Formulation and implementation of a high-order 3-D domain integral method for the extraction of energy release rates

This article presents a three dimensional (3-D) formulation and implementation of a high-order domain integral method for the computation of energy release rate. The method is derived using surface and domain formulations of the J -integral and the weighted residual method. The J -integral along 3-D...

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Bibliographic Details
Published in:Computational mechanics 2012-04, Vol.49 (4), p.459-476
Main Authors: Ozer, H., Duarte, C. A., Al-Qadi, I. L.
Format: Article
Language:English
Subjects:
Analysis
Boundary element method
Boundary layers
Classical and Continuum Physics
Computation
Computational Science and Engineering
Computer simulation
Energy release rate
Engineering
Finite element method
Formulations
Fracture mechanics
J integral
Methods
Original Paper
Polynomials
Stiffness matrix
Theoretical and Applied Mechanics
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Summary:This article presents a three dimensional (3-D) formulation and implementation of a high-order domain integral method for the computation of energy release rate. The method is derived using surface and domain formulations of the J -integral and the weighted residual method. The J -integral along 3-D crack fronts is approximated by high-order Legendre polynomials. The proposed implementation is tailored for the Generalized/eXtended Finite Element Method and can handle discontinuities arbitrarily located within a finite element mesh. The domain integral calculations are based on the same integration elements used for the computation of the stiffness matrix. Discontinuities of the integrands across crack surfaces and across computational element boundaries are fully accounted for. The proposed method is able to deliver smooth approximations and to capture the boundary layer behavior of the J -integral using tetrahedral meshes. Numerical simulations of mode-I and mixed mode benchmark fracture mechanics examples verify expected convergence rates for the computed energy release rates. The results are also in good agreement with other numerical solutions available in the literature.
ISSN:0178-7675
1432-0924
DOI:10.1007/s00466-011-0651-0