Multi-Axis Surface Machining
Overview
What's New?
Getting Started
Open the Part to Machine Create a Multi-Axis Sweeping Operation Replay the Toolpath Create a Multi-Axis Contour Driven Operation Create a Multi-Axis Curve Machining Operation Generate NC Code
User Tasks
Multi-Axis Milling Operations Multi-Axis Sweeping: Lead and Tilt Multi-Axis Sweeping: Fixed Multi-Axis Sweeping: Thru a Point Multi-Axis Sweeping: Normal to Line Multi-Axis Sweeping: 4-Axis Lead/Lag Multi-Axis Sweeping: Optimized Lead Multi-Axis Contour Driven: Between Contours Multi-axis Contour Driven: Parallel Contours Multi-Axis Contour Driven: Spine Contour Multi-Axis Curve Machining: Contact Multi-Axis Curve Machining: Between 2 curves with Tool Axis Interpolation Multi-Axis Curve Machining: Between 2 curves with Tangent Axis Guidance Multi-Axis Curve Machining: Between curve and part Multi-Axis Isoparametric Machining: Lead and Tilt Multi-Axis Isoparametric Machining: 4-Axis Lead/Lag Multi-Axis Isoparametric Machining: Interpolation
Auxiliary Operations Part Operations, Manufacturing Programs and Machining Processes NC Manufacturing Entities Verification, Simulation and Program Output
Workbench Description
Menu Bar Toolbars Specification Tree
Customizing
General Resources Operation
Output Program Photo/Video
Reference Information
Multi-Axis Sweeping Multi-Axis Isoparametric Machining Multi-Axis Contour Driven Multi-Axis Curve Machining Collision Checking
Methodology
Glossary
Index
OverviewWelcome to the Multi-Axis Surface Machining User's Guide! This guide is intended for users who need to become quickly familiar with the product.
This overview provides the following information:
● Multi-Axis Surface Machining in a Nutshell
● Before Reading this Guide
● Getting the Most Out of this Guide
● Accessing Sample Documents
● Conventions Used in this Guide
Multi-Axis Surface Machining in a NutshellMulti-Axis Surface Machining enables you to produce NC programs dedicated to machining parts designed in 3D wireframe or solids geometry using multi-axis machining techniques.
Based on industry recognized and leading edge technologies, Multi-Axis Surface Machining provides tight integration between tool path definition, verification and modification.
Multi-Axis Surface Machining is an add-on product to 3-Axis Surface Machining. Thus, the user benefits from superior 3-axis multiple surface machining and leading edge 5-axis simultaneous machining tightly integrated in a flexible NC Programming workbench.
Multi-Axis Surface Machining is particularly adapted for mockup and die machining in automotive domains where the use of 5-axis simultaneous machining brings unequalled surface quality. Moreover, it is targeted at prototype machining, 5-axis trimming and special machining where full 5-axis machining is the requirement for quick and accurate manufacturing.
Multi-Axis Surface Machining is also an add-on product to Prismatic Machining and Lathe Machining.
As an add-on product, it takes advantage of functions such as material removal simulation and NC data generation. It adds the following dedicated multi-axis surface machining techniques to the capabilities offered by the other NC Machining products:
● Multiple surface machining with various tool path styles
● Capability to machine the entire surface with full collision avoidance of the tool holder and cutter active part
● Multiple curve machining with various tool path styles for programming quickly and efficiently grooving, engraving, swarf cutting, flank machining for any desired area
● Various tool axis strategies including dynamic tool axis orientation for both multiple surface and multiple curve machining
● Complete toolkit for controlled and collision free transition tool paths provided for both multiple surface and multiple curve machining.
Before Reading this GuidePrior to reading the Multi-Axis Surface Machining User's Guide, you are recommended to have a look at the Infrastructure User's Guide for information on the generic capabilities common to all products.
Getting the Most Out of this GuideTo make the most out of this book, we suggest that a beginning user reads the Getting Started chapter first of all and the Workbench Description to find his way around the Multi-Axis Surface Machining workbench. The User Tasks section gives a quick description of the operating mode of the various actions, whereas the Reference Information section lists the parameters used in those actions.
Accessing Sample DocumentsTo perform the scenarios, sample documents are provided all along this documentation. For more information about this, refer to Accessing Sample Documents in the Infrastructure User's Guide.
What's New?
Enhanced Functionalities
Multi-Axis Sweeping, Multi-Axis Isoparametric Machining, Multi-Axis Contour Driven:Air cuts due to collisions with check can be optimized using the Covering mode.
Multi-Axis Curve Machining:Sequencing by level is now available.You can now activate/deactivate collision checking with guiding elements.Discontinuous Guides are supported.Maximum cut depth is available in Between 2 curves mode to replace an auxiliary curve.Unwanted tool axis variation can be avoided by applying a fanning distance.
Multi-Axis Isoparametric MachiningThe Interpolation Tool axis mode accepts additional tool axes.
Getting StartedBefore getting into the detailed instructions for using Multi-Axis Machining, this tutorial is intended to give you a feel of what you can accomplish with the product.
It provides the following step-by-step scenario that shows you how to use some of the key functionalities.
Open the Part to MachineCreate a Multi-Axis Sweeping Operation
Replay the ToolpathCreate a Multi-Axis Contour Driven OperationCreate a Multi-Axis Curve Machining Operation
Generate NC Code
Open the Part to MachineThis first task shows you how to open a part and enter the Surface Machining workbench.
1. Select File > Open then select the MultiAxisMilling01.CATPart document.
2. Select Machining > Surface Machining from the Start menu. The Surface Machining workbench
appears. The part is displayed in the Set Up Editor window along with the manufacturing specification
tree.
3. Double click Part Operation.1 in the tree. The Part Operation dialog box appears.
4. Select the Machine icon to access the Machine Editor dialog box.
Select the 5-axis Machine icon then click OK to return to the Part Operation dialog box.
5. Click OK to accept the Part Operation.
6. 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.
Create a Multi-Axis Sweeping OperationThis task shows you how to create a Multi-Axis Sweeping operation for machining part of the workpiece.
This operation will use the tool proposed by the program, so you just need to specify the geometry to be machined, set some of the machining parameters. You must specify View and Start directions to define the guiding plane for the operation.
1. Select the Multi-Axis Sweeping icon .
A Multi-Axis Sweeping.1 entity along with a default tool is added to the program.
The Multi-Axis Sweeping dialog box appears directly at the Geometry tab page .
2. Right click the red Part Body area in the icon and choose the Select faces contextual command. The
Face Selection toolbar appears.
3. Select two faces of the part as shown. Click OK in the toolbar to end face selection.
4. Select the Strategy tab page and set the Machining, Radial and Tool Axis parameters as
shown.
Click the View Direction arrow (V) and set the view direction in the dialog box as shown.
Click the Start Direction arrow (S) to make sure the direction is (1,0,0).
5. Click OK to create the operation.
Replay the Tool PathThis task shows you how to replay the tool path of the Multi-Axis Sweeping operation.
1. Select the Multi-Axis Sweeping operation in the tree then select the Tool Path Replay icon
.
The Replay dialog box appears.
2. Choose the Continuous replay mode by means of the drop down icon .
3. Click the button to position the tool at the start point of the operation.
4. Click the button to start the replay. The tool moves along the computed trajectory.
5. Click OK to quit the replay mode.
Create a Multi-Axis Contour Driven OperationThis task shows you how to create a Multi-Axis Contour Driven operation to machine part of the workpiece.
You will specify the geometry to be machined, set some of the machining parameters and select a new tool.Make sure that the Multi-Axis Sweeping operation is the current entity in the program.
1. Select the Multi-Axis Contour Driven icon . The Multi-Axis Contour Driven dialog box appears directly at the Geometry page
.
2. Right click the red Part area in the icon and choose the Select faces contextual command. The Face Selection toolbar appears.
Select the face to be machined and click OK in the toolbar.
3. Select the Strategy tab page and set the parameters as shown. This operation will use a Between Contours strategy and the
tool axis will be guided in Fixed Lead and Tilt mode. The other parameters are the same as the previous operation. However, in the
Radial tab page you can set the Stepover strategy to Distance on Part.
4. Click the View Direction arrow (V) and set the view direction to (0, -1, 0) in the dialog box.
5. Click the red Guide 1 curve in the icon then select the first guide curve in the model. Click the red Guide 2 curve in the icon then
select the second guide curve in the model.
6. Select the Tool tab page .
Enter a name of the new tool (for example, Ball Mill D 20).
Select the Ball-end tool checkbox.
Double click the D (nominal diameter) parameter in the icon, then enter 20mm in the Edit Parameter dialog box.
Set the db (body diameter) parameter to 24mm in the same way.
7. Click Tool Path Replay in the dialog box to visually check the operation's tool path.
Click OK to exit the replay mode and return to the Multi-Axis Contour Driven dialog box.
8. Click OK to create the operation.
Create a Multi-Axis Curve Machining OperationThis task shows you how to insert a Multi-Axis Curve Machining operation in the program.
1. Select the Multi-Axis Curve Machining icon . The Multi-Axis Curve Machining dialog box
appears directly at the Geometry page .
2. Set the curve machining mode to Between 2 Curves and in the sensitive icon set the curve
machining type to Side.
3. Select the red top guiding curve in the sensitive icon then select the desired guiding curve in the
part.
4. Select the two limit points of the curve.
5. Double click the Axial Offset 1 parameter in the sensitive icon,
then enter a value of -5mm in the Edit Parameter dialog box.
6. Select the Strategy tab page and set the Tool Axis direction to (0, -1, 0).
Choose Interpolation as the Tool axis mode.
7. Click one of the red tool axes in the sensitive icon, then specify the orientation of the interpolation
axis at the start of machining. You can do this by selecting a surface. In this case the surface
normal is used.
Click the other red tool axis in the sensitive icon, then specify the orientation of the interpolation
axis at the end of machining.
8. The tool axis will be interpolated between these two axes.
9. Click Tool Path Replay to replay the operation as described previously.
Click OK to exit the replay mode and return to the Multi-Axis Curve Machining dialog box.
10. Click OK to create the operation in the program.
Generate NC CodeThis task shows you how to generate the NC code from the program.
Before doing this task, double click the Part Operation entity in the tree and, in the dialog box that appears, click the Machine icon to access the Machine Editor dialog box. Make sure that you have selected a 5-axis machine and that the desired NC data format is set to Axis (X, Y, Z, I, J, K).
1. Use the right mouse key on the Manufacturing Program.1 entity in the tree to select Generate
NC Code Interactively. The Generate NC Output Interactively dialog box appears.
2. Select APT as the desired NC data type.
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 APT file.
An extract from a typical APT source file is given below.
$$ -----------------------------------------------------------------$$ Generated on Friday, January 19, 2001 03:49:48 PM$$ -----------------------------------------------------------------$$ Manufacturing Program.1$$ Part Operation.1$$*CATIA0$$ Manufacturing Program.1$$ 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 TO BE MACHINEDCOOLNT/ONCUTCOM/OFFPPRINT OPERATION NAME : Tool Change.1$$ Start generation of : Tool Change.1MULTAX$$ TOOLCHANGEBEGINNINGRAPIDGOTO / 0.00000, 0.00000, 100.00000, 0.000000, 0.000000, 1.000000CUTTER/ 10.000000, 2.000000, 3.000000, 2.000000, 0.000000$, 0.000000, 100.000000TOOLNO/1, 10.000000TPRINT/T1 End Mill D 10LOADTL/1$$ End of generation of : Tool Change.1PPRINT OPERATION NAME : Multi-Axis Sweeping.1$$ Start generation of : Multi-Axis Sweeping.1FEDRAT/ 1000.0000,MMPMSPINDL/ 70.0000,RPM,CLWGOTO / -401.86111, -831.36410, 233.69785,-0.224699,-0.974162, 0.022760GOTO / -365.04139, -841.83161, 233.65336,-0.240252,-0.967467, 0.079289
etc etc
SPINDL/OFFREWIND/0END
User TasksThe user tasks you will perform with Multi-Axis Surface Machining involve creating, editing and managing machining operations and other Machining entities.
Multi-Axis Milling OperationsAuxiliary Operations
Part Operations, Manufacturing Programs and Machining ProcessesNC Manufacturing Entities
Verification, Simulation and Program Output
Multi-Axis Machining OperationsThe tasks in this section show you how to create multi-axis machining operations in your manufacturing program.
Create a Multi-Axis Sweeping machining operation: ● Select the Multi-Axis Sweeping icon then select the geometry to be machined. You can use Offset
Groups and Features when defining geometry.
● Specify the tool to be used.
● Set the Tool axis mode then specify machining parameters, feeds and speeds, and NC macros as needed.
Basic tasks illustrate the following Tool axis modes for this operation:
● Lead and Tilt
● Fixed
● Thru a Point
● Normal to Line
● 4-Axis Lead/Lag
● Optimized Lead.
Create a Multi-Axis Contour Driven machining operation: ● Select the Multi-Axis Contour Driven icon then select the geometry to be machined. You can use Offset
Groups and Features when defining geometry.
● Specify the tool to be used.
● Set the Guiding strategy and choose one of the following Tool axis modes: ❍ Lead and Tilt
❍ Fixed
❍ Thru a Point
❍ Normal to Line
❍ 4-Axis Lead/Lag
❍ Optimized Lead.
● Specify machining parameters, feeds and speeds, and NC macros as needed.
Basic tasks illustrate the following Guiding strategies for this operation:
● Between contours
● Parallel contours
● Spine contour.
Create a Multi-Axis Curve Machining operation: ● Select the Multi-Axis Curve Machining icon then select the geometry to be machined.
● Specify the tool to be used.
● Set the Machining mode and choose one of the following Tool axis modes: ❍ Lead and Tilt
❍ Fixed
❍ Interpolation
❍ Thru a Point
❍ Normal to Line
❍ Optimized Lead (for Contact machining only)
❍ Tangent Axis (for Between 2 curves and Between curve and part modes only)
❍ 4-Axis Lead/Lag.
● Specify machining parameters, feeds and speeds, and NC macros as needed.
Basic tasks illustrate the following Machining modes for this operation:
● Contact
● Between 2 curves with Interpolation tool axis guidance and Tip machining
● Between 2 curves with Tangent Axis guidance and Side machining
● Between a curve and part with Tip or Side machining.
Create a Multi-Axis Isoparametric Machining operation: ● Select the Isoparametric Machining icon then select the geometry to be machined.
● Specify the tool to be used.
● Set the Machining mode and choose one of the following Tool axis modes: ❍ Lead and Tilt
❍ Fixed
❍ Interpolation
❍ Thru a Point
❍ Normal to Line
❍ Optimized Lead
❍ 4-Axis Lead/Lag
❍ 4-Axis Tilt.
● Specify machining parameters, feeds and speeds, and NC macros as needed.
Basic tasks illustrate the following Tool Axis modes for this operation:
● Lead and Tilt
● 4-Axis Lead
● Interpolation.
Create a Multi-Axis Sweeping Operationwith "Lead and Tilt" Tool Axis Guidance
This task illustrates how to create a Multi-Axis Sweeping operation in the program. To create the operation you must define:
● the geometry to be machined
● the tool that will be used
● the parameters of the machining strategy with the tool axis guided in Lead and Tilt mode
● the feedrates and spindle speeds
● the macros (transition paths) .
More information can be found in Selecting Geometry.Open the MultiAxisMilling01.CATPart document, then select Machining > Surface Machining from the Start menu. Make the Manufacturing Program current in the specification tree.
1. Select the Multi-Axis Sweeping icon .
A Multi-Axis Sweeping entity along with a default tool is added to the program.
The Multi-Axis Sweeping dialog box appears directly at the Geometry tab page .
This tab page includes a sensitive icon to help you specify the geometry to be machined.
The part surface of the icon is colored red indicating that this geometry is required. All other geometry is optional.
