Download - Fieldbus Calculator User Manual V1 5 0
FIELDBUS Network Calculator
FIELDBUS Segment Calculator V1.5.0
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MTL FIELDBUS Segment CalculatorIndex1Introduction
1.0Design Principles
1.1MTL Power Sources
2Flow chart of Worksheets2.1The Main Menu
2.2 The Segment Sheet
2.3 Instrument Data Sheet
2.4 Front Sheet
2.5 Key Notes Sheet
2.6 Excel Screen Settings
3Basic Design Mode
3.1Main Menu
3.2Segment Sheet
3.3Megablock Selection
3.4Minimum Segment Voltage
3.5Cable Resistance
3.6Length of Segment
3.7Segment Voltages
3.8Megablock models available
3.9System Parameters
3.10Megablock Internal Voltage drop
3.1110-Way Megablock
3.12System Check
3.13Clear Check
3.14Clear IS/SG Level
3.15Clear Screen & Partial Clear
3.16Megablocks Allocated
3.17Instrument Data Sheet
3.18Printing
3.19Project Documentation
3.20Moving between Worksheets
4.0 System Check
4.1Line voltage
4.2Segment Current
4.3Spur Excessive Currents
4.4Spur Short-Circuit Currents
4.5Fieldbus Cable Length
4.6Instrument Count
4.7Cable Resistance Specification
5Instrument Data Sheet
5.1Description of Instrument Data Sheet Facilities
5.1.1Power Conditioner
5.1 2MegaBlock Hubs
5.1 3Trunk surge devices
5.1.4Additional Segment devices
5.1.5Instrument Current consumption
5.1.6Data Transfer to Segment Sheet
5.1.7Data transfer of Segment Sheet Data to the Instrument Data Sheet.
5.1.8Typical Engineering Process Data
6.0 Appendix Error Codes
7.0 Conditions of Use of the Fieldbus Calculator
1 Introduction1.0 Design Principles
The Calculator is essentially a tool to assess voltages, currents, and various other parameters associated with a user-designed fieldbus segment. It allows for an inventory to be taken of all the components specified within a design, thus ensuring an account is taken of all the required materials.
It takes no consideration of the user having made the correct choice of components with regard to hazardous area location, nor the resulting nature of the networks, ie, whether they become Non-Incendive, Non-Arcing, or Intrinsically Safe.
Two fundamental approaches are available using the Calculator :
A facility whereby the user may simply make a choice of the power conditioner being employed, after which the fieldbus segment is constructed using various Megablock devices. Cable parameters are then entered and instruments added to complete the system design, using the System Check to ensure the design is a practical application. Warning flags are raised if significant parameters are exceeded.
Note that in this mode of program application it is not possible to add surge protection devices, Entity or Zone 0 interfaces.
The more comprehensive approach is to use the Instrument Data page to create a complete map of the required network. This facilitates, where required, the importing of system data from previously engineered process layouts. A sample spreadsheet of such a file is available for perusal & experimentation and may be downloaded from the web site.
This approach allows for the application of surge protection devices, Entity or Zone 0 interfaces to the main segment trunk and to each attached spur. Cable parameters are then entered to complete the system design, using the System Check to ensure the design is a practical application.
In conclusion, using either of the above methods, an inventory of the required components may be displayed, and the configured design printed out.
The completed design may of course be saved as a standard Excel file, using a unique name that relates to the project under consideration, forming part of the system documentation. At any future time it can be recalled for modification or review.
1.1 MTL Power Sources
The program caters for the range of MTL Power Sources :
Power Source Model
9121-IS
9122-IS
9111-NI
9112-NI
FPS (See * )
MTL5995
MTL5053
Note * : There are several versions of the FPS Power Supply :
FPS-I
Redundant power systemTerminator fitted on device carrier
FPS-2
Redundant power systemNo Terminator
FPS-DTDual power system
Terminator fitted on device carrier
FPS-D
Dual power system
No Terminator
F600A
Redundant power system for use with Yokogawa ALF111 card
F650A
Redundant power system for use with Honeywell Experion PKS FIM
As the facilities offered by the Calculator are enhanced, the latest versions will be posted on the MTL web site, and will be freely downloadable.
2 Flow chart of Worksheets
Fig 2.1 illustrates the interconnection of the design pages of the program. Buttons are available on each sheet to move efficiently between the various pages described.
