containing PQR cutter compensation data (that is, the drive surface normal).
This PQR data may be of 2 forms shown in the examples below.
Example 1:
CUTCOM/ NORMDS$$ START CUTCOM NORMDS XT,YT,ZT,I,J,K,P,Q,RGOTO / 100.00276, -17.79095, 34.00000, 0.000000, 0.000000, 1.00000$0, 0.000000,-1.000000, 0.000000...CUTCOM/OFF$$ END CUTCOM NORMDS XT,YT,ZT,I,J,K,P,Q,R
Example 2:
CUTCOM/ NORMDS
$$ START CUTCOM NORMDS XT,YT,ZT,P,Q,RGOTO / 100.00276, -17.79095, 34.00000, $ 0, 0.000000,-1.000000, 0.000000...CUTCOM/OFF$$ END CUTCOM NORMDS XT,YT,ZT,P,Q,R
Transition Paths
A Transition Path is a complex activity including linear transitions and machine rotations. Therefore it is imported as several entities (APT Import activities and machine rotations).
Linear transitions are imported as APT Import activities. When a machine rotation is found, the APT Import activity is ended, and a machine rotation activity is generated. Then another APT Import activity is created for the next linear transitions.
The supported forms for ROTABL instructions are the same as described in Table Rotation above.
The names of all APT Import and machine rotation activities created from a V5 Transition Path includes the Transition Path name.
Automatic Generation of Transition Paths
APT Import activities are compatible with the automatic generation of transition paths capability. This enables you to complete an imported program like any other V5 program.
NC Code Import
Sample Post Processor parameter files are delivered with the product in the folder\Startup\Manufacturing\PPParwhich provides NC output for various machine types.Post Processors are provided by Cenit, Intelligent Manufacturing Software (IMS), and ICAM Technologies Corporation.
Select the type of Post Processor parameter files to be made available for selection using Tools > Options > Machining > Output tab. If the output option is set to None, the PP File selection combo will not appear in the NC File Import dialog box (no PP parameter files will be available for selection).
For information about how to acquire Post Processor parameters files that provide machine specific NC code output, please contact your IBM representative.
Limitations
The following limitations apply. Please refer to Syntaxes Interpreted by APT Import for more information.
● The APT file is not imported if it contains OUTPUT PROFILE, TOOL FLANK OUTPUT, TOOL CENTER OUTPUT, or NURBS statements.
● During APT Import, all tool motions are considered as Tip positions. This is due to the fact that in the APT source file, no compensation data is written. So, it is not possible to:
❍ detect that the position is not the tip position, and
❍ compute the tip point corresponding to the position written in APT source file.
● A ROTHED statement cannot be imported.
Feature Attributes for Tool Queries, Checks and Formula
This section describes the feature attributes available in machining processes and machining operations for Tool Queries, Checks and Formula. It deals with the following categories of features:
● Holes
● Machinable Axial Features
● Prismatic Machining Areas.
It also gives some useful examples for Tool Queries, Checks and Formula.
Feature Attributes for Checks, Tool Queries and Formula
The dialog box that appears for Tool Queries, Checks and Formula allows you to access to the list of feature attributes with their type. It is not always easy to give the correct values to with String or Integer type attributes.
The example below shows the following check: Machinable Axial Feature is a simple, blind hole. In this check, Hole type=0 specifies a simple hole and Hole Extension=1 specifies a blind hole.
Here is a list of attributes that may not be directly accessible from the dialog box (String or Integer type attributes).
Hole Features
Check on Hole feature: double-click Hole in Type list.
Hole type attribute for checks:
Hole.Hole type = "Simple" (simple hole)Hole.Hole type = "Tapered" (taper hole)Hole.Hole type = "Counterbored" (counterbore hole)Hole.Hole type = "Countersink" (countersunk hole)Hole.Hole type = "Counterdrilled" (counterdrilled hole)
Limit type attribute for checks:
Hole.Limit type = "Blind"Hole.Limit type <> "Blind" Hole.Limit type = "Up_To_Last"Hole.Limit type = "Up_To_Next"Hole.Limit type = "Up_To_Surface"
Bottom type attribute for checks:
Hole.Bottom type = "Flat"Hole.Bottom type = "V_Bottom"
Threaded and Tap side attributes for checks:
Hole.Threaded = trueHole.Threaded = falseHole.Tap side = "Right_Threaded"Hole.Tap side = "Left_Threaded"
SemanticDimTabValue attribute for tolerance checks:
Hole.Diameter.SemanticDimTabValue="H7"Note that you must select the Diameter attribute before entering the SemanticDimTabValue="H7" string.
ToleranceMax and ToleranceMin attributes for tolerance formula or tool queries (example):
Diameter = Hole.Diameter+(Hole.Diameter.ToleranceMax-Hole.Diameter.ToleranceMin)/2Note that you must select the Diameter attribute before entering the ToleranceMin or ToleranceMax string.
Machinable Axial Features
Check on Machinable Axial Feature feature: double-click Machinable Axial Feature in Type list.
Hole type attribute for checks:
Machinable Axial Feature.Hole type = 0 (simple hole)Machinable Axial Feature.Hole type = 1 (taper hole)Machinable Axial Feature.Hole type = 2 (counterbore hole)Machinable Axial Feature.Hole type = 3 (countersunk hole)Machinable Axial Feature.Hole type = 4 (counterdrilled hole)Machinable Axial Feature.Hole type = 5 (Unknown)
Hole Extension attribute for checks:
Machinable Axial Feature.Hole Extension = 1 (blind)Machinable Axial Feature.Hole Extension = 2 (through)
Hole bottom type attribute for checks:
Machinable Axial Feature.Hole bottom type = "Flat Bottom"Machinable Axial Feature.Hole bottom type = "V Bottom"
Hole bottom angle attribute for checks (examples):
Machinable Axial Feature.Hole bottom angle = 0degMachinable Axial Feature.Hole bottom angle = 120deg
Threaded and Thread direction attributes for checks:
Machinable Axial Feature.Threaded = trueMachinable Axial Feature.Threaded = falseMachinable Axial Feature.Thread direction = "0" (Right threaded)Machinable Axial Feature.Thread direction = "1" (Left threaded)
IsToleranced and ToleranceType attributes for tolerance checks (examples):
Machinable Axial Feature.IsToleranced = trueMachinable Axial Feature.ToleranceType("Diameter") = "H7"
ToleranceMax and ToleranceMin attributes for tolerance formula or tool queries (example):
Machinable Axial Feature.Diameter+(Machinable Axial Feature.Diameter.ToleranceMax-Machinable Axial Feature.Diameter.ToleranceMin)/2Note that you must select the Diameter attribute before entering the ToleranceMin or ToleranceMax string.
Prismatic Machining Areas
Check on Prismatic machining area feature: double-click Prismatic machining area in Type list.
There are three dedicated length attributes for formula, tool queries and checks:
Maximum channel width attribute (examples):
Prismatic machining area.Maximum channel width<=100mm Prismatic machining area.Maximum channel width>48mm
Minimum channel width attribute (examples):
Prismatic machining area.Minimum channel width<=20mmPrismatic machining area. Minimum channel width>10mm
Minimum corner radius attribute (examples):
Prismatic machining area.Minimum corner radius<=8mmPrismatic machining area.Minimum corner radius>6mm
Useful Examples for Tool Queries, Checks and Formula
Tool Queries
Tool queries are used to define criteria for cutting tool selection.
Examples of Tool Queries using geometrical attributes:
Cutter diameter:
Nominal diameter>=Hole.Diameter-0.1mmNominal diameter<=Hole.Diameter+0.1mm
Cutting length:
Cutting length>=Hole.Depth*1.2Cutting length<=Hole.Depth*2
Examples of Tool Queries using technological attributes:
Way of rotation:
Way of rotation=RIGHT_HAND
Cutting material:
Tooth material desc.=COATED_HIGH_SPEED_STEEL
Checks
Checks are used to constrain the validity of a machining process or a machining operation. Some examples are given below.
Check for type of feature:
Standard hole:
Hole.Diameter.SemanticDimTabValue<>"H7"Hole.Threaded=false
Hole with fitting:
Hole.Diameter.SemanticDimTabValue="H7"Hole.Threaded=false
Threaded hole:
Hole.Diameter.SemanticDimTabValue<>"H7"Hole.Threaded=true
Note that you must select the Diameter attribute before entering the SemanticDimTabValue="H7" or SemanticDimTabValue<>"H7" string.
Check for size of feature:
Hole diameter:
Hole.Diameter>4mmHole.Diameter<=20mm
Hole depth:
Hole.Depth<=Hole.Diameter*3.5
Formula
Formula are used to compute parameters (mainly parameters of a machining operation) with a formula containing feature attributes.
The example below illustrates some of the possiblilities.Note that you must select the Diameter attribute before entering the ToleranceMin or ToleranceMax string.
PLM IntegrationThis section discusses some topics concerning the integration of Machining solutions in Product Lifecycle Management (PLM).
Simplified User Interface in Manufacturing Hub Context
When working in a Manufacturing hub context, all files and catalogs required as input and output data is stored in IPD and is not file-based. The user interface is simplified by removing fields requesting the user to specify input or output file paths.
Document Chooser Integration and Support of DLNames
You can now customize the document environment (Tools > Options > General > Document tab) in order to select documents or paths using various interfaces (folder, SmarTeam, and so on). The interface can be customized for a folder or DLName path selection interface.
CATProcess Document Support
These topics are discussed in the following sections:
CATProcess Documents Support in SmartTeamCATProcess Documents Support in Process Engineer
CATProcess Document Support in SmartTeamNC CATProcess document and related linked documents (such as APT source, NC code, tool user representation, machine) can be automatically managed in SmarTeam.
Whenever a V5 document needs to be loaded, SmarTeam can be accessed without duplicating documents in a folder.
Documents that have been saved in SmarTeam can be accessed in all the Machining products functionalities that reference external documents. This includes the following functionalities:
● Open a CATProcess from SmarTeam
● Select a CATProduct or CATPart from SmarTeam in the Part Operation editor
● Select a CATProduct from SmarTeam in the Machine editor
● Select a macro from a catalog stored in SmarTeam in the Machining Operation editor
● Select a Machining Process from a catalog stored in SmarTeam in catalog browser
● Select a Machining Process from a catalog stored in SmarTeam in Machining Processes Application command
● Select a CATProduct or CATPart from SmarTeam to add a User Representation on a tool
● Select an output file from SmarTeam for APT Import
● Select a CATProduct from SmarTeam to Import V4 data
● Select an output APT source from SmarTeam to associate it to V4 data.
You must specify in the document environment setting (Tools > Options > General > Document tab) that you want to be able to access to SmarTeam data. For that, just set SmarTeam to Allowed or Current.
If you set SmarTeam to Current, then SmarTeam becomes the current document environment and SmarTeam dialog boxes will be displayed when you access your documents.
If several document environments are set the Browse Document Environments toolbar allows you to choose SmarTeam.
Example
You can select a CATProduct or CATPart from SmarTeam to add a User Representation on a tool.
CATProcess Document Support in Process Engineer
NC CATProcess document and related documents are supported in Process Engineer.
Part Operations and NC Programs can be created in Process Engineer and detailed in V5 with Machining products through the PPR Hub loader.
The complete process chain is covered down to NC output generation.
The following related documents that are generated in Process Planning and Machining workbenches can be saved in the Process Engineer environment:
● In Process Model (CATPart and CATProduct)
● Drawings (CATDrawings)
● External tool paths (tpl)
● Video simulation results (CATProduct containing cgr (CATIA graphic representation) and WPC information).
● Images for documentation (jpg)
● NC data files (aptsource, clfile, and CATNCCode).
MethodologyThis section provides methodology and conceptual information on the following topics.
Machining ProcessesKnowledgeware in Machining Processes
CATProduct and CATProcess Document ManagementCopy/Paste and External Referencing of NC Manufacturing Data
Design Changes and Associativity MechanismsProduct-Setup Link in Manufacturing Hub ContextNC Synchronization in Manufacturing Hub Context
Lock/Unlock MechanismsPart Operation and Set Up Documents
Material Removal SimulationOpposite Hand Machining
User Features for MachiningProperties of a Machining Operation
Machining ProcessesMachining process capabilities can be useful when your work habits include:
● using the same options and strategies in machining operations, according to specific to geometric shapes, your machining techniques or the part material
● changing the options and parameters according to your needs
● checking that you are using the correct options
● defining and checking the approach/retract macros you want to use in such configurations.
Methodology
The proposed solution uses two major steps:
● Feeding the system with your know-how
● Using machining processes.
Feeding the System with Your Know-How
This is the Build Time step that includes creating machining processes and storing them in V5 Catalogs. It is usually performed by the Administrator or Support Group.
Create Machining Processes
1. You need to create different Machining Operations without geometry: just start from an empty session. 2. Activate the Machining Process toolbar in the View>Toolbars menu to display the Machining Process
commands:
❍ Machining Process View : to display the Machining Process window
❍ Machining Process : to create a new Machining Process.
3. Create your Machining Process operation by operation: all axial operations are available. Define parameters for operations just like in a Manufacturing Program (Offset, Feeds & Speeds, and so on).
4. Thanks to Knowledgeware integration, you can define formula and checks for each operation.5. Define tool query for each operation.
A user task for creating a machining process is described in this guide.
Store Machining Processes in Catalogs
You can either:
● right-click the Machining Process in the Machining Process View and select Save in Catalog.
● use the Catalog Editor to store the machining process in a new catalog.
1. Save the CATProcess containing the machining processes (do not close this document).2. Create a new Catalog with Catalog Editor.3. Save the machining process in this catalog.4. Save the catalog.
A user task for organizing machining processes in catalogs is described in this guide.
Using the Machining Process
This is the Run Time step, usually performed by the NC Programmer.
1. Retrieve the machining process from the catalog using Open Catalog .
2. Apply the machining process in your NC program.3. Edit the created machining operations to complete geometry selection and possibly the tool definition.
This is the case if no Tool Query was defined or the Tool Query did not find a suitable tool.
A user task for applying a machining process is described in this guide.
Step by Step Example
When working with Pocketing operations, you usually use a different set of options depending on the geometric shape to machine or the part material type.
You can define and put in the system a machining process to be used for:
● simple pockets
● pockets using High Speed Machining (HSM) techniques
● pockets using soft materials.
Steps for Creating the Machining Process
Click Machining Process .
1. Define one or more machining operations.2. For the machining operations, define your preferred Options, Strategies, Parameters, Macros, and
possibly tool queries.3. Save the CATProcess document using File > Save. 4. Store the Machining Process in a V5 Catalog.5. Select (or create) the Component Family in which you want to store the machining process.
6. Click Add Component .
7. Select Select External Feature in the dialog box that appears.8. Select the CATProcess document, then the Machining Process.
Some Hints
In order to facilitate the NC Programmer job at selection time:
● use explicit names for the Machining Processes
● possibly use home-made icons
● carefully manage the catalog families and sub-families.
Steps for Using the Machining Process
Click Open Catalog .
1. Navigate in your catalog, and select the required Machining Process.2. Select the operation after which you want the Pocketing operation to be created, and click OK.3. Edit the Machining Operations to specify the Tool to be used if no Tool Query was defined in the
machining process and complete geometry selection.
Some Hints
Catalog organization (structure, comments) is key for a quick and efficient selection of machining processes by the end-user.
For more information, refer to the following:
● Feature Attributes for Tool Queries, Checks and Formula
● Knowledgeware in Machining Processes.
Knowledgeware in Machining ProcessesThis document explains how to make use of Knowledgeware capabilities in Machining Processes.
