Shape gradients for the failure probability of a mechanical component under cyclical loading
For engineers designing mechanical components for fatigue life, this work enables efficient gradient-based optimization of reliability, addressing a previously non-differentiable problem.
This work proposes and validates a numerical method for computing shape gradients of failure probabilities for mechanical components under cyclical loading, using a first-discretize-then-adjoint approach. The method is demonstrated on examples from a bended rod to a complex 3D turbo charger geometry.
This work provides a numerical calculation of shape gradients of failure probabilities for mechanical components using a first discretize, then adjoint approach. While deterministic life prediction models for failure mechanisms are not (shape) differentiable, this changes in the case of probabilistic life prediction. The probabilistic, or reliability based, approach thus opens the way for efficient adjoint methods in the design for mechanical integrity. In this work we propose, implement and validate a method for the numerical calculation of the shape gradients of failure probabilities for the failure mechanism low cycle fatigue (LCF), which applies to polycrystalline metal. Numerical examples range from a bended rod to a complex geometry from a turbo charger in 3D.