Author:
Zheng Bing,Xu Dong,Zou Zhipeng,Wang Yiqun,Guo Longxin,Zhao Hongyang,Ju Dongying
Abstract
AbstractDuring the thermal simulation compression test, the formation of an obvious bulge in the specimen leads to a certain deviation between the calculated and actual values of the true stress. The finite element method was used to simulate the single-pass compression of specimens of 34CrNi3MoV steel and obtain the actual nonuniform deformation of the bulging belly during the compression process, and the results were applied to correct experimental flow curves. The results showed that the deformation conditions had a significant influence on the nonuniformity of the specimen deformation during the compression process, and all the modified flow curves were lower than the original ones. The size of the bulge and the metal flow line in the finite element simulation were consistent with the test results. The load value obtained by using the modified flow curve was similar to the load value measured in the test, which indicated that the modified flow curve was very close to the real flow force curve of the material. The method used to modify the flow force curve is simple and practical.
Funder
the National Natural Science Foundation of China
Special Projects for Military-Civilian Collaborative Innovation in Science and Technology by Hebei Natural Science Foundation
Science and Technology Project of Hebei Education Department
Publisher
Springer Science and Business Media LLC
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