✦ LIBER ✦

Crack propagation analysis for orthotropic non-homogeneous materials

✍ Scribed by M.Y.A. Younan; B.R. Dewey; J.E. Akin

Publisher: Elsevier Science
Year: 1982
Tongue: English
Weight: 911 KB
Volume: 16
Category: Article
ISSN: 0013-7944
DOI: 10.1016/0013-7944(82)90149-7

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✦ Synopsis

The fracture mechanics of orthotropic non-homogeneous materials like welds involves the use of a fracture criterion with the stress analysis of the specimen. A maximum energy release rate criterion is proposed in this analysis. A finite element model with special crack tip elements has been develpoed for this study. Two techniques have been developed to model the crack propagation. The model was then applied to a compact tension specimen with a hypothetical weldment and to a weldment with an edge crack.

The maximum energy release rate criterion seems to be the most suitable for fracture prediction of non-homogeneous materials, since it gives the crack propagation direction as well as the maximum value for the energy released. The virtual displacement technique for modeling the crack propagation saves computer time and gives accurate results. The analysis indicates the effect of orthotropy on the crack propagation direction and maximum energy release rate.

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