Fig 2.1
2.1 The Main Menu lists the power conditioners that are available, as listed in Section_1.1.
2.2 The Segment Sheet is where the fieldbus segment layout is created, where all components are graphically laid down, and where the System Check is carried out. An inventory of segment components may also be listed.
2.3 Instrument Data Sheet is where the more advanced mode of segment preparation is carried out. It is here that data may be imported from previously engineered data. Components such as surge protection devices, interfaces to allow for the connection of Entity certified instruments, and interfaces for connecting instruments located in Zone 0, may be added to the segment layout.
2.4 Front Sheet
For documentation purposes the project management details may be contained here, the headings being user-editable where required.
This data forms the front sheet of a hard-copy print out.
2.5 Key Notes Sheet
Information is given here regarding significant features that might affect how the program is used, eg, the ability to select the User Minimum Network Voltage.
This sheet is for information advice only.
2.6 Excel Screen Settings
As soon as the program is run many of the familiar screen settings used with Excel are removed to assist in providing a clear display.
These settings may persist once the program is terminated, and other Excel programs loaded. The familiar settings may be restored by selection of the menu options as under :
a) Select View, & check Formula Bar to restore the Excel Formula Bar.
b) Select View, & check Status Bar to restore the Excel Status Bar
c) Select View, Toolbars & check Formatting to restore the Excel Formatting menu view
d) Select View, Toolbars & check Drawing to restore the Excel Drawing menu view
e) Select Tools, Options, View; check Row & Column Headers; check Sheet Tabs
3 Basic Design Mode
This section describes the basic mode of design whereby the user lays down the network without reference to engineering data in electronic format.
3.1 Main Menu
Starting the program at the Main Menu, select the type of power source being deployed, after which the user is automatically taken to the Segment Sheet.
Power Source ModelNominal voltage availableNominal current availableEx protection
9121-IS12.4120 mAIS (ib)
9122-IS13.1265IS (ib)
9111-NI12.4180NI (Zone 2)
9112-NI13.1320NI (Zone 2)
FPS-I25.0350NA (Zone 2)
MTL599519.0350NA (Zone 2)
MTL505318.0580IS (ia)
IS
: Intrinsically Safe source
NI (Zone 2) : Non-Incendive source : for application only in safe area or Zone 2
NA (Zone 2) : Non-Arcing source : for application only in safe area or Zone 2
If at any stage of using the Segment Sheet the power source definition appears blank, then return to the Main Menu to make an appropriate selection.
If a system design is partially completed, but recourse is made to the Main Menu to select an alternative power source device it is essential to subsequently call the System Check facility to ensure that the new configuration still indicates a satisfactory layout.3.2 Segment Sheet
On entry to the Segment Sheet, the type of Megablock about to be placed will default automatically to :
IS Megablocks when any IS power conditioner has been selected.
Non-IS Megablocks with Spurguard when any Non-IS power conditioner has been selected.
The user may over-ride this choice by selecting the SpurGuard or IS buttons accordingly, but a warning will be given regarding the action taken.
Choosing a Non-IS Megablock with an IS power conditioner might create an unsafe, uncertified network.
Choosing a Non-IS Megablock without Spurguard might create an unreliable network where a single point of (spur) failure could jeopardise the operation of the whole network.
Such changes are not recommended by MTL in view of the possible conflict.
Note that once a Megablock is laid down on the segment, the type can only be changed by complete removal of that node and re-applied in its modified form.
3.3 Megablock Selection
Select the sequence of Megablock devices being deployed, in the order in which they will appear along the fieldbus segment. The screen display will show the selection accordingly.
The program allows for a maximum of four devices to be connected in cascade, which is felt will satisfy the majority of fieldbus applications.
It may be useful to include the physical location of each Megablock on the process plant. This designation could, for instance, be entered in the cell directly above the position of the Megablock, remembering that all entries on the spreadsheet will be saved with the overall file, or printed out as part of the system documentation
(see Fig 3.1)
Fig 3.1
3.4 Minimum Segment Voltage
A default minimum segment voltage of 9.0 volts is automatically inserted, this being the specified operating minimum for all fieldbus instruments. This value may, however, be overwritten at any time to allow for a further margin of operation in any calculations. This is achieved by entering the required value in the appropriate cell on the Segment worksheet.
