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教授

博士生导师

硕士生导师

性别:男

毕业院校:大连理工大学

学位:博士

所在单位:机械工程学院

学科:工程力学. 固体力学. 航空航天力学与工程. 应用与实验力学. 机械制造及其自动化. 机械设计及理论. 车辆工程. 工业工程

电子邮箱:renmf@dlut.edu.cn

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Extended multiscale finite element method for large deflection analysis of thin-walled composite structures with complicated microstructure characteristics

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论文类型:期刊论文

第一作者:Ren, Mingfa

通讯作者:Cong, J (reprint author), Dalian Univ Technol, Dept Engn Mech, State Key Lab Struct Anal Ind Equipment, Dalian 116024, Peoples R China.

合写作者:Cong, Jie,Wang, Bo,Wang, Lei

发表时间:2018-09-01

发表刊物:THIN-WALLED STRUCTURES

收录刊物:SCIE

卷号:130

页面范围:273-285

ISSN号:0263-8231

关键字:Extended multiscale finite element method; Thin-walled composite structures; Large deflection analysis; Multiscale base functions; Displacement boundary conditions; Microstructure characteristics

摘要:An efficient multiscale finite element method is developed for large deflection analysis of thin-walled composite structures with complicated microstructure characteristics. The multiscale base functions are reconstructed to consider the coupling effects of thin-walled composite structures by introducing some additional coupling terms among translations and rotations. For the construction of multiscale base functions, two kinds of displacement boundary conditions are proposed for in-plane and out-plane degrees of freedom. Moreover, two kinds of relaxed decoupled displacement boundary conditions are constructed by adopting the oversampling technique to further improve the accuracy of the method. Then, the equivalent incremental/iterative equilibrium equations for each load step can be constructed and solved directly on the macro scale which will improve the computing efficiency significantly. The microscopic results can be obtained by downscale computation in which the incremental/ iterative equilibrium equations on the micro scale are solved under the incremental boundary conditions updated by incremental macroscopic displacements. Several numerical examples demonstrate that the developed method possesses high computing accuracy and efficiency compared with the conventional finite element method.