Define Links to External Data (URL) for Machining Processes
In the Knowledge Advisor workbench you can define links to external data (URL) for Machining Processes. For example, you could define a link to workshop documentation that describes the Machining Process.
This documentation can be edited (with its editor) when:
● selecting the URL & Comments command in the Organize Knowledge tool bar
● applying the Machining Process by selecting this command in the Machining Process instantiation window.
Create Parameters for a Machining Operation in a Machining Process
In a Machining workbench, create a Machining Process with a machining operation (Drilling operation, for example).
In the Knowledge Advisor workbench, use the Parameters Explorer command to create a Length parameter called AxialLengthforNCMacro with a value of 2.5mm.
This parameter can be associated to the Drilling operation using the Edit Formula command. It will be solved in the same way as other parameters when the Machining Process is applied.
You can use this parameter to define f(x) formula on other parameters when editing the machining operation. In particular, it can be used for NC Macro parameters which are not available in Knowledgeware and Search functionalities.
Note the full integration of f(x) Knowledgeware in Machining Processes which are saved when a Machining Process is applied.
In the example above, the instantiation of the machining process on a design hole with a 10mm depth will set the AxialLengthforNCMacro parameter to 5mm and the Axial Macro approach distance to 5mm.
Please refer to the Knowledgeware documentation for more information.
CATProduct and CATProcess Document Management
This document explains how a Product (CATProduct document) is managed in a Process (CATProcess document), what happens when the Product is modified, and the recommended methodology in a Machining context.
What is a Product
A basic Product comprises Parts, Products and elements (constraints, positions). These constraints and positions define the relative/absolute position of the Parts and Products. The Part and Product documents are referenced by the Product by means of links.
Product in a Process
When a basic Product is to be used by a Process, an instance of the Product is created in the Process. The Product document is referenced by this Product instance by means of link.
The instance keeps the Product as reference according to one of two possible modes: Flexible (default mode) and Rigid.
What is Impacted by Flexible and Rigid Modes
There are three types of modifications that can be done inside and under the Product structure that is inserted in the Process:
● part modifications: for example, geometry modifications done in the Part Design workbench
● modifications to the structure of the products: addition, deletion or reordering products
● modification of geometric position data located in the CATProduct document.
Only modifications to geometric position data will function differently in Flexible and Rigid modes.
Part Modifications
Part modifications function in the same way in Flexible and Rigid modes.
Any modification to the Part does not impact Product or Process documents.
Modifications to the Structure of the Products
Modifications to the structure of the products function in the same way in Flexible and Rigid modes.
Propagation mechanisms of changes between the instance and the reference of the Product exist. The following are propagated immediately:
● insertion, destruction of constraints
● insertion, destruction and replacement of links to a Part
● insertion, destruction, or modification of parameters and rules.
Geometric Position Data Modifications
Modifications to geometric position data function differently in Flexible and Rigid modes.
Modification and update of the position of the Parts and the Products (using the compass) or the constraint values (such as offset, angle, and side) are propagated or not depending on the Rigid or Flexible mode.
In Rigid mode
Modification and update are propagated immediately.
In Flexible mode
In general, modification on the reference is propagated to the instance. However, when constraint or position data is changed on the instance, then instance and reference position data are no longer correlated. Any later modification to the reference is not propagated to the instanceTherefore, a modification done in the Product Structure workbench will be propagated on the Process document only if constraint or position data has not been overridden.
Note that data update is not propagated to the instance and has to be performed on the instance. To update the instance from the CATProcess document, go into the Assembly Design workbench and use the Update All command.
Modification and constraint update on the instance are not propagated to the reference.
To force the propagation of all modifications on the instance to the reference, use the Propagate position to
reference command on the instance.To forget all modifications on the instance and retrieve the reference state, use the Flexible/Rigid Sub-Assembly command twice on the instance.
These commands are available in the Assembly Design and Product Structure workbenches.
How to Change Mode
The mode can be changed on the instance using the Flexible/Rigid Sub-Assembly command. Modifications of positions and constraint values on the instance will be lost.
CATProduct Generic Machines
A generic machine is a CATProduct representation created using the NC Machine Tool Builder product. It can be referenced in a Part Operation in a CATProcess. The characteristics of the machine can be modified using the Part Operation's Machine Editor.
These machines adhere to the Instance/Reference mechanism described above. A generic machine is added to the ResourceList in Flexible mode. This means that any modification to the machine in the CATProcess is valid only for that instance of the machine in that CATProcess: the modification is not propagated to the reference (that is, the CATProduct file).
Methodology
Rigid Mode
You can modify the instance or the reference, they are both impacted by modifications. The Product has a strong link to the Processes where it is used. You are allowed to modify (and save) the CATProduct document.
For a Machining-dedicated Product that is used in a Machining CATProcess document, the preferred mode is Rigid.
Flexible Mode
You can modify the instance or the reference depending on what you want to do:
● For a specific position for the Process, modify the instance (through the Process document).
● For a specific position for the Product, modify the reference (through the Product document).
● The Product can be tuned for each Process where it is used.
For a Product that is not Machining-dedicated and used in a Machining CATProcess document, the preferred mode is Flexible.
Selective Loading of Machining Data
When the user loads a CATProcess in an NC Detailing workbench (NC Manufacturing Review, Prismatic Machining, Surface Machining, Advanced Machining or Lathe Machining), the associated CATProducts and CATParts are activated in Design mode. This is because the commands in these workbenches often require geometry selection. This is the case even when working with Cache management.
If the CATProduct or CATPart was saved in Visualization mode, this mode may be conserved for machine simulation, for example. So it is possible to work with Cache management in this case.
Copy/Paste of NC Manufacturing DataThis document deals with copying Machining data between CATProcess documents. You can Copy/Paste part operations, manufacturing programs, machining operations, and machining processes from one CATProcess document to another.
All the NC data is duplicated in the target document through the Copy/Paste mechanism.
Copy/Paste Between CATProcesses
You can Copy/Paste the following Machining activities:
● Part Operation pasted on a Part Operation or the Process
● Manufacturing Program pasted on a Part Operation or a Manufacturing Program
● Machining Operation pasted on a Part Operation, a Manufacturing Program, a Machining Operation, a Machining Process
● Machining process pasted on a Machining Process View or a Machining Process.
Note that Tool paths are not copied.
NC features
The Duplicate Geometry Links option in the Tools> Options > Machining > Operation tab page must be set to take into account the copy of NC Geometrical data.
All the NC features are copied with the activities which reference them. Machining Patterns, Machinable Area Features, Machining Features are copied. Features are copied only if they are used by operations.
If the option is not set, only NC activities and resources data are copied.
Product and Part documents data
If Machining Activities to be copied are included in a Part Operation, then:
● For a Part Operation, the Product reference is included in the target document
● For any other activity, the user has to check that the target Part Operation references the correct Product documents. In this case, each geometrical link will be maintained only if the Product associated to the link is included in the Product associated to the original Part Operation.
NC resources
The resource is in the original Process document:
● If the resource does not exist in the target document, it is copied in the resource list.
● If the resource exists in the target document (same attributes), no copy is done and the existing resource is used.
Design Changes and Associativity MechanismsThis section deals with design changes and the various associativity mechanisms provided with Machining products.
For information about... Please refer to...
Methodology for Design Changes.● Preparation
● Design/Manufacturing Reconciliation by:
❍ direct selection using the Part Operation editor
❍ Edit Links capability.
● Associativity and Publication in Machining Documents.
● Associativity and Publication for Axial Machining Operations.
Status for operation creation and modification, Geometry not up to date, Geometry not found, tool path status, and so on.
Product Behavior for Design Changes
Methodology for Design Change
The following example illustrates the methodology for Design/Manufacturing reconciliation after a design change.
Consider a Part Operation which references a CATProduct (Product1), which in turn references a CATPart (Part1).
Product.1, which is the component visible to the user in the interactive session, is stored in the document Product1.CATProduct.
Part.1, which is the component visible to the user in the interactive session, is stored in the document Part1.CATPart.
In order to modify the design of the CATPart proceed as follows.
Preparation Before Design/Manufacturing Reconciliation
1. Modify the design in Part1.2. Save Part1 as Part2 (rename Part1.CATPart as Part2.CATPart).3. Open Product1.4. Replace the component Part1 by Part2.5. Save Product1 as Product2 (rename Product1.CATProduct as Product2.CATProduct).
Note that component instance names of Product1 should be unique and they should be identical to the component instance names of Product2. Product part numbers may be different.
Then there are two ways for reconciliation of the design and manufacturing:
● by direct selection using the Part Operation editor
● by Edit Links.
Design/Manufacturing Reconciliation by Direct Selection using the Part Operation Editor
1. Open the CATProcess.
2. Edit the Part Operation that references the old design. Click Product in the Part Operation dialog box and select
the new product.
3. Click OK to quit the Part Operation dialog box. The various machining operations are updated.
Note that, depending on the document environment setting (Tools > Options > General > Document tab), the new product can be selected from a file, a catalog, and so on.
Design/Manufacturing Reconciliation by Edit Links
1. Select Edit > Links. 2. In the Links tab, select the line corresponding to the link of the Part Operation that references the old design, then
click the Replace button.
Notes
● You must use the Links tab to replace the old design. Do not use the Pointed Documents tab to do this.
● You must not do a Replace on the line corresponding to the Product > CATProduct link. This link is not managed by Machining products and so cannot be used in design/manufacturing reconciliation.
● The impacts of the reconciliation are global with respect to the CATProcess and not local to the Part Operation. This means that all the Part Operations that referenced the old design will now reference the new design.
More About Associativity in Machining Documents
In case of design changes, the designer provides the NC programmer with one or more new CATParts and CATProducts. The programmer has to replace the old CATProduct referenced by the CATProcess by a new one including the new CATParts and CATProducts. As described in the previous chapter, the programmer can use either the Edit Links capability or the Part Operation editor for this.
A CATProcess can be linked to CATProduct/CATPart in several ways:
1. There are links between Part Operation and the CATProduct containing the geometry to be machined.2. There are links between operations and the geometry to be machined contained in the different CATParts/CATProducts
included in the CATProduct linked to the Part Operation.3. There are links between formulas used by the operations and CATParts/CATProducts included in the CATProduct linked
to the Part Operation through the formula parameters.
When a design referenced by the CATProcess is modified, the NC programmer has to reconcile the CATProcess with the new CATProduct using the Edit Links capability.
After reconciliation using the Edit Links capability:
1. The new CATProduct should appear in the ProductList and be linked to each Part Operation that was linked to the old one.
2. Each operation that pointed a geometry that was included in the old CATProduct:
❍ should now be linked to the equivalent geometry in the new CATProduct if it exists
❍ or be in Geometry not found status, if the equivalent is not found in the new CATProduct.
3. Each formula that referenced an element of a CATPart of the old CATProduct, should now reference the equivalent element in the new CATProduct.
That is, if a formula points to parameters that are defined in the CATProduct you want to replace, after reconciliation the formula will point to the corresponding parameters in the new CATProduct.
If some of these parameters are not found, the behavior will be the same as when a parameter is deleted. A clone of the parameter will be aggregated under the formula. It will take the value of the old parameter and becomes fixed. The formula will be not broken and will continue to be associative with the other parameters.
Note that this rerouting is possible only if the new CATParts and CATProducts are created by a Save As of the old ones. The instance names in the new CATProduct must be the same as in the old CATProduct.
Associativity and Publication in Machining Documents
All links on published geometric elements can be retrieved using the Edit Links capability or the Part Operation editor even when the replaced part is new compared to the previous one. This means that associativity is assured in design change scenarios even when CATProduct/CATPart B is a New From of CATProduct/CATPart A.
Consider the following scenario where the NC programmer receives a CATProduct, in which some geometric elements have been published.
The programmer defines the process by selecting either the published elements in the specification tree or the geometry in the geometry visualization area.
The publication name of the published reference geometry is displayed in the Geometry Analyser dialog box. This enables the programmer to be sure that the selected geometry has been published.
The NC programmer receives a new version of this CATProduct. To reconcile the original CATProcess with this new version, the programmer can use the Edit Links capability or modify the CATProduct using the Part Operation editor.
To be sure there are no positioning problems in the old and new CATProducts, each instance corresponding to an old one should have the same instance name.
Then the NC programmer must select the new CATProduct.
For each operation pointing to published geometry, the system searches for the same publication name in the corresponding product instance (same instance name). If the corresponding publication is found, the operation will be rerouted to the new geometry.
Manual rerouting is proposed for publications that have not been solved automatically in the following dialog box.
The NC programmer must select the new publication in the new CATProduct inserted the ProductList that corresponds to the old publication.
In this case, all operations that pointed to the geometry under the old publication will be rerouted to the geometry under the new one.
Publications that are not solved at this time will be lost and operations that pointed to geometry in this old publication will be in Geometry not found status.
The NC programmer obtains a new CATProcess with operations whose status is Not up to date (or Geometry not found if some selected geometry was not published or have no corresponding publications in the new CATProduct). The programmer must then validate the reconciliation by analyzing geometry and replaying the tool path.
Associativity and Publication for Axial Machining Operations
Geometry in axial operations is defined by a machining pattern and a geometrical feature. The geometrical feature is automatically linked to a design geometry when the first position of the machining pattern is selected. If this position is a design pattern, then the geometrical feature is linked to the design pattern's reference.
An axial operation is geometrically complete when:
● its geometrical feature is linked to a design geometry
● its machining pattern contains at least one point.
In the following example, Drilling.1 contains a machining pattern whose referenced geometry is RectPattern.1. When RectPattern.1 is selected, Hole.1 (reference of RectPattern.1) is linked to the geometrical feature of Drilling.1.
If you want to make a design change by replacing the Part or Product in the Part Operation, both RectPattern.1 and Hole.1 must be published. Then all geometrical links in the axial operation can be resolved.
Product Behavior for Design Changes
The rules described below describe the various status of the elements referenced by machining operations and how to recognize these status. It deals with the following:
● Elements referenced in a machining operation, which are colored according to the Color and Highlight settings specified in Tools > Options > Machining > General.
● Status lights on machining operation tabs, for example .
● Masks used in the specification tree, for example .
● Texts used in the specification tree, for example Computed.
Useful settings in Tools > Options > Machining > General for tracking design changes are:
● Smart NC mode
● Optimized detection of design changes
● Update activity status automatically.
Operation Creation
Before selection, a required element is colored according to the color setting for Required parameters. Once selected, it is colored according to the color setting for Valuated parameters.
Before selection, an optional element is colored according to the color setting for Optional parameters. Once selected, it is colored according to the color setting for Valuated parameters.
The status light on a tab is Red when all the required elements of that tab have not been selected. Once selected, the status light becomes Green.
The Replay is not available when the status light on a tab is Red.
After a successful Replay, the status of the operation becomes Computed. Depending on the Machining product and/or type of operation, a tool path node may be added to the computed operation in the specification tree.
Operation Modification
Once modified, a selected element is colored according to the color setting for Geometry not up to date.This allows quick recognition of impacted machining features.
The Analysis of the element is then possible: its status becomes Not up to date. Its Smart Geometry is visible.
The status light of the corresponding tab is Orange.
In the specification tree, the operation icon has an Update mask . If the operation had Computed status, it remains in this state.
The Replay is available.
Selected Element No Longer Present
Once deleted (or no longer present), a selected element is colored according to the color setting for Geometry not found. This allows quick recognition of deleted machined geometry.
The Analysis of the element is then possible: its status becomes Not found. Its Smart Geometry is visible.
The status light of the corresponding tab is Red.
In the specification tree, the operation icon has an Exclamation mask . If the operation had Computed status, it remains in this state.
