An adaptive algorithm for cohesive zone model and arbitrary crack propagation

Vincent Chiaruttini; Dominique Geoffroy; Vincent Riolo; Marc Bonnet

doi:10.1080/17797179.2012.744544

An adaptive algorithm for cohesive zone model and arbitrary crack propagation

Vincent Chiaruttini
, Dominique Geoffroy
, Vincent Riolo
, Marc Bonnet

ONERA Office National d'Etudes et Recherches Aerospatiales
Department of Mechanics École Polytechnique

Résultats de recherche: Contribution à un journal › Article › Revue par des pairs

Résumé

This paper presents an approach to the numerical simulation of crack propagation with cohesive models for the case of structures subjected to mixed mode loadings. The evolution of the crack path is followed by using an adaptive method: with the help of a macroscopic branching criterion based on the calculation of an energetic integral, the evolving crack path is remeshed as the crack evolves in the simulation. Special attention is paid to the unknown fields transfer approach that is crucial for the success of the computational treatment. This approach has been implemented in the finite element code Z-Set (jointly developed by Onera and Ecole des Mines) and is tested on two examples, one featuring a straight crack path and the other involving a complex crack propagation under critical monotonous loading.

langue originale	Anglais
Pages (de - à)	208-218
Nombre de pages	11
journal	European Journal of Computational Mechanics
Volume	21
Numéro de publication	3-6
Les DOIs	https://doi.org/10.1080/17797179.2012.744544
état	Publié - 1 janv. 2012

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title = "An adaptive algorithm for cohesive zone model and arbitrary crack propagation",

abstract = "This paper presents an approach to the numerical simulation of crack propagation with cohesive models for the case of structures subjected to mixed mode loadings. The evolution of the crack path is followed by using an adaptive method: with the help of a macroscopic branching criterion based on the calculation of an energetic integral, the evolving crack path is remeshed as the crack evolves in the simulation. Special attention is paid to the unknown fields transfer approach that is crucial for the success of the computational treatment. This approach has been implemented in the finite element code Z-Set (jointly developed by Onera and Ecole des Mines) and is tested on two examples, one featuring a straight crack path and the other involving a complex crack propagation under critical monotonous loading.",

keywords = "Cohesive zone model, Field transfer, Mixed mode crack propagation, Remeshing",

author = "Vincent Chiaruttini and Dominique Geoffroy and Vincent Riolo and Marc Bonnet",

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AU - Geoffroy, Dominique

AU - Riolo, Vincent

AU - Bonnet, Marc

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N2 - This paper presents an approach to the numerical simulation of crack propagation with cohesive models for the case of structures subjected to mixed mode loadings. The evolution of the crack path is followed by using an adaptive method: with the help of a macroscopic branching criterion based on the calculation of an energetic integral, the evolving crack path is remeshed as the crack evolves in the simulation. Special attention is paid to the unknown fields transfer approach that is crucial for the success of the computational treatment. This approach has been implemented in the finite element code Z-Set (jointly developed by Onera and Ecole des Mines) and is tested on two examples, one featuring a straight crack path and the other involving a complex crack propagation under critical monotonous loading.

AB - This paper presents an approach to the numerical simulation of crack propagation with cohesive models for the case of structures subjected to mixed mode loadings. The evolution of the crack path is followed by using an adaptive method: with the help of a macroscopic branching criterion based on the calculation of an energetic integral, the evolving crack path is remeshed as the crack evolves in the simulation. Special attention is paid to the unknown fields transfer approach that is crucial for the success of the computational treatment. This approach has been implemented in the finite element code Z-Set (jointly developed by Onera and Ecole des Mines) and is tested on two examples, one featuring a straight crack path and the other involving a complex crack propagation under critical monotonous loading.

KW - Cohesive zone model

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KW - Remeshing

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JO - European Journal of Computational Mechanics

JF - European Journal of Computational Mechanics

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ER -

An adaptive algorithm for cohesive zone model and arbitrary crack propagation

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