An acceleration scheme for the phase field fatigue fracture simulation with a concurrent temporal homogenization method.

The phase field approach for fracture has been adapted for fatigue fracture in recent years. In this work, we propose an efficient acceleration scheme for this approach based on concurrent time-scale homogenization. In this scheme, the fatigue fracture problem is decomposed into a macrochronological problem and a microchronological problem, and is accelerated with the macrochronological time steps adaptively determined. The macrochronological time step is monitored during the whole simulation, and is corrected by a predictor–corrector strategy if necessary. Numerical examples demonstrate that this scheme is able to accelerate fatigue fracture simulations without sacrificing much accuracy, and can be up to 200 times faster than direct numerical simulations in some cases. For certain force-controlled examples, the proposed scheme, equipped with the arc-length control, is able to reproduce Paris' law with a correlation coefficient higher than 0.91 in the logarithmic scale. • An efficient scheme for fatigue fracture with the phase field approach is proposed based on a concurrent time homogenization method. • The macrochronological time step is adaptively determined. • A predictor–corrector strategy is developed to monitor the time step size. • This scheme effectively reduces the time cost with high accuracy. • The scheme is able to reproduce Paris' law with a correlation coefficient higher than 0.91. [ABSTRACT FROM AUTHOR]