The Replay is not available.
The status light of the corresponding tab becomes Green when all the elements with the Geometry not found or Required parameters color setting are:
● selected (they take the Valuated parameters color setting)
● or "removed" (they take the Optional parameters color setting).
The Replay is not available when the status light on a tab is Red.
Operation Status
An Update mask means that at least one selected element has been modified. In the corresponding tab the status color is Orange and the color setting is Geometry not up to date.
An Exclamation mask means one of the following:
● At least one selected element is no longer present. In the corresponding tab the status color is Red and the color setting is Geometry not found.
● At least one required element has not been selected. In the corresponding tab the status color is Red and the color setting is Required Geometry.
A Locked mask means that a computed operation and its tool path is in a Locked state. The OK button of the operation editor is not available. This is the result of a deliberate user action and the operation remains in this state until it is unlocked by the user.
Please refer to Lock/Unlock Mechanisms for more information.
Status are obtained when Update Activity Status Automatically is not set in Tools > Options > Machining > General. To
know the status of one, several or all operations of a program, you must click Status of Selected Activities in the
Auxiliary Commands toolbar.
Tool Path Status
The Computed text in the specification tree means that the operation has been computed (that is, the tool path is present).
It does not guarantee the coherence of the operation with respect to the context. Its coherence is guaranteed by a replay when this available.
When there is no text, this means that the operation has not been computed (that is, the tool path is not present). This status is obtained after creating an operation without a tool path replay or after removing a tool path.
Product-Setup Link in Manufacturing Hub ContextAs from V5R16, association or replacement of the NC Setup Assembly (or Product) referenced by the Part Operation (or Setup) by selecting it in the Product List is possible in the Manufacturing Hub context.Now, when an NC detailing application handles Process Engineer project data in the Manufacturing Hub context, only product instances are managed using the Product List.
Prior to V5R16, NC product replacement or association to Part Operation could only be done in a file based context.
Manufacturing Hub contextAllows NC detailing in CATIA V5 environment and process planning in Process Engineer E5 environment.V5/E5 interoperability allows transferring project data from Process Engineer to NC detailing and saving NC detailing data in a Process Engineer project.
Product-Setup Link Issues (Prior to V5R16)
Prior to V5R16, the Part Operation (or Setup) references either product references or product instances according to how these components are linked. In the Manufacturing Hub context, this is the source of two major issues:
● NC product association to Part Operation
● NC product replacement (design change scenario).
NC Product Association to Part Operation
Design Products are created and managed through the Engineering Hub. Machining Processes are defined and managed through the Manufacturing Hub.
In the figure below, the design (Product V1) was associated to the Product View in E5 (1). Only the product instances are available in this context.
In V5R15, association by drag and drop in E5 (2a) is the only one which enables to associate a NC product to a Part Operation. The association through Part Operation (2b) in V5 does not work.
NC Product Replacement (Design Change Scenario)
In the figure below, Product V2 is a second version of Product V1 (1).
A new Subassembly is created in E5 and Product V2 is associated to this new one (2). However, it is not possible to support a Design Change scenario with V5R15 services (Part Operation editor or Edit/Links) whose mechanism is based on links to product reference (3).
Product-Setup Link Solutions (As from V5R16)
To solve these problems in V5R16, the Product-Setup link will be the same since Part Operations will always be associated to product instances. This enables to associate or replace a Product whatever the methodology used.
In addition, the link to product instances enables the following:
● Making the Product-Setup link persistent after save in IPD.
● Managing several machining phases of the same Product in a unique Process, each phase corresponding to one instance of the Product. You can manage different setups or constraints for the same Product.
● Making design changes local to the Setup and not necessarily global to the Process.
The different ways to associate a Product to a Part Operation and to replace a Product by a new one are discussed below. Most of the services described here already exist in V5R15 but they can only work in Manufacturing Hub context if there is a link to a product instance.
How to Associate a NC Setup Assembly to the Part Operation
This can be done as follows:
● NC Setup Assembly instance selection through Part Operation editor.
● Drag and drop in Process Engineer.
● Drag and drop in CATIA/DELMIA.
In what follows, we assume that you have already created a Process Engineer Project including a Process View and a Product View. In the Process View, you have already created a WorkPlan (machining process) including a ManufacturingSetUp (Part Operation). In the Product View, you have already created a NC subassembly.
NC Setup Assembly Instance Selection through Part Operation Editor
There are two ways to achieve this association:
Methodology 1:
● Drag and drop of the NC Setup Assembly to the Workplan (machining process) in the Process Engineer Project (1).
● Load this Project in CATIA\DELMIA by using the PPR Hub toolbar (2-3). NC Setup Assembly is inserted in the ProductList (4).
● To associate this NC Setup Assembly to the Part Operation, edit the Part Operation by clicking on the Product Instance Selection icon and selecting the NC Setup Assembly in the ProductList (5-6).
Methodology 2:
● Load the Project in CATIA\DELMIA (1-2-3).
● Load the NC Setup Assembly in the ProductList in CATIA/DELMIA by using the PPR Hub toolbar (4).NC Setup Assembly is inserted in the ProductList (5).
● To associate this NC Setup Assembly to the Part Operation, edit the Part Operation by clicking on the new Product Instance Selection icon and selecting the NC Setup Assembly in the ProductList (6-7).
Drag and Drop in Process Engineer
You can associate the NC Setup Assembly directly in the Process Engineer Project. In the Project you have already created a Subassembly (NC Setup Assembly) in the Design View and you have created a ManufacturingSetup (Part Operation).
● Select the Subassembly and drag and drop (1) it to the ManufacturingSetup.
● Create a Process Processes Product type link (2).
Drag and Drop in CATIA/DELMIA
Assuming you already made either the steps (1) to (4) of Methodology 1 or the steps (1) to (5) of second Methodology 2.In CATIA/DELMIA, to associate this NC Setup Assembly to the Part Operation, drag and drop the NC Setup Assembly instance from the ProductList to the Part Operation.
How to Replace a NC Setup Assembly in the Part Operation
In CATIA V5, note that it becomes impossible to use Edit/Links functionality to replace the Product in the Machining context. In fact, Edit/Links is based on the exposition of an external link between the Part Operation and the product reference (Product/Part). This link no longer exists so it is impossible to expose it. The Part Operation now points to a product instance not to a product reference.
In what follows Revision means when the document is modified and saved on the same document and Version means when the document is modified and saved as a new document.
In Manufacturing Hub context, there are two ways to manage the NC Setup Assembly. In both cases you have to create a Product View, a Design View and a Subassembly in the Process Engineer Project. The Subassembly corresponds to the NC Setup Assembly.
Then you have two different modes to create the Subassembly:
● You can directly link this Subassembly to a Product (the structure of the NC Setup Assembly is not visible through Process Engineer): Double-click the Subassembly (1)Select the Graphic tab (2)Associate the Product to the Subassembly (3).
● You can split the Subassembly into subelements (Parts, IPMs, and so on) and associate Parts to these subelements (the structure of the NC Setup Assembly is visible through Process Engineer).Double-click a subelement of the Subassembly (1)Select the Graphic tab (2)Associate the Product to the Subassembly (3).
New Revisions of NC Setup Assembly or Part
If you just do revisions of your design documents, reconciliation is automatic. You just have to compute the tool path again if it is necessary.
New Versions of NC Setup Assembly
In the following methodologies the Subassembly is linked directly to a Product.
Methodology 1:
● In E5: You can directly replace the current NC Setup Assembly (ProductV1) associated to IPD Subassembly (Subassembly V1) by a new one (1-2-3) and save the Project.
● In V5: Open the Project in V5 and synchronize the Process (4). Here, the machining operation is no longer synchronized because the design change scenario was processed in E5 environment. Refer to NC Synchronization in Manufacturing Hub Context.
Methodology 2:
● In E5: You can create a new IPD Subassembly under the same Production View (1) and link it to the new version of the NC Setup Assembly (2-3-4). Then you save the Project in IPD.
● In V5: Open the Project in V5, and edit the Part Operation (5). Click on Product Instance Selection icon and select the new NC Subassembly: Subassembly V2 (6). The replacement is done (7). Note that the Machining Operation is always synchronized because the design change scenario was processed in V5.
New Versioning of Part when the Subassembly is Linked Directly to a Product
In V5: You just have to replace the NC Part in the NC Setup Assembly (Product) and synchronize the Process.Refer to NC Synchronization in Manufacturing Hub Context.
New Versioning of Part when the Subassembly is Split into Subelements
Methodology 1:
● In E5: You can directly replace the current Part (PartV1) associated to IPD Part (Part, 1) by a new one (1-2-3) and save the Project.
● In V5: Open the Project in V5 and synchronize the Process (4). Here, the machining operation is no longer synchronized because the design change scenario was processed in E5 environment. Refer to NC Synchronization in Manufacturing Hub Context.
Methodology 2:
● In E5: You can create a new IPD Subassembly and new IPD Part under the same Production View (1). Note that the name of the IPD Part must be the same in the both IPD Subassemblies. Then, link the new NC Part (PartV2) to the IPD Part of the new version of IPD Subassembly (2-3-4) and save the Project in IPD.
● In V5: Open the Project in V5, edit the Part Operation (5). Click on Product Instance Selection icon and select the new Subassembly (6). The replacement is done (7). Note that the Machining Operations are always synchronized.
Multi-replacement of NC Setup Assembly
In V5, it is possible to locally replace the Part Operation or globally replace all Part Operations pointing to the same NC Setup Assembly.
Case 1: In selected Part Operation onlyIf you choose a local replacement, even if there are several Part Operations pointing to the same NC Setup Assembly, the design changes will impact only the edited Part Operation. All the other Part Operations, pointing to the same NC Setup Assembly, continue to point to that one. Nevertheless, if the other Part Operations reference some activities using some shared elements that are also used by the edited Part Operation (such as formula, Patterns, and Machining Areas) they will also be impacted by the design changes.
Case 2: In whole ProcessIf you choose a global replacement, all Part Operations pointing to the same NC Setup Assembly will be impacted by the replacement. If the selected Part Operation is the only one pointing to a given NC Setup Assembly, the global mode is automatically applied.
As an example of this, imagine that several Part Operations point to "New Subassembly 1".
1. Edit the first one.
2. Replace the current NC Setup Assembly by "New Subassembly 2". The Product Replacement dialog box appears.
3. If you select In selected Part Operation only then only the edited Part Operation will be impacted. If you select In whole Process then all the Part operations will be impacted.
How to Copy Activities Between Projects
This section deals with the inter-project copy of activities (that is, machining operations).
Reminder: In V5 application in Manufacturing Hub context, it is not possible to copy an activity from a Project A to a Project B if the Part Operation included in Project B is not already associated to a NC Setup Assembly.
When you copy activities from a Project A (1) to a Project B (2) in a Part Operation with an associated NC Setup Assembly, three different cases can occur according to NC Setup Assembly associated to the origin Part Operation and NC Setup Assembly associated to the target Part Operation (3).
Case 1: The target NC Setup Assembly is the same as the origin NC Setup Assembly. In this case the activities will be rerouted on the new NC Setup Assembly instance. The status of the NC geometries does not change.
Case 2: The target NC Setup Assembly is a Save As from the origin NC Setup Assembly. The status of NC geometries are "Not up to date" for geometries that have changed.
Case 3: The target NC Setup Assembly is completely different from the origin NC Setup Assembly (or a New From). In this case, the status of all NC geometries are "Not Found".
If you do not use the Duplicate geometry links option, all the activities will be disconnected in any case.
NC Synchronization in Manufacturing Hub Context
This section discusses NC Synchronization in the Manufacturing Hub context.
This capability enables you to delete at least one Part belonging to the NC Setup Assembly or replace the current version of it by a new version. You can manually or automatically synchronize the Process with the new version of the Part.
Detecting Synchronization Problems
New Not Synchronous Mask on Activity in the Graph
The following status values are possible for an activity:
● Up To Date: In this case, no specific mask is displayed.
● Not Up To Date: In this case, an Update mask is displayed on the graph node of this activity. This symbol appears when the geometry pointed has been modified (for example, if you made a new revision of the Part and, in this revision, you have modified a surface that is used by a facing operation).
● Not Complete: In this case, an Exclamation mask is displayed on the graph node of this activity. This symbol appears when the geometry pointed has been deleted (example: You made a new revision of the Part. In this revision you have deleted a surface that is used by a facing operation).
● Not Synchronous: In this case, a red cross mask is displayed (as from V5R16). This symbol will appear, when the geometry pointed belongs to a Document which does not correspond to the Product instance pointed in the ProductList.
Example: You have made a new version of the Part and you have replaced it in the Product, but you have saved the Product without versioning. So in the ProductList the new version of the Part is visualized but the operation still points on the old Part.
As for the other statuses, the Not synchronous mask will be visualized automatically only if the Update activity status automatically option is active. Otherwise, it will be displayed only if the user refreshes the activity status.
The priorities between the different statuses are the following.
● First, a check is done to see if the activity is synchronous, otherwise the mask is displayed.
● Then, a check is done to see if the activity is complete, otherwise the mask is displayed.
● Finally, a check is done to see if the activity is up to date, otherwise the mask is displayed.
New Color of Geometry Manipulators
In order to help the user to understand the status defined on the operation, different colors are customizable to display the geometry manipulators in the editors.
By default, Up to date geometries are displayed in green, Not up to date geometries are displayed in brown, Not Found geometries are displayed in purple, and Not synchronous geometries are displayed in dark mauve.All these colors are customizable in Tools/Options.
New Status in Process Table
In the Process Table, an operation can have the following statuses:
● Up To Date if the operation is up to date
● Not Up To Date if the operation is not up to date
● Missing Information if the operation is not complete
● Not Synchronous if the operation points on a design that does not correspond to the one defined in the Product List.
New Status in Analyze Geometry Dialog Box
The following statuses are displayed for each geometric element in the Analyze Geometry dialog box:
● Up to date
● Not up to date
● Not found
● Not synchronous.
Manual and Automatic Synchronization
Manual Synchronization
Prior to V5R16, when an operation was not synchronous, the only way to synchronize it was to remove all geometry links and manually select the new geometry. It is still possible to synchronize this manually but it is easier to know the geometry links that need to be reselected thanks to the Not Synchronous color of the geometry manipulator and the Not Synchronous status in the Analyze Geometry dialog box.
Automatic Synchronization
As from V5R16, you can synchronize the CATProcess automatically with Synchronize Process in the
Auxiliary Commands toolbar. The synchronization is global to the CATProcess. This command takes into account the Optimized detection of design changes option. It is possible to undo the synchronization.
Synchronization corresponds to reconciliation between the operation and the document present in the Product List.
Concerning Geometry
Reroute will be possible in the following cases:
● Geometric element is not published and the Part A' is a Save As of the Part A.
● Geometric element pointed in Part A is published in Part A itself (not in the product).
In these cases, reroute will also take into account the Optimized detection of design changes option.
Reroute will not be possible and operation will be disconnected in the following cases:
● Part A has been removed from the Product.
● Geometric element is not published and the Part A' is not a Save As of Part A.
● Geometric element pointed in Part A was published in Product context but not directly in Part A.
Concerning Formula
When a formula points on a parameter defined in a document that is not present in the Product List, two cases may be considered:
1. If it is possible to find the equivalent parameter in one of the documents of the Product List, we reroute the formula on it.
2. If it is not possible, we create a clone of the old parameter set with its previous value in the formula. In this case, the formula is not parameterized any more.
Compute Tool Path, Replay, Simulation and CATMFG
When an activity is not synchronous the integrity of the computed tool path cannot be guaranteed. It is considered as not complete. Therefore, if an activity is not synchronous, then compute tool path, replay, simulation and CATMFG will not be available except if the tool path or the activity is locked.
