chapter 22-machining operations ii
DESCRIPTION
Dr. Rizwan GulTRANSCRIPT
Page 1
Chapter 22:Machining Operations and Machine
Tools II
Rizwan M. GulNWFP UET
Page 2
MACHINING OPERATIONS AND MACHINE TOOLS
• Turning and Related Operations• Drilling and Related Operations• Milling• Machining Centers and Turning Centers• Other Machining Operations
Shaping and Planing Broaching Sawing
• High Speed Machining
Page 3
Shaping and Planing • Shaping and planing are similar operations• Both use a single point cutting tool moved linearly relative to the
workpart• Difference?
In shaping, the speed motion is accomplished by moving the cutting tool
In planing, speed motion is accomplished by moving the workpart
Figure 22.29 ‑ (a) Shaping, and (b) planing
Page 4
Shaping and Planing
• A straight, flat surface is created in both operations• Interrupted cutting
Subjects tool to impact loading when entering work
• Low cutting speeds due to start‑and‑stop motion • Usual tooling: single point high speed steel tools• The machine tool for shaping is called shaper• The machine tool for planing is called planer
Page 5
Figure 22.30 ‑ Components of a shaper
Page 6
Shaper
• Parts: ram, column, worktable, and base• The motion of ram consists of a forward stroke to
achieve the cut, and a return stroke (which is more quicker) during which the tool is lifted slightly to clear the work
• On completion of each return stroke, the worktable is advanced laterally relative to the ram motion in order to feed the part
• Both hydraulic and mechanical drive mechanisms are used but mechanical is more common
Page 7
Figure 22.31 ‑ Open side planer
Page 8
Planer
• Construction and motion capability of a planer permit much lager parts to be machined than on shaper
• Planer can be classified as either open side planer (single column planer) or double column planer
• Double column planer provide more rigid structure for operation; however, the two columns limit the width of the work that can be handled on this machine
• Planer are run by hydraulic mechanism
Page 9
Other Shapes Cut by Shaping and Planing
Page 10
Broaching • Moves a multiple tooth cutting tool linearly relative to
work in direction of tool axis• The cutting tool is called a broach and the machine
tool is called a broaching machine• In certain jobs for which broach can be used, it is a
highly productive method
Figure 22.33 ‑ The broaching operation
Page 11
Broaching
Broach
Internal broach
Page 12
Advantages: • Good surface finish• Close tolerances• Variety of work shapes possible Limitations:• Owing to complicated and often custom‑shaped
geometry, tooling is expensive Types:• The two types of broaching are external (or surface
broaching) and internal broachingExternal Broaching:• Performed on the outside surface of the work to
create a certain cross-sectional shape on the surface
Page 13
Internal Broaching• Performed on internal surface of a hole• A starting hole must be present in the part to insert
broach at beginning of stroke
Figure 22.34 ‑ Work shapes that can be cut by internal broaching; cross‑hatching indicates the surfaces broached
Page 14
Broaching Machines
• Broaching machine provide a precise linear motion of the tool past a stationary work position
• Vertical broaching machine: designed to move the broach along a vertical path
• Horizontal broaching machine: providing horizontal tool trajectory
• Most broaching machines pull the broach past the work - pull action
• However, in broaching press the broach is pushed the through the workpart
Page 15
Page 16
Page 17
Sawing
• Cuts narrow slit in work by a tool consisting of a series of narrowly spaced teeth
• Tool called a saw blade• Typical functions:
Separate a workpart into two pieces Cut off unwanted portions of part
• In most sawing operations, the work is held stationary and the saw blade is moved relative to it
• According to the type of blade motion the types of sawing are: Hacksawing Bandsawing Circular sawing
Page 18
Saw Blades
Page 19
Power hacksaw –linear reciprocating motion of hacksaw blade against work
Cutting is accomplished only on the forward stroke
Can also be done manually
Page 20
• Bandsaw (vertical) – linear continuous motion of bandsaw blade, which is in the form of an endless flexible loop with teeth on one edge
• Vertical bandsaws can also be sued for contouring and slotting
Page 21
• Circular saw – rotating saw blade provides continuous motion of tool past workpart
• Circular sawing is commonly used to cut long bars, tubes, and similar shapes to the specified length
• In abrasive cutoff, an abrasive disk is used to perform cutoff operations on hard materials that would be difficult to saw with conventional saw blade
Page 22
High Speed Machining (HSM)
Cutting at speeds significantly higher than those used in conventional machining operations
• A persistent trend throughout history of machining is higher and higher cutting speeds
• At present there is a renewed interest in HSM due to potential for faster production rates, shorter lead times, and reduced costs
Page 23
High Speed Machining
Comparison of conventional vs. high speed machining
Indexable tools (face mills)
Work material Conventional speed High speed
m/min ft/min m/min ft/min
Aluminum 600+ 2000+ 3600+ 12,000+
Cast iron, soft 360 1200 1200 4000
Cast iron, ductile 250 800 900 3000
Steel, alloy 210 700 360 1200
Source: Kennametal Inc.
Page 24
Other HSM Definitions – DN Ratio
DN ratio = bearing bore diameter (mm) multiplied by maximum spindle speed (rev/min)
• For high speed machining, typical DN ratio is between 500,000 and 1,000,000
• Allows larger diameter bearings to fall within HSM range, even though they operate at lower rotational speeds than smaller bearings
Page 25
Other HSM Definitions – HP/RPM Ratio
hp/rpm ratio = ratio of horsepower to maximum spindle speed
• Conventional machine tools usually have a higher hp/rpm ratio than those equipped for HSM
• Dividing line between conventional machining and HSM is around 0.005 hp/rpm
• Thus, HSM includes 15 hp spindles that can rotate at 30,000 rpm (0.0005 hp/rpm)
Page 26
Other HSM Definitions
• Emphasize: Higher production rates Shorter lead times Rather than functions of spindle speed
• Important non-cutting factors: Rapid traverse speeds Automatic tool changes
Page 27
Requirements for High Speed Machining
• Special bearings designed for high rpm• High feed rate capability (e.g., 50 m/min)• CNC motion controls with “look-ahead” features to
avoid “undershooting” or “overshooting” tool path• Balanced cutting tools, toolholders, and spindles to
minimize vibration • Coolant delivery systems that provide higher
pressures than conventional machining• Chip control and removal systems to cope with much
larger metal removal rates
Page 28
High Speed Machining Applications
• Aircraft industry, machining of large airframe components from large aluminum blocks Much metal removal, mostly by milling
• Multiple machining operations on aluminum to produce automotive, computer, and medical components Quick tool changes and tool path control important
• Die and mold industry Fabricating complex geometries from hard
materials