2. Select the Select faces item in the contextual menu of Part in the icon then select the desired
face in the 3D window.
The part surface of the icon is now colored green indicating that this geometry is now defined.
3. Click the orange check surface in the icon then select the desired check element in the 3D window.
4. Double click Offset on Check in the icon. Set this value to 5mm in the Edit Parameter dialog
box and click OK.
5. Select the Strategy tab page to specify parameters for:
● Machining
● Radial
● Tool axis.
6. Click the View Direction arrow (V) and set this direction to (0, -1, 0)
Click the Start Direction arrow (S) and set this direction to (1, 0,0) in the dialog box that appears.
The View and Start directions define the guiding plane for the operation.
7. Click Preview in the dialog box to verify the parameters that you have specified. A message box
appears giving feedback about this verification.
A tool is proposed by default when you want to create a machining operation. If the proposed tool is not
suitable, just select the Tool tab page to specify the tool you want to use. Please refer to Edit the
Tool of an Operation.
8. Select the Feeds and Speeds tab page to specify the feedrates and spindle speeds for the
operation.
9. Select the Macros tab page to specify the operation's transition paths (approach and
retract motion, for example). See Define Macros of an Operation for an example of specifying
transition paths on a multi-axis machining operation.
Before accepting the operation, you should check its validity by replaying the tool path.
10. Click OK to create the operation.
Create a Multi-Axis Sweeping Operation with "Fixed Axis" Tool Axis Guidance
This task shows how to insert a Multi-Axis Sweeping operation in the program.
To create the operation you must define:
● the geometry to be machined
● the tool that will be used
● the parameters of the machining strategy with the tool axis guided in Fixed Axis mode.
● the feedrates and spindle speeds
● the macros (transition paths) .
More information can be found in Selecting Geometry.Open the MultiAxisMilling01.CATPart document, then select Machining > Surface Machining from the Start menu. Make the Manufacturing Program current in the specification tree.
1. Select the Multi-Axis Sweeping icon .
A Multi-Axis Sweeping entity along with a default tool is added to the program.
The Multi-Axis Sweeping dialog box appears directly at the Geometry tab page .
This tab page includes a sensitive icon to help you specify the geometry to be machined.
The part surface of the icon is colored red indicating that this geometry is required. All other geometry is optional.
2. Select the Select faces item in the contextual menu of Part in the icon then select the desired
face in the 3D window.
3. Select the Strategy tab page to specify parameters for:
● Machining
● Radial
● Tool axis (set it to Fixed Axis).
4. Click the Tool Axis arrow (A) and select the part surface. The surface normal is used as the tool
axis.
Click the View Direction arrow (V) and select the part surface. The surface
normal is used as the view direction.
Click the Start Direction arrow (S) and set this direction to (0,0,1) in the
dialog box that appears.
A tool is proposed by default when you want to create a machining operation. If the proposed tool is not
suitable, just select the Tool tab page to specify the tool you want to use.
This is described in Edit the Tool of an Operation.
5. Select the Feeds and Speeds tab page to specify the feedrates and spindle speeds for the
operation.
6. Select the Macros tab page to specify the operation's transition paths (approach and
retract motion, for example).
See Define Macros of an Operation for an example of specifying transition paths on a multi-axis machining operation.
Before accepting the operation, you should check its validity by replaying the tool path.
7. Click OK to create the operation.
Create a Multi-Axis Sweeping Operation with "Thru a Point" Tool Axis Guidance
This task shows how to insert a Multi-Axis Sweeping operation in the program.
To create the operation you must define:
● the geometry to be machined
● the tool that will be used
● the parameters of the machining strategy with the tool axis guided in Thru a Point mode
● the feedrates and spindle speeds
● the macros (transition paths) .
More information can be found in Selecting Geometry.Open the MultiAxisMilling01.CATPart document, then select Machining > Surface Machining from the Start menu. Make the Manufacturing Program current in the specification tree.
1. Select the Multi-Axis Sweeping icon .
A Multi-Axis Sweeping entity along with a default tool is added to the program.
The Multi-Axis Sweeping dialog box appears directly at the Geometry tab page .
This tab page includes a sensitive icon to help you specify the geometry to be machined.
The part surface of the icon is colored red indicating that this geometry is required. All other geometry is optional.
2. Select the Select faces item in the contextual menu of Part in the icon then select the desired
face in the 3D window.
3. Select the Strategy tab page to specify parameters for:
● Machining
● Radial
● Tool axis (set it to Thru a Point).
4. Select the red Point symbol in the icon then select the desired Axis point
Set the condition To / From.
5. Click the View Direction arrow (V) and select the part surface. The surface normal is used as the
view direction.
Click the Start Direction arrow (S) and set this direction to (0,0,1) in the dialog box that appears.
A tool is proposed by default when you want to create a machining operation. If the proposed tool is not
suitable, just select the Tool tab page to specify the tool you want to use.
This is described in Edit the Tool of an Operation.
6. Select the Feeds and Speeds tab page to specify the feedrates and spindle speeds for the
operation.
7. Select the Macros tab page to specify the operation's transition paths (approach and
retract motion, for example).
See Define Macros of an Operation for an example of specifying transition paths on a multi-axis machining operation.
Before accepting the operation, you should check its validity by replaying the tool path.
8. Click OK to create the operation.
Create a Multi-Axis Sweeping Operation with "Normal to Line" Tool Axis Guidance
This task shows how to insert a Multi-Axis Sweeping operation in the program.
To create the operation you must define:
● the geometry to be machined
● the tool that will be used
● the parameters of the machining strategy with the tool axis guided in Normal to Line mode
● the feedrates and spindle speeds
● the macros (transition paths) .
More information can be found in Selecting Geometry.Open the MultiAxisMilling01.CATPart document, then select Machining > Surface Machining from the Start menu. Make the Manufacturing Program current in the specification tree.
1. Select the Multi-Axis Sweeping icon .
A Multi-Axis Sweeping entity along with a default tool is added to the program.
The Multi-Axis Sweeping dialog box appears directly at the Geometry
tab page .
This tab page includes a sensitive icon to help you specify the geometry to be machined.
The part surface of the icon is colored red indicating that this geometry is required. All other geometry is optional.
2. Select the Select faces item in the contextual menu of Part in the icon then select the desired
face in the 3D window.
3. Select the Strategy tab page to specify parameters for:
● Machining
● Radial
● Tool axis (set it to Normal to Line).
4. Select the red Line symbol in the icon then select the desired Axis line.
Set the condition To / From.
5. Click the View Direction arrow (V) and select the part surface. The surface normal is used as the
view direction.
Click the Start Direction arrow (S) and set this direction to (0,0,1) in the dialog box that appears.
A tool is proposed by default when you want to create a machining operation. If the proposed tool is not
suitable, just select the Tool tab page to specify the tool you want to use.
This is described in Edit the Tool of an Operation.
6. Select the Feeds and Speeds tab page to specify the feedrates and spindle speeds for the
operation.
7. Select the Macros tab page to specify the operation's transition paths (approach and
retract motion, for example).
See Define Macros of an Operation for an example of specifying transition paths on a multi-axis
machining operation.
Before accepting the operation, you should check its validity by replaying the tool path.
8. Click OK to create the operation.
Create a Multi-Axis Sweeping Operation with "4-Axis Lead/Lag" Tool Axis Guidance
This task illustrates how to create a Multi-Axis Sweeping operation in the program.
To create the operation you must define:
● the geometry to be machined
● the tool that will be used
● the parameters of the machining strategy with the tool axis guided in 4-Axis Lead/Lag
mode
● the feedrates and spindle speeds
● the macros (transition paths) .
More information can be found in Selecting Geometry.
Open the MultiAxisMilling01.CATPart document, then select Machining > Surface Machining from the Start menu. Make the Manufacturing Program current in the specification tree.
1. Select the Multi-Axis Sweeping icon .
A Multi-Axis Sweeping entity along with a default tool is added to the program.
The Multi-Axis Sweeping dialog box appears directly at the Geometry
tab page .
This tab page includes a sensitive icon to help you specify the geometry to be machined.
The part surface of the icon is colored red indicating that this geometry is required. All other geometry is optional.
2. Select the Select faces item in the contextual menu of Part in the icon then select the desired
face in the 3D window.
The part surface of the icon is now colored green indicating that this geometry is now defined.
3. Select the Strategy tab page to specify parameters for:
● Machining
● Radial
● Tool axis (set it to 4-Axis Lead/Lag).
4. Click the View Direction arrow (V) and select the part surface. The surface normal is used as the
view direction.
Click the Start Direction arrow (S) and set this direction to (0,0,1) in the dialog box that appears.
Click the 4-Axis Constraint arrow (N in the 3D window or the arrow normal to the plane in the sensitive icon) and set this direction in the dialog box that appears. This is the normal to the plane in which the tool axis is constrained.
It is also possible to click the Overall Machining Direction arrow (M in the 3D window) to reverse this direction.
The View and Start directions define the guiding plane for the operation.
5. Click Preview in the dialog box to verify the parameters that you have specified.
A message box appears giving feedback about this verification.
A tool is proposed by default when you want to create a machining operation. If the proposed tool is not
suitable, just select the Tool tab page to specify the tool you want to use.
Please refer to Edit the Tool of an Operation.
6. Select the Feeds and Speeds tab page to specify the feedrates and spindle speeds for
the operation.
7. Select the Macros tab page to specify the operation's transition paths (approach and
retract motion, for example).
See Define Macros of an Operation for an example of specifying transition paths on a multi-axis machining operation.
Before accepting the operation, you should check its validity by replaying the tool path.
8. Click OK to create the operation.
Create a Multi-Axis Sweeping Operation with "Optimized Lead" Tool Axis Guidance
This task illustrates how to create a Multi-Axis Sweeping operation in the program.
To create the operation you must define:
● the geometry to be machined
● the tool that will be used
● the parameters of the machining strategy with the tool axis guided in Optimized Lead mode
● the feedrates and spindle speeds
● the macros (transition paths) .
More information can be found in Selecting Geometry.Open the MultiAxisMilling01.CATPart document, then select Machining > Surface Machining from the Start menu. Make the Manufacturing Program current in the specification tree.
1. Select the Multi-Axis Sweeping icon .
A Multi-Axis Sweeping entity along with a default tool is added to the program.
The Multi-Axis Sweeping dialog box appears directly at the Geometry
tab page .
This tab page includes a sensitive icon to help you specify the geometry to be machined.
The part surface of the icon is colored red indicating that this geometry is required. All other geometry is optional.
2. Select the Select faces item in the contextual menu of Part in the icon then select the desired
face in the 3D window.
The part surface of the icon is now colored green indicating that this geometry is now defined.
3. Select the Strategy tab page to specify parameters for:
● Machining
● Radial
● Tool axis (set it to Optimized Lead).
4. Click the View Direction arrow (V) and select the part surface. The surface normal is used as the
view direction.
Click the Start Direction arrow (S) and set this direction to (0,0,1) in the dialog box that appears.
The View and Start directions define the guiding plane for the operation.
5. Click Preview in the dialog box to verify the parameters that you have specified.
A message box appears giving feedback about this verification.
A tool is proposed by default when you want to create a machining operation. If the proposed tool is not
suitable, just select the Tool tab page to specify the tool you want to use.
Please refer to Edit the Tool of an Operation.
6. Select the Feeds and Speeds tab page to specify the feedrates and spindle speeds for the
operation.
7. Select the Macros tab page to specify the operation's transition paths (approach and
retract motion, for example).
See Define Macros of an Operation for an example of specifying transition paths on a multi-axis machining operation.
Before accepting the operation, you should check its validity by replaying the tool path.
8. Click OK to create the operation.
Create a Multi-Axis Contour Driven Operation Between Contours
This task shows how to insert a Multi-Axis Contour Driven operation in the program. To create the operation you must define:
● the geometry to be machined
● the tool that will be used
● the parameters of the machining strategy with the Guiding Strategy set to Between
Contours
● the feedrates and spindle speeds
● the macros (transition paths) .
More information can be found in Selecting Geometry.Open the MultiAxisMilling01.CATPart document, then select Machining > Surface Machining from the Start menu. Make the Manufacturing Program current in the specification tree.
1. Select the Multi-Axis Contour Driven icon . A Multi-Axis Contour Driven entity along with
a default tool is added to the program.
The Multi-Axis Contour Driven dialog box appears directly at the
Geometry tab page . This tab page includes a sensitive icon to help
you specify the geometry to be machined.
The part surface of the icon is colored red indicating that this geometry is required.
2. Click the red area in the icon, then select the desired part in the 3D window.
3. Select the Strategy tab page . Make sure that the Guiding Strategy is set to Between
Contours,
then specify the parameters for:
● Machining
● Radial
● Tool axis: set it to Fixed Lead and Tilt.
In the sensitive icon:
4. Click the View Direction arrow (V) and select the part surface. The surface normal is used as the
view direction.
5. Click the red Guide 1 curve in the icon then select the first guide curve in the model.
You can position the tool with respect to this curve using using the setting: Inside, Outside or On. You can also specify an offset.
6. Click the red Guide 2 curve in the icon then select the second guide curve in the model.
You can position the tool with respect to this curve using using the setting: Inside, Outside or On. You can also specify an offset.
7. A tool is proposed by default when you want to create a machining operation. If the proposed tool
is not suitable, just select the Tool tab page to specify the tool you want to use. This is
described in Edit the Tool of an Operation.
8. Select the Feeds and Speeds tab page to specify the feedrates and spindle speeds for the
operation.
9. If you want to specify approach and retract motion for the operation, select the Macros tab page
to specify the desired transition paths. The general procedure for this is described in Define
Macros of an Operation.
10. Before accepting the operation, you should check its validity by replaying the tool path.
11. Click OK to create the operation.
Create a Multi-Axis Contour Driven Operation with Parallel Contours
This task shows how to insert a 'Parallel Contour' Multi-Axis Contour Driven operation in the program.
To create the operation you must define:
● the geometry to be machined
● the tool that will be used
● the parameters of the machining strategy with the Guiding Strategy set to Parallel Contour
● the feedrates and spindle speeds
● the macros (transition paths) .
More information can be found in Selecting Geometry.Open the MultiAxisMilling01.CATPart document, then select Machining > Surface Machining from the Start menu. Make the Manufacturing Program current in the specification tree.
1. Select the Multi-Axis Contour Driven icon .
A Multi-Axis Contour Driven entity along with a default tool is added to the program.The Multi-Axis Contour Driven dialog box appears directly at the Geometry
tab page .
This tab page includes a sensitive icon to help you specify the geometry to be machined.
The part surface of the icon is colored red indicating that this geometry is required.
2. Click the red part surface in the icon then select the desired part in the 3D window.
3. Select the Strategy tab page . Make sure that the Guiding Strategy is set to Parallel
Contour
then specify the parameters for:
● Machining
● Strategy:Stepover Side to LeftMax width to machine to 75mm
● Tool axis: Fixed Lead and Tilt.
4. Click the red Guide 1 curve in the icon then select the desired guide curve in the model.
5. Click the View Direction arrow (V) and select the part surface. The surface normal is used as the
view direction.
A tool is proposed by default when you want to create a machining operation. If the proposed tool is not
suitable, just select the Tool tab page to specify the tool you want to use.
This is described in Edit the Tool of an Operation.
6. Select the Feeds and Speeds tab page to specify the feedrates and spindle speeds for the
operation.
7. If you want to specify approach and retract motion for the operation, select the Macros tab page
to specify the desired transition paths.
The general procedure for this is described in Define Macros of an Operation.Before accepting the operation, you should check its validity by replaying the tool path.
8. Click OK to create the operation.
Create a Multi-Axis Contour Driven Operation with Spine Contour
This task shows how to insert a 'Spine Contour' Multi-Axis Contour Driven operation in the program.