In CATMFG a message is generated in the Log file to indicate the Not synchronous status of this activity.
Examples of Scenarios Resulting in a Non Synchronized Process
Refer to New Versioning of NC Setup Assembly (Methodology 1) and New Versioning of Part when the Subassembly is Split into Subelements (Methodology 1) for detail about scenarios which cause the de-synchronization of NC geometry.
Lock/Unlock Mechanisms
Locked Machining Operations
Often, when a machining operation is computed (that is, the tool path is calculated), it can be useful to lock the operation to prevent the tool path from being removed (for example, in case of design or operator change) and allow the NC Programmer to determine what was machined and how it was machined based on the replay of the locked tool path.
Lock / Unlock Commands on Machining Operations
In the contextual menu for a computed machining operation, there are four commands allowing different lock/unlock actions.
Lock: Lock the tool path and the operation parameters.In this case the Locked mask (yellow padlock) appears on the operation icon in the PPR tree.
Unlock: Unlock the tool path and the operation parameters.
Lock Tool Path: Lock the tool path only.In this case the Locked Tool Path mask (green padlock) appears on the operation icon in the PPR tree.
Unlock Tool Path: Unlock the tool path only.
Commands available depending on the operation's Lock state
The operation is not locked and its tool path is not locked.Available commands are Lock and Lock Tool Path.
The operation is not locked but its tool path is locked.Available commands are Lock and Unlock Tool Path.
The operation is locked (Tool path and operation parameters)Available command is Unlock.
Functionalities available depending on operation's Lock state
The operation is locked (Tool path and operation parameters):
● Replay, simulation and NC data generation are based on the locked tool path.
● Compute tool path and remove tool path are not possible.
● Replace tool is unavailable.
● The OK button on the operation editor is disabled. You can only browse the operation.
● Tool path edition is possible for operations with a tool path node.
The operation is not locked but its tool path is locked:
● Replay, simulation and NC data generation are based on the locked tool path.
● Compute tool path and remove tool path are not possible.
● Replace tool is available.
● The operation editor is available but no update of the operation will be done by means of the OK button.
● Tool path edition is possible for operations with a tool path node.
Please note the following points.
● To modify the tool path using the tool path editor, the Edit Tool Path checkbox must be selected in the Tools > Options > Machining > Output.
● When generate NC data is generated for a locked machining operation, a specific message will be issued in the CATMFG.log file.
● The Lock Operations checkbox can be set in the Generate NC Output in Batch Mode dialog box to lock all operations after NC data generation when Save document is requested.
Lock / Unlock Commands on Manufacturing Programs
By right-clicking a Manufacturing Program you can use the Lock Children or Unlock Children command to lock or unlock all the children nodes of the program (that is, the program's machining operations) .
Lock Children:The child node is not locked and its tool path is not locked: Lock Tool Path and operation parameters.The child node is not locked but its tool path is locked: Lock operation parameters, Tool Path already locked. The child node is locked: Tool Path and operation parameters already locked.
Unlock Children:The child is not locked and its tool path is not locked: Tool Path and operation parameters already unlocked.The child is not locked but its tool path is locked: Unlock Tool Path, operation parameters already unlocked.The child is locked: Unlock Tool Path and operation parameters.
By right-clicking a Manufacturing Program you can use the Lock Tool Path or Unlock Tool Path command to lock or unlock all the tool path nodes of the program.
Lock Tool Path:The child node is not locked and its tool path is not locked: Lock Tool Path.The child node is not locked but its tool path is locked: Tool Path already locked.The child node is locked: Tool Path already locked.
Unlock Tool Path:The child node is not locked and its tool path is not locked: Tool Path already unlocked.The child node is not locked but its tool path is locked: Unlock Tool Path.The child node is locked: Tool Path is protected by the operation lock. You cannot unlock the Tool Path only. You have to unlock the operation.
Tool Path Stability
The Lock Tool Path functionality offers a means for ensuring the stability of a computed NC tool path from one release to another.
Knowing that tool path variations may be introduced from one release to another due to algorithm enhancements or maintenance interventions, this functionality reduces NC Programmer time and effort by eliminating the need to re-calculate and re-validate previously computed NC data.
When Lock Tool Path is used, the computed tool path data is stored in the model. If an operation is not modified from one release to another (that is, geometry, parameters, and so on are unchanged), it is not re-calculated: the previously stored tool path data will be read.
Part Operation and Set Up DocumentsThis document provides methodology for setting up the workpiece, stock, and fixtures on the machine.
A user task showing you how to manage part set up is also include in this guide.
Terminology
Part Operation means:
● One machine
● One set up (that is, workpiece in position on the machine )
● One or more Manufacturing Programs (same set up). One program equals one NC output file (APT, CLFile, or NC code).
Set up is usually defined through a CATProduct document. It includes the machine table, the workpiece (in position), the fixtures, and the stock.
A CATProcess document can include several Part Operations. Each Part Operation references a different CATProduct set up document.
Preparing the First Set Up
Create one CATProduct document for first set up with:
● Machine table (one CATPart document)
● Workpiece (one CATPart document)
● Three fixtures (three instances of the same CATPart document).
Preparing the Second Set Up
Create one CATProduct document for second set up with:
● Machine table (one CATPart document)
● Workpiece (one CATPart document)
● Two fixtures (two instances of the same CATPart document)
● Support (one CATPart document).
Programming the Top of the Workpiece
Use the first CATProduct document for first Part Operation.
Programming the Bottom of the Workpiece
In the same CATProcess document (or in another), create a Part Operation that refers to the second CATProduct (that is, the second set up).
Hints
If there are several Part Operations in the same CATProcess document, then by activating one Part Operation, the system will show the corresponding Product(s) referenced by that Part Operation.
Material Removal SimulationThis section deals with the material removal simulation capability provided with the Replay Tool Path command.
For information about... Please refer to...
CATProduct user representation of tools● CATProduct User Representation of Milling Tools
● CATProduct User Representation of Lathe Tools
● CATProduct User Representation of Cleaning Tools
CATPart tools for milling CATPart Tools for Photo or Video Mode
Stock considerations Stock for Material Removal Simulation
CATProduct User Representation of Milling Tools
You can attach a CATProduct to a tool or tool assembly by means of the NC Resources > Add User Representation contextual command in the Resource List.
Parts of this CATProduct are the components of the tool:
● tool holder, which is a non-cutting component
● shank, which is a non-cutting component
● cutter, which is a cutting component.
The tool created from the CATProduct can be used in Video simulation. This tool can have multiple cutters, holders, and shanks.
Please note however that user representation may reduce the performance of the material removal simulation.
Preliminary Settings under Tools > Options
To allow Parameter nodes to be displayed in the PPR tree, make the following settings:
● Parameters and Measure: set Parameter Tree View checkbox in the Knowledge tab.
● Part Infrastructure: set Parameters checkbox in the Display tab.
Tool Structure
You can define tool geometry as a CATProduct file. CATParts instantiated in this CATProduct (there may be intermediate products between root product and parts at any level ) are components of this tool. A given component may be instantiated several times in the product, at different locations.
Naming Convention and Content of Parts
Some components are cutting components and are used in simulation and in In-Process Model (IPM) generation. Some other components are non-cutting and are used in collision detection. A non-cutting component may be a shank or a holder. These sub-categories of non-cutting components must be differentiated as well.
To identify the type of a component, the corresponding CATPart must contain a Knowledgeware parameter (added using the Fx button in Part Design).Parameter name is CuttingType (type string).Possible values of this parameter are CUTTER, SHANK and HOLDER.Any CATPart not containing this parameter is ignored in the simulation and in IPM generation.
Note that Photo simulation allows one shank or holder only.
In the following example:
● CUTCutterBig.1, CUTCutterBig.2, and CUTCutterSmall.1 are cutting components (note that one of them is instantiated twice).
● NOCUTShank.1 is a non-cutting component.
● HOLD.1 component is ignored in simulation and in IPM generation.
Material Removal
You can perform material removal with tool assemblies with multiple cutting parts.
For example:
If you perform machining with the tool assembly as shown above, then all three cutting parts should be considered for material removal.
CATProduct User Representation of Lathe Tools
You can attach a CATProduct to a lathe tool by means of the NC Resources > Add User Representation contextual command in the Resource List.
Parts of this CATProduct are the components of the lathe tool:
● insert, which is a cutting component
● insert holder, which is a non-cutting component.
The lathe tool user representation can be used in Video simulation. However, unlike the user representation used for milling tools, only one cutting and one non-cutting component can be used for lathe tools. Also, the insert holder does not participate in material removal (regardless of Rapid or Feed mode) and is used only for collision detection.
The sketch conventions outlined below for cutting and non-cutting components must be respected. Non-cutting parts must be convex (that is, the profiles used do not have any cut-outs).
Please note however that user representation may reduce the performance of the material removal simulation.
Preliminary Settings under Tools > Options
To allow Parameter nodes to be displayed in the PPR tree, make the following settings:
● Parameters and Measure: set Parameter Tree View checkbox in the Knowledge tab.
● Part Infrastructure: set Parameters checkbox in the Display tab.
To allow you to pick individual points during the material removal simulation, make the following setting:
● Sketcher: set Grid Graduations to 100.
Define the Cutting Component (the insert)
Create a part (New > Part) then select the F(x) Formula command.
In the Formula dialog box, set CuttingType to CUTTER.
In the Sketcher workbench, select the ZX plane (in lathe machining, Z is the spindle axis and X is the radial axis). Create a closed profile, adding successive elements in the anti-clockwise direction.
Note that:
● the Sketch user representation of tools can include construction elements.
● transformations (such as rotation or translation) must not be applied on this sketch as they will not be taken into account for simulation.
In the Part Design workbench, create a Pad from the sketch (2mm thick, for example). This will represent the lathe insert.
Right-click the Part in the tree and select Properties. Rename the Part Number (Insert001, for example).
Save the CATPart.
Define the Non-Cutting Component (the insert holder)
Define the non-cutting component using the same procedure.
Create a part (New > Part) then select the F(x) Formula command. In the Formula dialog box, set CuttingType to HOLDER.
In the Sketcher workbench, select the ZX plane. Create a rectangle.
In the Part Design workbench, create a Pad from the sketch. This will represent the lathe insert holder.
Right-click the Part in the tree and select Properties. Rename the Part Number (Holder001, for example).
Save the CATPart.
Create the CATProduct User Representation
Create a new CATProduct instantiated with the Insert and Holder CATParts.
You can then use the CATProduct as the Tool in the Video simulation.
CATProduct User Representation of Cleaning Tools
A Cleaning operation is a non-machining operation that uses a CATProduct user representation tool. It is defined by first creating a machining operation (depending upon the strategy required by the cleaning process) so as to generate the tool path for cleaning. Then by assigning a specific user representation tool a cleaning behavior can be simulated. Cleaning simulation can be performed in Video mode only.
The tool assigned to cleaning operations must be a CATProduct user representation and must conform to the following rules. The CuttingType knowledge attribute needs to be defined with a value equal to CLEANING for defining the cleaning component of the tool (which may be a brush, for example). Possible values for the non-cleaning components are SHANK and HOLDER.
In operations where cleaning tools as described above are used, the Video simulation has the behavior as illustrated below:
● The cleaning tool will not remove any material.
● Collisions will be detected (if collisions detection is set ON) between the holder and the other components in the system, as is the normal collision detection behavior.
● In rapid mode, collision detection will be performed between the cleaning element and the rest of the components in the system, including the stock.
● No collision will be reported during the cleaning action, provided it is in feed mode between the work-piece and the cleaning element of the tool.
Note that Cleaning tools are not supported for turning operations or in Photo mode.
CATPart Tools for Photo or Video Mode
Please note that the CATProduct user representation of tools described above is the recommended method.
You can attach a CATPart to a tool or tool assembly by means of the NC Resources > Add User Representation contextual command in the Resource List.
You can add a sketch called CUT to define the cutting part of the tool and, optionally, a sketch called NOCUT to define the non-cutting part of the tool. These profiles will be used in the material removal simulation in Photo or Video mode.Note that the sketches must be called CUT and NOCUT: no other names are possible.
Please note however that user representation may reduce the performance of the material removal simulation .
Here is a step-by step procedure for defining the CUT and NOCUT profiles.
Define a closed profile representing the cutting part of the tool:
● In the Sketcher workbench, create a sketch in the Oyz plane.
● Click the Axis icon then create an axis from (0,0) along the V-axis. This is useful if you want to use the profile to generate a 3D representation of the cutting part of the tool.
● Create the profile, starting from a position on the V-axis. Create the profile using line segments and circular arcs in an anti-clockwise direction. H coordinates must be positive. Close the profile using a line segment.
Examples of correct profiles:
● Using the Properties contextual command, name this profile CUT in the Feature Properties tab of the dialog box that appears.
If needed, define a profile representing the non-cutting part of the tool:
● In the Sketcher workbench, create a sketch in the Oyz plane.
● Click the Axis icon then create an axis from (0,0) along the V-axis. This is useful if you want to use the profile to generate a 3D representation of the non-cutting part of the tool.
● Create the profile, starting from a position on the V-axis. Create the profile using line segments and circular arcs in an anti-clockwise direction. H coordinates must be positive. Close the profile using a line segment.
● Using the Properties contextual command, name this profile NOCUT in the Feature Properties tab of the displayed dialog box.
Stock, Design and Fixtures for Material Removal Simulation
The following can be defined as stock, design or fixtures in the Part Operation editor:
● CATPart bodies
● hybrid bodies
● cloud of points bodies
● Video result stored in a CATProduct.Note: This CATProduct contains cgr (CATIA graphic representation) and WPC information.
Video results can be used effectively in a Part Operation that contains more that one program. The Video result of the last operation of a program can be used as the stock for a following program. For that, you must set the Simulation at Part Operation level option and use the Video from Last Saved Result command when using simulation in the following program.
If there is no stock defined, the envelope volume of the design part is used. If there is no design part, the envelope volume of the design part is used.
In Video mode only, if the stock geometry is not correctly closed, a stock representing the envelope volume of the design part is computed.
Opposite Hand MachiningThis document provides methodology for machining symmetrical parts and left-hand/right-hand parts. A user task showing you how to program using Opposite Hand Machining techniques is also include in this guide.
Although this is quite a flexible process, there are usually 3 steps involved:
1. Preparing the program2. Transforming the machining operations and reversing the machining conditions3. Locally editing the transformed program.
By following this method, you will obtain a program for the symmetrical part that has the same cutting conditions as the initial part.
Preparing the Program
The following methodology assumes that a proven program already exists for one symmetrical half of a part or for one workpiece in a left-hand/right-hand pair.
Taking the example of an existing left-hand program, you should make a copy of the program (or the operations in the program) in one of the following ways:
● Copy/Paste the left-hand program to create a new program. This method is suitable for symmetrical left-hand/right-hand parts
● Copy/Paste operations in left-hand program to create a new operations in that program. This method is suitable for a symmetrical (or nearly symmetrical) workpiece.
● perform a File>Save As of the CATProcess.
Transforming the Program and Reversing Machining Conditions
To transform the copied program (or operations):
● Use the TRACUT Operator command to create and apply a transformation in order to create a symmetrical tool path (Mirror or other suitable transformation).
After applying the transformation to the tool path, the cutting conditions of some operations may be reversed (climb/conventional milling, for example).
● Select the Opposite Hand Machining Options command . In the dialog box that appears, select the types of operations whose cutting conditions change after a Mirror type transformation. You can now apply a Reverse Machining Conditions processing to the selected operation types.
