Vibration of Solar Panels in Consideration of Nonlinear Stiffness of Tape Spring Hinges and Flexible Deformation of Panels
ID:40 View Protection:ATTENDEE Updated Time:2021-08-16 14:42:42 Hits:439 Oral Presentation

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Abstract
Solar panels of satellite are deployed by tape spring hinges (TSHs) which have changeable stiffness. Generally, the stiffness of the TSH is small at folded status so that the panels are driven slightly. However, to lock up panels, the stiffness becomes large sharply at deployed status. Since the solar panel is thin sheet, flexible deformation is generated by driving torques of TSHs. Both the nonlinear stiffness of TSHs and the flexible deformation of panels generate obvious vibration which affects the deployment performance and operational stability of satellite. To obtain expected deployment performances such as the low latch-up load, latching without overshoot and high deployment stiffness, the vibration of solar panels is analyzed by using commercial software RecurDyn in this paper. To express the flexible deformation, the panels are modeled by the model order reduction (MOR) method and the finite element method (FEM), respectively. The driving torque between adjacent panels is described as function of the stiffness factor, damping coefficient, rotation angle, angular velocity and one spline (stiffness-angle profile). After that, two virtual maneuvers including deployment and orbit maneuver are design to figure the differences between FEM and MOR in modeling of vibration of solar panels. Although the MOR is much efficient than FEM, final results show that the vibration accelerations by the MOR is much lower than those by FEM. The MOR is incompetent in modeling of vibration of solar panels of satellites.
Keywords
Vibration; Solar panels; Tape spring hinges; Nonlinear stiffness; Flexible deformation
Speaker
Wenyan GU
PhD candidate Shandong University

Learning experience
2010.09-2014.07 Changzhou Institute of Technology, Mechanical Design Manufacturing and Automation, Bachelor's degree
2014.09-2017.07 Jiangsu University, Vehicle Engineering, Master's Degree
2021.09-present Shandong University, Mechanical Engineering, Ph.D. degree

Research field
Dynamic modeling of mechanical system and reliability design of key components; Environmental load identification and data processing; Advanced manufacturing technology and intelligent equipment

Submission Author
Wenyan Gu Shandong University
Xiangqian Zhu Shandong University
Jinsheng Zhang Shandong University
Yegao Qu Shanghai Jiao Tong University
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Important Date
  • Conference Date

    Nov 01

    2022

    to

    Nov 03

    2022

  • Oct 30 2022

    Draft paper submission deadline

  • Nov 09 2022

    Registration deadline

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Qingdao University of Technology