Abstract
A boundary element method is developed for the analysis of fractures in two-dimensional solids. The solids are assumed to be linearly elastic and isotropic, and both bounded and unbounded domains are treated. The development of the boundary integral equations exploits (as usual) Somigliana's identity, but a special manipulation is carried out to ‘regularize’ certain integrals associated with the crack line. The resulting integral equations consist of the conventional ordinary boundary terms and two additional terms which can be identified as a distribution of concentrated forces and a distribution of dislocations along each crack line. The strategy for establishing the integral equations is first outlined in terms of real variables, after which complex variable techniques are adopted for the detailed development. In the numerical implementation of the formulation, the ordinary boundary integrals are treated with standard boundary element techniques, while a novel numerical procedure is developed to treat the crack line integrals. The resulting numerical procedure is used to solve several sample problems for both embedded and surface-breaking cracks, and it is shown that the technique is both accurate and efficient. The utility of the method for simulating curvilinear crack propagation is also demonstrated.
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References
C.A. Brebbia and J. Dominguez, Boundary Elements An Introductory Course, McGraw-Hill (1992).
T.A. Cruse, Boundary Element Analysis in Computational Fracture Mechanics, Kluwer Academic (1988).
M.D. Snyder and T.A. Cruse, International Journal of Fracture 11–2 (1975) 315–328.
P.W. Tan, I.S. Raju and J.C. Newman, in Fracture Mechanics: Eighteenth Symposium, ASTM STP 945 (1988) 259–277.
G.E. Blanford, A.R. Ingraffea and J.A. Liggett, International Journal for Numerical Methods in Engineering 17 (1981) 387–404.
W. Zang and P. Gudmundson, International Journal of Fracture 38 (1988) 275–294.
N. Ghosh, H. Rajiyah, S. Ghosh and S. Mukherjee, Journal of Applied Mechanics 53 (1986) 69–76.
J. Weaver, International Journal of Solids and Structures 13 (1977) 321–330.
V. Sládek and J. Sládek, Applied Mathematical Modelling 6 (1982) 374–380.
A. Portela, M.H. Aliabadi and D.P. Rooke, in Advances in Boundary Element Methods for Fracture Mechanics, Computational Mechanics (1993).
U. Heise, Acta Mechanica 31 (1978) 33–69.
N.I. Muskhelishvili, Some Basic Problems of The Mathematical Theory of Elasticity, P. Noordhoff (1963).
A.E. Green and W. Zerna, Theoretical Elasticity, Oxford University Press (1968).
C.C. Chang and M.E. Mear, Engineering Mechanics Research Laboratory, EMRL Report No. 93/13, The University of Texas at Austin (1993).
B.A. Bilby and J.D. Eshelby, in Fracture, An Advanced Treatise, Vol. 1 Academic Press (1968) 99–182.
J.R. Rice, in Fracture, An Advanced Treatise, Vol. 2 Academic Press (1968) 191–311.
G.R. Irwin, Transactions of ASME, Series E, Journal of Applied Mechanics 24–3 (1957) 361–364.
F. Erdogan, Proceedings of The Fourth U.S. National Congress of Applied Mechanics (1962) 547–553.
Y. Murakami, Stress Intensity Factors Handbook, Vol. 1, Pergamon Press (1987).
F. Erdogan and G.C. Sih, Journal of Basic Engineering 85 (1963) 519–527.
F. Erdogan and G.D. Gupta, Quarterly of Applied Mathematics 29 (1972) 525–534.
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Chang, C., Mear, M.E. A boundary element method for two dimensional linear elastic fracture analysis. Int J Fract 74, 219–251 (1996). https://doi.org/10.1007/BF00033829
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DOI: https://doi.org/10.1007/BF00033829