● In the specification tree, select the program (or groups of operations) whose cutting conditions have been
reversed and apply the Reverse Machining Conditions command .
Modified operations can be easily identified in the program due to the update symbols ( ) that appear in the tree. The tool paths of these operations must be computed or re-computed.
Due to the applied transformation followed by the Reverse Machining Conditions processing, the cutting conditions are now reset to the values of the initial program. A summary of the processing appears on an information pop-up.
Note that the cutting conditions of deactivated operations ( ) can be changed, since they can be edited. However, the cutting conditions of locked operations ( ) cannot be changed, since they cannot be edited.
Locally Editing the Transformed Program
The program may need to be finalized by means of some local editing.
If the operations of the original program are linked one after the other, you may need to reverse the order of these operations in the processed program. This is the case, for example, if the end point of Operation1 is the start point of Operation2.
In this case, you can use the Reorder Operations List command to reverse the order of one or more groups of operations. In the example below, the groups A, B, C and E, F were selected and reversed.
Operation.A
Operation.B
Operation.C --------------->
Operation.C
Operation.B
Operation.A
Operation.D Operation.D
Operation.E
Operation.F
Operation.F
Operation.E
Note that groups of operations must be selected one after the other in the tree and they must use the same tool. Operations in each group must be selected from top to bottom.
Similarly, it may be necessary to inverse the approach and retract macros on an operation. In this case, select
the relevant operations and select the Inverse Macros command .
Operations Processed by Opposite Hand Machining
The following table summarizes the references elements that are transformed by Opposite Hand Machining. Typically, the Reverse Machining Conditions command must be applied to these operations in order to retrieve the cutting conditions of the initial program.
Operation Effect of Opposite Hand Machining
3-axis Roughing Climb and Conventional options are inverted.
Spiral Milling Climb and Conventional options are inverted.
Axial Machining Operations Order of pattern points is reversed in the tool path.
Pocketing Climb and Conventional options are inverted.
Facing Climb and Conventional options are inverted.
Profile Contouring Climb and Conventional options are inverted.Order of multi-contour is inverted.Start and End elements, offsets, and conditions are inverted.
Groove Milling Climb and Conventional options are inverted.
3-axis/5-axis Isoparametric Machining Order of parts is inverted.Corners 1 and 2 are swapped.Corners 3 and 4 are swapped.Corresponding interpolation axes at corners are swapped.
5-axis Flank Contouring Order of drives is inverted as follows when the Close tool path checkbox is not selected in the operation's Machining parameters tab. Drives A, B, C, D are machined in the order D, C, B, A.
Before Opposite Hand Machining:
After Opposite Hand Machining:
Order of drives is inverted as follows when the Close tool path checkbox is selected in the operation's Machining parameters tab. Drives A, B, C, D are machined in the order A, D, C, B, A. Drive A is the first and last machined element.
Before Opposite Hand Machining:
After Opposite Hand Machining:
Start and End elements, offsets, and conditions are inverted.Approach and Leave distances are swapped.Manual direction is reversed (Left / Right).Local stopping condition and Local restarting direction are updated.
5-axis Curve Machining Climb and Conventional options are inverted.Sign of Tilt angle is changed to invert the left/right condition.Couple of Points limit elements are swapped.
For Tangent Axis guidance along isoparametric lines:when machining a strip of drive surfaces, check that the reference tool axis gives the desired result for the best matching u or v isoparametric line of the first machined face.
CUTCOM You should check that the desired cutter compensation is still applied (correct side, and so on).
Typical User Scenarios
Machining of any symmetrical right part, when left part machining is already defined.The right part does not exist as a physical model, everything is referenced on the left part.
Scenario 1: Creation
Program of left-hand part has been defined.
1. Duplicate left-hand program (CTRL+C, CTRL+V) and rename it 'Right Program before Transform'.2. Use the TRACUT Operator command to manage the symmetry. You can also use another way to
transform the resulting tool path. The CUTCOM syntax is not taken into account by the transformation. PQR output is taken into account by the transformation. This may be done in a 'Final left program after symmetry'.
3. Select the Auxiliary Operations tool bar.4. Check the Options command in order to select operation types for Reverse Machining Conditions
processing.5. Select the block of operations to be processed.6. Select the Reverse Machining Conditions command.7. Compute the new tool paths.8. Locally edit the program, if needed (to reverse the order of operations, macros, pattern points, and so
on).
Scenario 2: Modification of the left program
Operations in left-hand program have been updated because of design changes, but the tool path was fully associative.
In this case, right-hand program is updated and is associative.
Scenario 3: Modification of the left program
Operations in left-hand program have been updated because of design changes, some operations have been edited to take new geometry into account.
1. Delete existing old operations in the 'Right Program before Transform'.2. Select and duplicate the modified operations in the 'Right Program before Transform'.3. Do local opposite hand processing and modifications on operations.
Scenario 4: Modification of the left program
Some operations' options in left-hand program have been modified, or some operations have been added to left part.
1. Delete existing old operations in the 'Right Program before Transform'.2. Select and duplicate the new and modified operations in the 'Right Program before Transform'.3. Do local opposite hand processing and modifications on the operations.
Create a User Feature for Machining
This task shows how to: ● define a User Feature for Machining
● create a machining process that makes use of the User Feature.
Please refer to the Product Knowledge Template User's Guide for more information about creating user features, storing them in catalogs, and reusing them in documents.
Mapping Rule File
A default mapping dedicated to the User Features and their use in Axial Operations can be defined through a mapping rule file.
This file is located in \resources\msgcatalog\CATMfgUdfForMappingToMfg.CATNls. It contains:
● Drilling Point (MfgHolePoint) which has to be an input or output point of the User Feature
● Drilling Axis (MfgHoleAxis) which has to be an input or output planar face of the User Feature
● Drilling Diameter (MfgHoleDiameter) which has to be a published parameter of the User Feature
● Drilling Depth (MfgHoleDepth) which has to be a published parameter of the User Feature.
It enables you to use a User Feature when defining a machining pattern or an axial operation without any other mapping consideration.
For more complex mapping rules, the Machining Process functionality is more suitable.
1. In the Part Design workbench, select Insert > User Feature > User Feature Creation.
The User Feature Definition dialog box appears.
The left part of the graph displays the features that are required to build the selected object.To rename these features, just select a feature in the graph and enter a new name in the Name field. When the Inputs tab is selected, the user feature inputs are indicated by red arrows in the geometry area.
2. In the Parameters tab, all available parameters are displayed along with their values. By default, the instantiation process of a user feature forbids the modification of a parameter value. If you want to get round this, you can publish a parameter. That means you must declare that the value of this parameter can be modified in a user feature instance.To do so, select the parameter to be modified in a forthcoming instantiation and check the Published option.You can rename a parameter. Just select it and enter its new name in the Name field. For the purpose of this scenario, declare the Depth for NC and Diameter for NC parameters as published. Note that a published parameter is identified by a Yes in the Published column.
The Type tab manages the User Feature type that will be accessible in the formula definition. In this example, it is UserFeature1. Managing type is required in order to access all user feature attributes in the Machining Process definition.
Click OK to define the user feature.
3. Select a Machining workbench from the Start menu and select Machining Process View .
The Machining Process View dialog box appears.
4. Select Machining Process .
The dialog box is updated with a new machining process as shown.
5. Select Drilling .
The Operation Definition dialog box appears, if the Start Edit mode is selected in the Tools > Options > Machining > Operation settings.
6. Just click OK to add a reference Drilling operation to the machining process.
The reference operation has an associated Tool Query.
You can associate Formulas or Checks to the operation and specify a Tool Query.
7. Right-click the Drilling operation in the Machining Process View and select Edit Formula.
The Formula Editor dialog box appears at the Numerical Expressions tab page.
A formula is an expression associated to an operation or a machining feature attribute, which will be converted to a F(x) formula when the machining process is applied.
Define the Diameter and Depth attributes of the formula as shown:
8. In the Geometrical Expressions tab page, define the Drilling Point and Axis as shown below.
Fill in the two fields with:
● anchor point of the Drilling operation as "Entry Point for NC" user feature input parameter
● axis of the Drilling operation as "Entry Face for NC" user feature input parameter.
Click OK to assign the formula to the Drilling operation.
9. Double-click the Tool Query associated to the Drilling operation.
The Tool Query Definition dialog box appears.
Define a simple tool query as shown below.
10.
Select the tool repository ToolsSampleMP using the Look in combo.
Click OK to assign the tool query to the Drilling operation.
11. Select File > Save As to save the machining process in a CATProcess document calledUserFeatureMachProcess01.CATProcess, for example.
You can then apply this machining process following the general procedure described in Apply a Machining Process.
How to Use Properties of a Machining OperationThis document shows you how use the properties of a machining operation and how to get information on it.
Right-click the desired operation in the program, then select Properties. The Properties dialog box appears.
To get information about the duration of the operation:
In the General tab page, the Calculated cycle time is indicated in seconds:
This is the same as the Total time indicated in the panel of replay:
The description is the same as that displayed in the Comment field in the operation editor.
Notes:
● Total time = Machining time (that is, time of motions that actually perform machining at machining feedrate) + time of other motions.
● Total time and Machining time can be displayed in the Process table.
● Total time and Machining time for turning operations are updated according to the Master/Slave context when the NC Gantt Chart is used.
● The duration of the tool path from the tool change point to the first point of the tool path (represented by dashed line during replay) in not included in the Total time.
To modify the color of the tool path:
Select the More button in the Properties dialog box and select the Graphic tab page.
Change the default green color for lines and curves to any desired color.
Note that you can also modify this color by selecting the operation and set the new color through the Graphic Toolbar.
This tool path will be displayed in the set color if Display tool path of operation in current Part Operation is set in Tools > Options > Machining > Operation.
Double-clicking the colored tool path activates the dialog box of the corresponding machining operation.
Note: This color has no influence on the color of feedrates while replaying an operation.
Glossary
A
approach macro
Motion defined for approaching the operation start point.
APT Import activity
This is an entity created in the Manufacturing Program by importing NC data (APT source, Clfile or NC code). It references a tool path, like a machining operation, but it has no attribute specification. The tool path comprises tool motions and/or Post-Processor words.
APT Tool This is a tool which is created from the CUTTER definition found in the APT source file or Clfile. The CUTTER definition includes 7 parameters which are tool radius, corner radius, horizontal and vertical distances from the center of the corner to the tool axis or bottom, bottom and flank angles, and finally the tool height. This definition is quite poor to define a Version 5 tool. An APT Tool is a resource which cannot be modified and used by Version 5 machining operations.
auxiliary command
A control function such as tool change or machine table rotation. These commands may be interpreted by a specific post-processor.
axial machining operation
Operation in which machining is done along a single axis and is mainly intended for hole making (drilling, counter boring, and so on).
B
back and forth Machining in which motion is done alternately in one direction then the other. Compare with one way.
bottom plane A planar geometric element that represents the bottom surface of an area to machine. It is normal to the tool axis.
C
check A list of Knowledgeware expressions that are used to constrain the validity of a machining process or a machining operation.
In a single expression, operators such as and and or are available. In a list of expressions, an and operator is applied between check expressions. When a machining process is applied, the checks list is executed, a logical status is returned, and the operation is created if the status is true.
clearance macro
Motion that involves retracting to a safety plane, a linear trajectory in that plane and then plunging from that plane.
climb milling Milling in which the advancing tool rotates down into the material. Chips of cut material tend to be thrown behind the tool, which results to give good surface finish. Compare with conventional milling.
conventional milling
Milling in which the advancing tool rotates up into the material. Chips of cut material tend to be carried around with the tool, which often impairs good surface finish. Compare with climb milling.
D
DPM Digital Process for Manufacturing.
E
extension type
Defines the end type of a hole as being through hole or blind.
F
Facing operation
A surfacing operation in which material is removed in one cut or several axial cuts of equal depth according to a pre-defined machining strategy. Boundaries of the planar area to be machined are soft.
Fault Types of faults in material removal simulation are gouge, undercut, and tool clash.
feedrate Rate at which a cutter advances into a work piece. Measured in linear or angular units (mm/min or mm/rev, for example).
fixture Elements used to secure or support the workpiece on a machine.
formula A Knowlegeware expression containing feature attributes that is used to compute parameters (mainly parameters of a machining operation).
G
generic machine
A CATProduct machine representation that was created using the NC Machine Tool Builder product.
gouge Area where the tool has removed too much material from the workpiece.
H
hard A geometric element (such as a boundary or a bottom face) that the tool cannot pass beyond.
I
inward helical Machining in which motion starts from a point inside the domain to machine and follows paths parallel to the domain boundary towards the center of the domain. Compare with outward helical.
L
linking motion Motion that involves retracting to a safety plane, a linear trajectory in that plane and then plunging from that plane.
M
machine rotation
An auxiliary command in the program that corresponds to a rotation of the machine table.
machining axis system
Reference axis system in which coordinates of points of the tool path are given.
machining feature
A feature instance representing a volume of material to be removed, a machining axis, tolerances, and other technological attributes. These features may be hole type or milling type.
machining operation
Contains all the necessary information for machining a part of the workpiece using a single tool.
machining process
An ordered list of machining operations, PP instructions and, possibly, machine rotations. It can be used in two ways:
● to generate a complete subprogram by defining all the operations from geometrical information which will be solved when the machining process is instantiated into another CATProcess file.
● to generate a subprogram by defining all the operations without any geometrical information (design or manufacturing geometrical features): this way is dedicated to the settings mode.
machining tolerance
The maximum allowed difference between the theoretical and computed tool path.
manufacturing process
Defines the sequence of part operations necessary for the complete manufacture of a part.
manufacturing program
Describes the processing order of the NC entities that are taken into account for tool path computation: machining operations, auxiliary commands and PP instructions.
manufacturing view
Allows various views of the part operation:
● sorted by features
● sorted by operations
● sorted by patterns
● sorted by tooling (that is, tools or tool assemblies)
● sorted by machinable features.
milling operation
Operation in which 2.5 to 5-axis capabilities are used for part machining (roughing, pocketing, surface machining, contouring, and so on).
multi-level operation
Milling operation (such as Pocketing or Profile Contouring) that is done in a series of axial cuts.
N
NC Setup Assembly
The assembly in the process that contains the design part and all other parts (such as fixtures, stock, and In Process Model) that are necessary to perform the process. All the components of the NC Setup Assembly are positioned.
O
offset Specifies a virtual displacement of a reference geometric element in an operation (such as the offset on the bottom plane of a pocket, for example).An offset value can be greater than, less than, or equal to zero. It is measured normal to the referenced geometry or in a specific direction such as axial or radial. For example, a 5mm Offset on Contour means that a virtual displacement is applied normal to the contour geometry. A 5mm Axial Part Offset means that a virtual displacement is applied to the part geometry along the tool axis direction.Compare with thickness.
one way Machining in which motion is always done in the same direction. Compare with zig zag or back and forth.
outward helical
Machining in which motion starts from a point inside the domain to machine and follows paths parallel to the domain boundary away from the center of the domain. Compare with inward helical.
P
part operation Links all the operations necessary for machining a part based on a unique part registration on a machine. The part operation links these operations with the associated fixture and set-up entities.
pocket An area to be machined that is defined by an open or closed boundary and a bottom plane. The pocket definition may also include a top plane and one or more islands.
Pocketing operation
A machining operation in which material is removed from a pocket in one cut or several axial cuts of equal depth according to a pre-defined machining strategy.
Point to Point operation
A milling operation in which the tool moves in straight line segments between user-defined points.
PP instruction Instructions that control certain functions that are auxiliary to the tool-part relationship. They may be interpreted by a specific post processor.