3.5 Cable Resistance
Referring to the Foundation Fieldbus document ag-181 four different cable specifications are given for fieldbus operation :
Cable typeResistance per loop kilometreScreened cable
Type A44 (Individually screened / twisted pairs
Type B112 (Overall screen / twisted pairs
Type C264 (Twisted pairs / No screen
Type D40 (Multi-core / No screen
Selection of the cable type (and its resistivity) is made on the Segment Sheet. Selecting the Apply button will globally insert the selected value in all trunk & segment spurs. Variations may subsequently be made to individual trunks and/or spurs, where a non-compliant cable is being employed, by simply entering an appropriate value in a given cell.
Where resistance values are left blank any calculation will assume that an instrument is located adjacent to the Megablock, and the voltage present calculated accordingly.
Note : The use of non-screened cable in IS systems located in a hazardous area is not permitted according to the IEC60079-14 Installation Standard. This might preclude the use of Types C & D above, or similar non-screened cables.
3.6 Length of Segment Enter the length of each part of the segment/spur, and enter the current drawn by each instrument. The system assumes that a single instrument is attached per spur when reporting the number of instruments deployed on the segment.
3.7 Segment Voltages
Voltages along the segment are displayed instantly as the parameters are entered.
3.8 Megablock models available :
ModelSpursSpurGuardApplications
FCS-MB22GP/NA/NI/IS
FCS-MB2-SG2YesGP/NA Trunk/NI spurs
FCS-MB44GP/NA/NI/IS
FCS-MB4-SG4YesGP/NA Trunk/NI spurs
FCS-MB88GP/NA/NI/IS
FCS-MB8-SG8YesGP/NA Trunk/NI spurs
FCS-MB10-T10GP/NA/NI/IS
FCS-MB10-SG-T10YesGP/NA Trunk/NI spurs
F2412S/CIS ia
F2454S/CIS ia
F2518S/CIS ia
F25910S/CIS ia
GP
: General Purpose (Safe Areas)
IS
: Intrinsically Safe source
S/C
: Short Circuit protected spurs
NI (Zone 2) : Non-Incendive source : for application only in safe area or Zone 2
NA (Zone 2) : Non-Arcing source : for application only in safe area or Zone 2
3.9 System Parameters inserted into the selected layout include the following :
Overall segmentMinimum acceptable voltage (default = 9.0 volts)
Main TrunkCable Resistance
(/loop kmLength of each segment
SpursCable Resistance
(/loop kmLength of each segmentCurrent drawn
Values reported on-screen with immediate effect :
Main Trunk
Voltage at Megablock entry pointVoltage at Megablock exit point
SpursVoltage at instrument point
The display of the above parameters are illustrated below.
3.10 Megablock Internal Voltage drop
Voltage drops occurring, if any, by virtue of a current drawn through a Megablock, are automatically incorporated in the calculations appropriate to the selected hub device.
Equally, the small current consumed by each Megablock is automatically included in the calculations.
3.11 10-Way Megablock
All 10-way Megablocks contain an integral network terminator. Hence, any attempt to add subsequent devices further down the segment is prevented, with a suitable warning being given.
It would be bad fieldbus practice to add further cable & Megablock hub devices after the segment had been terminated.
3.12 System Check
Select System Check to see all the significant parameters displayed on-screen.
See Section 4.0 for a full description.
3.13 Clear Check
Having called a System Check (above) against the design, causing an appropriate display on the Segment worksheet, this display, and any warning messages, may be cleared by selecting the Clear Check option.
3.14 Clear IS/SG Level
Select this option to clear an otherwise short-circuited spur value of current. See Section 4.4 for a full description.
3.15 Clear Screen & Partial Clear
By selecting Clear Screen all the current segment data is deleted, ready to re-commence a new design.
If, however, only a portion of a design is to be replaced, the 1, 2, 3, 4 buttons allow for just those hubs to be removed. Subsequently, any further Megablock device selected will be placed in the vacant slot nearest to the power conditioner, in chronological order.
Note that any 10-way device must be deployed at the extremity of the network, since they contain a fieldbus terminator. It is not technically practical to cascade further devices after a 10-way device is selected (see 3.10 above).
Using the Partial Clear function and attempting to insert a 10-way block that precedes other existing blocks is prevented.
