Dynamic analysis and nonlinear identification of space deployable structure
来源期刊:中南大学学报(英文版)2013年第5期
论文作者:GUO Hong-wei(郭宏伟) LIU Rong-qiang(刘荣强) DENG Zong-quan(邓宗全)
文章页码:1204 - 1213
Key words:deployable structure; finite element model; equivalent continuum model; nonlinear; dynamic analysis
Abstract: The dynamic equivalent continuum modeling method of the mast which is based on energy equivalency principle was investigated. And three kinds of mast dynamic model were established, which were equivalent continuum model, finite element model and simulation model, respectively. The mast frequencies and mode shapes were calculated by these models and compared with each other. The error between the equivalent continuum model and the finite element model is less than 5% when the mast length is longer. Dynamic responses of the mast with different lengths are tested, the mode frequencies and mode shapes are compared with finite element model. The mode shapes match well with each other, while the frequencies tested by experiments are lower than the results of the finite element model, which reflects the joints lower the mast stiffness. The nonlinear dynamic characteristics are presented in the dynamic responses of the mast under different excitation force levels. The joint nonlinearities in the deployable mast are identified as nonlinear hysteresis contributed by the coulomb friction which soften the mast stiffness and lower the mast frequencies.
GUO Hong-wei(郭宏伟)1,2, LIU Rong-qiang(刘荣强)1, DENG Zong-quan(邓宗全)1
(1. School of Mechatronics Engineering, Harbin Institute of Technology, Harbin 150001, China;
2. Department of Engineering Science, University of Oxford, Oxford OX13PJ, UK)
Abstract:The dynamic equivalent continuum modeling method of the mast which is based on energy equivalency principle was investigated. And three kinds of mast dynamic model were established, which were equivalent continuum model, finite element model and simulation model, respectively. The mast frequencies and mode shapes were calculated by these models and compared with each other. The error between the equivalent continuum model and the finite element model is less than 5% when the mast length is longer. Dynamic responses of the mast with different lengths are tested, the mode frequencies and mode shapes are compared with finite element model. The mode shapes match well with each other, while the frequencies tested by experiments are lower than the results of the finite element model, which reflects the joints lower the mast stiffness. The nonlinear dynamic characteristics are presented in the dynamic responses of the mast under different excitation force levels. The joint nonlinearities in the deployable mast are identified as nonlinear hysteresis contributed by the coulomb friction which soften the mast stiffness and lower the mast frequencies.
Key words:deployable structure; finite element model; equivalent continuum model; nonlinear; dynamic analysis