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Goal of this tutorial

  • Use a manual model set-up to realize Casting Regions

  • Modify the optimisation input accoridingly

  • Run the optimisation in the command line

Training:

Relevant data for this tutorial:

https://amendate.atlassian.net/wiki/x/AQAE0

This Tutorial is based on the previous Tutorial for the Manufacturing Method: Casting. With some modifications it is possible to create Casting Regions. A Casting Region defines casting specific settings (e.g. draw direction / tapering angle) for separate regions of the Design Space.

Step 1: Open existing casting project

Open the already set up casting project of the Triple Clamp.

image-20240514-084030.png

Step 2: Define Casting Regions

To define Casting Regions additional volumes have to be defined an exported. In this case we want to create one Casting Region on the left-hand side and another on the right-hand side.

Therefore, a new Part is created in the model tree with a copy of the Design Space solid (Transform tool, movement with 0mm) and a surface to split the Design Space into several Casting Regions. The Split Tool is used to perform this action.

image-20240514-105051.png

Two solids are created which are renamed to Solid 1 & Solid 2:

image-20240514-105152.png

Step 3: Add Advanced User Settings - Casting Regions settings

The already defined settings for the previous casting optimisation are kept. These define the Casting optimisation as well as two draw directions with a tapering angle of 5°.

configuration.strategy=Casting

tool.tool0.draft=5
tool.tool0.direction.x=0
tool.tool0.direction.y=0
tool.tool0.direction.z=1

tool.tool1.draft=5
tool.tool1.direction.x=0
tool.tool1.direction.y=0
tool.tool1.direction.z=-1

image-20240514-085100.png

Additionally, the both casting regions are added and linked to the draw directions.

toolRegion.region0.geometryName= toolRegion0

toolRegion.region0.tools.tool0

toolRegion.region1.geometryName= toolRegion1

toolRegion.region1.tools.tool1

geometry.toolRegion0.path = Solid 1.stl

geometry.toolRegion1.path = Solid 2.stl

There is no limitation in the number of draw directions (tools) and Casting Regions (toolRegions). Several draw directions can be linked to one Casting Region.

Step 4: Export of the optimisation scenario & casting regions

The optimisation scenario is exported to a freely selectable folder.

image-20240514-105426.png

Into the same folder the created Casting Regions are exported as a .stl file. (Attention: The unit system has to be in meters!)

image-20240514-105533.png

Step 5: Command line optimisation start

Now, inside the exported folder the optimisation input (configuration file & geometry files) as well as the manual created Casting Regions can be found:

image-20240514-105719.png

A PowerShell or command line has to be opened in this folder. Inside the MSC Apex installation folder the runGD_Engine.bat has to be executed to start the optimisation. As an argument the name of the configuration file has to be added.

& 'C:\Program Files\MSC.Software\MSC Apex\2024-011290\runGD_Engine.bat' -c .\GD_Scenario_1.json
image-20240514-110014.png

After pressing enter the optimisation starts in the command line.

Step 6: Quick modification of the optimisation set-up

By opening the configuration file (.json) the optimisation parameters and the casting set-up can be modified easily.

In the tool section additional tools can be added and linked to the toolRegion. Each tool can be one draw direction with a specified tapering angle.

image-20240514-110306.png

Step 7: Post Processing & Visualisation of the results

The optimisation results are saved in an additional subfolder with a timestamp.

image-20240514-112544.png

These results can be imported back to MSC Apex GD.

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