The Live Parts growth process consists of multiple stages: pre-target growth and post-target growth. During the pre-target growth phase, the initial Seed Cells grow and spawn new cells in the direction of their pre-defined end location, forming a stem. This stem encounters simulated simulated gravity forces in the Live Part environment. When these gravity forces cause the stem to experience strain and deform, Live Parts triggers additional cell growth in the free directions where there are no cells in order to strengthen the stem. Without gravity forces during the pre-target phase, the stem will grow long and thin due to lack of strain, and are prone to being killed off.
By default, the Live Parts for SOLIDWORKS Add-in has expression values for oscillating gravity waves in the X and Z directions and a constant negative (downward) value for gravity forces in the Y direction.
Adjusting Gravity Forces in SOLIDWORKS:
- Select Settings in the Live Parts for SOLIDWORKS Add-in Toolbar.
- Adjust the "Pre Target Gravity Forces" and/or the "Post Target Gravity Forces". You can input constant values or define these as expressions varying over time.
- Select Save.
Alternatively, you can also adjust the gravity forces dynamically during the Live Parts growth process by using the checking Gravity Override box and using the corresponding sliders in the Controls Toolbar while in Advanced Mode in Live Parts. For more information, please visit our Controls Toolbar: Advanced Mode article.
Notes on Gravity Forces:
- In Live Parts, it is generally good practice to have a strong and constant gravitational force in one direction and to define oscillating gravity waves in the other two directions.
- This simulates the way wind blows on tree branches, causing them to have resilience to unexpected forces.
- As an example: if you are growing a symmetrical wheel standing upright with the main axis in the Z direction, you should align the constant gravity force in the Z direction and oscillating gravity waves in the X and Y directions. This way the wheel would experience forces aligned with the symmetry of the part.