Highlights

Highlights

Our automated optimization processes respond flexibly to changing boundary conditions and extract the technically feasible maximum from every component.

Ein 3D-Modell von einem Bauteil eines Automobils
Ein 3D-Modell von einem Bauteil eines Automobils

Welded Consoles

Objective:
Reduction of stress concentrations at the console run-out before fatigue cracks can occur.


Method:

  • Fully automated shape finding

  • Sliding of the console across bended surfaces


Result:

  • Optimal console trajectory

  • Optimal console height

  • Optimal console thickness


All achieved in a single step and directly transferable to CAD.

Ein 3D-Modell von einem Bauteil eines Automobils

Classic casting- & plastic-parts

Objective:
Precise performance at minimal weight.


Method:

  • Fully automated shape finding of the rib structure


Result:

  • Optimal height distribution of the ribs

  • Optimal thickness distribution in the base plate and ribs


All in a single step and easy to transfer to CAD.

Ein 3D-Modell von einem Bauteil eines Automobils

Advanced casting- & plastic-parts

Objective:
Precise performance at minimal weight.


Method:

  • Fully automated shape and thickness optimization of the rib structure and the base surface


Result:

  • Optimal height distribution and shape of the ribs

  • Optimal shape of the base surface

  • Optimal thickness distribution in the base surface and ribs


The high-end level of component design. One click for an ideal, fully bionic design.

Ein 3D-Modell von einem Bauteil eines Automobils

Solid- & forged-parts

Objective:
Precise performance at minimal weight.


Method:

  • Fully automated shape finding of the entire geometry based on a primitive starting design

  • Consideration of complex manufacturing constraints and load cases


Result:

  • Optimal component shape


The high-end level of component design. One click to generate an ideal design.

Welded Consoles

Objective:
Reduction of stress concentrations at the console run-out before fatigue cracks can occur.


Method:

  • Fully automated shape finding

  • Sliding of the console across bended surfaces


Result:

  • Optimal console trajectory

  • Optimal console height

  • Optimal console thickness


All achieved in a single step and directly transferable to CAD.

Classic casting- & plastic-parts

Objective:
Precise performance at minimal weight.


Method:

  • Fully automated shape finding of the rib structure


Result:

  • Optimal height distribution of the ribs

  • Optimal thickness distribution in the base plate and ribs


All in a single step and easy to transfer to CAD.

Advanced casting- & plastic-parts

Objective:
Precise performance at minimal weight.


Method:

  • Fully automated shape and thickness optimization of the rib structure and the base surface


Result:

  • Optimal height distribution and shape of the ribs

  • Optimal shape of the base surface

  • Optimal thickness distribution in the base surface and ribs


The high-end level of component design. One click for an ideal, fully bionic design.

Solid- & forged-parts

Objective:
Precise performance at minimal weight.


Method:

  • Fully automated shape finding of the entire geometry based on a primitive starting design

  • Consideration of complex manufacturing constraints and load cases


Result:

  • Optimal component shape


The high-end level of component design. One click to generate an ideal design.

Welded Consoles

Objective:
Reduction of stress concentrations at the console run-out before fatigue cracks can occur.


Method:

  • Fully automated shape finding

  • Sliding of the console across bended surfaces


Result:

  • Optimal console trajectory

  • Optimal console height

  • Optimal console thickness


All achieved in a single step and directly transferable to CAD.

Classic casting- & plastic-parts

Objective:
Precise performance at minimal weight.


Method:

  • Fully automated shape finding of the rib structure


Result:

  • Optimal height distribution of the ribs

  • Optimal thickness distribution in the base plate and ribs


All in a single step and easy to transfer to CAD.

Advanced casting- & plastic-parts

Objective:
Precise performance at minimal weight.


Method:

  • Fully automated shape and thickness optimization of the rib structure and the base surface


Result:

  • Optimal height distribution and shape of the ribs

  • Optimal shape of the base surface

  • Optimal thickness distribution in the base surface and ribs


The high-end level of component design. One click for an ideal, fully bionic design.

Solid- & forged-parts

Objective:
Precise performance at minimal weight.


Method:

  • Fully automated shape finding of the entire geometry based on a primitive starting design

  • Consideration of complex manufacturing constraints and load cases


Result:

  • Optimal component shape


The high-end level of component design. One click to generate an ideal design.