To create the operation you must define:
● the geometry of the pocket to be machined
● the tool that will be used
● the parameters of the machining strategy with the Guiding Strategy set to Spine Contour
● the feedrates and spindle speeds
● the macros (transition paths) .
More information can be found in Selecting Geometry.Open the MultiAxisMilling01.CATPart document, then select Machining > Surface Machining from the Start menu. Make the Manufacturing Program current in the specification tree.
1. Select the Multi-Axis Contour Driven icon .
A Multi-Axis Contour Driven entity along with a default tool is added to the program.
The Multi-Axis Contour Driven dialog box appears directly at the
Geometry tab page .
This tab page includes a sensitive icon to help you specify the geometry to be machined.
The part surface of the icon is colored red indicating that this geometry is required.
2. Click the red area in the icon then select the desired part surface in the 3D window.
● Select the Strategy tab page . Make sure that the Guiding Strategy is set to Spine Contour
then specify the parameters for:
● Machining
● Radial
● Tool axis: Fixed Lead and Tilt.
4. Click the red Guide 1 in the icon then select the desired guide curve in the model.
5. Click the View Direction arrow (V) and select the part surface. The surface normal is used as the
view direction.
A tool is proposed by default when you want to create a machining operation. If the proposed tool is not
suitable, just select the Tool tab page to specify the tool you want to use.
This is described in Edit the Tool of an Operation.
6. Select the Feeds and Speeds tab page to specify the feedrates and spindle speeds for the
operation.
7. Select the Macros tab page to specify the operation's transition paths (approach and
retract motion, for example).
See Define Macros of an Operation for an example of specifying transition paths on a machining operation. Before accepting the operation, you should check its validity by replaying the tool path.
8. Click OK to create the operation.
Create a Multi-Axis Contact CurveMachining Operation
This task shows how to insert a 'Contact' Curve Machining operation in the program. To create the operation you must define:
● the Curve Machining mode as Contact
● the geometry to be machined
● the tool that will be used
● the parameters of the machining strategy with the tool axis guided in Lead and Tilt mode
● the feedrates and spindle speeds
● the macros (transition paths) .
Open the MultiAxisMilling01.CATPart document, then select Machining > Surface Machining from the Start menu. Make the Manufacturing Program current in the specification tree.
1. Select the Multi-Axis Curve Machining icon .
The Multi-Axis Curve Machining dialog box appears directly at the
Geometry tab page .
This page includes a sensitive icon to help you specify the geometry to be machined.
Set the Curve Machining mode to Contact to drive the contact point.
The part and guide curve in the icon are colored red indicating that this geometry is required for defining the operation. All other geometry is optional.
2. Click the red part in the icon, then select the four faces in the 3D window as shown in the figure
below.
3. Click the red guide element in the icon, then select four edges in the 3D window as shown in the
figure below. Note that a Guide is created for each set of continuous edges, and that discontinuous
Guides are accepted.
The four faces and the four edges are selected:
The part and guide elements of the icon are now colored green indicating that this geometry is now defined. These are also indicated on the part. Make sure that the arrows representing the part surface orientation are all pointing upwards.
4. Select the Strategy tab page . You can then use the tab pages to set parameters for:
● Machining
● Radial
● Axial
● Finishing
● Tool Axis Specify Fixed Lead and Tilt with Lead angle = 20deg and Tilt angle = 0deg.
A tool is proposed by default when you want to create a machining operation. If the proposed tool is not
suitable, just select the Tool tab page to specify the tool you want to use. This is described in Edit
the Tool of an Operation.
5. Select the Feeds and Speeds tab page to specify the feedrates and spindle speeds for the
operation.
If you want to specify approach and retract motion for the operation, select the Macros tab page
to specify the desired transition paths. The general procedure for this is described in Define Macros of an Operation.
6. Check the validity of the operation by replaying the tool path.
7. Click OK to create the operation.
Create a Multi-Axis Curve Machining Operation Between 2 curves with Tool Axis Interpolation
This task shows how to insert a 'Between 2 curves' Multi-Axis Curve Machining operation in the program. In this scenario the tool axis will be guided in Interpolation mode.
To create the operation you must define:
● the Curve Machining mode as Between 2 curves and the Curve Machining type as Tip
● the geometry to be machined
● the tool that will be used
● the parameters of the machining strategy with the tool axis guided in Interpolation mode
● the feedrates and spindle speeds
● the macros (transition paths) .
Open the MultiAxisMilling01.CATPart document, then select Machining > Surface Machining from the Start menu. Make the Manufacturing Program current in the specification tree.
1. Select the Multi-Axis Curve Machining icon .
The Multi-Axis Curve Machining dialog box appears directly at the
Geometry tab page .
This page includes a sensitive icon to help you specify the geometry to be machined.
Set the Curve Machining mode to Between 2 curves.
The top guiding curve in the icon is colored red indicating that this geometry is required for defining the operation. All other geometry is optional.
Set the Curve Machining type to Tip to drive the extremity of the tool.
2. Click the top guiding curve in the icon, then select the five edges in the 3D window as shown in
the figure below.
The guide elements of the icon are now colored green indicating that this geometry is now defined. These are also indicated on the part.
3. Select the Strategy tab page . You can then use the tab pages to set parameters for:
● Machining
● Radial
● Axial
● Finishing
● Tool Axis (set to Interpolation).
4. Click the tool axis arrow (A) in the sensitive icon, then specify the reference tool axis direction for
the operation. You can do this by selecting a surface. In this case the surface normal is used.
Click one of the red interpolation axes in the sensitive icon, then select a position for the first interpolation axis. The axis is visualized by means of an arrow (I.1).
You can then specify the orientation of this axis using the Interpolation Axis dialog box that appears. If you select a surface, the surface normal is used.
Select one or more positions for other interpolation axes and specify their orientations in the same way.
A tool is proposed by default when you want to create a machining operation. If the proposed tool is not
suitable, just select the Tool tab page to specify the tool you want to use.
This is described in Edit the Tool of an Operation.
5. Select the Feeds and Speeds tab page to specify the feedrates and spindle speeds for the
operation.
6. Check the validity of the operation by replaying the tool path.
You can add approach and retract motions to the operation in the Macros tab page . This is
described in Define Macros of an Operation.
7. Click OK to create the operation.
Create a Multi-Axis Curve Machining Operation Between 2 curves with Tangent Axis Guidance
This task shows how to insert a 'Between 2 curves' Multi-Axis Curve Machining operation in the program. In this scenario the tool axis will be guided in Tangent Axis mode along the isoparametrics of the selected drive surfaces.
To create the operation you must define:
● the Curve Machining mode as Between 2 curves and the Curve Machining type as Side
● the geometry to be machined
● the tool that will be used
● the parameters of the machining strategy with the tool axis guided in Tangent Axis mode
● the feedrates and spindle speeds
● the macros (transition paths) .
Open the MultiAxisMilling03.CATPart document, then select Machining > Surface Machining from the Start menu. Make the Manufacturing Program current in the specification tree.
1. Select the Multi-Axis Curve Machining icon .
The Multi-Axis Curve Machining dialog box appears directly at the
Geometry tab page .
This page includes a sensitive icon to help you specify the geometry to be machined.
Set the Curve Machining mode to Between 2 curves.
2. Click the top guiding curve in the icon. In the Edge Selection toolbar that appears, set Link
types to Insert line then select the three edges on the part as shown in the figure below. Note
that any gaps between the edges are filled thanks to the Insert link option.
Set the Curve Machining type to Side to drive the flank of the tool.
3. Select the Strategy tab page . This page includes a sensitive icon to help you specify the
drive surfaces and reference tool axis.
You can use the tab pages to set parameters for:
● Machining
● Radial
● Axial
● Tool Axis (set to Tangent Axis - Along isoparametric lines).
Click the sensitive drive element in the icon, then select the three drive surfaces in the 3D window as
shown in the figure.
A default reference tool axis is displayed in the 3D view. If needed, you can modify it by clicking the tool axis arrow (A) in the sensitive icon, then specifying a different tool axis direction. You can do this by selecting a surface. In this case the surface normal is used.
When machining a strip (or band) for faces, the tool axis is deduced from the isoparametrics of the faces in order to ensure continuity of the trajectory. See Tangent Axis - Along isoparametric lines for more information.
4. A tool is proposed by default when you want to create a machining operation. If the proposed tool
is not suitable, just select the Tool tab page to specify the tool you want to use.
This is described in Edit the Tool of an Operation.
5. Select the Feeds and Speeds tab page to specify the feedrates and spindle speeds for the
operation.
6. Check the validity of the operation by replaying the tool path.
You can add approach and retract motions to the operation in the Macros tab page . This is
described in Define Macros of an Operation.
7. Click OK to create the operation.
Create a Multi-Axis Curve Machining Operation Between a Curve and Part
This task shows how to insert a 'Between curve and part' Multi-Axis Curve Machining operation in the program.
To create the operation you must define:
● the Curve Machining mode as Between curve and part and the Curve Machining type to Side
● the geometry to be machined
● the tool that will be used
● the parameters of the machining strategy with the tool axis guided in Interpolation mode
● the feedrates and spindle speeds
● the macros (transition paths) .
Open the MultiAxisMilling01.CATPart document, then select Machining > Surface Machining from the Start menu. Make the Manufacturing Program current in the specification tree.
1. Select the Multi-Axis Curve Machining icon .
The Multi-Axis Curve Machining dialog box appears directly at the
Geometry tab page .
This page includes a sensitive icon to help you specify the geometry to be machined.
Set the Curve machining mode to Between curve and part.
The top guiding curve and part bottom in the icon are colored red indicating that this geometry is required for defining the operation. All other geometry is optional.
Set the Curve Machining type to Side to drive the tool flank.
2. Click the red bottom in the icon, then select the 6 faces in the 3D window as shown in the figure.
3. Click the top guiding curve in the icon, then select the 6 edges in the 3D window as shown in the
figure.
The part and guide elements of the icon are now colored green indicating that this geometry is now defined. These are also indicated on the part.
4. Select the Strategy tab page . You can then use the tab pages to set parameters for:
● Machining
● Radial (set Radial strategy with Distance between paths = 3mm and Number of paths = 4)
● Axial
● Finishing
● Tool Axis (set to Interpolation).
5. Click the tool axis arrow (A) in the sensitive icon, then specify the reference tool axis direction for
the operation. You can do this by selecting a surface. In this case the surface normal is used.
Click one of the red interpolation axes in the sensitive icon, then select a position for the first interpolation axis. The axis is visualized by means of an arrow (I.1). You can then specify the orientation of this axis using the Interpolation Axis dialog box that appears. If you select a surface, the surface normal is used.
Select one or more positions for other interpolation axes and specify their orientations in the same way.
A tool is proposed by default when you want to create a machining operation. If the proposed tool is not
suitable, just select the Tool tab page to specify the tool you want to use.
This is described in Edit the Tool of an Operation.
6. Select the Feeds and Speeds tab page to specify the feedrates and spindle speeds for the
operation.
7. Check the validity of the operation by replaying the tool path.
You can add approach and retract motions to the operation in the Macros tab page . This is
described in Define Macros of an Operation.
8. Click OK to create the operation.
Create a Multi-Axis Isoparametric Machining Operation with "Lead and Tilt" Tool Axis
GuidanceThis task illustrates how to create a Multi-Axis Isoparametric Machining operation in the program. To create the operation you must define:
● the geometry to be machined
● the tool that will be used
● the parameters of the machining strategy with the tool axis guided in Lead and Tilt mode
● the feedrates and spindle speeds
● the macros (transition paths) .
Open the MultiAxisMilling02.CATPart document, then select Machining > Surface Machining from the Start menu. Make the Manufacturing Program current in the specification tree.
1. Select the Isoparametric Machining icon . An Isoparametric Machining entity along with
a default tool is added to the program. The Isoparametric Machining dialog box appears directly
at the Geometry tab page .
The part surface and corner points of the sensitive icon are colored red indicating that this geometry is required. All other geometry is optional.
2. Click the red part surface in the icon then select the desired surfaces in the 3D window. The Face
Selection toolbar appears to help you select faces or belts of faces. These can be adjacent or non-
adjacent. For more information please refer to Non-Adjacent Belts of Faces.
Click a red point in the icon then select the four corner points of the selected surfaces.
Machining starts from point 1 to point 2, and finishes either from point 3 to 4 or 4 to 3 (depending on the One way or Zig zag tool path style).
3. A default reference tool axis (A) is displayed. You can double click on this axis to modify it.
The part surface and corner points of the icon are now colored green indicating that this geometry is now defined.
4. Select the Strategy tab page to specify parameters for:
● Tool axis:
● Machining:
● Radial:
5. Click Preview in the dialog box to verify the parameters that you have specified. A message box
appears giving feedback about this verification.
A tool is proposed by default when you want to create a machining operation. If the proposed tool is not
suitable, just select the Tool tab page to specify the tool you want to use. Please refer to Edit the
Tool of an Operation.
6. Select the Feeds and Speeds tab page to specify the feedrates and spindle speeds for the
operation.
7. Select the Macros tab page to specify the operation's transition paths (approach and
retract motion, for example). See Define Macros of an Operation for an example of specifying
transition paths on a multi-axis machining operation.
Before accepting the operation, you should check its validity by replaying the tool path.
8. Click OK to create the operation.
Create a Multi-Axis Isoparametric Machining Operation with "4-Axis Lead/Lag" Tool Axis
GuidanceThis task illustrates how to create a Multi-Axis Isoparametric Machining operation in the program.
To create the operation you must define:
● the geometry to be machined
● the tool that will be used
● the parameters of the machining strategy with the tool axis guided in 4-Axis Lead/Lag mode
● the feedrates and spindle speeds
● the macros (transition paths) .
Open the MultiAxisMilling02.CATPart document, then select Machining > Surface Machining from the Start menu. Make the Manufacturing Program current in the specification tree.
1. Select the Isoparametric Machining icon . An Isoparametric Machining entity along with
a default tool is added to the program. The Isoparametric Machining dialog box appears directly
at the Geometry tab page .
The part surface and corner points of the sensitive icon are colored red indicating that this geometry is required. All other geometry is optional.
2. Click the red part surface in the icon then select the desired surfaces in the 3D window.
The Face Selection toolbar appears to help you select faces or belts of faces. These can be adjacent or non-adjacent. For more information please refer to Non-Adjacent Belts of Faces.
3. Click a red point in the icon then select the four corner points of the selected surfaces.
Machining starts from point 1 to point 2, and finishes either from point 3 to 4 or 4 to 3 (depending on the One way or Zig zag tool path style).
The part surface and corner points of the icon are now colored green indicating that this geometry is now defined.
4. Select the Strategy tab page to specify parameters for:
● Tool axis:
A default reference tool axis (A) and 4-Axis Constraint arrow (N) are displayed. You can double click on these axes to modify them.
Click the 4-Axis Constraint arrow (N). This is the normal to the plane in which the tool axis is constrained. A dialog box appears showing the default direction. You can modify this direction, if needed.
● Machining:
● Radial:
5. Click Preview in the dialog box to verify the parameters that you have specified.
A message box appears giving feedback about this verification.
6. A tool is proposed by default when you want to create a machining operation. If the proposed tool
is not suitable, just select the Tool tab page to specify the tool you want to use.
Please refer to Edit the Tool of an Operation.
7. Select the Feeds and Speeds tab page to specify the feedrates and spindle speeds for the
operation.
8. Select the Macros tab page to specify the operation's transition paths (approach and
retract motion, for example).
See Define Macros of an Operation for an example of specifying transition paths on a multi-axis machining operation.
9. Before accepting the operation, you should check its validity by replaying the tool path.
10. Click OK to create the operation.
Create a Multi-Axis Isoparametric Machining Operation with "Interpolation" Tool Axis
GuidanceThis task illustrates how to create a Multi-Axis Isoparametric Machining operation in the program.