3.16 Megablocks Allocated
As Megablocks are deployed the device currently assigned to each slot is illustrated on-screen.
3.17 Instrument Data Sheet
In many instances Process Loop information is available at an early stage of a project design in spreadsheet format (Excel or Access). If available, this may be imported into the Fieldbus Calculator, facilitating a very efficient compilation of system design.
More detailed usage of this mode of design is given later in this document (Section 5).
3.18 Printing
Selecting the Print option produces a hard-copy to the default printer currently attached to the PC, the exact content being WYSIWYG.
This allows text to be added by users, entering any data relevant to the project on the spreadsheet, and in whichever cell is appropriate, with subsequent hard-copy being available. An example of this might be to enter the location ID of each Megablock directly above the block item, as seen in Fig 3.1.
3.19 Project Documentation
Projects may be saved for documentation purposes, or for later amendment, by simply saving the Excel program in its entirety under some user-specific name. Further projects may then be commenced using the base program.
3.20 Moving between Worksheets
Switching between various worksheets does not cause loss of the current Segment worksheet display & its data. Note, however, that selecting an alternative power source device in this way could result in erroneous data being displayed, since the source voltage & current values may differ from those used in an earlier calculation.
This situation can be avoided by simply re-selecting the System Check once the power conditioner has been changed.
4.0 System Check
Selecting the System Check option will report on numerous parameters associated with the completed fieldbus segment.
4.1 Line voltage
Depending on the line resistance values & current consumption along each leg of the segment, including spurs, the resulting voltage at each instrument point is reviewed. These levels are compared against the minimum acceptable voltage (9.0 volts by default) set by the user. Any point appearing below this minimum will cause an alarm display. Since this condition could exist at any spur ending, the point/s at which it is occurring is displayed against a red background for ease of identification.
Note : Unlike all other power sources featured in this manual, the MTL5053 device has internal source resistance.
When specifying an MTL5053 it is essential that the System Check option is called, to ensure that this internal resistance is included in the resulting segment calculation.
Only by calling System Check can the segment current be totalised and the effect of this with the source impedance be calculated.
4.2 Segment Current
The accumulation of the current consumption entered for each spur, together with the small amount consumed by the Megablocks, is deduced, and reported in this check. Note that both the Design Current & Current Limit of the chosen power source is displayed, the latter being 20 mA greater than the Design Current..
The Current Limit represents the absolute maximum that can be drawn from a power source, as opposed to the published Design Current for the device.
This current margin might allow for a switch-on surge, etc, representing an abnormal operating situation, for in a network operating near its current capacity limit.
The MTL5053 is unique in not having this margin of difference.
An alarm condition, highlighted in red, is given if a figure exceeds the current capacity of the source.
4.3 Spur Excessive Currents
Megablocks offering SpurGuard or Intrinsically Safe spur connections have, under normal operation, a maximum available current. This is according to Table 4.1, with values of 58 & 40 mA respectively.
Designs demanding a current in excess of these values must be avoided as being above the capacity that can be sourced.
Table 4.1
MegablockTechnologyMaximum current capacity
FCS-MB2-SGSpurGuard58 mA
FCS-MB4-SGSpurGuard58
FCS-MB8-SGSpurGuard58
FCS-MB10-SG-TSpurGuard58
F241IS40
F245IS40
F251IS40
F259IS40
4.4 Spur Short-Circuit Currents
Megablocks offering SpurGuard or Intrinsically Safe spur connections exhibit a current drain increase to a maximum value if that particular spur is inadvertently short-circuited during operation. This is to a value of 60 & 42 mA, for a SpurGuard or IS device, respectively.
The potential effect of this on the total source current drawn will be displayed, highlighted with a red background, as the System Check function is selected. The increment introduced will be the difference between the normal current drawn on the spur in question and the value of 60 or 42 mA.
The spur furthest down the segment, and also showing the lowest current consumption at that juncture, will automatically be replaced by the fault current. This new value will then feature in the subsequent segment calculations and appear under the Current Limit column. The basis for this automatic choice is that the furthest hub, and then the lowest current drawn from that hub, will have the greatest effect on instrument terminal voltages along the segment.
To restore the fault value to the user-inserted value, select the Clear IS/SG Level button. This must be done prior to further entries being made, eg, more Megablocks added, since a different spur may become the short-circuit focus of interest.