PPR Process Product Resources.
Process Template
A CATProcess that is 'cleaned' from all linked files and all unnecessary information (except machining operations). For example, all links to external tool paths, IPM bodies or CATDrawings associated to the previous design are removed. This allows reusing a CATProcess structure to program the machining of a new design by keeping the sequence of operations and the parameter values that were used in the previous program.
Profile Contouring operation
A milling operation in which the tool follows a guide curve and possibly other guide elements while respecting user-defined geometric limitations and machining strategy parameters.
R
retract macro Motion defined for retracting from the operation end point
return macro Motion for linking between paths or between levels. It involves retracting to a safety plane, a linear trajectory in that plane and then plunging from that plane.
S
safety plane A plane normal to the tool axis in which the tool tip can move or remain a clearance distance away from the workpiece, fixture or machine.
set up Describes how the part, stock and fixture are positioned on the machine.
soft A geometric element (such as a boundary or a bottom face) that the tool can pass beyond.
spindle speed The angular speed of the machine spindle. Measured in linear or angular units (m/min or rev/min, for example).
stock Workpiece prior to machining by the operations of a part operation.
T
thickness Specifies a thickness of material to be removed by machining. A thickness value must be greater than zero and is measured normal to the machined geometry. For example, if a 5mm Finish Thickness is specified on an operation then 5mm of material will be removed during the finish pass. Compare with offset.
top plane A planar geometric element that represents the top surface of an area to machine. It is always normal to the associated tool's rotational axis.
tool axis Center line of the cutter.
tool change An auxiliary command in the program that corresponds to a change of tool.
tool clash Area where the tool collided with the workpiece during a rapid move.
tool path The path that the center of the tool tip follows during a machining operation.
tooling query One or more Knowledgeware expressions that define criteria to find an appropriate tool for a given machining operation.
total depth The total depth including breakthrough distance that is machined in a hole making operation.
U
undercut Area where the tool has left material behind on the workpiece.
W
WPC file This is the file format for data resulting from a material removal session. A typical ascii WPC file contains the number of faces/edges available in the solid and all the vertex information forming each of the triangles in the solid.
Z
zig zag Machining in which motion is done alternately in one direction then the other. Compare with one way.
Index
AAccept Geometry Selections command
Activate (macro path) contextual command
Activate contextual command
Add User Representation contextual command
Align Center command
Align Side command
Analyze command
approach macro
APT format
APT source generation in batch mode
Associate Video Result to Machining Operation icon command
Associativity
Attach command
Auto Sequence command
Auto-sequence operations
auxiliary command Auxiliary operation
COPY Operator
Copy Transformation
Machine Rotation
Machining Axis Change
PP Instruction
Tool Change
TRACUT Operator
axial machining operation
Axial Process for Design Holes command
BBatch queue management
Boring and chamfering tool
Boring and Chamfering Tool command
Boring bar
Boring Bar command
CCancel Geometry Selections command
CATProduct generation
Center drill
Center Drill command
Check Reachability command
checks in machining process
clearance macro
Clfile format
Clfile generation
climb milling
Close Contour with Line command
Closeup contextual command
Column Filter contextual command
Column Order contextual command command
Accept Geometry Selections
Align Center
Align Side
Attach
Auto Sequence
Axial Process for Design Holes
Boring and Chamfering Tool
Boring Bar
Cancel Geometry Selections
Center Drill
Check Reachability
Close Contour with Line
Conical Mill
COPY Operator
Copy Transformation Instruction
Counterbore Mill
Countersink
Display Status of Selected Activities
Distribute
Drill
End Mill
Face Mill
Generate Documentation
Generate NC Code in Batch Mode
Generate NC Code Interactively
Generate Transition Paths
Import/List Tools
Insert Lines on Gaps
Inverse Macros
Isolate Process Data
Machine Rotation
Machining Axis Change
Machining Axis System
Machining Instruction
Machining Pattern
Machining Processes Application
Manufacturing Program
Manufacturing View
Multi-Diameter Drill
Navigate on Belt of Edges
Navigate on Belt of Faces
Navigate on Edges Until an Edge
Navigate on Faces
Navigate on Faces Until a Face
Open Catalog
Opposite Hand Machining Options
Part Operation
Post-Processor Instruction
Preview the Contour
Process Table
Reamer
Remove Transition Paths
Reorder Operations List
Replace Tools
Replay Tool Path
Reset All Selections
Resource Context
Retrieve Faces of Same Color
Reverse Machining Conditions
Rotate to Align
Rules Manager
Screen Capture
Select Faces in a Polygon Trap
Select Normal Faces
Selection Sets
Snap
Spot Drill
Standard Drilling
Standard Multi-Axis Flank Contouring
Starts Machine Simulation
Synchronize Process
Tap
Thread Mill
Tool Change
TRACUT Operator
T-Slotter
Two Sides Chamfering Tool
Update Transition Paths
Workpiece Automatic Mount
compensation
Compute Tool Path contextual command
Conical mill
Conical Mill command contextual command
Activate
Activate (macro path)
Add User Representation
Closeup
Column Filter
Column Order
Compute Tool Path
Deactivate
Deactivate (macro path)
Delete
Delete (macro path)
Delete Generated Machine Rotations
Delete Generated Tool Changes
Delete Unused (machining features)
Delete Unused Indices
Delete Unused Resources
Display NC File
Edit NC Resources
Expand Tree to Machining operations
Expand Tree to Tool changes
Expand Tree to Tool paths
Feedrate (macro path)
Generate Machine Rotations
Generate NC Code Interactively
Generate Tool Changes
Hide Children
Import APT, Clfile or NC Code File
Insert (macro path)
Lock Children
Machine Instruction
Pack Tool Path
Parameter (macro path)
Remove Tool Path
Remove Video Result
Rename Current View
Replace Tool
Replay Tool Path
Save in Catalog
Select by String
Selected Objects
Send to Catalog
Show Children
Simulate Machine using NC Code
Simulate Machine using Tool Path
Sort by Features
Sort by Machining Features
Sort by Operations
Sort by Patterns
Sort by Tooling
Start Video Simulation
Start Video Simulation using NC Code
Start Video Simulation using Tool Path
Starts Machine Simulation
Unlock Children
Unpack Tool Path
conventional milling
COPY Operator command
Copy Transformation Instruction command
Copy/Paste of Manufacturing Data
Counterbore mill
Counterbore Mill command
Countersink
Countersink command
cutting conditions
cutting speed, cutting condition
DDeactivate (macro path) contextual command
Deactivate contextual command
Delete (macro path) contextual command
Delete contextual command
Delete Generated Machine Rotations contextual command
Delete Generated Tool Changes contextual command
Delete Unused (machining features) contextual command
Delete Unused Indices contextual command
Delete Unused Resources contextual command
depth of cut, cutting condition
Design Changes
dialog box for Tool Path Replay
Diamond insert
Display NC File contextual command
Display Status of Selected Activities command
Distribute command
Document Management
Documentation generation
Drill
Drill command
EEdit NC Resources contextual command
End mill
End Mill command
Expand Tree to Machining operations contextual command
Expand Tree to Tool changes contextual command
Expand Tree to Tool paths contextual command
External groove insert holder
External insert holder
External thread insert holder
FFace mill
Face Mill command
Fault
Feature based programming
Feedrate (macro path) contextual command
feedrate/tooth, cutting condition
formula in machining process
Frontal groove insert holder
Full Video icon command
GGenerate Documentation command
Generate Machine Rotations contextual command
Generate NC Code in Batch Mode command
Generate NC Code Interactively command
Generate NC Code Interactively contextual command
Generate Tool Changes contextual command
Generate Transition Paths command
generic machine
Geometry Analyzer dialog box
gouge
Groove insert
Hhard geometric element
Hide Children contextual command
Iicon command
Associate Video Result to Machining Operation
Full Video
Mixed Photo/Video
Save Video Result in a CATProduct
Video Collision Report
Video from Last Saved Result
Import APT, Clfile or NC Code File contextual command
Import/List Tools command
Insert
Diamond
Groove
Round
Square
Thread
Triangular
Trigon
Insert (macro path) contextual command Insert holder
External
External groove
External thread
Frontal groove
Internal
Internal groove
Internal thread
Insert Lines on Gaps command
Internal groove insert holder
Internal insert holder
Internal thread Insert holder
Inverse Macros
Isolate Process Data command
LLock Children contextual command
MMachine Editor dialog box
Machine Instruction command
Machine Instruction contextual command
machine rotation
Machine Rotation command
Machining Axis Change command
machining axis system
Machining Axis System command
machining feature
machining feedrate (Vf)
machining operation
machining pattern
Machining Pattern command
machining process
Machining Process command
Machining Process View command
Machining Process, Apply
Machining Process, Apply Automatically
Machining Process, Create
Machining Process, Knowledgeware
Machining Process, Methodology
Machining Process, Organize
Machining Processes Application command
machining tolerance
manufacturing process
manufacturing program
Manufacturing Program command
manufacturing view
Manufacturing View command
Manufacturing View, with formula
Manufacturing View, with parameters
Manufacturing View, with relations
Mapping Rule File
Material Removal Simulation
Photo mode
Video mode MFG_AA_FINISH attribute
MfgConicalMillTool
MfgEndMillTool
MfgFaceMillTool
MfgTSlotterTool MFG_AA_ROUGH attribute
MfgConicalMillTool
MfgEndMillTool
MfgFaceMillTool
MfgTSlotterTool MFG_ANGLE2 attribute
MfgMultiDiamDrillTool
MfgTwoSidesChamferingTool MFG_AR_FINISH attribute
MfgConicalMillTool
MfgEndMillTool
MfgFaceMillTool
MfgTSlotterTool MFG_AR_ROUGH attribute
MfgConicalMillTool
MfgEndMillTool
MfgFaceMillTool
MfgTSlotterTool MFG_ASS_GAGE_1 attribute
MfgMillAndDrillToolAssembly MFG_ASS_GAGE_2 attribute
MfgMillAndDrillToolAssembly MFG_AXIAL_RADIAL_MOVE attribute
Mfg3AxisMachine
Mfg3AxisWithTableRotationMachine
Mfg5AxisMachine
MfgHorizontalLatheMachine
MfgVerticalLatheMachine MFG_BALL_TYPE attribute
MfgConicalMillTool
MfgEndMillTool
MfgTSlotterTool MFG_BAR_CUT_RAD attribute
MfgGrooveInternalTool
MfgInternalTool
MfgThreadInternalTool MFG_BAR_LENGTH_1 attribute
MfgGrooveInternalTool
MfgInternalTool
MfgThreadInternalTool MFG_BAR_LENGTH_2 attribute
MfgGrooveInternalTool
MfgInternalTool
MfgThreadInternalTool MFG_BODY_DIAM attribute
MfgBoringAndChamferingTool
MfgBoringBarTool
MfgCenterDrillTool
MfgConicalMillTool
MfgCounterboreMillTool
MfgCountersinkTool
MfgDrillTool
MfgEndMillTool
MfgFaceMillTool
MfgGrooveInternalTool
MfgInternalTool
MfgMultiDiamDrillTool
MfgReamerTool
MfgSpotDrillTool
MfgTapTool
MfgThreadInternalTool
MfgThreadMillTool
MfgTSlotterTool
MfgTwoSidesChamferingTool MFG_BORE_ABILITY attribute
MfgBoringBarTool MFG_BOTTOM_ANGLE attribute
MfgGrooveInsert MFG_CHAMFR_DIAM1 attribute
MfgBoringAndChamferingTool
MfgMultiDiamDrillTool MFG_CHAMFR_DIAM2 attribute
MfgMultiDiamDrillTool MFG_CLEAR_ANGLE attribute
MfgDiamondInsert
MfgExternalTool
MfgGrooveExternalTool
MfgGrooveFrontalTool
MfgGrooveInsert
MfgGrooveInternalTool
MfgInternalTool
MfgRoundInsert
MfgSquareInsert