To create the operation you must define:
● the geometry to be machined
● the tool that will be used
● the parameters of the machining strategy with the tool axis guided in Interpolation mode
● the feedrates and spindle speeds
● the macros (transition paths) .
Open the MultiAxisMilling04.CATPart document, then select Machining > Surface Machining from the Start menu. Make the Manufacturing Program current in the specification tree.
1. Select the Isoparametric Machining icon . An Isoparametric Machining entity along with
a default tool is added to the program. The Isoparametric Machining dialog box appears directly
at the Geometry tab page .
This tab page includes a sensitive icon to help you specify the geometry to be machined.
The part surface and corner points of the icon are colored red indicating that this geometry is required. All other geometry is optional.
2. Click the red part surface in the icon then select the desired surface in the 3D window.
The Face Selection toolbar appears to help you select faces or belts of faces. These can be adjacent or non-adjacent. For more information please refer to Non-Adjacent Belts of Faces.
3. Click the orange check surface in the icon then select the desired surface in the 3D window as
shown below.
4. Click a red point in the icon then select the four corner points of the selected surface.
Machining starts from point 1 to point 2, and finishes either from point 3 to 4 or 4 to 3 (depending on the One way or Zig zag tool path style).
The part surface and corner points of the icon are now colored green indicating that this geometry is now defined.
4. Select the Strategy tab page to specify parameters for:
● Tool axis guidance:
A default reference tool axis (A) is displayed. You can double click on this axis to modify it.
● Machining:
● Radial:
5. Click an interpolation axis symbol in the icon.
An interpolation axis (I) appears at each of the corners of the surface to be machined. Click on the axis symbol and specify the desired orientation using options proposed in the Interpol Axis dialog box that appears.
In some cases, such as the machining of turbine blades, you need to avoid collisions and have a perfect fluidity of the tool trajectory. To achieve this, you can define additional interpolation axis on the part to machine, either by selecting existing points on the part, or by clicking on the part to create them interactively.
A dialog box opens to let you define this additional interpolation axis.
If you select a point that does not belong to a selected face, the point is projected to the nearest select face.
6. Click Preview in the dialog box to verify the parameters that you have specified.
A message box appears giving feedback about this verification.
7. A tool is proposed by default when you want to create a machining operation. If the proposed tool
is not suitable, just select the Tool tab page to specify the tool you want to use.
Please refer to Edit the Tool of an Operation.
8. Select the Feeds and Speeds tab page to specify the feedrates and spindle speeds for the
operation.
9. Select the Macros tab page to specify the operation's transition paths (approach and
retract motion, for example).
See Define Macros of an Operation for an example of specifying transition paths on a multi-axis machining operation.
10. Before accepting the operation, you should check its validity by replaying the tool path.
Without an additional interpolation axis:
With an additional interpolation axis:
11. Click OK to create the operation.
Auxiliary OperationsThe tasks for inserting auxiliary operations in the manufacturing program are documented in the Machining Infrastructure User's Guide.
Insert Tool Change: Select the Tool Change icon then select the tool type to be referenced in the tool change.
Insert Machine Rotation: Select the Machine Rotation icon then specify the tool rotation characteristics.
Insert Machining Axis System Change: Select the Machining Change icon then specify the characteristics of the new machining axis system.
Insert PP Instruction: Select the PP Instruction icon then enter the syntax of the PP instruction.
Insert COPY Operator (P2 functionality): Select the COPY Operator icon then select the reference operation. You can then specify the number of copies and the characteristics of the transformation.
Insert TRACUT Operator (P2 functionality): Select the TRACUT Operator icon then select the reference operation. You can then specify the characteristics of the transformation.
Insert Copy Transformation Instruction: Select the Copy Transformation icon then select the reference operation. You can then specify the number of copies and the characteristics of the transformation.
Part Operations, Manufacturing Programs and Machining Processes
The tasks for creating and managing Part Operations, Manufacturing Programs and Machining Processes are documented in the Machining Infrastructure User's Guide.
Create and Edit a Part Operation: Select the Part Operation icon 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 the Manufacturing Program icon to add a program to the current part operation then insert all necessary program entities: machining operations, tool changes, PP instructions, and so on.
Create a Machining Process: Select the Machining Process icon to create a machining process, which can then be stored in a catalog.
Apply a Machining Process: Select the Open Catalog icon to access the machining process to be applied to selected geometry.
Machining EntitiesThe tasks for creating and managing specific entities of the Machining environment are documented in the Machining Infrastructure User's Guide.
● 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 tool.
● 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 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.
● Replace Tools in Resource List: Click the Replace Tools icon to rename tools already used in your document.
● 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 .
● Create and Use Machining Patterns: 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.
● 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.
● Build and Use a Macros Catalog.
● 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.
Verification, Simulation and Program OutputThe tasks for using capabilities such as tool path verification, material removal simulation, and production of NC output data are documented in the Machining Infrastructure User's Guide.
Replay Tool Path: Select the Tool Path Replay icon then specify the display options for an animated tool path display of the manufacturing program of machining operation. Simulate Material Removal: Select the desired icon in the Tool Path Replay dialog box to run a material removal simulation either in Photo or Video mode.
● Generate APT Source Code in Batch Mode: Select the Generate NC Code in Batch Mode icon then select
the manufacturing program to be processed and define the APT source processing options.
● Generate NC Code in Batch Mode: Select the Generate NC Code in Batch Mode icon then select the
manufacturing program to be processed and define the NC code processing options.
● Generate Clfile Code in Batch Mode: Select the Generate NC Code in Batch Mode icon then select the
manufacturing program to be processed and define the Clfile processing options.
● Generate a CGR File in Batch Mode: Select the Generate NC Code in Batch Mode icon then select the
manufacturing program to be processed and define the CGR file processing options.
● MfgBatch Utility 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 Code in Interactive Mode: Select the Generate NC Code Interactively icon then select the manufacturing program to be processed and define processing options.
Generate Documentation: Select the Generate Documentation icon 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.
Workbench DescriptionThis section contains the description of the menu commands and icon toolbars that are specific to the Surface Machining workbench when Multi-Axis Surface Machining is installed.
Menu BarToolbars
Specification Tree
Multi-Axis Surface Machining Menu Bar The menu commands that are made available when Multi-Axis Surface Machining is installed are described below.
Start File Edit View Insert Tools Windows Help
Tasks corresponding to general menu commands are described in the CATIA Version 5 Infrastructure User's Guide.
Insert Menu
Insert > Machining Operations > Multi-Axis Machining Operations Command... Description...
Multi-Axis SweepingCreate a Multi-Axis Sweeping Operation
Isoparametric MachiningCreate an Isoparametric Machining Operation
Multi-Axis Contour Driven Create a Multi-Axis Contour Driven Operation
Multi-Axis Curve Machining Create a Multi-Axis Curve Following Operation
Machining Operations ToolbarWhen Multi-Axis Surface Machining is installed with 3-Axis Surface Machining, the Machining Operations toolbar is enhanced with specific drop-down icons for creating multi-axis surface machining operations.
When Multi-Axis Surface Machining is installed with Prismatic Machining and Lathe Machining, a Multi-Axis Milling Operations toolbar is added to the workbench.
The additional commands are as follows.
To create or edit a Multi-Axis Sweeping Operation.
Basic tasks illustrate the following tool axis modes for this operation:
● Lead and Tilt
● Fixed
● Thru a Point
● Normal to Line
● 4-Axis Lead/Lag
● Optimized Lead.
To create or edit a Multi-Axis Isoparametric Machining Operation.
Basic tasks illustrate the following Tool Axis modes for this operation:
● Lead and Tilt
● 4-Axis Lead
● Interpolation.
To create or edit a Multi-Axis Contour Driven Operation.
Basic tasks illustrate the following guiding strategies for this operation:
● Between contours
● Parallel contours
● Spine contours.
To create or edit a Multi-Axis Curve Machining Operation.
Basic tasks illustrate the following machining modes for this operation:
● Contact
● Between 2 curves with Tip / Interpolation machining
● Between a curve and part with Side / Interpolation machining.
The other toolbars of this workbench are described in the 3-Axis Surface Machining User's Guide.
Specification TreeHere is an example of a Process Product Resources (PPR) specification tree for Machining products.
Process List is a plan that gives all the activities and machining operations 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 has not been computed
❍ Drilling.2 is complete but has been computed (by means of a replay)
❍ Drilling.3 does not have all of the necessary data (indicated by the exclamation mark symbol)
❍ Drilling.4 has been deactivated by the user (indicated by the brackets symbol)
❍ Drilling.5 has been modified and needs to be recomputed (indicated by the update symbol).
Product List gives all of the parts to machine as well as CATPart documents containing complementary geometry. Resources List gives all of the resources such as machine or tools that can be used in the program.
Customizing
This section describes how to customize settings for Machining.
Before you start your first working session, you can customize the way you work to suit your habits. This type of customization is stored in permanent setting files: these settings will not be lost if you end your session.
Other tasks for customizing your Machining environment are documented in the Machining Infrastructure User's Guide:
Build a Tools Catalog Access External Tools Catalogs Add User Attributes on Tool Types PP Word Syntaxes NC Documentation Workbenches and Tool Bars
1. Select the Tools -> Options command. 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 productsResources tooling, feeds&speeds and resource filesOperation machining operationsOutput PP files and NC data outputProgram manufacturing programs (sequencing, and so on)Photo/Video material removal simulation
4. Set options in these tabs 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 checkbox if you want the status of activities in the tree to be updated automatically.
● If this checkbox is not selected:
❍ you can update activity status manually in your workbench using the Update Status icon in the Auxiliary Commands toolbar.
❍ the status of the activity after a manual update is masked at the first action on the node (for example, edit, replay, collapse/expand of a parent node). To retrieve the status of the activity you must select the Update Status icon again.
If this checkbox is not selected, performance is improved.
By default, the checkbox 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 checkbox to use highlighting. Performance is improved when all the Highlight checkboxes are selected.
Tool Path Replay
Display tool near cursor position on tool path
Select this checkbox 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.
Display tool center instead of tool tip
Select this checkbox if you want to display the tool center point instead of the tool tip during a tool path replay.
Display circles
Select this checkbox 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 checkboxes 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 checkbox to create a CATPart dedicated to manufacturing-specific geometry in the Product List of the PPR tree.
By default, the checkbox is not selected.
Design Changes
Smart NC mode
Select this checkbox 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 checkbox is not selected.
Optimized detection of design changes
Select this check box to enable a geometrical comparison mode in order to more precisely determine the design change status of machining operations.
By default, these checkboxes 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 checkbox if you want to to activate an automatic query after each modification of a tool parameter. Performance is improved when this checkbox is not selected.
Tool preview after selection
Select this checkbox if you want to preview the tool after selection.
By default, these checkboxes are selected.
Automatic Compute from Tool Feeds and Speeds
Feedrate attributes of the operation
Select this checkbox 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 checkbox 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 checkboxes 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.
Default Values
Select the checkbox 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 checkbox is selected.
After Creation or Machining Process (MP) Instantiation
Select the desired checkboxes 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 checkbox 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.
By default, these checkboxes are selected.
When Copying
Select the checkbox 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 checkbox is not selected.
By default, this checkbox is selected.
Display
Select the checkbox if you want to display tool paths of operations in the current Part Operation.
By default, this checkbox is not selected.
User Interface
Select the checkbox 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 checkbox is not 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 the type of PP files to be used for generating NC code output 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
Select the desired Processor option:
● None: no Post Processor is defined. NC code output is not possible in this case
● Cenit: you can choose from among the Post Processor parameter files proposed by Cenit to generate your NC code
● IMS: you can choose from among the Post Processor parameter files proposed by Intelligent Manufacturing Software (IMS) to generate your NC code
● ICAM: you can choose from among the Post Processor parameter files proposed by ICAM Technologies Corporation (ICAM) to generate your NC code.
Enter the path of the folder containing Post processors. 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 checkbox 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 checkbox is selected.
During Tool Path Computation
Select the checkbox if you want to store contact points in the tool path.
Performance is improved when this checkbox is not selected.
By default, this checkbox 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 checkbox. 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 the Associate Video Result
to Machining Operation icon in the Tool Path Replay dialog box.
By default, the Tool path: Store at same location as the CATProcess checkbox 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 checkbox 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 checkbox is selected.
Display sequencing rules and priorities
Select the Display sequencing rules and priorities checkbox to authorize the display of sequencing rules and priorities in the user's view. In this case two more checkboxes can be selected in order to:
● allow the user to filter rules
● allow the user to modify rule priorities.
By default, these checkboxes 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 checkbox if you want the Video simulation to stop each time a tool change is encountered in the program.
By default, this checkbox 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 checkbox if you want touch (or contact) type of collision to be detected.
By default, this checkbox is selected.
Multiple Video result on program
Select the Multiple Video result on program checkbox if you want to store video results on more than one operation in the program.
By default, this checkbox 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.
Best performance is obtained when no bounding box is required and the checkbox is not selected.
By default, the Wireframe option is selected.
Select the checkbox to compute all information at picked point.
By default, this checkbox is not selected.
Best performance is obtained when Fault box: None is selected and the checkbox 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
Set the Optimized rendering for Video checkbox 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 checkbox 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.
Reference InformationReference information that is specific to the Multi-Axis Surface Machining product can be found in this section.
Multi-Axis SweepingMulti-Axis Isoparametric Machining
Multi-Axis Contour DrivenMulti-Axis Curve Machining
Collision Checking
Essential reference information on the following topics is provided in the Machining Infrastructure User's Guide.
Machining ResourcesNC Macros
PP Tables and PP Word SyntaxesFeeds and Speeds
APT FormatsCLfile Formats
Multi-Axis Sweeping
The information in this section will help you create and edit Multi-Axis Sweeping operations in your Machining program.
Select the Multi-Axis Sweeping icon, then select the geometry to be machined . More
information can be found in Selecting Geometry.
A number of strategy parameters are available for defining:
● machining criteria
● radial conditions
● tool axis guidance
● cutter compensation.
Specify the tool to be used , feeds and speeds , and NC macros as needed.
The Stepover tab has been renamed into Radial tab.
Multi-Axis Sweeping: Strategy Parameters
Multi-Axis Sweeping: Machining Parameters
Tool path style
Indicates the cutting mode of the operation:
● Zig Zag: the machining direction is reversed from one path to the next
● One way: the same machining direction is used from one path to the next.
Machining toleranceSpecifies the maximum allowed distance between the theoretical and computed tool path. Consider it to be the acceptable chord error.Maximum discretization stepEnsures linearity between points that are far apart. Maximum discretization angleSpecifies the maximum angular change of tool axis between tool positions. It is used to add more tool positions (points and axis) if value is exceeded. Minimum path lengthSpecifies the minimum length of path to be taken into account. The Maximum discretization step and Maximum discretization angle influence the number of points on the tool path.
The values should be chosen carefully if you want to avoid having a high concentration of points along the tool trajectory.
These parameters also apply to macro paths that are defined in machining feedrate. They do not apply to macro paths that do not have machining feedrate (RAPID, Approach, Retract, User, and so on).
Default value for Maximum discretization step is 100 m. Default value for Maximum discretization angle is 180 degrees.
Multi-Axis Sweeping: Radial Parameters
Radial strategy
Defines how the distance between two consecutive paths is to be computed.
Scallop height:
The associated parameter is Scallop height that specifies the maximum scallop height between two consecutive tool paths in a radial strategy.
Distance on part:
The associated parameter is Distance between paths that defines the maximum distance between two consecutive tool paths in a radial strategy.
Distance on plane:
The associated parameter is Distance between paths that defines the maximum distance between two consecutive tool paths in a radial strategy.
Number of paths:
The associated parameter is Number of paths that defines the number of tool paths in a radial strategy. Stepover sideSpecifies the side of the guiding plane that will be used to determine the overall machining direction.
Multi-Axis Sweeping: Tool Axis Parameters(Only Tool Axis Parameters tabs containing parameters have been captured)
You can define several axes with this icon:
● V, for the view direction,
● S, for the start direction,
● A, for the tool axis direction.