Clearly, if a spur offering no short-circuit limit in current is being used it will cause the voltage to collapse, and hence disable the operation of the whole segment, ie, when using those devices listed in Table 4.2.
No warning of this possible phenomenon is given when using the Calculator.
Table 4.2
MegablockTechnology
FCS-MB2No bus protection
FCS-MB4No bus protection
FCS-MB8No bus protection
FCS-MB10-TNo bus protection
4.5 Fieldbus Cable Length
When deducing the total length of a fieldbus segment, the Calculator assesses compliance against several specified limits, as contained in Tables 4.3 & 4.4.
Table 4.3
Applying StandardHazardMax. Segment Length including spurs
Foundation Fieldbus FF-816Safe Area
& all hazards1900 metres
(see table below for spur limits)
FISCO or FNICOIIC Gases1000 metres
FISCO or FNICOIIB Gases1900 metres
Cable typesMax. Segment Length including spurs
Type A1900 metres
Type B1200 metres
Type C400 metres
Type D200 metres
Table 4.4
Fieldbus : Maximum loading recommendationsTotal Instrument population1 device per spur2 devices per spur3 devices per spur4 devices per spur
1-12120 metres90 m60 m30 m
13-1490 m60 m30 m0
15-1860 m30 m00
19-2430 m000
25-320000
Any excess outside these limits is reported.
In certain design exercises, the application may not require compliance, eg, a Foundation Fieldbus (Entity) project does not have to comply with the 1000 metre limit in a IIC gas, or restrict any spur length to a maximum of 60 metres, as would be the case for a FISCO design.
The user should use discretion and ignore irrelevant data.
4.6 Instrument Count
The total number of instruments, or more accurately the number of spurs drawing an active current, are deduced. The specified maximum is 32 on a single fieldbus segment, but this is unlikely to be exceeded in practice.
Since the utility has no method for the user to assign multiple instruments to a single spur, it is assumed that all active spurs are supporting a single instrument.
4.7 Cable Resistance Specification
Whilst it is important to employ cable to the highest possible specification, resulting in optimum operation, FISCO & FNICO do require cables to be employed having specific parameters. The utility will check that the resistance values inserted throughout the application comply with the requirement for FISCO & FNICO as being between 15 ( and 150 (. Any variation from this produces a warning.
Again, the application being designed may not require compliance, eg, a Foundation Fieldbus (Entity) project does not have to comply with this requirement.
The user should use discretion and ignore irrelevant data.
5.0 Instrument Data Sheet
An illustration of the upper portion of the Instrument Sheet display is shown in
Fig 5.1 overleaf.
5.1 Description of Instrument Data Sheet Facilities
5.1.1 Power Conditioner
The selected device is shown in the top left hand corner of the sheet. If this is blank then return to the Main Menu to select the required device.
5.1.2 MegaBlock Hubs
Up to four Megablock hubs are available, featured to the left of the sheet, this number being assumed to represent the maximum size of envisaged network.
5.1.3 Trunk surge devices
Each section of trunk has the facility to define surge protection devices, appearing down the left hand section of the screen. Defining surge protection on a particular trunk section involves the provision of an FP32 device at each end of the section, this being taken into account when listing inventory.
5.1.4 Additional Segment devices
Provision is given to add surge protection, an Entity interface, or a Zone 0 interface to each spur.
To the right of each block of spur devices is a pointer (red spot) which can be manoeuvred to point at the required spur by operating the adjacent scroll bar. Then selecting the appropriate function button, ie, Surge, Entity, or Zone 0, will add/delete that function to the spur.
It is not recommended that both an Entity interface and a Zone 0 interface are used on a single spur. Technically, this will work, and is certifiably safe, but the voltage drop of such a combination is likely to be excessive to the point where the resulting instrument voltage will be below the minimum operating level of 9.0 volts.
For this reason the application of both devices to a single spur is prevented.
5.1.5 Instrument Current consumptionA further facility on the Instrument Data Sheet is a library of instrument manufacturers data. Select the radio button, at the bottom-right of the screen, appropriate to the manufacturer in question; next use the adjacent scroll-bar to move to the specific instrument of interest.
The information listed displays : Manufacturer; Device Functionality; Device Model Number; Design Current.
Once instrument model types are entered in the Megablock fields, it is possible to automatically insert the current consumption values from this internal database.
