Configurational force based analysis of creep crack growth

被引:0
作者
O. Kolednik
A. Tiwari
C. Posch
M. Kegl
机构
[1] Austrian Academy of Sciences,Erich Schmid Institute of Materials Science
[2] Materials Center Leoben,Faculty of Mechanical Engineering
[3] University of Maribor,Metallurgical & Materials Engineering Department
[4] Indian Institute of Technology Ropar,undefined
来源
International Journal of Fracture | 2022年 / 236卷
关键词
Creep crack growth; Crack driving force; -integral; -integral; Configurational force concept; Finite element method;
D O I
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中图分类号
学科分类号
摘要
Based on the concept of configurational forces, the driving force of cracks in elastic–plastic, creeping materials is derived. In a numerical study, the variation of the crack driving force with increasing creep time is compared to the behaviors of different parameters that have been used in literature to describe the tendency to creep crack growth. This is performed for the assumption of stationary cracks in C(T)-specimens made of Waspaloy at 700 °C. The loading conditions are varied so that small-scale creep, transition creep, or extensive creep conditions prevail. Either the load or the load-point displacement are held constant. It is demonstrated that, for the considered cases, the conventional creep crack growth parameters do not reflect the crack driving force, but qualitatively follow a behavior similar to the (absolute value of the) time derivative of the crack driving force.
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页码:175 / 199
页数:24
相关论文
共 90 条
  • [1] Bassani JL(1981)Creep relaxation of stress around a crack tip Int J Solids Struct 17 79-89
  • [2] McClintock FL(1988)Evaluation of ASTM STP 995 7-26
  • [3] Bassani JL(2012) parameter for characterizing creep crack growth rate in the transient regime Int J Fract 174 61-74
  • [4] Hawk DE(1996)On configurational forces at boundaries in fracture mechanics J Mech Phys Solids 44 905-927
  • [5] Saxena A(1996)Configurational forces and the basic laws for crack propagation Int J Mech Sci 38 385-403
  • [6] Fischer FD(1954)Prediction of creep failure in aeroengine materials under multi-axial stress states Q Appl Math 12 49-55
  • [7] Simha NK(1968)Approximate analysis of structures in the presence of moderately large creep deformations J Mech Phys Solids 16 13-31
  • [8] Predan J(2010)Singular behavior at the end of a tensile crack tip in a hardening material Eng Fract Mech 77 3611-3624
  • [9] Schöngrundner R(2014)Reprint of “Cracks in inhomogeneous materials: comprehensive assessment using the configurational forces concept” Int J Fract 187 77-107
  • [10] Kolednik O(2019)A new view on ASME J Appl Mech 86 128-148
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