The view and the start directions define the machining guiding plane: machining is done in planes parallel to the guiding plane.
The tool axis definition depends on the Tool axis mode. The tool axis arrow turns white when its definition box is not available (e.g. when the tool axis is defined through a point or a line, ...).
A click on one of the direction arrows displays its definition box.
● View direction:
● Start direction:
● Tool axis direction:
Tool axis mode
Specifies how the tool axis is to be guided.
Below you will find the explanations of the various modes, then the explanations of the associated parameters.
Lead and Tilt
In this mode the tool axis is normal to the part surface with respect to a given lead angle (alpha) in the forward tool motion and with respect to a given tilt angle (beta) in the perpendicular direction to this forward motion.
There are several guidance modes as follows:
Fixed lead and tilt: Here both the lead and tilt angles are constant.
Variable lead and fixed tilt: Here the tool axis can vary from the specified lead angle within an allowed range, the tilt angle remaining constant. The allowed range is defined by Minimum and Maximum lead angles.
Fixed lead and variable tilt: Here the tool axis can vary from the specified tilt angle within an allowed range, the lead angle remaining constant. The allowed range is defined by an Allowed tilt (the tool axis can move within a range of +/ - Allowed tilt angle).
The purpose of the variable modes is to avoid collisions between the part to machine and the tool.
Fixed Axis
The tool axis remains constant for the operation.
Thru a Point
The tool axis passes through a specified point. The tool axis can be oriented To the point or From the point.
Click the point in the sensitive icon and select a point in the graphic area. Then decide whether the tool axis is defined from that point or to that point by clicking of the toggle From/To in the sensitive icon.
Normal to Line
The tool axis passes through a specified curve, and is normal to this curve at all points. The tool axis can be oriented To the line or From the line.
Click the point in the sensitive icon and select a line in the graphic area. Then decide whether the tool axis is defined from that line or to that line by clicking of the toggle From/To in the sensitive icon.
Optimized Lead
The tool axis is allowed to vary from the specified lead angle within an allowed range. The allowed range is defined by Minimum and Maximum lead angles. The back of the cutter is to be kept clear of the part by means of a Minimum heel distance.
Optimized lead works as follows:
● lead defined as minimum to fit the part curvature
● lead increases if necessary to respect the Minimum heel distance.
If the required lead is outside the allowed range, the tool position will not be kept in the tool path.
The maximum material removal is obtained when the tool curvature along the trajectory matches the part curvature.
4-axis Lead/Lag
The tool axis is normal to the part surface with respect to a given lead angle in the forward direction and constrained to a specified plane.
Click the 4-Axis Constraint arrow (N in the 3D window or the arrow normal to the plane in the sensitive icon) and set this direction in the dialog box that appears. This is the normal to the plane in which the tool axis is constrained.
The tool axis is computed like in Lead and Tilt mode and then projected into the constraint plane.
Lead angleSpecifies a user-defined incline of the tool axis in a plane defined by the direction of motion and the normal to the part surface. The lead angle is with respect to the part surface normal.
Maximum lead angleSpecifies a maximum lead angle.
Minimum lead angleSpecifies a minimum lead angle.
Tilt angleSpecifies a user-defined incline of the tool axis in a plane normal to the direction of motion. The tilt angle is with respect to the part surface normal.
Allowed tiltSpecifies the range of allowed tilt variation.
Minimum heel distanceAllows the back of the cutter to be kept clear of the part (for example, when machining a smooth concave ruled part in Optimized Lead).
Multi-Axis Sweeping: Cutter Compensation Parameters
(Double-click the part operation and push the Machine icon to open the Machine Editor)
In the Machine Editor, the Compensation tab contains options for:
● globally defining the 3D contact cutter compensation mode: None/Contact/Tip and Contact
● imposing the compensation mode to all operations supporting the selected mode whatever the choice defined at machining operation level.
If the options are set as follows, compensation can be managed at machining operation level.
In this case a Compensation tab appears in the Strategy page of the machining operation editor, and the following options are available.
Output typeAllows you to manage the generation of Cutter compensation (CUTCOM) instructions in the NC data output:
The following options are proposed:
● 3D Contact (G29/CAT3Dxx)
● None.
3D Contact (G29/CAT3Dxx)
The tool contact point will be visualized during tool path replay. Cutter compensation instructions are automatically generated in the NC data output. An approach macro must be defined to allow the compensation to be applied.Example of generated APT source:
$$ Start generation of : Multi-Axis Sweeping.1FEDRAT/ 1000.0000,MMPMSPINDL/ 70.0000,RPM,CLWCUTCOM/NORMPS$$ START CUTCOM NORMPS XC, YC, ZC, XN, YN, ZN, I, J, K.../...CUTCOM/OFF$$ END CUTCOM NORMPS XC, YC, ZC, XN, YN, ZN, I, J, K$$ End of generation of : Multi-Axis Sweeping.1
None
Cutter compensation instructions are not automatically generated in the NC data output. However, CUTCOM instructions can be inserted manually. For more information, please refer to How to generate CUTCOM syntaxes provided in the Prismatic Machining User's Guide.
Multi-Axis Sweeping: Geometry
You can specify the following Geometry:
● Part with possible Offset on Part.
● Check elements with possible Offset on Check.
● Areas to avoid.
● Limiting Contour.
You can use Offset Groups and Features when defining geometry.
In R13, the behavior of offset group has changed and is now similar to that of 3 Axis Surface Machining.
Collision Checking is also available.
Multi-Axis Sweeping: Tools
Recommended tools for Multi-Axis Sweeping are End Mills, Face Mills, Conical Mills and T-Slotters.
In general, you should choose:
● a ball-end tool for Fixed lead and variable tilt tool axis guidance
● a filleted-end tool for Variable lead and fixed tilt tool axis guidance.
Multi-Axis Sweeping: Feeds and Speeds
In the Feeds and Speeds tab page, feedrates for approach, retract and machining as well as a machining spindle speed.
Feedrates and spindle speed can be defined in linear or angular units.
A Spindle output checkbox is available for managing output of the SPINDL instruction in the generated NC data file. If the checkbox is selected, the instruction is generated. Otherwise, it is not generated.
Feeds and speeds of the operation can be updated automatically according to tooling data and the Rough or Finish quality of the operation. This is described in Update of Feeds and Speeds on Machining Operation.
Multi-Axis Sweeping: NC Macros
You can define transition paths in your machining operations by means of NC Macros. These transition paths are useful for providing approach, retract, return, and linking motion in the tool path.
An Approach macro is used to approach the operation start point.
A Retract macro is used to retract from the operation end point.
A Linking macro may be to link two non consecutive paths, for example. It comprises an approach and a retract path.
A Return in a Level macro is used in a multi-path operation to link two consecutive paths in a given level. It comprises an approach and a retract path.
A Clearance macro can be used in a machining operation to avoid a fixture, for example.
Multi-Axis Isoparametric Machining
The information in this section will help you create and edit Multi-Axis Isoparametric Machining operations in your Machining program.
Click the Multi-Axis Isoparametric Machining icon, then select the geometry to be machined .
A number of strategy parameters are available for defining:
● machining criteria
● radial conditions
● tool axis guidance
● cutter compensation.
Specify the tool to be used , feeds and speeds , and NC macros as needed.
Multi-Axis Isoparametric Machining: Strategy Parameters
Multi-Axis Isoparametric Machining: Machining Parameters
Tool path styleIndicates the cutting mode of the operation:
● Zig Zag: the machining direction is reversed from one path to the next
● One way: the same machining direction is used from one path to the next.
Machining toleranceSpecifies the maximum allowed distance between the theoretical and computed tool path. Consider it to be the acceptable chord error.Maximum discretization stepEnsures linearity between points that are far apart. Maximum discretization angleSpecifies the maximum angular change of tool axis between tool positions. It is used to add more tool positions (points and axis) if value is exceeded.
The Maximum discretization step and Maximum discretization angle influence the number of points on the tool path.
The values should be chosen carefully if you want to avoid having a high concentration of points along the tool trajectory.
These parameters also apply to macro paths that are defined in machining feedrate. They do not apply to macro paths that do not have machining feedrate (RAPID, Approach, Retract, User, and so on).
Default value for Maximum discretization step is 100 m. Default value for Maximum discretization angle is 180 degrees.
Multi-Axis Isoparametric Machining: Radial Parameters
Stepover
Defines how the distance between two consecutive paths is to be computed.
You can choose to define it by
● Scallop height,
The associated parameter is Scallop height that specifies the maximum scallop height between two consecutive tool paths in a radial strategy.
● Distance on part,
The associated parameter is Distance between paths that defines the maximum distance between two consecutive tool paths in a radial strategy.
● or the Number of paths
The associated parameter is Number of paths that defines the number of tool paths in a radial strategy.
In Zig zag mode, the tool path generated always starts from point 1 to point 2 and finishes from point 3 to point 4. For this purpose, an additional path may be added on top of the radial strategy criterion.
In One way mode, all paths are oriented from point 1 to point 2. For this purpose, the tool path may finish on point 3 or point 4.
Those rules also applies when Skip path or Start extension/End extension are active.
Skip path
You may also choose to skip (not machine) the first or last path or both of the tool path in all three of the radial strategies.
Start extension
Specifies the length of an additional machined area located before the first path on part. This value can be either positive (the global machined area is extended) or negative (the global machined area is shrunk).
End extension
Specifies the length of an additional machined area located after the last path on part. This value can be either positive (the global machined area is extended) or negative (the global machined area is shrunk).
Example : Case 1 : Tool path generated with the Radial strategy set to Number of paths=5.
Case 2 : the same with Skip path set on First and last.
Multi-Axis Isoparametric Machining: Tool Axis Parameters
Tool axis guidance
Specifies how the tool axis is to be guided.
Below you will find the explanations of the various Guidance types, then the explanations of the associated parameters.
(Only Tool Axis Parameters tabs containing parameters have been captured)
Lead and Tilt
In this mode the tool axis is normal to the part surface with respect to a given lead angle (alpha) in the forward tool motion
and with respect to a given tilt angle (beta) in the perpendicular direction to this forward motion.
There are several types of lead and tilt modes as follows:
● Fixed lead and tilt: Here both the lead and tilt angles are constant.
● Variable lead and fixed tilt: Here the tool axis is allowed to move from the specified lead angle within a specified range, the tilt angle remaining constant.
● Fixed lead and variable tilt: Here the tool axis is allowed to move from the specified tilt angle within a specified range, the lead angle remaining constant.
Fixed Axis
The tool axis remains constant for the operation.
Interpolation
The tool axis is interpolated between two selected axes. Enter the Allowed tilt value.
Thru a Point
The tool axis passes through a specified point.
The tool axis can be oriented To the point or From the point.
Normal to Line
The tool axis passes through a specified curve, and is normal to this curve at all points. The tool axis can be oriented To or
From the line.
Optimized Lead
The tool axis is allowed to vary from the specified lead angle within an allowed range. The allowed range is defined by Minimum and Maximum lead angles. The back of the cutter is to be kept clear of the part by means of a Minimum heel distance.
Optimized lead works as follows:
● lead defined as minimum to fit the part curvature
● lead increases if necessary to respect the Minimum heel distance.
If the required lead is outside the allowed range, the tool position will not be kept in the tool path.
The maximum material removal is obtained when the tool curvature along the trajectory matches the part curvature.
4-axis Lead/Lag
The tool axis is normal to the part surface with respect to a given lead angle in the forward direction and is constrained to a specified plane.
The tool axis is computed like in Lead and Tilt mode and then projected into the constraint plane.
4-axis Tilt
The tool axis is normal to the part surface with respect to a given tilt angle and is constrained to a specified plane.
This is dedicated to milling parts with tool axis nearly parallel to the part itself (near flank milling).
This axis strategy is primary dedicated to NC machine whose configuration is A+C, but can be used on any other multi-axis machine. The figure below shows a machine with A and C axis on the table.
When A=C=0.00, the normal to the table is equal to the spindle orientation of the machine (which is fixed and equal to Z, there is no rotary axis on the head).
On such a configuration, 4-axis Tilt strategy can be used to achieve a tool path in which the value of the A machine axis will be constant. Tool axis variation is provided by the C machine axis variation.
You are able to define the 4-axis constraint direction (that is, the direction in which tool axis component will be constant). In the figure below, the highlight of the table shows that this direction has been defined by the normal to the table.
The Tilt angle is set to 45.00 degrees.
Lead angleSpecifies a user-defined incline of the tool axis in a plane defined by the direction of motion and the normal to the part surface. The lead angle is with respect to the part surface normal.
Maximum lead angleSpecifies a maximum lead angle.
Minimum lead angleSpecifies a minimum lead angle. Tilt angleSpecifies a user-defined incline of the tool axis in a plane normal to the direction of motion. The tilt angle is with respect to the part surface normal. Allowed tiltSpecifies the range of allowed tilt variation. Minimum heel distanceAllows the back of the cutter to be kept clear of the part (for example, when machining a smooth concave ruled part with Optimized Lead tool axis guidance).
Multi-Axis Isoparametric Machining: Cutter Compensation Parameters
(Double-click the part operation and push the Machine icon to open the Machine Editor)
In the Machine Editor, the Compensation tab contains options for:
● globally defining the 3D contact cutter compensation mode: None/Contact/Tip and Contact
● imposing the compensation mode to all operations supporting the selected mode whatever the choice defined at machining operation level.
If the options are set as follows, compensation can be managed at machining operation level.
In this case a Compensation tab appears in the Strategy page of the machining operation editor, and the following options are available.
Output typeAllows you to manage the generation of Cutter compensation (CUTCOM) instructions in the NC data output:
The following options are proposed:
● 3D Contact (G29/CAT3Dxx)
● None.
3D Contact (G29/CAT3Dxx)
The tool contact point will be visualized during tool path replay. Cutter compensation instructions are automatically generated in the NC data output. An approach macro must be defined to allow the compensation to be applied.Example of generated APT source:
$$ Start generation of : Multi-Axis Isoparametric.1FEDRAT/ 1000.0000,MMPMSPINDL/ 70.0000,RPM,CLWCUTCOM/NORMPS$$ START CUTCOM NORMPS XC, YC, ZC, XN, YN, ZN, I, J, K.../...CUTCOM/OFF$$ END CUTCOM NORMPS XC, YC, ZC, XN, YN, ZN, I, J, K$$ End of generation of : Multi-Axis Isoparametric.1
None
Cutter compensation instructions are not automatically generated in the NC data output. However, CUTCOM instructions can be inserted manually. For more information, please refer to How to generate CUTCOM syntaxes provided in the Prismatic Machining User's Guide.
Multi-Axis Isoparametric Machining: Geometry
You can specify the following Geometry:
● Part elements (faces or belts of faces) with possible Offset on Part. Faces and belts of faces can be adjacent or non-adjacent.
● Check elements with possible Offset on Check.
● Up to four Corner points for each face or belt of faces.
Non-Adjacent Belts of Faces
The following selection of part elements can be machined in a single Isoparametric Machining operation.
● Parts 1.1 and 1.2 make up a belt of adjacent faces.
● Part 2.1 is a non-adjacent face.
● Part 3.1 is a non-adjacent face (for example, an IGES design part).
● Parts 4.1 and 4.2 make up a belt of adjacent faces.
In this case corners must be selected for each face and belt of face. Also an orientation (side to mill) must be defined for each face and belt of faces.
Collision Checking is also available.
Multi-Axis Isoparametric Machining: Tools
Recommended tools for Multi-Axis Isoparametric Machining are End Mills, Face Mills, Conical Mills and T-Slotters.
Multi-Axis Isoparametric Machining: Feeds and Speeds
In the Feeds and Speeds tab page, you can specify feedrates for approach, retract and machining as well as a machining spindle speed.