MfgTriangularInsert
MfgTrigonInsert MFG_COMMENT attribute
Mfg3AxisMachine
Mfg3AxisWithTableRotationMachine
Mfg5AxisMachine
MfgBoringAndChamferingTool
MfgBoringBarTool
MfgCenterDrillTool
MfgConicalMillTool
MfgCounterboreMillTool
MfgCountersinkTool
MfgDiamondInsert
MfgDrillTool
MfgEndMillTool
MfgExternalTool
MfgFaceMillTool
MfgGrooveExternalTool
MfgGrooveFrontalTool
MfgGrooveInsert
MfgGrooveInternalTool
MfgHorizontalLatheMachine
MfgInternalTool
MfgLatheToolAssembly
MfgMillAndDrillToolAssembly
MfgMultiDiamDrillTool
MfgReamerTool
MfgRoundInsert
MfgSpotDrillTool
MfgSquareInsert
MfgTapTool
MfgThreadExternalTool
MfgThreadInsert
MfgThreadInternalTool
MfgThreadMillTool
MfgTriangularInsert
MfgTrigonInsert
MfgTSlotterTool
MfgTwoSidesChamferingTool
MfgVerticalLatheMachine MFG_COMPOSITION attribute
MfgBoringBarTool
MfgConicalMillTool
MfgCounterboreMillTool
MfgEndMillTool
MfgFaceMillTool
MfgTSlotterTool MFG_COOLNT_SNTX attribute
MfgBoringAndChamferingTool
MfgBoringBarTool
MfgCenterDrillTool
MfgConicalMillTool
MfgCounterboreMillTool
MfgCountersinkTool
MfgDrillTool
MfgEndMillTool
MfgExternalTool
MfgFaceMillTool
MfgGrooveExternalTool
MfgGrooveFrontalTool
MfgGrooveInternalTool
MfgInternalTool
MfgMultiDiamDrillTool
MfgReamerTool
MfgSpotDrillTool
MfgTapTool
MfgThreadExternalTool
MfgThreadInternalTool
MfgThreadMillTool
MfgTSlotterTool
MfgTwoSidesChamferingTool MFG_CORNER_RAD attribute
MfgBoringAndChamferingTool
MfgConicalMillTool
MfgCountersinkTool
MfgEndMillTool
MfgFaceMillTool
MfgTSlotterTool MFG_CORNER_RAD_2 attribute
MfgTSlotterTool MFG_CUT_ANGLE attribute
MfgBoringBarTool
MfgCenterDrillTool
MfgConicalMillTool
MfgCountersinkTool
MfgDrillTool
MfgFaceMillTool
MfgMultiDiamDrillTool
MfgSpotDrillTool
MfgTwoSidesChamferingTool MFG_CUT_LENGTH attribute
MfgBoringAndChamferingTool
MfgBoringBarTool
MfgCenterDrillTool
MfgConicalMillTool
MfgCounterboreMillTool
MfgCountersinkTool
MfgDrillTool
MfgEndMillTool
MfgFaceMillTool
MfgGrooveInsert
MfgMultiDiamDrillTool
MfgReamerTool
MfgTapTool
MfgThreadMillTool
MfgTwoSidesChamferingTool MFG_DESC_CODE attribute
MfgDiamondInsert
MfgRoundInsert
MfgSquareInsert
MfgTriangularInsert
MfgTrigonInsert MFG_DIAMETER_1 attribute
MfgMillAndDrillToolAssembly MFG_DIAMETER_2 attribute
MfgMillAndDrillToolAssembly MFG_DIAMETER_3 attribute
MfgMillAndDrillToolAssembly MFG_ENTRY_DIAM attribute
MfgConicalMillTool
MfgCounterboreMillTool
MfgCountersinkTool
MfgReamerTool
MfgTapTool
MfgTwoSidesChamferingTool MFG_FLANK_ANG_1 attribute
MfgGrooveInsert MFG_FLANK_ANG_2 attribute
MfgGrooveInsert MFG_GAUGING_ANG attribute
MfgGrooveExternalTool
MfgGrooveFrontalTool
MfgGrooveInternalTool MFG_GROOVE_TYPE attribute
MfgGrooveInsert MFG_HAND_ANGLE attribute
MfgGrooveExternalTool
MfgGrooveInternalTool MFG_HAND_STYLE attribute
MfgExternalTool
MfgGrooveExternalTool
MfgGrooveFrontalTool
MfgGrooveInternalTool
MfgInternalTool
MfgThreadExternalTool
MfgThreadInsert
MfgThreadInternalTool MFG_HOLDER_CAPAB attribute
MfgExternalTool MFG_INIT_ROT_POS attribute
Mfg3AxisWithTableRotationMachine
MfgHorizontalLatheMachine
MfgVerticalLatheMachine MFG_INSCRIB_DIAM attribute
MfgDiamondInsert
MfgSquareInsert
MfgTriangularInsert
MfgTrigonInsert MFG_INSERT_ANGLE attribute
MfgDiamondInsert
MfgExternalTool
MfgInternalTool MFG_INSERT_HEIGH attribute
MfgGrooveInsert MFG_INSERT_LGTH attribute
MfgDiamondInsert
MfgExternalTool
MfgInternalTool
MfgSquareInsert
MfgThreadExternalTool
MfgThreadInsert
MfgThreadInternalTool
MfgTriangularInsert
MfgTrigonInsert MFG_INSERT_MAT attribute
MfgDiamondInsert
MfgGrooveInsert
MfgRoundInsert
MfgSquareInsert
MfgThreadInsert
MfgTriangularInsert
MfgTrigonInsert MFG_INSERT_THICK attribute
MfgDiamondInsert
MfgGrooveInsert
MfgRoundInsert
MfgSquareInsert
MfgThreadInsert
MfgTriangularInsert
MfgTrigonInsert MFG_INSERT_WIDTH attribute
MfgGrooveExternalTool
MfgGrooveFrontalTool
MfgGrooveInsert
MfgGrooveInternalTool MFG_INT_CIRC_2D attribute
Mfg3AxisMachine
Mfg3AxisWithTableRotationMachine
Mfg5AxisMachine
MfgHorizontalLatheMachine
MfgVerticalLatheMachine MFG_INT_CIRC_3D attribute
Mfg3AxisMachine
Mfg3AxisWithTableRotationMachine
Mfg5AxisMachine
MfgHorizontalLatheMachine
MfgVerticalLatheMachine MFG_INT_LIN_3D attribute
Mfg3AxisMachine
Mfg3AxisWithTableRotationMachine
Mfg5AxisMachine
MfgHorizontalLatheMachine
MfgVerticalLatheMachine MFG_KAPPA_R attribute
MfgExternalTool
MfgInternalTool MFG_LATHE_RAD_AX attribute
MfgHorizontalLatheMachine
MfgVerticalLatheMachine MFG_LATHE_SPN_AX attribute
MfgHorizontalLatheMachine
MfgVerticalLatheMachine MFG_LEADING_ANG attribute
MfgExternalTool
MfgInternalTool MFG_LENGTH attribute
MfgBoringAndChamferingTool
MfgBoringBarTool
MfgCenterDrillTool
MfgConicalMillTool
MfgCounterboreMillTool
MfgCountersinkTool
MfgDrillTool
MfgEndMillTool
MfgFaceMillTool
MfgMultiDiamDrillTool
MfgReamerTool
MfgSpotDrillTool
MfgTapTool
MfgThreadMillTool
MfgTSlotterTool
MfgTwoSidesChamferingTool MFG_LENGTH_1 attribute
MfgBoringAndChamferingTool
MfgMultiDiamDrillTool
MfgThreadMillTool MFG_LENGTH_2 attribute
MfgMultiDiamDrillTool MFG_LIFE_TIME attribute
MfgDiamondInsert
MfgRoundInsert
MfgSquareInsert
MfgThreadInsert
MfgTriangularInsert
MfgTrigonInsert MFG_MACH_QUALITY attribute
MfgBoringAndChamferingTool
MfgBoringBarTool
MfgConicalMillTool
MfgCounterboreMillTool
MfgCountersinkTool
MfgDiamondInsert
MfgDrillTool
MfgEndMillTool
MfgFaceMillTool
MfgGrooveInsert
MfgMultiDiamDrillTool
MfgRoundInsert
MfgSquareInsert
MfgThreadInsert
MfgTriangularInsert
MfgTrigonInsert
MfgTSlotterTool MFG_MACH_TYPE attribute
MfgThreadInsert MFG_MAX_BOR_DPTH attribute
MfgInternalTool MFG_MAX_CUT_DIAM attribute
MfgGrooveFrontalTool MFG_MAX_CUT_DPTH attribute
MfgGrooveExternalTool
MfgGrooveFrontalTool
MfgGrooveInternalTool MFG_MAX_CUT_WDTH attribute
MfgGrooveExternalTool
MfgGrooveFrontalTool
MfgGrooveInternalTool MFG_MAX_DIAMETER attribute
MfgBoringBarTool MFG_MAX_FEEDRATE attribute
Mfg3AxisMachine
Mfg3AxisWithTableRotationMachine
Mfg5AxisMachine
MfgHorizontalLatheMachine
MfgVerticalLatheMachine MFG_MAX_MIL_LENGTH attribute
MfgBoringAndChamferingTool
MfgBoringBarTool
MfgCenterDrillTool
MfgConicalMillTool
MfgCounterboreMillTool
MfgCountersinkTool
MfgDrillTool
MfgEndMillTool
MfgExternalTool
MfgFaceMillTool
MfgGrooveExternalTool
MfgGrooveFrontalTool
MfgGrooveInternalTool
MfgInternalTool
MfgMultiDiamDrillTool
MfgReamerTool
MfgSpotDrillTool
MfgTapTool
MfgThreadExternalTool
MfgThreadInternalTool
MfgThreadMillTool
MfgTSlotterTool
MfgTwoSidesChamferingTool MFG_MAX_MIL_TIME attribute
MfgBoringAndChamferingTool
MfgBoringBarTool
MfgCenterDrillTool
MfgConicalMillTool
MfgCounterboreMillTool
MfgCountersinkTool
MfgDrillTool
MfgEndMillTool
MfgExternalTool
MfgFaceMillTool
MfgGrooveExternalTool
MfgGrooveFrontalTool
MfgGrooveInternalTool
MfgInternalTool
MfgMultiDiamDrillTool
MfgReamerTool
MfgSpotDrillTool
MfgTapTool
MfgThreadExternalTool
MfgThreadInternalTool
MfgThreadMillTool
MfgTSlotterTool
MfgTwoSidesChamferingTool MFG_MAX_PLNG_ANG attribute
MfgConicalMillTool
MfgCounterboreMillTool
MfgEndMillTool
MfgFaceMillTool MFG_MAX_REC_DPTH attribute
MfgExternalTool
MfgInternalTool MFG_MIN_ANGLE attribute
Mfg3AxisMachine
Mfg3AxisWithTableRotationMachine
Mfg5AxisMachine
MfgHorizontalLatheMachine
MfgVerticalLatheMachine MFG_MIN_DIAM attribute
MfgGrooveInternalTool
MfgInternalTool
MfgThreadInternalTool MFG_MIN_DIAMETER attribute
MfgBoringBarTool MFG_MIN_DISC attribute
Mfg3AxisMachine
Mfg3AxisWithTableRotationMachine
Mfg5AxisMachine
MfgHorizontalLatheMachine
MfgVerticalLatheMachine MFG_NAME attribute
Mfg3AxisMachine
Mfg3AxisWithTableRotationMachine
Mfg5AxisMachine
MfgBoringAndChamferingTool
MfgBoringBarTool
MfgCenterDrillTool
MfgConicalMillTool
MfgCounterboreMillTool
MfgCountersinkTool
MfgDiamondInsert
MfgDrillTool
MfgEndMillTool
MfgExternalTool
MfgFaceMillTool
MfgGrooveExternalTool
MfgGrooveFrontalTool
MfgGrooveInsert
MfgGrooveInternalTool
MfgHorizontalLatheMachine
MfgInternalTool
MfgLatheToolAssembly
MfgMillAndDrillToolAssembly
MfgMultiDiamDrillTool
MfgReamerTool
MfgRoundInsert
MfgSpotDrillTool
MfgSquareInsert
MfgTapTool
MfgThreadExternalTool
MfgThreadInsert
MfgThreadInternalTool
MfgThreadMillTool
MfgTriangularInsert
MfgTrigonInsert
MfgTSlotterTool
MfgTwoSidesChamferingTool
MfgVerticalLatheMachine MFG_NB_OF_COMP attribute
MfgLatheToolAssembly
MfgMillAndDrillToolAssembly MFG_NB_OF_FLUTES attribute
MfgBoringAndChamferingTool
MfgConicalMillTool
MfgCounterboreMillTool
MfgCountersinkTool
MfgDrillTool
MfgEndMillTool
MfgFaceMillTool
MfgMultiDiamDrillTool
MfgReamerTool
MfgSpotDrillTool
MfgTapTool
MfgThreadMillTool
MfgTSlotterTool
MfgTwoSidesChamferingTool MFG_NB_OF_STAGES attribute
MfgMultiDiamDrillTool MFG_NOMINAL_DIAM attribute
MfgBoringAndChamferingTool
MfgBoringBarTool
MfgCenterDrillTool
MfgConicalMillTool
MfgCounterboreMillTool
MfgCountersinkTool
MfgDrillTool
MfgEndMillTool
MfgFaceMillTool
MfgMultiDiamDrillTool
MfgReamerTool
MfgSpotDrillTool
MfgTapTool
MfgThreadMillTool
MfgTSlotterTool
MfgTwoSidesChamferingTool MFG_NON_CUT_DIAM attribute
MfgBoringBarTool MFG_NOSE_RAD_1 attribute
MfgGrooveInsert MFG_NOSE_RAD_2 attribute
MfgGrooveInsert MFG_NOSE_RADIUS attribute
MfgDiamondInsert
MfgRoundInsert
MfgSquareInsert
MfgThreadInsert
MfgTriangularInsert
MfgTrigonInsert MFG_NURBS_OUTPUT attribute
Mfg3AxisMachine
Mfg3AxisWithTableRotationMachine
Mfg5AxisMachine MFG_ORIENT_ANGLE attribute
MfgMillAndDrillToolAssembly MFG_OUTP_PREF_1 attribute
MfgLatheToolAssembly MFG_OUTP_PREF_2 attribute
MfgLatheToolAssembly MFG_OUTP_PREF_3 attribute
MfgLatheToolAssembly MFG_OUTPUT_FRMT attribute
Mfg3AxisMachine
Mfg3AxisWithTableRotationMachine
Mfg5AxisMachine
MfgHorizontalLatheMachine
MfgVerticalLatheMachine MFG_OUTPUT_TYPE attribute
Mfg3AxisMachine
Mfg3AxisWithTableRotationMachine
Mfg5AxisMachine
MfgHorizontalLatheMachine
MfgVerticalLatheMachine MFG_OUTSIDE_DIAM attribute
MfgCountersinkTool
MfgFaceMillTool
MfgThreadMillTool MFG_OVERALL_LGTH attribute
MfgBoringAndChamferingTool
MfgBoringBarTool
MfgCenterDrillTool
MfgConicalMillTool
MfgCounterboreMillTool
MfgCountersinkTool
MfgDrillTool
MfgEndMillTool
MfgFaceMillTool
MfgMultiDiamDrillTool
MfgReamerTool
MfgSpotDrillTool
MfgTapTool
MfgThreadMillTool
MfgTSlotterTool
MfgTwoSidesChamferingTool MFG_PITCH_NUMBER attribute
MfgThreadInsert MFG_PITCH_OF_THREAD attribute
MfgTapTool
MfgThreadInsert
MfgThreadMillTool MFG_PP attribute
MfgBoringAndChamferingTool
MfgBoringBarTool
MfgCenterDrillTool
MfgCounterboreMillTool
MfgCountersinkTool
MfgDrillTool
MfgMultiDiamDrillTool
MfgReamerTool
MfgSpotDrillTool
MfgTapTool
MfgThreadMillTool
MfgTwoSidesChamferingTool MFG_PP_WORD_TBL attribute
Mfg3AxisMachine
Mfg3AxisWithTableRotationMachine
Mfg5AxisMachine
MfgHorizontalLatheMachine
MfgVerticalLatheMachine MFG_R_MAX_CIRC attribute
Mfg3AxisMachine
Mfg3AxisWithTableRotationMachine
Mfg5AxisMachine
MfgHorizontalLatheMachine
MfgVerticalLatheMachine MFG_R_MIN_CIRC attribute
Mfg3AxisMachine
Mfg3AxisWithTableRotationMachine
Mfg5AxisMachine
MfgHorizontalLatheMachine
MfgVerticalLatheMachine MFG_RAPID_FEED attribute
Mfg3AxisMachine MFG_ROT_DIR attribute
Mfg3AxisWithTableRotationMachine
MfgHorizontalLatheMachine
MfgVerticalLatheMachine MFG_ROT_TYP attribute
Mfg3AxisWithTableRotationMachine
MfgHorizontalLatheMachine
MfgVerticalLatheMachine MFG_ROTABL_OUTPUT attribute
Mfg3AxisWithTableRotationMachine MFG_ROTARY_ANGLE attribute
Mfg3AxisWithTableRotationMachine
MfgHorizontalLatheMachine
MfgVerticalLatheMachine MFG_ROTARY_AXIS attribute
Mfg3AxisWithTableRotationMachine MFG_SHANK_HEIGHT attribute
MfgExternalTool
MfgGrooveExternalTool
MfgGrooveFrontalTool
MfgThreadExternalTool MFG_SHANK_WIDTH attribute
MfgExternalTool
MfgGrooveExternalTool
MfgGrooveFrontalTool
MfgThreadExternalTool MFG_SHK_CUT_WDTH attribute
MfgExternalTool
MfgGrooveExternalTool
MfgGrooveFrontalTool
MfgThreadExternalTool MFG_SHK_LENGTH_1 attribute
MfgExternalTool
MfgGrooveExternalTool
MfgGrooveFrontalTool
MfgThreadExternalTool MFG_SHK_LENGTH_2 attribute
MfgExternalTool
MfgGrooveExternalTool
MfgGrooveFrontalTool
MfgThreadExternalTool MFG_STRT_PT_SYNT attribute
Mfg3AxisMachine
Mfg3AxisWithTableRotationMachine
