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Simulation of Dynamic 3D Crack Propagation within the Material Point Method

This paper presents the principles and algorithms for simulation of dynamic crack propagation in elastic bodies by the material point method (MPM), from relatively simple two-dimensional cases to full three-dimensional, mixed-mode crack propagation. The paper is intended to give a summary of the lat...

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Published in:Computer modeling in engineering & sciences 2017-01, Vol.113 (4), p.389-410
Main Authors: Guo, Y.J., Nairn, J.A.
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Language:English
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description This paper presents the principles and algorithms for simulation of dynamic crack propagation in elastic bodies by the material point method (MPM), from relatively simple two-dimensional cases to full three-dimensional, mixed-mode crack propagation. The paper is intended to give a summary of the latest achievements on simulation of three-dimensional dynamic crack propagation, which is essentially an unexplored area. Application of the methodology presented in this paper to several dynamic crack propagation problems has shown that the MPM is a reliable and powerful approach for simulating three-dimensional, mixed-mode crack propagation.
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subjects Algorithms
Computer simulation
Crack Propagation
Dynamic Fracture
Elastic bodies
Goal programming
Material Point Method (mpm)
Mixed-Mode Fracture
Propagation
Propagation modes
Simulation
Three-Dimensional Cracks
title Simulation of Dynamic 3D Crack Propagation within the Material Point Method
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