Feedrates and spindle speed can be defined in linear or angular units.
A Spindle output checkbox is available for managing output the SPINDL instruction in the generated NC data file. If the checkbox is selected, the instruction is generated. Otherwise, it is not generated.
Feeds and speeds of the operation can be updated automatically according to tooling data and the Rough or Finish quality of the operation. This is described in Update of Feeds and Speeds on Machining Operation.
Multi-Axis Isoparametric Machining: NC Macros
You can define transition paths in your machining operations by means of NC Macros. These transition paths are useful for providing approach, retract, return, and linking motion in the tool path.
An Approach macro is used to approach the operation start point.
A Retract macro is used to retract from the operation end point.
A Linking macro may be to link two non consecutive paths, for example. It comprises an approach and a retract path.
A Return in a Level macro is used in a multi-path operation to link two consecutive paths in a given level. It comprises an approach and a retract path.
A Clearance macro can be used in a machining operation to avoid a fixture, for example.
Multi-Axis Contour Driven
The information in this section will help you create and manage Multi-Axis Contour Driven operations in your Machining program.
To create a Multi-Axis Contour Driven operation, select the icon and select the geometry to be
machined . More information can be found in Selecting Geometry.
Select the machining strategy tab and choose a guiding strategy for this operation:
● Between contours where the tool sweeps between guide contours,
● Parallel contours where the tool sweeps out an area by following contours parallel to a reference contour,
● Spine contour where the tool sweeps across a contour in perpendicular planes.
Depending on the chosen strategy, select the necessary guiding elements.
Then set the following strategy parameters according to the desired machining:
● machining criteria
● radial conditions
● tool axis guidance
● cutter compensation.
Specify the tool to be used, feeds and speeds , and NC macros as needed.
Multi-Axis Contour Driven: Strategy Parameters
Multi-Axis Contour Driven: Machining Parameters
Tool path styleIndicates the cutting mode of the operation:
● Zig Zag: the machining direction is reversed from one path to the next
● One way: the same machining direction is used from one path to the next.
Machining toleranceSpecifies the maximum allowed distance between the theoretical and computed tool path.
Maximum discretization stepEnsures linearity between points that are far apart.
Maximum discretization angleSpecifies the maximum angular change of tool axis between tool positions. It is used to add more tool positions (points and axis) if value is exceeded.
Minimum path lengthSpecifies the minimum length that a path needs to have to be taken into account.
The Maximum discretization step and Maximum discretization angle influence the number of points on the tool path.
The values should be chosen carefully if you want to avoid having a high concentration of points along the tool trajectory.
These parameters also apply to macro paths that are defined in machining feedrate. They do not apply to macro paths that do not have machining feedrate (RAPID, Approach, Retract, User, and so on).
Default value for Maximum discretization step is 100 m. Default value for Maximum discretization angle is 180 degrees.
Multi-Axis Contour Driven: Strategy Parameters
Those parameters are available only when the guiding strategy is Parallel contour.
Offset on contour
Distance the tool will be from the guide contour at the beginning of the operation
Maximum width to machineSpecifies the width to machine starting from the guide contour in the stepover direction.
Stepover sideDefines the side of the contour where machining will be performed (left or right), i.e. if you choose Left, the tool will machine on the left side of the guide contour for the Maximum width distance,
Direction
● From contour: machining starts from the guide contour (in red in the figure below) over an area defined by the maximum width to machine.
● To contour: machining is done up to the guide contour (in red in the figure below) over an area defined by the maximum width to machine.
The limit of the area to machine is indicated in yellow in the figures above.
Multi-Axis Contour Driven: Radial Parameters
Radial strategy mode
Defines how the distance between two consecutive paths is to be computed.
Scallop height:
The associated parameter is Scallop height that specifies the maximum scallop height between two consecutive tool paths in a radial strategy.
Distance on part:
The associated parameter is Distance between paths that defines the maximum distance between two consecutive tool paths in a radial strategy.
Distance on plane:
The associated parameter is Distance between paths that defines the maximum distance between two consecutive tool paths in a radial strategy.
Number of paths:
The associated parameter is Number of paths that defines the number of tool paths in a radial strategy.
The following offsets and positional modifiers allow you to extend or reduce the area to machine in the Between Contours guiding strategy without needing to create additional geometry.
Offset on guide 1Specifies an offset on the first guide contour in Between Contours guiding strategy.
Offset on guide 2Specifies an offset on the second guide contour in Between Contours guiding strategy.
Position on guide 1Specifies the position of the tool with respect to the first guide contour: Inside, Outside or On.
Position on guide 2Specifies the position of the tool with respect to the second guide contour: Inside, Outside or On.
Multi-Axis Contour Driven: Tool Axis ParametersTool axis mode
Below you will find the explanations of the various Guidance types and tool axis modes, then the explanations of the associated parameters.
(Only Tool Axis Parameters tabs containing parameters have been captured)
Lead and Tilt
In this mode the tool axis is normal to the part surface with respect to a given lead angle in the forward tool motion and with respect to a given tilt angle in the perpendicular direction to this forward motion.
GuidanceSpecifies how the tool axis is to be guided.
There are several types of lead and tilt modes as follows:
● Fixed lead and tilt: Here both the lead and tilt angles are constant.
● Variable lead and fixed tilt: Here the tool axis is allowed to move from the specified lead angle within a specified range, the tilt angle remaining constant.
● Fixed lead and variable tilt: Here the tool axis is allowed to move from the specified tilt angle within a specified range, the lead angle remaining constant.
The purpose of the variable modes is to avoid collisions between the part to machine and the tool.
Fixed Axis
The tool axis remains constant for the operation.
Thru a Point
The tool axis passes through a specified point. The tool axis can be oriented to point To or From the point.
Normal to Line
The tool axis passes through a specified curve, and is normal to this curve at all points. The tool axis can be oriented to point To or From the line.
Optimized Lead
he tool axis is allowed to vary from the specified lead angle within an allowed range. The allowed range is defined by Minimum and Maximum lead angles. The back of the cutter is to be kept clear of the part by means of a Minimum heel distance.
Optimized lead works as follows:
● lead defined as minimum to fit the part curvature
● lead increases if necessary to respect the Minimum heel distance.
If the required lead is outside the allowed range, the tool position will not be kept in the tool path.
The maximum material removal is obtained when the tool curvature along the trajectory matches the part curvature.
4-axis Lead/Lag
The tool axis is normal to the part surface with respect to a given lead angle in the forward direction and is constrained to a specified plane.
The tool axis is computed like in Lead and Tilt mode and then projected into the constraint plane.
Lead angleSpecifies a user-defined incline of the tool axis in a plane defined by the direction of motion and the normal to the part surface. The lead angle is with respect to the part surface normal.
Maximum lead angleSpecifies a maximum lead angle.
Minimum lead angleSpecifies a minimum lead angle. Tilt angleSpecifies a user-defined incline of the tool axis in a plane normal to the direction of motion. The tilt angle is with respect to the part surface normal.
Allowed tiltSpecifies the range of allowed tilt variation. Minimum heel distanceAllows the back of the cutter to be kept clear of the part (for example, when machining a smooth concave ruled part with Optimized Lead tool axis guidance).
Multi-Axis Contour Driven: Cutter Compensation Parameters
(Double-click the part operation and push the Machine icon to open the Machine Editor)
In the Machine Editor, the Compensation tab contains options for:
● globally defining the 3D contact cutter compensation mode: None/Contact/Tip and Contact
● imposing the compensation mode to all operations supporting the selected mode whatever the choice defined at machining operation level.
If the options are set as follows, compensation can be managed at machining operation level.
In this case a Compensation tab appears in the Strategy page of the machining operation editor, and the
following options are available.
Output typeAllows you to manage the generation of Cutter compensation (CUTCOM) instructions in the NC data output:
The following options are proposed:
● 3D Contact (G29/CAT3Dxx)
● None.
3D Contact (G29/CAT3Dxx)
The tool contact point will be visualized during tool path replay. Cutter compensation instructions are automatically generated in the NC data output. An approach macro must be defined to allow the compensation to be applied.Example of generated APT source:
$$ Start generation of : Multi-Axis Contour Driven.1FEDRAT/ 1000.0000,MMPMSPINDL/ 70.0000,RPM,CLWCUTCOM/NORMPS$$ START CUTCOM NORMPS XC, YC, ZC, XN, YN, ZN, I, J, K.../...CUTCOM/OFF$$ END CUTCOM NORMPS XC, YC, ZC, XN, YN, ZN, I, J, K$$ End of generation of : Multi-Axis Contour Driven.1
None
Cutter compensation instructions are not automatically generated in the NC data output. However, CUTCOM instructions can be inserted manually. For more information, please refer to How to generate CUTCOM syntaxes provided in the Prismatic Machining User's Guide.
Multi-Axis Contour Driven: Geometry
You can specify the following Geometry:
● Part with possible Offset on Part.❍ For Between Contours strategy, the area to machine on the selected part is determined by
selecting two guide curves and two limit curves. Tool paths are parallel to the selected guide curves.
❍ For Parallel Contours strategy, the area to machine on the selected part is determined by selecting a guide curve specifying a maximum width to machine. Tool paths are parallel to the spine curve.
❍ For Spine Contour strategy, the area to machine on the selected part is determined by selecting a spine curve. Tool paths are perpendicular to the spine curve.
● Check elements with possible Offset on Check.
● Areas to avoid.
● Limiting Contour, which defines the limit for machining on the part.
You can use Offset Groups and Features when defining geometry.
In R13, the behavior of offset group has changed and is now similar to that of 3 Axis Surface Machining.
Collision Checking is also available.
Multi-Axis Contour Driven: Tools
Recommended tools for Multi-Axis Contour Driven are End Mills, Face Mills, Conical Mills and T-Slotters.
Multi-Axis Contour Driven: Feeds and Speeds
In the Feeds and Speeds tab page, you can specify feedrates for approach, retract and machining as well as a machining spindle speed.
Feedrates and spindle speed can be defined in linear or angular units.
A Spindle output checkbox is available for managing output the SPINDL instruction in the generated NC data file. If the checkbox is selected, the instruction is generated. Otherwise, it is not generated.
Feeds and speeds of the operation can be updated automatically according to tooling data and the Rough or Finish quality of the operation. This is described in Update of Feeds and Speeds on Machining Operation.
Multi-Axis Contour Driven: NC Macros
You can define transition paths in your machining operations by means of NC Macros. These transition paths are useful for providing approach, retract, return, and linking motion in the tool path.
An Approach macro is used to approach the operation start point.
A Retract macro is used to retract from the operation end point.
A Linking macro may be to link two non consecutive paths, for example. It comprises an approach and a retract path.
A Return in a Level macro is used in a multi-path operation to link two consecutive paths in a given level. It comprises an approach and a retract path.
A Clearance macro can be used in a machining operation to avoid a fixture, for example.
Multi-Axis Curve Machining
The information in this section will help you create and edit Multi-Axis Curve Machining operations in your Machining program.
Select the icon then choose the desired Machining mode:
● Contact
● Between 2 curves with Tip or Side machining
● Between a curve and part with Tip or Side machining.
Select the geometry to be machined.
A number of strategy parameters are available for defining:
● machining criteria
● radial conditions
● axial conditions
● finishing
● tool axis guidance
● cutter compensation (in Contact machining mode only).
Specify the tool to be used , feeds and speeds , and NC macros as needed.
● The Stepover tab has been split into Radial and Axial tabs
● Tool path style has been moved from the Stepover tab to the Machining tab
● Sequencing has been moved from the Stepover tab to the Machining tab and enhanced
Multi-Axis Curve Machining: Strategy Parameters
Multi-Axis Curve Machining: Machining Parameters
Tool path styleIndicates the cutting mode of the operation:
● Zig Zag: the machining direction is reversed from one path to the next
● One way: the same machining direction is used from one path to the next.
Machining toleranceSpecifies the maximum allowed distance between the theoretical and computed tool path. Direction of cutSpecifies how milling is to be done:
● Climb milling: the front of the advancing tool (in the machining direction) cuts into the material first
● Conventional milling: the rear of the advancing tool (in the machining direction) cuts into the material first
This parameter can be used to reverse the machining direction.Sequencing
Specifies in which order the machining is to be done:
Radial first (by segment): the order is axial machining first, then the radial machining, and all the levels of the current couple of relimitation points are machined before the going to the next couple of relimitation points.
Axial first (by segment): the order is radial machining first, then the axial machining, and all the levels of the current couple of relimitation points are machined before the going to the next couple of relimitation points.
Radial first (by level): the order is axial machining first, then the radial machining, and all the machining is done level by level.
Axial first (by level): the order is radial machining first, then the axial machining, and all the machining is done level by level.
Maximum discretization stepEnsures linearity between points that are far apart. Maximum discretization angleSpecifies the maximum angular change of tool axis between tool positions. It is used to add more tool positions (points and axis) if value is exceeded. The Maximum discretization step and Maximum discretization angle influence the number of points on the tool path.
The values should be chosen carefully if you want to avoid having a high concentration of points along the tool trajectory.
These parameters also apply to macro paths that are defined in machining feedrate. They do not apply to macro paths that do not have machining feedrate (RAPID, Approach, Retract, User, and so on).
Default value for Maximum discretization step is 100 m. Default value for Maximum discretization angle is 180 degrees.
Type of contouringIndicates whether the contouring type of corners is:
● Circular: the tool pivots around the corner point, following a contour whose radius is equal to the tool radius
● Angular: the tool does not remain in contact with the corner point, following a contour comprised of two line segments
● Optimized: the tool follows a contour derived from the corner that is continuous in tangent
● Forced circular: the tool follows a near-circular contour comprised of line segments.
Forced contourSpecifies whether the contour is to be forced open or closed. Closed contour overlapSpecifies the percentage of overlap on the closed contour.
Multi-Axis Curve Machining: Radial Parameters
Distance between pathsDefines the maximum distance between two consecutive tool paths in a radial strategy. Number of pathsDefines the number of tool paths in a radial strategy.
Multi-Axis Curve Machining: Axial Parameters
Maximum cut depth
This parameter is used in Contact or in Between 2 curves modes when no auxiliary curve has been defined.Defines the maximum depth of cut in an axial strategy. Number of levelsDefines the number of levels to be machined in an axial strategy.
Multi-Axis Curve Machining: Finishing Parameters
Finishing mode
Indicates whether or not finish passes are to be generated on the sides and bottom of the area to machine. Side finishing can be done at each level or only at the last level of the operation. Side finish thicknessSpecifies the thickness used for side finishing. Side finish thickness on bottomSpecifies the thickness used for the last side finish pass at the end of the operation. Bottom finish thicknessSpecifies the thickness used for bottom finishing. Bottom finish path styleDefines the bottom finish path style: Zig zag or One way. Spring passIndicates whether or not a spring pass is to be generated on the sides in the same condition as the previous Side finish pass. The spring pass is used to compensate the natural `spring' of the tool.
Multi-Axis Curve Machining: Tool Axis ParametersTool axis guidance
Specifies how the tool axis is to be guided.
Below you will find the explanations of the various Guidance types and tool axis modes, then the explanations of the associated parameters.
(Only Tool Axis Parameters tabs containing parameters have been captured)
Lead and Tilt
For Contact machining, the tool axis is normal to the part surface with respect to a given lead angle in the forward tool motion and with respect to a given tilt angle in the perpendicular direction to this forward motion.
For Tip and Side machining, the tool axis is normal to the guides with respect to a given lead angle in the forward tool motion and with respect to a given tilt angle in the perpendicular direction to this forward motion.
There are several types of lead and tilt modes as follows:
● Fixed lead and tilt: Here both the lead and tilt angles are constant.
● Variable lead and fixed tilt: Here the tool axis is allowed to move from the specified lead angle within a specified range, the tilt angle remaining constant.
● Fixed lead and variable tilt: Here the tool axis is allowed to move from the specified tilt angle within a specified range, the lead angle remaining constant.
