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Computer implementation of damage models by finite element and meshfree methods. (English) Zbl 0980.74063

From the summary: We propose a computational methodology of a micromechanic cell model to establish the constitutive law during material fracture. As an application, we investigate the ductile fracture process and obtain a new model parameter function for damage based on a computational cell modeling technique. Aspects of computer implementation for finite element and meshfree methods are described. The technique is applied to numerical examples including necking behavior of a tensile bar, a cracked panel under tension, an edge notched panel under pure bending a plane strain plate under compression, and the ductile tearing with large deformation of a notch-bend specimen. We also study applications of reproducing kernel particle method to the ductile fracture process involving damage evolution, and perform a multiresolution analysis on shear bands. The analytical and numerical results confirm the efficiency of proposed methodology.

MSC:

74S05 Finite element methods applied to problems in solid mechanics
74S30 Other numerical methods in solid mechanics (MSC2010)
74R20 Anelastic fracture and damage
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