A two-scale time-dependent damage model based on non-planar growth of micro-cracks

A two-scale time-dependent damage model based on non-planar growth of micro-cracks

This paper presents the theoretical developments and the numerical applications of a time-dependent damage law. This law is deduced from considerations at the micro-scale where non-planar growth of micro-cracks, following a subcritical propagation criterion, is assumed. The orientation of the crack...

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Bibliographic Details
Published in:Journal of the mechanics and physics of solids Vol. 58; no. 11; pp. 1928 - 1946
Main Authors: François, Bertrand, Dascalu, Cristian
Format: Journal Article Web Resource
Language:English
Published: Elsevier Ltd 01-11-2010
Elsevier
Subjects:
Asymptotic properties
Civil engineering
Crack rotation
Cracks
Damage
Engineering, computing & technology
Homogenization
Homogenizing
Ingénierie civile
Ingénierie, informatique & technologie
Law
Mathematical models
Microcracks
Orientation
Sciences de l'ingénieur
Size effects
Subcritical propagation
Time-dependent damage
Homogenization
Size effects
Crack rotation
Subcritical propagation
Time-dependent damage
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Summary:This paper presents the theoretical developments and the numerical applications of a time-dependent damage law. This law is deduced from considerations at the micro-scale where non-planar growth of micro-cracks, following a subcritical propagation criterion, is assumed. The orientation of the crack growth is governed by the maximum energy release rate at the crack tips and the introduction of an equivalent straight crack. The passage from micro-scale to macro-scale is done through an asymptotic homogenization approach. The model is built in two steps. First, the effective coefficients are calculated at the micro-scale in finite periodical cells, with respect to the micro-cracks length and their orientation. Then, a subcritical damage law is developed in order to establish the evolution of damage. This damage law is obtained as a differential equation depending on the microscopic stress intensity factors, which are a priori calculated for different crack lengths and orientations. The developed model enables to reproduce not only the classical short-term stress–strain response of materials (in tension and compression) but also the long-term behavior encountering relaxation and creep effects. Numerical simulations show the ability of the developed model to reproduce this time-dependent damage response of materials.
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content type line 23
scopus-id:2-s2.0-77957756054
ISSN:0022-5096
DOI:10.1016/j.jmps.2010.07.018