Introductory Optimization - Jet-Engine-Bracket
- Anne Düchting (Unlicensed)
- Lennart Krüger (Unlicensed)
Goal of this tutorial
- Introduction to MSC Apex Generative Design 2019
Gain basic optimization knowledge
Training:
You can find all relevant data for this tutorial in the Example folder! ("C:\Program Files\MSC.Software\MSC Apex Generative Design\2019\Examples")
Step 1: Create a new project
In a first step, you need to create a new project. All data (geometry and configuration) will be copied and saved directly in a new project folder, located in your workspace:
- Start MSC Apex Generative Design 2019
- Create a new project using the symbol
- Enter a project name and save the project
- Open the newly created project
Step 2: Model generation
- Upload all relevant stl files by clicking on the symbol in the objects/surfaces area
- Select all stl files
- The field at the bottom shows notifications to help you generate an optimization model
- The uploaded objects are listed in the objects/surfaces area
- Assign a Material to each object/surface and enter the specific values for the Young's Modulus (115e3) and poisson ratio (0.33) in the Material Editor
- Activate the option design space for the relevant stl file. Only one volume can be selected as such.
- In this case: Jet_engine_bracket - design-1
Step 3: Definition of boundary conditions
Go to the boundary conditions tab to enter the loads and fixations. For each boundary condition a name, a space and the specification of the boundary condition is entered as follows:
| Name | Object | Direction | Value in N |
|---|---|---|---|
| Force1 | interface1 | x | 18904 |
| Force2 | interface2 | x | 18904 |
| Force3 | interface1 | y | 17792 |
| Force4 | interface2 | y | 17792 |
| Force5 | interface1 | x | 19483 |
| Force6 | interface2 | x | 19483 |
| Force7 | interface1 | x y | 15701 14137 |
| Force8 | interface2 | x y | 15701 14137 |
| Name | Object | Direction |
|---|---|---|
Fixation1 | interface3 | x, y, z (=0) |
| Fixation2 | interface4 | x, y, z (=0) |
| Fixation3 | interface5 | x, y, z (=0) |
| Fixation4 | interface6 | x, y, z (=0) |
- A total of 8 forces and 4 fixations should have been created as a result.
All boundary conditions must be assigned to the load cases. The number of load cases can be changed using the "+" or "-" characters. The assignment of the boundaries to the load cases can be made in the boundary conditions or load cases area by selecting the different boundary conditions while the load case is activated.
- Active in Loadcase1: Force1, Force2, Fixation1, Fixation2, Fixation3 and Fixation4
- Active in Loadcase2: Force3, Force4, Fixation1, Fixation2, Fixation3 and Fixation4
- Active in Loadcase3: Force5, Force6, Fixation1, Fixation2, Fixation3 and Fixation4
- Active in Loadcase4: Force7, Force8, Fixation1, Fixation2, Fixation3 and Fixation4
Step 4: Definition of optimization parameters
Switch to the optimization area. You can find more information about the parameter selection here.
- Choose the design type normal
- Enter the optimization goal stress: 600 MPa
- Open Result File Formats. The following result files should be activated:
- stl File: results of each iteration in stl file format
- stl Files Intersected: result of each iteration intersected with the design space in stl file format
- ply Files with Stress: results with the information of stresses of each iteration (must be activated to show the results in the Visualization space)
- ply Files with Displacement: results with the information of displacements of each iteration (must be activated to show the results in the Visualization space)
- More information on result file formats here
All Inputs can be viewed and checked in the configuration file. The file should look like this.
Please make sure only one .amendate file is in your project folder.
You will find the optimizations with design type filigree and massive in the example files and can try out these variations.
Step 5: Save the project
Step 6: Starting the optimization and visualizing the results
If all data are correct, the optimization can be started and tracked in the results area.
All result iterations are displayed as soon as they are available. The progress of the optimization can also be monitored via the AMendate log file. Furtheremore you are able to stop the optimization in this selection area. A restart however is not possible.
The optimization is finished after 64 iterations (optimizationtype: optimizing).
Step 7: Visualization of Stresses
The legend can be influenced using the slider. The function "Automatically set to local minimum and maximum" considers the stresses of each iteration and sets the values from the current iteration.
Step 8: Visualization of Displacements
The legend can be influenced using the slider. The function "Automatically set to local minimum and maximum" considers the displacements of each iteration and sets the values from the current iteration.
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