Simulation of crack propagation based on eigenerosion in brittle and ductile materials subject to finite strains

• Published in: Archive of applied mechanics (1991) Vol. 92; no. 4; pp. 1199 - 1221
• Main Authors: Wingender, Dennis, Balzani, Daniel
• Format: Journal Article
• Language: English
• Published: Berlin/Heidelberg Springer Berlin Heidelberg 01.04.2022; Springer Nature B.V
• Subjects: Classical Mechanics; Comparative studies; Crack propagation; Cyclic loads; Ductile fracture; Ductile-brittle transition; Edge dislocations; Engineering; Finite element method; Flux density; Heat treating; Original; Propagation; Regularization; Shear bands; Theoretical and Applied Mechanics; Elasto-plasticity; Cyclic loading; Ductile crack propagation; Finite strains; Eigenerosion
• ISSN: 0939-1533; 1432-0681
• DOI: 10.1007/s00419-021-02101-1

In this paper, a framework for the simulation of crack propagation in brittle and ductile materials is proposed. The framework is derived by extending the eigenerosion approach of Pandolfi and Ortiz (Int J Numer Methods Eng 92(8):694–714, 2012. https://doi.org/10.1002/nme.4352 ) to finite strains and by connecting it with a generalized energy-based, Griffith-type failure criterion for ductile fracture. To model the elasto-plastic response, a classical finite strain formulation is extended by viscous regularization to account for the shear band localization prior to fracture. The compression–tension asymmetry, which becomes particularly important during crack propagation under cyclic loading, is incorporated by splitting the strain energy density into a tensile and compression part. In a comparative study based on benchmark problems, it is shown that the unified approach is indeed able to represent brittle and ductile fracture at finite strains and to ensure converging, mesh-independent solutions. Furthermore, the proposed approach is analyzed for cyclic loading, and it is shown that classical Wöhler curves can be represented.