The extended finite element method (XFEM) is a numerical method for modeling discontinuities within
a classical finite element framework. Based on the algorithm of XFEM, the major factors such as integral domain
factor and mesh density which all influence the calculation accuracy of stress intensity factor (SIF) are discussed,
and the proper parameters to calculate the SIF are given. The results from the case analysis demonstrate that the
crack path is the most sensitive to the crack growth increment size, and the crack path is not mesh-sensitive. A
reanalysis method for the XFEM has been introduced. The example presented shows that there is a significantly
reduced computational cost for each iteration of crack growth achieved by using the reanalysis method and the
reanalysis approach has increasing benefits as the mesh density increases or the value of crack growth increments
size decreases.
ZHENG An-xing (郑安兴), LUO Xian-qi*(罗先启)
. Numerical Study of Quasi-Static Crack Growth Problems Based on Extended Finite Element Method[J]. Journal of Shanghai Jiaotong University(Science), 2014
, 19(6)
: 736
-746
.
DOI: 10.1007/s12204-014-1557-8
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