This is actioned by selecting the Auto-insert Current Drawn button. If a particular instrument is not available in the database the Instrument Current value field will be left blank.
The database of instruments may be reviewed by use of the scroll-bar on the far-right of the screen.
If the instrument required appears as a near-match or an alternative instrument identified, the instrument data may be transferred by moving the pointer (red spot) to the spur required, using the scroll-bar, and selecting the appropriate Transfer Instrument Data to Block n button. The instrument data and its current consumption will appear in the Megablock window.
5.1.6 Data Transfer to Segment Sheet
Once the block information is completed it may then be transferred directly to the Segment Sheet.
Select the Write Megablock n button to transfer the complete data, including the additional surge, Entity, and Zone 0 interfaces. This will create the size of Megablock on the Segment Sheet, over-writing any previous data on that page.Note : On a blank Segment Sheet, Megablock data must be transferred in the order in which they are required to appear on the Segment Sheet, eg, selecting Block 2 followed by Block 1 to a blank Segment will result in Block 2 being laid down preceding Block 1.
5.1.7 Data transfer of Segment Sheet Data to the Instrument Data Sheet.
Exactly the opposite procedure to that described in 5.1.6 is available whereby the Segment Sheet Data may be transferred to the Instrument Data Sheet to enable modifications to be carried out.
Note that the only means of adding/modifying Surge devices, Entity, and Zone 0 interfaces is using the Instrument Data Sheet.
5.1.8 Typical Engineering Process Data
A typical spreadsheet containing engineering information is included on the web site to illustrate an example of how data may be transferred electronically, thus avoiding human typing errors, and reducing preparation time.
In the example given, headings include :
Instrument No.
Plant Location
Instrument Manufacturer
Instrument Type
Instrument Model
Instrument Current
Process Loop Name
The spreadsheet example shows several columns of engineering data that might have been pre-prepared for a given project. It defines the size of each Megablock that might be required, by reference to the number of instruments required at specific locations. Of the data shown, the last three columns are relevant to the Fieldbus Calculator, viz, Instrument Model, Instrument Current, & Process Loop Name.
Using Windows Copy & Paste the three columns of data described, of the size of the Megablock required, may be quickly transferred into the required cells in the Instrument Data Sheet.
The values of current consumption may be quickly applied using the Auto-Insert Current Drawn feature (see Section 5.1.5).
The data is now ready to create a segment design as described in 5.1.6.
The foot of the Instrument Data Sheet contains the table published by Foundation Fieldbus equating the recommended total number of field devices appearing on a fieldbus segment against the number of devices that should be connected per spur of that segment.
Fig 5.1
6.0 Appendix Error Codes
When applying additional devices to the Megablock definition on the Instrument Data Sheet certain Error Codes may be brought up adjacent to the selection being made.
An interpretation of these errors is given below :
Error typePossible cause
Error ATrying to deploy both Entity & Zone 0 interfaces
Error BZone 0 Interface NOT allowed, eg, with Non-IS power conditioners
Error CEntity Interface NOT allowed, eg, with a power conditioner with a high operating voltage
In general, an IS power conditioner is required to use either of the Entity or Zone 0 interfaces, due to excessively high voltages specified by all the other power sources.
7.0 Conditions of Use of the Spreadsheet
Express limitation of liability, warranty, indemnification and representation.
To the maximum extent permitted by applicable law, MTL Instruments Ltd and its suppliers make no warranties, indemnification, representations, terms or conditions of any kind, express, implied or statutory, about the Fieldbus Calculation Program, the services or suitability, workability, legality or accuracy of the program and its information, or products and services described or contained in the program, and expressly disclaim all implied warranties, terms or conditions of satisfactory quality, merchantability, fitness for a particular purpose, title or non-infringement.
In no event will MTL Instruments Ltd be or feel liable with regard to the Fieldbus Calculator Program and its usage to any other party for any consequential, indirect, exemplary, punitive, or special damages that are directly or indirectly related to the Fieldbus Calculation Program, regardless of whether such damages are caused by the ordinary negligence of MTL Instruments Ltd.
MTL Instruments Ltd.
Power Court
Luton
Bedfordshire LU1 3JJ
UK
e-mail [email protected]: +44 (0)1582 723633
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V1.5.0: October 2004