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Mixed mode axisymmetric cracks in transversely isotropic infinite solid cylinders

•New analytical dislocation solution in a transversely isotropic cylinder is developed.•Material anisotropy has an efficient effect on stress intensity factors.•Interaction of cracks implies that need for mixed-mode analysis is essential.•Loading type and crack length have also a crucial effect on s...

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Bibliographic Details
Published in:Applied mathematical modelling 2017-09, Vol.49, p.279-301
Main Authors: Pourseifi, M., Faal, R.T.
Format: Article
Language:English
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Summary:•New analytical dislocation solution in a transversely isotropic cylinder is developed.•Material anisotropy has an efficient effect on stress intensity factors.•Interaction of cracks implies that need for mixed-mode analysis is essential.•Loading type and crack length have also a crucial effect on stress intensity factors. The present study examined mixed mode cracking in a transversely isotropic infinite cylinder. The solutions to axisymmetric Volterra climb and glide dislocations in an infinite circular cylinder of the transversely isotropic material are first obtained. The solutions are represented in terms of the biharmonic stress function. Next, the problem of a transversely isotropic infinite cylinder with a set of concentric axisymmetric penny-shaped, annular, and circumferential cracks is formulated using the distributed dislocation technique. Two types of loadings are considered: (i) the lateral cylinder is loaded by two self-equilibrating distributed shear stresses; (ii) the curved surface of the cylinder is under the action of a distributed normal stress. The resulting integral equations are solved by using a numerical scheme to compute the dislocation density on the borders of the cracks. The dislocation densities are employed to determine stress intensity factors for axisymmetric interacting cracks. Finally, a good amount of examples are solved to depict the effect of crack type and location on the stress intensity factors at crack tips and interaction between cracks. Numerical solutions for practical materials are presented and the effect of transverse isotropy on stress intensity factors is discussed.
ISSN:0307-904X
DOI:10.1016/j.apm.2017.04.035