Substructuring Technique for Dynamics Analysis of Flexible Beams with Large Deformation

doi:10.1007/s12204-017-1875-8

上海交通大学学报（英文版） ›› 2017, Vol. 22 ›› Issue (5): 562-569.doi: 10.1007/s12204-017-1875-8

Substructuring Technique for Dynamics Analysis of Flexible Beams with Large Deformation

ZHANG Jianshu (张建书), RUI Xiaoting* (芮筱亭), LIU Feifei (刘飞飞), ZHOU Qinbo (周秦渤), GU Lilin (顾利琳)

(Institute of Launch Dynamics, Nanjing University of Science & Technology, Nanjing 210094, China)

出版日期:2017-09-30 发布日期:2017-09-30
通讯作者: RUI Xiaoting (芮筱亭) E-mail: ruixt@163.net

Substructuring Technique for Dynamics Analysis of Flexible Beams with Large Deformation

ZHANG Jianshu (张建书), RUI Xiaoting* (芮筱亭), LIU Feifei (刘飞飞), ZHOU Qinbo (周秦渤), GU Lilin (顾利琳)

(Institute of Launch Dynamics, Nanjing University of Science & Technology, Nanjing 210094, China)

Online:2017-09-30 Published:2017-09-30
Contact: RUI Xiaoting (芮筱亭) E-mail: ruixt@163.net

摘要/Abstract

摘要： In this paper, the substructuring technique is extended for the dynamics simulation of flexible beams with large deformation. The dynamics equation of a spatial straight beam undergoing large displacement and small deformation is deduced by using the Jourdain variation principle and the model synthesis method. The longitudinal shortening effect due to the transversal deformation is taken into consideration in the dynamics equation. In this way, the geometric stiffening effect, which is also called stress stiffening effect, is accounted for in the dynamics equation. The transfer equation of the flexible beam is obtained by assembling the dynamics equation and the kinematic relationship between the two connection points of the flexible beam. Treating a flexible beam with small deformation as a substructure, one can solve the dynamics of a flexible beam with large deformation by using the substructuring technique and the transfer matrix method. The dynamics simulation of a flexible beam with large deformation is carried out by using the proposed approach and the results are verified by comparing with those obtained from Abaqus software.

关键词: flexible beam, large deformation, substructure, model synthesis

Abstract: In this paper, the substructuring technique is extended for the dynamics simulation of flexible beams with large deformation. The dynamics equation of a spatial straight beam undergoing large displacement and small deformation is deduced by using the Jourdain variation principle and the model synthesis method. The longitudinal shortening effect due to the transversal deformation is taken into consideration in the dynamics equation. In this way, the geometric stiffening effect, which is also called stress stiffening effect, is accounted for in the dynamics equation. The transfer equation of the flexible beam is obtained by assembling the dynamics equation and the kinematic relationship between the two connection points of the flexible beam. Treating a flexible beam with small deformation as a substructure, one can solve the dynamics of a flexible beam with large deformation by using the substructuring technique and the transfer matrix method. The dynamics simulation of a flexible beam with large deformation is carried out by using the proposed approach and the results are verified by comparing with those obtained from Abaqus software.

Key words: flexible beam, large deformation, substructure, model synthesis

中图分类号:

O 313.7

ZHANG Jianshu (张建书), RUI Xiaoting* (芮筱亭), LIU Feifei (刘飞飞),. Substructuring Technique for Dynamics Analysis of Flexible Beams with Large Deformation[J]. 上海交通大学学报（英文版）, 2017, 22(5): 562-569.

ZHANG Jianshu (张建书), RUI Xiaoting* (芮筱亭), LIU Feifei (刘飞飞),. Substructuring Technique for Dynamics Analysis of Flexible Beams with Large Deformation[J]. Journal of shanghai Jiaotong University (Science), 2017, 22(5): 562-569.

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Substructuring Technique for Dynamics Analysis of Flexible Beams with Large Deformation

Substructuring Technique for Dynamics Analysis of Flexible Beams with Large Deformation

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