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Training:

Relevant data for this tutorial:

View file
nameBookshelf_B01 - NonDesign_Bolt3-1.STL
View file
nameBookshelf_B01 - NonDesign_Bolt2-1.STL
View file
nameBookshelf_B01 - NonDesign_Bolt1-1.STL
View file
nameBookshelf_B01 - NonDesign_Plate-1.STL
View file
nameBookshelf_B01 - Design-1.STL

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:

...

  • 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

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  • Activate the option design space for the relevant stl file. Only one volume can be selected as such.

  • In this case: Eccentric Pedal - design-1

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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

hand_open

Eccentrichand1

y

200

hand_close

Eccentrichand1

Force

Pedalfootsurface1

y

-200

90_degree_bolt

Eccentricbolt1

x

-3000

45_degree_bolt

Eccentricbolt1

x

y

-3000

-3000

0_degree_bolt

Eccentricbolt1

y

-5000

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Name

Object

Direction

Fixation_0degree1

Eccentric0_degree11

x, y, z (=0)

Fixation_0degree2

Eccentric0_degree21

x, y, z (=0)

Fixation_45degree1

Eccentric45_degree11

x, y, z (=0)

Fixation_45degree2

Eccentric45_degree21

x, y, z (=0)

Fixation_90degree1

Eccentric90_degree11

x, y, z (=0)

Fixation_90degree2

Eccentric90_degree211000

  • Object "Pedalfootsurface1" experiences a force of -1000 N in y-direction (Force). The force of the whole pedal is -2000 N. If you are using the symmetry option, the force must be adjusted to the calculation model. If only half of the component is calculated (symmetry about the XY-Plane), the force must also be cut in half. The example already considers this restriction.

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Name

Object

Direction

Fixation

Pedalaxle1

x, y, z (=0)

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  • A total of 5 forces and 6 fixations 1 force and 1 fixation should have been created as a result

  • The object "Pedalfixation1" does not experience any force or fixation but it's necessary to connect the pedal with the axle. Therfore the form is considered in the optimization.

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: hand_close, 0_degree_bolt, Fixation_0degree1 Force and Fixation_0degree2

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  • Active in Loadcase2: hand_close, 45_degree_bolt, Fixation_45degree1 and Fixation_45degree2

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  • Active in Loadcase 3: hand_close, 90_degree_bolt, Fixation_90degree1 and Fixation_90degree2

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  • ctive in Loadcase4: hand_open, 0_degree_bolt, Fixation_0degree1 and Fixation_0degree2

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  • Active in Loadcase5: hand_open, 45_degree_bolt, Fixation_45degree1 and Fixation_45degree2

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  • Active in Loadcase 6: hand_open, 90_degree_bolt, Fixation_90degree1 and Fixation_90degree2

...

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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: 50 MPa

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  • 60 MPa

  • Set the symmetry setting: XY-Plane

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Open Result File Formats. The following result files should be activated:

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  • You can always change the design type, stress and solverMaxMemory to influence the results and try out different options. You can find further information here.

Step 5: Save the Project

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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.

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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.

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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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Step 9: Influence of different settings

  • By varying the settings the optimization results can be influenced

  • The solverMaxMemory can be increased for a higher resolution (increased calculation time!). You can find further information here.

  • The Design Type influences the strucures which are formed during optimization. You can find further information here.

  • You can generate all the designs below by adjusting these two values (depending on your workstation).

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