On the analysis of crack‐closure behaviour using the phase‐field method together with the novel concept of Representative Crack Elements

Storm, Johannes; Supriatna, Dennie; Kaliske, Michael

doi:10.1002/pamm.201900314

Cited by 2 publications

(1 citation statement)

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“…for example [27,33,34,35,28,36,37,38]. In case of large deformation kinematics, similar approaches can be found [39,40,41,42,43]. In this contribution, the so-called tensile split [27,Section 3…”

Section: Diffuse Modeling Of Elastic Heterogeneitiesmentioning

confidence: 79%

Phase-field modeling of fracture in heterogeneous materials: jump conditions, convergence and crack propagation

2020

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In this contribution, a variational diffuse modeling framework for cracks in heterogeneous media is presented. A static order parameter smoothly bridges the discontinuity at material interfaces, while an evolving phase-field captures the regularized crack. The key novelty is the combination of a strain energy split with a partial rank-I relaxation in the vicinity of the diffuse interface. The former is necessary to account for physically meaningful crack kinematics like crack closure, the latter ensures the mechanical jump conditions throughout the diffuse region. The model is verified by a convergence study, where a circular bi-material disc with and without a crack is subjected to radial loads. For the uncracked case, analytical solutions are taken as reference. In a second step, the model is applied to crack propagation, where a meaningful influence on crack branching is observed, that underlines the necessity of a reasonable homogenization scheme. The presented model is particularly relevant for the combination of any variational strain energy split in the fracture phase-field model with a diffuse modeling approach for material heterogeneities.

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