Xu Xiao-wei, Shen Jue-ming, Wu Yao-zong. A Finite Element Method for Stress Analysis of Elastoplastic Body with Polygonal Line Strain-Hardening[J]. Applied Mathematics and Mechanics, 1984, 5(3): 411-417.
Citation:
Xu Xiao-wei, Shen Jue-ming, Wu Yao-zong. A Finite Element Method for Stress Analysis of Elastoplastic Body with Polygonal Line Strain-Hardening[J]. Applied Mathematics and Mechanics, 1984, 5(3): 411-417.
Xu Xiao-wei, Shen Jue-ming, Wu Yao-zong. A Finite Element Method for Stress Analysis of Elastoplastic Body with Polygonal Line Strain-Hardening[J]. Applied Mathematics and Mechanics, 1984, 5(3): 411-417.
Citation:
Xu Xiao-wei, Shen Jue-ming, Wu Yao-zong. A Finite Element Method for Stress Analysis of Elastoplastic Body with Polygonal Line Strain-Hardening[J]. Applied Mathematics and Mechanics, 1984, 5(3): 411-417.
In this paper, the stress-strain curve of material is fitted by polygonal line composed of three lines. According to the theory of proportional loading in elastoplasticity, we simplify the complete stress-strain relations, which are given by the increment theory of elastoplasticity. Thus, the finite element equation with the solution of displacement is derived. The assemblage elastoplastic stiffness matrix can be obtained by adding something to the elastic matrix, hence it will shorten the computing time. The determination of every loading increment follows the von Mises yield criteria. The iterative method is used in computation. It omits the redecomposition of the assemblage stiffness matrix and it will step further to shorten the computing time. Illustrations are given to the high-order element application departure from proportional loading, the computation of unloading fitting to the curve and the problem of load estimation.