Abstract
This paper presents a fracture mechanics analysis of the base-edge-cracked reverse-tapered (RT) fracture geometry. Motivation for this study was the use of this test geometry in Phase 1 of a recently completed joint-industry-agency project entitled ‘Large-Scale Ice Fracture Experiments’. Underlying the choice of the RT fracture geometry for Phase 1 was the desirability of achieving crack propagation in a controlled and stable manner; such control would allow a number of observations to be made on one testpiece. Reverse tapering greatly improves not only crack growth stability but also crack path stability. The weight function method was used to provide accurate wide-ranging stress intensity factor (SIF), crack face displacement (COD) and crack opening area (COA) expressions for the RT subject to any loading. The required weight function was obtained through a finite element analysis of this geometry subject to a reference load case which determined the associated stress intensity factor and crack opening displacements. The Wu and Carlsson procedure was followed. A key modification to the latter procedure facilitated the attainment of the reference CMOD for all crack lengths, including the zero ligament limit; this was achieved by considering an additional reference solution. This modification is general in nature and could be pursued whenever the reference CMOD is not known analytically. An analytical solution for the crack opening area (COA) was also achieved for the special case of concentrated loading at the crack mouth. This solution can be applied to any geometry where the reference CMOD expression is known.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
D. Blanchet, A.C. Churcher, J.P. Fitzpatrick and P. Badra-Blanchet, in Working Group on Ice Forces, U.S. Army Cold Regions Research and Engineering Laboratory, Hanover, NH (1989) 77–124.
D. Blanchet, Canadian Geotechnical Journal 27 (1990) 701–725.
K.P. Kennedy, J.P. Dempsey, S.J. DeFranco, P.A. Spencer and D.M. Masterson, in Proceedings 12 th International Conference on Port and Ocean Engineering under Arctic Conditions Vol. 2 (1993) 527–536.
S.J. DeFranco and J.P. Dempsey, in The Mechanics of Creep Brittle Materials-2, A. C. F. Cocks and A. R. S. Ponter (Eds.), Elsevier (1991) 25–36.
S.J. DeFranco and J.P. Dempsey, Journal of Glaciology (1994) (in press).
C. Gurney and J. Hunt, Proceedings of the Royal Society A361 (1967) 254–263.
Y.W. Mai, A.G. Atkins and R.M. Caddell, International Journal of Fracture 11 (1975) 939–953.
H.F. Bueckner, Z. angew. Mathematik und Mechanik 50 (1970) 529–546.
J.R. Rice, International Journal of Solids and Structures 8 (1972) 751–758.
H.J. Petroski and J.D. Achenbach, Engineering Fracture Mechanics 10 (1978) 257–266.
X.R. Wu and A.J. Carlsson, in Weight Functions and Stress Intensity Factor Solutions, Pergamon Press (1991).
T. Fett, C. Mattheck and D. Munz, Engineering Fracture Mechanics 27 (1987) 697–715.
M.P. Stallybrass, International Journal of Engineering Science 8 (1970) 351–362.
L.A. Kipnis, Applied Mathematical Mechanics (PMM) 43 (1970) 164–170.
X.R. Wu, International Journal of Fracture 48 (1991) 179–199.
H. Tada, P.C. Paris and G.R. Irwin, in The Stress Analysis of Cracks Handbook (1985).
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Dempsey, J.P., Adamson, R.M. & Defranco, S.J. Fracture analysis of base-edge-cracked reverse-tapered plates. Int J Fract 69, 281–294 (1995). https://doi.org/10.1007/BF00037379
Received:
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF00037379