The purpose of the variable modes is to avoid collisions between the part to machine and the tool.
Fixed Axis
The tool axis remains constant for the operation.
Interpolation
The tool axis is interpolated between two selected axes.
Thru a Point
The tool axis passes through a specified point. The tool axis can be oriented to point To or From the point.
Normal to Line
The tool axis passes through a specified curve, and is normal to this curve at all points. The tool axis can be oriented to point To or From the line.
4-Axis Lead/Lag
The tool axis is normal to the part surface with respect to a given lead angle in the forward direction and constrained to a specified plane.
The tool axis is computed like in Lead and Tilt mode and then projected into the constraint plane.
Optimized Lead
For Contact machining only. The tool axis is allowed to vary from the specified lead angle within an allowed range. The allowed range is defined by Minimum and Maximum lead angles. The back of the cutter is to be kept clear of the part by means of a Minimum heel distance.
Optimized lead works as follows:
● lead defined as minimum to fit the part curvature
● lead increases if necessary to respect the Minimum heel distance.
If the required lead is outside the allowed range, the tool position will not be kept in the tool path.
The maximum material removal is obtained when the tool curvature along the trajectory matches the part curvature.
Tangent Axis
Tangent axis guidance is available for Between 2 Curves and Between curve and part machining modes only. Note that a cylindrical tool should be used.
The Tangent axis modes are as follows:
● Along ruling directionDedicated to milling walls made of a set (strip) of ruled and developable surfaces (possibly with some planar ones), by mapping the tool axis to the ruling direction of the drive surfaces. Maximum material removal is obtained when ruling direction on drive surface matches the ruling direction on tool.
● Along isoparametric linesRecommended when the drive surfaces are ruled (even if not developable), ruling directions are the isoparametric lines of the surfaces. The tool axis is mapped to the isoparametric lines (the one which is least parallel to the drive curve). This is done even if the surface is planar, or it is not developable.
When machining a strip (or band) of drive surfaces, the best matching u or v isoparametric line of the first machined face is deduced from the reference tool axis. For the next machined face, the program analyzes the zone near the adjacent faces, and chooses the isoparametric line that assures best continuity of the trajectory. Machining continues in this way in the order of the faces in the strip.If several drives surfaces are selected they must be in a continuous strip or band (that is, one after the other). This behavior is available for operations created as from Release 12.
When two consecutive drive surfaces do not have parallel isoparametric lines, this creates an unwanted tool axis variation.
To avoid this, you can define a Fanning distance that will be applied before and after the seam of the two drive surfaces. Within this fanning distance, the tool will remain tangent to the drive contour and the tool axis will be interpolated :
In some cases, when fanning is applied to two areas that are very close to each other, those two areas are merged into a single area.
● Normal to drive curveRecommended when the isoparametric lines of the drive surfaces are not compatible with the NC machine travel limits. This may lead to collision with the machine head or loops in the tool path. In these cases, the user wants the tool axis to be tangent to the drive surface, and normal to the drive curve.
For Along isoparametric lines and Normal to drive curve Tangent Axis guidance, because the tool axis is not always the ruling direction of a developable surface, some undercuts or overcuts may occur. In this case, the maximum and minimum deviations to the drive surfaces are displayed at the end of the computation.
Lead angleSpecifies a user-defined incline of the tool axis in a plane defined by the direction of motion and the normal to the part surface. The lead angle is with respect to the part surface normal.
Maximum lead angleSpecifies a maximum lead angle.
Minimum lead angleSpecifies a minimum lead angle. Allowed leadSpecifies the range of allowed lead variation (available when the tool axis is guided in Tangent Axis along a ruling direction). Tilt angleSpecifies a user-defined incline of the tool axis in a plane normal to the direction of motion. The tilt angle is with respect to the part surface normal. Allowed tiltSpecifies the range of allowed tilt variation. Minimum heel distanceAllows the back of the cutter to be kept clear of the part (for example, when machining a smooth concave ruled part with Optimized Lead tool axis guidance). Fanning distanceSpecifies a distance over which tool fanning takes place (available when the tool axis is guided in Tangent Axis along a ruling direction).
Multi-Axis Curve Machining: Cutter Compensation Parameters
(Double-click the part operation and push the Machine icon to open the Machine Editor)
The following concerns the Curve Machining in Contact mode only.
In the Machine Editor, the Compensation tab contains options for:
● globally defining the 3D contact cutter compensation mode: None/Contact/Tip & Contact
● imposing the compensation mode to all operations supporting the selected mode whatever the choice defined at machining operation level.
If the options are set as follows, compensation can be managed at machining operation level.
In this case a Compensation tab appears in the Strategy page of the machining operation editor, and the following options are available.
Output typeAllows you to manage the generation of Cutter compensation (CUTCOM) instructions in the NC data output:
The following options are proposed:
● 3D Contact (G29/CAT3Dxx)
● None.
3D Contact (G29/CAT3Dxx)
The tool contact point will be visualized during tool path replay. Cutter compensation instructions are automatically generated in the NC data output. An approach macro must be defined to allow the compensation to be applied.Example of generated APT source:
$$ Start generation of : Multi-Axis Curve Machining.1FEDRAT/ 1000.0000,MMPMSPINDL/ 70.0000,RPM,CLWCUTCOM/NORMPS
$$ START CUTCOM NORMPS XC, YC, ZC, XN, YN, ZN, I, J, K.../...CUTCOM/OFF$$ END CUTCOM NORMPS XC, YC, ZC, XN, YN, ZN, I, J, K$$ End of generation of : Multi-Axis Curve Machining .1
None
Cutter compensation instructions are not automatically generated in the NC data output. However, CUTCOM instructions can be inserted manually. For more information, please refer to How to generate CUTCOM syntaxes provided in the Prismatic Machining User's Guide.
Multi-Axis Curve Machining: Geometry
A Multi-Axis Curve Machining operation can be created in one of the following Machining modes.
Contact
Tool follows the trajectory defined by the projection of the guiding contour on the part surface while respecting user-defined geometry limitations and machining strategy parameters.
You can specify the following Geometry:
● Part surface with possible Offset on Part.
● Guiding contour (edges or sketch) with possible Offset on Contour:
● An axial offset.
● A Start point and End point with possible Offsets.
● Fixture or check elements with possible Offset on Check.
Between 2 curves
Tool follows a trajectory defined by the Guide contour and Auxiliary Guide contour while respecting user-defined geometry limitations and machining strategy parameters.
You can specify the following Geometry:
● Guide contour and Auxiliary Guide contour (edges or sketch) with possible global radial Offset on Contour and an Axial Offset on each contour.
● Start point and End point with possible Offsets
● Fixture or check elements with possible Offset on Check.
Guide contour is used for positioning the flank of the tool (radial positioning).
Auxiliary Guide contour is used for positioning the tool tip along the tool axis (axial positioning).
If no Auxiliary Guide contour is specified, the Guide contour is used for positioning both the flank and the tip of the tool.
Between a Curve and Surfaces
Tool follows trajectory defined by a top guide curve and bottom surfaces while respecting user-defined geometry limitations and machining strategy parameters.
You can specify the following Geometry:
● Part with possible Offset on Part.
● Guiding contour (edges or sketch) with possible Offset on Contour:
● A Start point and End point with possible Offsets.
● Fixture or check elements with possible Offset on Check.
● Axial Offset.
The three Curve Machining Modes accept discontinuous contours as guides.
Those contours can be selected using the Edge Selection Toolbar. A Guide.x element is displayed for each continuous ordered contour.
The side to mill is shown by the orange arrow. Click on the arrow to inverse this side to mill.
The selection order determines the machining sequence of the different contours.
The linking macro is used to link two discontinuous tool path of the same radial path. Otherwise, a straight line is generated.
Once the selection of the guides is validated (i.e. when the dialog box is displayed again), the following contextual menus become available:
On a guide in the graphic area:
On a guide in the dialog box icon:
Remove Element
Removes the selected element from the Guide.
You can also remove an element by picking it again, after having launched the Edge Selection Toolbar. If the guide is no longer continuous, an other guide is created.
Before After
You can add elements to a guide by simply picking the element, after having launched the Edge Selection Toolbar. If the element picked is connected to that guide, it is automatically added to that guide. If the element picked is connected to two guides, the element is added and the two guides are merged into one.
Remove Guide x
Removes the selected guide.
Before After
Remove All Guides
Removes all guides
Before After
Connect Guide.x
Connects a guide to another one. Select the original guide, then the item Connect Guide.x in the contextual menu and the target guide.
Before After
The connection is done either by inserting a line or extrapolating a contour.
Connect All Guides
Connects all guides into one.
Before After
Collision Checking is also available.
Multi-Axis Curve Machining: Tools
Recommended tools for Multi-Axis Curve Machining are End Mills, Face Mills, Conical Mills and T-Slotters.
Multi-Axis Curve Machining: Feeds and Speeds
In the Feeds and Speeds tab page, you can specify feedrates for approach, retract, machining and finishing as well as a machining spindle speed.
Feedrates and spindle speed can be defined in linear or angular units.
A Spindle output checkbox is available for managing output the SPINDL instruction in the generated NC data file. If the checkbox is selected, the instruction is generated. Otherwise, it is not generated.
Feeds and speeds of the operation can be updated automatically according to tooling data and the Rough or Finish quality of the operation. This is described in Update of Feeds and Speeds on Machining Operation.
Feedrate Reduction in Corners
You can reduce feedrates in corners encountered along the tool path depending on values given in the Feeds and Speeds tab page: reduction rate, maximum radius, minimum angle, and distances before and after the corner.
Feed reduction is applied to corners along the tool path whose radius is less than the Maximum radius value and whose arc angle is greater than the Minimum angle value. Corners can be angled or rounded.
For Multi-Axis Curve Machining, feedrate reduction applies to inside corners for machining or finishing passes. It does not apply for macros or default linking and return motions.
If a cornering is defined with a radius of 5mm and the Feedrate reduction in corners set to a lower radius value, the feedrate will not be reduced.
Multi-Axis Curve Machining: NC Macros
You can define transition paths in your machining operations by means of NC Macros. These transition paths are useful for providing approach, retract, return, and linking motion in the tool path.
An Approach macro is used to approach the operation start point.
A Retract macro is used to retract from the operation end point.
A Linking macro may be used in several cases, for example:
● to link two non consecutive paths
● to access finish and spring passes.
A Return in a Level macro is used in a multi-path operation to link two consecutive paths in a given level. It comprises an approach and a retract path.
A Return between Levels macro is used in a multi-level machining operation to go to the next level. It comprises an approach and a retract path.
A Return to Finish Pass macro is used in a machining operation to go to the finish pass. It comprises an approach and a retract
path.
A Clearance macro can be used in a machining operation to avoid a fixture, for example.
Collision CheckingThis section shows how collision checking is managed in Multi-Axis Curve Machining, Sweeping, Contour Driven and Isoparametric Machining. The Collision Checking parameters are accessed in the Geometry tab page of the operation's dialog box. You will find below information on:
● Collisions with Part Elements for all Multi-Axis operations,
● Collisions with Check Elements for all Multi-Axis operations,
● Collisions with Drive Elements for Multi-Axis Curve Machining only,
● Checking for Collisions between Tool and Guide Elements during Macro Motions, for Multi-Axis Curve Machining only
Collision checking can be performed on check and part elements with the tool assembly (that is, the complete shape of the cutter plus its holder) or the cutting part of the tool (red part of following tools):
To save computation time you should use tool assembly only if the geometry to be checked can interfere with the upper part of the cutter.
Collisions with Part Elements
To activate collision checking on part elements, you must select the Active checkbox.
Part accuracy
Defines the maximum error to be accepted with respect to the part with its offset. This parameter is set to the
machining tolerance value. It can be only be changed by modifying the machining tolerance.
Allowed gouging
Defines the maximum cutter interference with the part during "linking passes" (including approach and retract motion).
Collision checking with part elements is useful in the following cases:
● Concave part machined with Fixed tool axis mode.
● Concave and non smooth part milled with 0 degree Lead angle. Note that Allowed gouging must be set to a non zero value, otherwise a "Nothing to Mill" message may be issued.
Collision checking on part elements is not useful in the following cases:
● Convex part machined with ball, flat or filleted ended tool or with Fixed or Variable tool axis mode.
● Concave part milled with 0 degree Lead angle. A "Nothing to Mill" message may be issued.
Ruled and smooth part with Optimized Lead tool axis mode. Minimum heel distance will keep the back of the cutter clear.
Collisions with Check Elements
For Multi-axis Sweeping, Contour Driven, Isoparametric Machining:
For Multi-axis Curve Machining:
The parameters involved for check elements (such as fixtures) are described below:
Check (or Fixture) accuracy
Defines the maximum error to be accepted with respect to the fixture with its offset. Setting this parameter to a correct value avoids spending too much computation time to achieve unnecessary precision.
Offset on check
Defines theminimum distance between the cutter and the fixture, used to limit the tool path.
Allowed gouging
Defines themaximum cutter interference with the fixture during "linking passes" (including approach and retract motion).
The illustrationbelow shows return motion with no macro or jump.
The illustrationbelowshows return motion with macro between path and fixture.
Covering mode
Available for Multi-axis Sweeping, Contour Driven, Isoparametric Machining:
Select this option to optimize air cuts due to collision with the check.
In the example below, a Return in Level macro has been defined.
The Covering mode is not selected:
The Covering mode is selected, the air cut is reduced:
● You can apply a positive or negative offset on the check,
● The Covering mode applies to the tool path (in green), not to the macro motions (in red),
● The Covering mode applies to the whole set of check surfaces defined in the machining operation
Collisions withDriveElements
To activate collision checking onDrive elements, you must select the Active checkbox.
Drive Accuracy
Defines the maximum error to be accepted with respect to the drive with itsthickness.
Allowed gouging
Defines the maximum cutter interference with the driveduring "linking passes" (including approach and retract motion).
Checking for Collisions between Tool and Guide Elements during Macro Motions
For Multi-Axis Curve Machining.
By default, the macro tool paths are not checked for collisions with guiding elements.
If you select Active, all macro tool paths of the operation will be checked for collision with guiding elements.
MethodologyMethodology and conceptual information on the following topics is provided in the Machining Infrastructure User's Guide.
Machining ProcessesKnowledgeware in Machining Processes
CATProduct and CATProcess Document ManagementDesign Changes and Associativity Mechanisms
Part Operation and Set Up DocumentsOpposite Hand Machining
User Features for Machining
Methodology and conceptual information on the following topics is provided in the Prismatic Machining User's Guide.
How to Generate CUTCOM SyntaxesSelect Hole Design Features for Machining
Use Tolerances on Design Features for Machining.
Glossary
A
approach macro Motion defined for approaching the operation start pointauxiliary 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.
Between Contours mode Machining mode of a Contour Driven operation in which the tool follows a Zig zag or One way trajectory between two user defined curves.
bottom plane A planar geometric element that represents the bottom surface of an area to machine. It is normal to the tool axis.
C
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 in 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
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.
G
gouge Area where the tool has removed too much material from the workpiece.guiding plane In sweeping operations, this plane is deduced from the view and starting
directions. Machining is done in planes parallel to the guiding plane. The tool contact point is guided by this plane during machining.
H
hard A geometric element (such as a boundary or a bottom face) that the tool cannot pass beyond.
L
lead angle User-defined incline of the tool axis in a plane defined by the direction of motion and the normal to the part surface. The tool axis incline is with respect to the part surface normal. Compare with tilt angle.
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 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 The set of machining features defined in the part operation.Multi-axis Contour Driven A milling operation in which the tool is driven along a contour while respecting
user-defined geometric limitations and machining strategy parameters. Three machining modes are Parallel Contours, Between Contours and Spine Contour. A number of tool axis guidance modes are available.
