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Plane strain stress intensity factors for branched cracks

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Abstract

A method of calculating stress intensity factors for branched and bent cracks embedded in an infinite body has been developed. The branches are always assumed to be sharp cracks and are modelled by dislocation distributions. The original crack may be either sharp or of elliptical cross-section with finite root radius. Hence, the method which has a precision ±2%, is also applicable to the study of crack branches emanating from elliptical holes and, approximately, also from notches. The following detailed calculations have been made assuming mode I loading: branched sharp crack with branches of equal and different length, bent sharp crack, and one and two crack branches emanating from the crack with a finite root radius. Bending of a sharp crack under mixed mode loading has also been studied. The criteria of maximum tensile stress and maximum energy release rate used in the study of direction of crack propagation are discussed.

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Authors and Affiliations

  1. Materials Division, Central Electricity Research Laboratories, KT 22 7SE, Leatherhead, Surrey, UK

    V. Vitek

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  1. V. Vitek
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Vitek, V. Plane strain stress intensity factors for branched cracks. Int J Fract 13, 481–501 (1977). https://doi.org/10.1007/BF00034249

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  • DOI: https://doi.org/10.1007/BF00034249

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