Mfg5AxisMachine
MfgHorizontalLatheMachine
MfgVerticalLatheMachine MFG_SZ attribute
MfgBoringAndChamferingTool
MfgBoringBarTool
MfgCenterDrillTool
MfgCounterboreMillTool
MfgCountersinkTool
MfgDrillTool
MfgMultiDiamDrillTool
MfgReamerTool
MfgSpotDrillTool
MfgTapTool
MfgThreadMillTool
MfgTwoSidesChamferingTool MFG_SZ_FINISH attribute
MfgConicalMillTool
MfgDiamondInsert
MfgEndMillTool
MfgFaceMillTool
MfgGrooveInsert
MfgRoundInsert
MfgSquareInsert
MfgThreadInsert
MfgTriangularInsert
MfgTrigonInsert
MfgTSlotterTool MFG_SZ_ROUGH attribute
MfgConicalMillTool
MfgDiamondInsert
MfgEndMillTool
MfgFaceMillTool
MfgGrooveInsert
MfgRoundInsert
MfgSquareInsert
MfgThreadInsert
MfgTriangularInsert
MfgTrigonInsert
MfgTSlotterTool MFG_TAPER_ANGLE attribute
MfgBoringAndChamferingTool
MfgCenterDrillTool
MfgMultiDiamDrillTool
MfgTapTool
MfgThreadMillTool MFG_THD_CLS_DESC attribute
MfgTapTool
MfgThreadMillTool MFG_THD_FRM_DESC attribute
MfgTapTool
MfgThreadMillTool MFG_THREAD_ANGLE attribute
MfgThreadInsert MFG_THREAD_CLASS attribute
MfgTapTool
MfgThreadMillTool MFG_THREAD_DEF attribute
MfgThreadInsert MFG_THREAD_FORM attribute
MfgTapTool
MfgThreadMillTool MFG_THREAD_PROF attribute
MfgThreadInsert MFG_TIP_ANGLE attribute
MfgBoringBarTool MFG_TIP_LENGTH attribute
MfgBoringBarTool MFG_TIP_RADIUS attribute
MfgBoringBarTool MFG_TL_RAKE_ANG attribute
MfgBoringAndChamferingTool
MfgBoringBarTool
MfgConicalMillTool
MfgCounterboreMillTool
MfgCountersinkTool
MfgDrillTool
MfgEndMillTool
MfgFaceMillTool
MfgMultiDiamDrillTool
MfgReamerTool
MfgSpotDrillTool
MfgTSlotterTool
MfgTwoSidesChamferingTool MFG_TL_SET_LGTH attribute
MfgMillAndDrillToolAssembly MFG_TL_SET_X attribute
MfgLatheToolAssembly
MfgMillAndDrillToolAssembly MFG_TL_SET_Y attribute
MfgLatheToolAssembly
MfgMillAndDrillToolAssembly MFG_TL_SET_Z attribute
MfgLatheToolAssembly
MfgMillAndDrillToolAssembly MFG_TL_SETUP_ANG attribute
MfgLatheToolAssembly MFG_TL_TIP_LGTH attribute
MfgBoringBarTool
MfgCounterboreMillTool
MfgDrillTool
MfgMultiDiamDrillTool
MfgReamerTool
MfgTapTool
MfgTwoSidesChamferingTool MFG_TOOL_ANGLE attribute
MfgBoringBarTool MFG_TOOL_ASS_POWER attribute
MfgMillAndDrillToolAssembly MFG_TOOL_CORE_DIAMETER attribute
MfgEndMillTool
MfgFaceMillTool MFG_TOOL_INVERT attribute
MfgLatheToolAssembly MFG_TOOL_NUMBER attribute
MfgBoringAndChamferingTool
MfgBoringBarTool
MfgCenterDrillTool
MfgConicalMillTool
MfgCounterboreMillTool
MfgCountersinkTool
MfgDrillTool
MfgEndMillTool
MfgFaceMillTool
MfgLatheToolAssembly
MfgMillAndDrillToolAssembly
MfgMultiDiamDrillTool
MfgReamerTool
MfgSpotDrillTool
MfgTapTool
MfgThreadMillTool
MfgTSlotterTool
MfgTwoSidesChamferingTool MFG_TOOTH_DES attribute
MfgBoringAndChamferingTool
MfgBoringBarTool
MfgConicalMillTool
MfgCountersinkTool
MfgDrillTool
MfgFaceMillTool
MfgMultiDiamDrillTool
MfgReamerTool
MfgSpotDrillTool
MfgTapTool
MfgThreadMillTool
MfgTSlotterTool
MfgTwoSidesChamferingTool MFG_TOOTH_DESC attribute
MfgEndMillTool MFG_TOOTH_H attribute
MfgThreadInsert MFG_TOOTH_MAT attribute
MfgBoringAndChamferingTool
MfgBoringBarTool
MfgConicalMillTool
MfgCounterboreMillTool
MfgCountersinkTool
MfgDrillTool
MfgEndMillTool
MfgFaceMillTool
MfgMultiDiamDrillTool
MfgReamerTool
MfgSpotDrillTool
MfgTapTool
MfgThreadMillTool
MfgTSlotterTool
MfgTwoSidesChamferingTool MFG_TOOTH_MATDES attribute
MfgBoringAndChamferingTool
MfgBoringBarTool
MfgConicalMillTool
MfgCountersinkTool
MfgDrillTool
MfgFaceMillTool
MfgMultiDiamDrillTool
MfgReamerTool
MfgSpotDrillTool
MfgTapTool
MfgThreadMillTool
MfgTSlotterTool
MfgTwoSidesChamferingTool MFG_TOOTH_MATDESC attribute
MfgEndMillTool MFG_TOOTH_X attribute
MfgThreadInsert MFG_TOOTH_Z attribute
MfgThreadInsert MFG_TRAILING_ANG attribute
MfgExternalTool
MfgInternalTool MFG_TRAV_PITCH attribute
MfgVerticalLatheMachine MFG_TRAVERSE_NB attribute
MfgVerticalLatheMachine
MFG_VC attribute
MfgBoringAndChamferingTool
MfgBoringBarTool
MfgCenterDrillTool
MfgCounterboreMillTool
MfgCountersinkTool
MfgDrillTool
MfgMultiDiamDrillTool
MfgReamerTool
MfgSpotDrillTool
MfgTapTool
MfgThreadMillTool
MfgTwoSidesChamferingTool MFG_VC_FINISH attribute
MfgConicalMillTool
MfgDiamondInsert
MfgEndMillTool
MfgFaceMillTool
MfgGrooveInsert
MfgRoundInsert
MfgSquareInsert
MfgThreadInsert
MfgTriangularInsert
MfgTrigonInsert
MfgTSlotterTool MFG_VC_ROUGH attribute
MfgConicalMillTool
MfgDiamondInsert
MfgEndMillTool
MfgFaceMillTool
MfgGrooveInsert
MfgRoundInsert
MfgSquareInsert
MfgThreadInsert
MfgTriangularInsert
MfgTrigonInsert
MfgTSlotterTool MFG_WAY_OF_ROT attribute
MfgBoringAndChamferingTool
MfgBoringBarTool
MfgConicalMillTool
MfgCounterboreMillTool
MfgCountersinkTool
MfgDrillTool
MfgEndMillTool
MfgFaceMillTool
MfgMultiDiamDrillTool
MfgReamerTool
MfgSpotDrillTool
MfgTapTool
MfgThreadMillTool
MfgTSlotterTool
MfgTwoSidesChamferingTool MFG_WEIGHT_SNTX attribute
MfgBoringAndChamferingTool
MfgBoringBarTool
MfgCenterDrillTool
MfgConicalMillTool
MfgCounterboreMillTool
MfgCountersinkTool
MfgDrillTool
MfgEndMillTool
MfgExternalTool
MfgFaceMillTool
MfgGrooveExternalTool
MfgGrooveFrontalTool
MfgGrooveInternalTool
MfgInternalTool
MfgMultiDiamDrillTool
MfgReamerTool
MfgSpotDrillTool
MfgTapTool
MfgThreadExternalTool
MfgThreadInternalTool
MfgThreadMillTool
MfgTSlotterTool
MfgTwoSidesChamferingTool MFG_X_HOME_POS attribute
Mfg3AxisMachine
Mfg3AxisWithTableRotationMachine
Mfg5AxisMachine
MfgHorizontalLatheMachine
MfgVerticalLatheMachine MFG_X_INIT_SPNDL attribute
Mfg3AxisMachine
Mfg3AxisWithTableRotationMachine
Mfg5AxisMachine
MfgHorizontalLatheMachine
MfgVerticalLatheMachine MFG_X_ROT_CENTER attribute
Mfg3AxisWithTableRotationMachine
MfgHorizontalLatheMachine
MfgVerticalLatheMachine MFG_Y_HOME_POS attribute
Mfg3AxisMachine
Mfg3AxisWithTableRotationMachine
Mfg5AxisMachine
MfgHorizontalLatheMachine
MfgVerticalLatheMachine MFG_Y_INIT_SPNDL attribute
Mfg3AxisMachine
Mfg3AxisWithTableRotationMachine
Mfg5AxisMachine
MfgHorizontalLatheMachine
MfgVerticalLatheMachine MFG_Y_ROT_CENTER attribute
Mfg3AxisWithTableRotationMachine
MfgHorizontalLatheMachine
MfgVerticalLatheMachine MFG_Z_HOME_POS attribute
Mfg3AxisMachine
Mfg3AxisWithTableRotationMachine
Mfg5AxisMachine
MfgHorizontalLatheMachine
MfgVerticalLatheMachine MFG_Z_INIT_SPNDL attribute
Mfg3AxisMachine
Mfg3AxisWithTableRotationMachine
Mfg5AxisMachine
MfgHorizontalLatheMachine
MfgVerticalLatheMachine MFG_Z_ROT_CENTER attribute
Mfg3AxisWithTableRotationMachine
MfgHorizontalLatheMachine
MfgVerticalLatheMachine
MfgBatch utility MfgResourcePackage
Mfg3AxisMachine
Mfg3AxisWithTableRotationMachine
Mfg5AxisMachine
MfgBoringAndChamferingTool
MfgBoringBarTool
MfgCenterDrillTool
MfgConicalMillTool
MfgCounterboreMillTool
MfgCountersinkTool
MfgDiamondInsert
MfgDrillTool
MfgEndMillTool
MfgExternalTool
MfgFaceMillTool
MfgGrooveExternalTool
MfgGrooveFrontalTool
MfgGrooveInsert
MfgGrooveInternalTool
MfgHorizontalLatheMachine
MfgInternalTool
MfgLatheToolAssembly
MfgMillAndDrillToolAssembly
MfgMultiDiamDrillTool
MfgReamerTool
MfgRoundInsert
MfgSpotDrillTool
MfgSquareInsert
MfgTapTool
MfgThreadExternalTool
MfgThreadInsert
MfgThreadInternalTool
MfgThreadMillTool
MfgTriangularInsert
MfgTrigonInsert
MfgTSlotterTool
MfgTwoSidesChamferingTool
MfgVerticalLatheMachine
milling operation
Mixed Photo/Video icon command
Multi-diameter drill
Multi-Diameter Drill command
NNavigate on Belt of Edges command
Navigate on Belt of Faces command
Navigate on Edges Until an Edge command
Navigate on Faces command
Navigate on Faces Until a Face command
NC Code Based Simulation
NC code generation NC command
NC_3X_MO_START_COMMENT
NC_5X_MO_START_COMMENT
NC_AXIAL_MO_START_COMMENT
NC_CHANGE_REF_PT
NC_COMMENT
NC_COMPENSATION
NC_CUTCOM_LEFT
NC_CUTCOM_NORMDS_OFF
NC_CUTCOM_NORMDS_ON
NC_CUTCOM_NORMPS_OFF
NC_CUTCOM_NORMPS_ON
NC_CUTCOM_OFF
NC_CUTCOM_ON
NC_CUTCOM_RIGHT
NC_DELAY
NC_FEEDRATE
NC_LATHE_MO_START_COMMENT
NC_MACHINING_AXIS
NC_MILL_MO_START_COMMENT
NC_MULTAX_OFF
NC_MULTAX_ON
NC_PITCH
NC_SPINDLE
NC_SPINDLE_LATHE
NC_SPINDLE_LOCK
NC_SPINDLE_OFF
NC_SPINDLE_ON
NC_SPINDLE_START
NC_SPINDLE_STOP
NC_THREAD_TURN
NC_THREAD_TURN_OFF
NC data generation in interactive mode
NC Gantt Chart command NC instruction, auxiliary command type
NC_ACTIVITY_HEADER
NC_END_MACRO
NC_HEAD_ROTATION
NC_ORIGIN
NC_PROGRAM_HEADER
NC_START_MACRO
NC_TABLE_ROTATION
NC_TOOL_CHANGE
NC_TOOL_CHANGE_LATHE NC instruction, axial machining type
NC_BACK_BORING
NC_BORING
NC_BORING_AND_CHAMFERING
NC_BORING_SPINDLE_STOP
NC_BREAK_CHIPS
NC_CIRCULAR_MILLING
NC_COUNTERBORING
NC_COUNTERSINKING
NC_DEEPHOLE
NC_DRILLING
NC_DRILLING_DWELL_DELAY
NC_LATHE_THREADING
NC_REAMING
NC_REVERSE_THREADING
NC_SPOT_DRILLING
NC_T_SLOTTING
NC_TAPPING
NC_THREAD_MILLING
NC_THREAD_WITHOUT_TAP_HEAD
NC_TWO_SIDES_CHAMFERING
OOpen Catalog command
Opposite Hand Machining
Opposite Hand Machining Options
Origin
PPack Tool Path contextual command
Parameter (macro path) contextual command
part operation
Part Operation command
pattern of holes
Photo material removal simulation
Post-Processor Instruction command
PP instruction
PP word table
PPR
Preview the Contour command
Process Engineer Support
Process List
Process Table command
Product List
Properties of Machining Operations
RReamer
Reamer command
Remove Tool Path contextual command
Remove Transition Paths command
Remove Video Result contextual command
Rename Current View contextual command
Reorder Operations List
Replace Tool contextual command
Replace Tools command
Replay Tool Path command
Replay Tool Path contextual command
Reset All Selections command
Resource Context command
Resources List
retract macro
Retrieve Faces of Same Color command
return macro return macro type
between levels
on same level
to finish pass
Reverse Machining Conditions
Rotate to Align command
Round insert
Rules Manager command
SSave in Catalog contextual command
Save Video Result in a CATProduct icon command
Screen Capture command
Select by String contextual command
Select Faces in a Polygon Trap command
Select Normal Faces command
Selected Objects contextual command
Selection Sets command
Send to Catalog contextual command
Set Up Documents
Show Children contextual command
Simulate Machine using NC Code contextual command
Simulate Machine using Tool Path contextual command
SmarTeam support
Snap command
soft geometric element
Sort by Features contextual command
Sort by Machining Features contextual command
Sort by Operations contextual command
Sort by Patterns contextual command
Sort by Tooling contextual command
spindle speed (N)
Spot drill
Spot Drill command
Square insert
Standard Drilling command
Standard Multi-Axis Flank Contouring command
Start Video Simulation contextual command
Start Video Simulation using NC Code contextual command
Start Video Simulation using Tool Path contextual command
Starts Machine Simulation command
Starts Machine Simulation contextual command
Synchronize Process command
TTap
Tap command
TDM
Thread insert
Thread mill
Thread Mill command Tool
Boring and chamfering tool
Boring bar
Center drill
Conical mill
Counterbore mill
Countersink
Drill
End mill
Face mill
Multi-diameter drill
Reamer
Spot drill
Tap
Thread mill
T-slotter
Two sides chamfering tool tool assembly in operation
edit or select another Tool Assembly in Resource List
add
edit
Tool Axis
Tool Catalog from Resource List
tool change
Tool Change command
tool clash tool in operation
edit or select another tool in resource list
edit
tool path
tooling query in machining process
Tools catalog Tools Options - Machining
General
Operation
Output
Photo/Video
Program
Resources
TRACUT Operator command
TRACUT/NOMORE
Transition paths
Triangular insert
Trigon insert
T-slotter
T-Slotter command
Two sides chamfering tool
Two Sides Chamfering Tool command
Uundercut
Unlock Children contextual command
Unpack Tool Path contextual command
Update Transition Paths command
User Feature
User parameters, in APT source
User parameters, in PP instruction utility
MfgBatch
VVideo Collision Report icon command
Video from Last Saved Result icon command
Video material removal simulation
WWorkpiece Automatic Mount command
WPC file