Kinematics and Dynamics of Deployable Structures with Scissor-Like-Elements Based on Screw Theory

Because the deployable structures are complex multi-loop structures and methods of derivation which lead to simpler kinematic and dynamic equations of motion are the subject of research effort, the kinematics and dynamics of deployable structures with scissor-like-elements are presented based on scr...

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Bibliographic Details
Published inChinese journal of mechanical engineering Vol. 27; no. 4; pp. 655 - 662
Main Authors Sun, Yuantao, Wang, Sanmin, Mills, James K., Zhi, Changjian
Format Journal Article
LanguageEnglish
Published Beijing Chinese Mechanical Engineering Society 01.07.2014
Springer Nature B.V
School of Mechanical Engineering, Northwestern Polytechnical University, Xi'an, 710072, PR China%Department of Mechanical and Industrial Engineering, University of Toronto, 5 King's College Rd.,Toronto, Ontario, Canada
EditionEnglish ed.
Subjects
Acceleration
Closed loops
Computer simulation
Deployable structures
Dynamics
Electrical Machines and Networks
Electronics and Microelectronics
Engineering
Engineering Thermodynamics
Equations of motion
Heat and Mass Transfer
Instrumentation
Jacobi matrix method
Kinematics
Machines
Manufacturing
Mathematical analysis
Matrix methods
Mechanical Engineering
Power Electronics
Processes
Screw theory
Screws
Spacecraft
Theoretical and Applied Mechanics
Topology
元素
剪刀
动力学方程
环结构
螺旋理论
运动学
运动方程
雅可比矩阵
screw theory
kinematics
dynamics
the principle of virtual work
scissor-like-element
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Summary:Because the deployable structures are complex multi-loop structures and methods of derivation which lead to simpler kinematic and dynamic equations of motion are the subject of research effort, the kinematics and dynamics of deployable structures with scissor-like-elements are presented based on screw theory and the principle of virtual work respectively. According to the geometric characteristic of the deployable structure examined, the basic structural unit is the common scissor-like-element(SLE). First, a spatial deployable structure, comprised of three SLEs, is defined, and the constraint topology graph is obtained. The equations of motion are then derived based on screw theory and the geometric nature of scissor elements. Second, to develop the dynamics of the whole deployable structure, the local coordinates of the SLEs and the Jacobian matrices of the center of mass of the deployable structure are derived. Then, the equivalent forces are assembled and added in the equations of motion based on the principle of virtual work. Finally, dynamic behavior and unfolded process of the deployable structure are simulated. Its figures of velocity, acceleration and input torque are obtained based on the simulate results. Screw theory not only provides an efficient solution formulation and theory guidance for complex multi-closed loop deployable structures, but also extends the method to solve dynamics of deployable structures. As an efficient mathematical tool, the simper equations of motion are derived based on screw theory.
Bibliography:scissor-like-element;screw theory;kinematics;dynamics;the principle of virtual work
SUN Yuantao, WANG Sanmin, MILLS James K, and ZHI Changjian( 1 School of Mechanical Engineering, Northwestern Polytechnical University, Xi "an, 710072, PR China 2 Department of Mechanical and Industrial Engineering, University of Toronto, 5 King's College Rd., Toronto, Ontario, Canada)
11-2737/TH
Because the deployable structures are complex multi-loop structures and methods of derivation which lead to simpler kinematic and dynamic equations of motion are the subject of research effort, the kinematics and dynamics of deployable structures with scissor-like-elements are presented based on screw theory and the principle of virtual work respectively. According to the geometric characteristic of the deployable structure examined, the basic structural unit is the common scissor-like-element(SLE). First, a spatial deployable structure, comprised of three SLEs, is defined, and the constraint topology graph is obtained. The equations of motion are then derived based on screw theory and the geometric nature of scissor elements. Second, to develop the dynamics of the whole deployable structure, the local coordinates of the SLEs and the Jacobian matrices of the center of mass of the deployable structure are derived. Then, the equivalent forces are assembled and added in the equations of motion based on the principle of virtual work. Finally, dynamic behavior and unfolded process of the deployable structure are simulated. Its figures of velocity, acceleration and input torque are obtained based on the simulate results. Screw theory not only provides an efficient solution formulation and theory guidance for complex multi-closed loop deployable structures, but also extends the method to solve dynamics of deployable structures. As an efficient mathematical tool, the simper equations of motion are derived based on screw theory.
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ISSN:1000-9345
2192-8258
DOI:10.3901/CJME.2014.0519.098