Multi-axis Curve MachiningA milling operation in which the tool's side, tip or contact point is driven along a curve while respecting user-defined geometric limitations and machining strategy parameters. A number of tool axis guidance modes are available.
Multi-axis Sweeping A milling operation in which the tool path is executed in parallel planes while respecting user-defined geometric limitations and machining strategy parameters. A number of tool axis guidance modes are available.
multi-level operation Milling operation (such as Pocketing or Profile Contouring) that is done in a series of axial cuts.
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). Compare with thickness.
one way Machining in which motion is always done in the same direction. Compare with zig zag or back and forth.
P
Parallel Contours mode Machining mode of a Contour Driven operation in which the tool follows a Zig zag or One way trajectory that is offset from a user-defined guide curve.
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.
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.
R
retract macro Motion defined for retracting from the operation end pointreturn 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).Spine Contour mode Machining mode of a Contour Driven operation in which the tool follows a Zig zag
or One way trajectory that is perpendicular to a user-defined spine curve.start direction Specifies the direction in which machining will start.stock Workpiece prior to machining by the operations of a part operation.
T
thickness Specifies a thickness of material to be removed by machining. Compare with offset.
tilt angle User-defined incline of the tool axis in a plane normal to the direction of motion. The tool axis incline is with respect to the part surface normal.Compare with lead angle.
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.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.
V
View direction Specifies the direction from which the part is viewed for relimiting and machining.
Z
zig zag Machining in which motion is done alternately in one direction then the other. Compare with one way.
Index
Numerics4-Axis Constraint arrow (N) 4-Axis Lead/Lag
Multi-Axis Contour Driven tool axis guidance
Multi-Axis Curve Machining tool axis guidance
Multi-Axis Isoparametric Machining tool axis guidance
Multi-Axis Sweeping tool axis guidance 4-Axis Tilt
Multi-Axis Isoparametric Machining tool axis guidance
AAllowed gouging, check
Allowed gouging, part Allowed lead
Multi-Axis Curve Machining parameter Allowed tilt
Multi-Axis Contour Driven parameter
Multi-Axis Curve Machining parameter
Multi-Axis Isoparametric Machining parameter
Multi-Axis Sweeping parameter Along isoparametric lines
Multi-Axis Curve Machining parameter Along ruling direction
Multi-Axis Curve Machining parameter
APT import
APT source generation
auxiliary command Auxiliary operation
COPY Operator
Copy Transformation
Machine Rotation
Machining Axis Change
PP Instruction
Tool Change
TRACUT Operator
axial machining operation Axial Parameters
Multi-Axis Curve Machining
Bback and forth Between 2 curves
Multi-Axis Curve Machining
Multi-Axis Curve Machining mode Between a Curve and Surfaces
Multi-Axis Curve Machining Between Contours
Multi-Axis Contour Driven guiding strategy Between curve and part
Multi-Axis Curve Machining mode Bottom finish path style
Multi-Axis Curve Machining parameter Bottom finish thickness
Multi-Axis Curve Machining parameter
CCGR file generation
Clfile code generation
climb milling Closed contour overlap
Multi-Axis Curve Machining parameter
Collision checking on check elements
Collision checking on part elements command
Isoparametric Machining
Multi-Axis Contour Driven
Multi-Axis Curve Machining
Multi-Axis Sweeping Contact
Multi-Axis Curve Machining mode
conventional milling
COPY Operator
Copy Transformation Instruction Covering mode
Isoparametric Machining Cutter Compensation Parameters
Multi-Axis Contour Driven
Multi-Axis Curve Machining
Multi-Axis Isoparametric Machining
Multi-Axis Sweeping
DDirection of cut
Multi-Axis Curve Machining parameter
Distance before corner (feed reduction) Distance between paths
Multi-Axis Contour Driven parameter
Multi-Axis Curve Machining parameter
Multi-Axis Sweeping parameter
Documentation generation
EEnd extension
Multi-Axis Isoparametric Machining
FFanning distance
Multi-Axis Curve Machining
Multi-Axis Curve Machining parameter
Fault Feedrate reduction in corners
Multi-Axis Curve Machining parameter Feeds and Speeds
Multi-Axis Contour Driven
Multi-Axis Curve Machining
Multi-Axis Isoparametric Machining Finishing mode
Multi-Axis Curve Machining parameter Finishing Parameters
Multi-Axis Curve Machining Fixed
Multi-Axis Contour Driven tool axis guidance
Multi-Axis Curve Machining tool axis guidance
Multi-Axis Isoparametric Machining tool axis guidance
Multi-Axis Sweeping tool axis guidance Fixed lead and tilt
Multi-Axis Contour Driven tool axis guidance
Multi-Axis Curve Machining tool axis guidance
Multi-Axis Isoparametric Machining tool axis guidance
Multi-Axis Sweeping tool axis guidance Fixed lead and variable tilt
Multi-Axis Contour Driven tool axis guidance
Multi-Axis Curve Machining tool axis guidance
Multi-Axis Isoparametric Machining tool axis guidance
Fixture accuracy Forced contour
Multi-Axis Curve Machining parameter
GGeometry
Multi-Axis Contour Driven
Multi-Axis Curve Machining
Multi-Axis Isoparametric Machining
gouge
guiding plane
Hhard geometric element
IInterpolation
Multi-Axis Curve Machining tool axis guidance
Multi-Axis Isoparametric Machining tool axis guidance Isoparametric Machining
Covering mode
Isoparametric Machining command
LLead and Tilt
Multi-Axis Contour Driven tool axis guidance
Multi-Axis Curve Machining tool axis guidance
Multi-Axis Isoparametric Machining tool axis guidance
Multi-Axis Sweeping tool axis guidance
Lead angle
Multi-Axis Contour Driven parameter
Multi-Axis Curve Machining parameter
Multi-Axis Isoparametric Machining parameter
Multi-Axis Sweeping parameter
MMachine Rotation
Machining Axis Change
machining axis system
machining feature
machining operation Machining Parameters
Multi-Axis Contour Driven
Multi-Axis Curve Machining
Multi-Axis Isoparametric Machining
Multi-Axis Sweeping
Machining Process, Apply
Machining Process, Create Machining tolerance
Multi-Axis Contour Driven parameter
Multi-Axis Curve Machining parameter
Multi-Axis Isoparametric Machining parameter
Multi-Axis Sweeping parameter
machining tolerance
Manufacturing Process
Manufacturing Program
Manufacturing View Maximum depth of cut
Multi-Axis Curve Machining parameter Maximum discretization angle
Multi-Axis Contour Driven parameter
Multi-Axis Curve Machining parameter
Multi-Axis Isoparametric Machining parameter
Multi-Axis Sweeping parameter Maximum discretization step
Multi-Axis Contour Driven parameter
Multi-Axis Curve Machining parameter
Multi-Axis Isoparametric Machining parameter
Multi-Axis Sweeping parameter Maximum lead angle
Multi-Axis Contour Driven parameter
Multi-Axis Curve Machining parameter
Multi-Axis Isoparametric Machining parameter
Multi-Axis Sweeping parameter
Maximum radius (feed reduction) Maximum width to machine
Multi-Axis Contour Driven parameter
Minimum angle (feed reduction) Minimum heel distance
Multi-Axis Contour Driven parameter
Multi-Axis Curve Machining parameter
Multi-Axis Isoparametric Machining parameter
Multi-Axis Sweeping parameter
Minimum heel distance, collision check Minimum lead angle
Multi-Axis Contour Driven parameter
Multi-Axis Curve Machining parameter
Multi-Axis Isoparametric Machining parameter
Multi-Axis Sweeping parameter Minimum path length
Multi-Axis Contour Driven parameter
Multi-Axis Sweeping parameter
Multi-Axis Contour Driven
Cutter Compensation Parameters
Feeds and Speeds
Geometry
Machining Parameters
NC Macros
Radial Parameters
Strategy Parameters
Tool Axis Parameters
Tools
Multi-Axis Contour Driven command Multi-Axis Contour Driven guiding strategy
Between Contours
Parallel Contours
Spine Contour
Multi-Axis Contour Driven operation Multi-Axis Contour Driven parameter
Allowed tilt
Distance between paths
Lead angle
Machining tolerance
Maximum discretization angle
Maximum discretization step
Maximum lead angle
Maximum width to machine
Minimum heel distance
Minimum lead angle
Minimum path length
Number of paths
Output type
Radial strategy mode
Scallop height
Stepover direction
Stepover side
Tilt angle
Tool axis guidance
Tool path style Multi-Axis Contour Driven tool axis guidance
4-Axis Lead/Lag
Fixed
Fixed lead and tilt
Fixed lead and variable tilt
Lead and Tilt
Normal to Line
Optimized Lead
Thru a Point
Variable lead and fixed tilt Multi-Axis Contour-driven
Offset on contour
Multi-Axis Curve Machining
Axial Parameters
Between 2 curves
Between a Curve and Surfaces
Cutter Compensation Parameters
Fanning distance
Feeds and Speeds
Finishing Parameters
Geometry
Machining Parameters
NC Macros
Radial Parameters
Sequencing
Tool Axis Parameters
Tools
Multi-Axis Curve Machining command Multi-Axis Curve Machining mode
Between 2 curves
Between curve and part
Contact
Multi-Axis Curve Machining operation Multi-Axis Curve Machining parameter
Allowed lead
Allowed tilt
Along isoparametric lines
Along ruling direction
Bottom finish path style
Bottom finish thickness
Closed contour overlap
Direction of cut
Distance between paths
Fanning distance
Feedrate reduction in corners
Finishing mode
Forced contour
Lead angle
Machining tolerance
Maximum depth of cut
Maximum discretization angle
Maximum discretization step
Maximum lead angle
Minimum heel distance
Minimum lead angle
Normal to drive curve
Number of levels
Number of paths
Output type
Side finish thickness
Side finish thickness on bottom
Spring pass
Tilt angle
Tool axis guidance
Tool path style
Type of contouring Multi-Axis Curve Machining tool axis guidance
4-Axis Lead/Lag
Fixed
Fixed lead and tilt
Fixed lead and variable tilt
Interpolation
Lead and Tilt
Normal to Line
Optimized Lead
Tangent Axis
Thru a Point
Variable lead and fixed tilt
Multi-Axis Isoparametric Machining
Cutter Compensation Parameters
End extension
Feeds and Speeds
Geometry
Machining Parameters
NC Macros
Radial Parameters
Skip path
Start extension
Stepover
Tool Axis Parameters
Tools
Multi-Axis Isoparametric Machining operation Multi-Axis Isoparametric Machining parameter
Allowed tilt
Lead angle
Machining tolerance
Maximum discretization angle
Maximum discretization step
Maximum lead angle
Minimum heel distance
Minimum lead angle
Output type
Tilt angle
Tool axis guidance
Tool path style Multi-Axis Isoparametric Machining tool axis guidance
4-Axis Lead/Lag
4-Axis Tilt
Fixed
Fixed lead and tilt
Fixed lead and variable tilt
Interpolation
Lead and Tilt
Normal to Line
Optimized Lead
Thru a Point
Variable lead and fixed tilt
Multi-Axis Sweeping
Cutter Compensation Parameters
Machining Parameters
Radial Parameters
Radial strategy
Tool Axis Parameters
Multi-Axis Sweeping command
Multi-Axis Sweeping operation Multi-Axis Sweeping parameter
Allowed tilt
Distance between paths
Lead angle
Machining tolerance
Maximum discretization angle
Maximum discretization step
Maximum lead angle
Minimum heel distance
Minimum lead angle
Minimum path length
Number of paths
Output type
Radial strategy mode
Scallop height
Stepover side
Tilt angle
Tool axis guidance
Tool path style Multi-Axis Sweeping tool axis guidance
4-Axis Lead/Lag
Fixed
Fixed lead and tilt
Lead and Tilt
Normal to Line
Optimized Lead
Thru a Point
N
NC code generation NC Macros
Multi-Axis Contour Driven
Multi-Axis Curve Machining
Multi-Axis Isoparametric Machining Normal to drive curve
Multi-Axis Curve Machining parameter Normal to Line
Multi-Axis Contour Driven tool axis guidance
Multi-Axis Curve Machining tool axis guidance
Multi-Axis Isoparametric Machining tool axis guidance
Multi-Axis Sweeping tool axis guidance Number of levels
Multi-Axis Curve Machining parameter Number of paths
Multi-Axis Contour Driven parameter
Multi-Axis Curve Machining parameter
Multi-Axis Sweeping parameter
Ooffset
Offset on check Offset on contour
Multi-Axis Contour-driven
one way Optimized Lead
Multi-Axis Contour Driven tool axis guidance
Multi-Axis Curve Machining tool axis guidance
Multi-Axis Isoparametric Machining tool axis guidance
Multi-Axis Sweeping tool axis guidance Output type
Multi-Axis Contour Driven parameter
Multi-Axis Curve Machining parameter
Multi-Axis Isoparametric Machining parameter
Multi-Axis Sweeping parameter
Overall Machining Direction arrow (M)
PParallel Contours
Multi-Axis Contour Driven guiding strategy
Part Operation
PP Instruction
PPR
Process List
Product List
RRadial Parameters
Multi-Axis Contour Driven
Multi-Axis Curve Machining
Multi-Axis Isoparametric Machining
Multi-Axis Sweeping Radial strategy
Multi-Axis Sweeping Radial strategy mode
Multi-Axis Contour Driven parameter
Multi-Axis Sweeping parameter
Reduction rate (feed reduction)
Resources List
SScallop height
Multi-Axis Contour Driven parameter
Multi-Axis Sweeping parameter Sequencing
Multi-Axis Curve Machining Side finish thickness
Multi-Axis Curve Machining parameter Side finish thickness on bottom
Multi-Axis Curve Machining parameter
Simulate material removal Skip path
Multi-Axis Isoparametric Machining
soft geometric element Spine Contour
Multi-Axis Contour Driven guiding strategy Spring pass
Multi-Axis Curve Machining parameter
start direction
Start Direction arrow (S) Start extension
Multi-Axis Isoparametric Machining Stepover
Multi-Axis Isoparametric Machining Stepover direction
Multi-Axis Contour Driven parameter Stepover side
Multi-Axis Contour Driven parameter
Multi-Axis Sweeping parameter Strategy Parameters
Multi-Axis Contour Driven
TTangent Axis
Multi-Axis Curve Machining tool axis guidance
thickness
Thru a Point
Multi-Axis Contour Driven tool axis guidance
Multi-Axis Curve Machining tool axis guidance
Multi-Axis Isoparametric Machining tool axis guidance
Multi-Axis Sweeping tool axis guidance
Tilt angle
Multi-Axis Contour Driven parameter
Multi-Axis Curve Machining parameter
Multi-Axis Isoparametric Machining parameter
Multi-Axis Sweeping parameter
Tool Axis arrow (A) Tool axis guidance
Multi-Axis Contour Driven parameter
Multi-Axis Curve Machining parameter
Multi-Axis Isoparametric Machining parameter
Multi-Axis Sweeping parameter Tool Axis Parameters
Multi-Axis Contour Driven
Multi-Axis Curve Machining
Multi-Axis Isoparametric Machining
Multi-Axis Sweeping
Tool Change
tool clash
Tool path replay Tool path style
Multi-Axis Contour Driven parameter
Multi-Axis Curve Machining parameter
Multi-Axis Isoparametric Machining parameter
Multi-Axis Sweeping parameter Tools
Multi-Axis Contour Driven
Multi-Axis Curve Machining
Multi-Axis Isoparametric Machining Tools Options - Machining
General
Operation
Output
Photo/Video
Program
Resources
TRACUT Operator Type of contouring
Multi-Axis Curve Machining parameter
Uundercut
VVariable lead and fixed tilt
Multi-Axis Contour Driven tool axis guidance
Multi-Axis Curve Machining tool axis guidance
Multi-Axis Isoparametric Machining tool axis guidance
view direction
View Direction arrow (V)
Zzig zag
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