基于脉冲子结构的探测器结构动力学优化设计

Shu Lin Chen; Li Liu; Zhao Yue Chen; Zhen Jiang Yue; Hao Ran Sun

doi:10.3873/j.issn.1000-1328.2018.09.004

基于脉冲子结构的探测器结构动力学优化设计

Translated title of the contribution: Dynamic Optimum Design of Lunar Lander Based on Impulse Substructuring Technique

Shu Lin Chen, Li Liu^*, Zhao Yue Chen, Zhen Jiang Yue, Hao Ran Sun

^*Corresponding author for this work

School of Aerospace Engineering

Beijing Institute of Technology

Research output: Contribution to journal › Article › peer-review

1 Citation (Scopus)

Abstract

To overcome the shortcomings of using the time-consuming refined model in the dynamic optimum design of the complex structures, the efficient and accurate dynamic responses prediction method named the impulse based substructuring (IBS) method is introduced. Meanwhile, a dynamic optimum design process considering the structural dynamic responses is proposed and the structure of the solar wings of a lunar lander is optimized. After the optimum design process, the structural design parameters of the solar wings are obtained. The dynamic performance of the solar wings and the dynamics environment of the critical locations of the lunar lander are improved. The results indicate that the IBS method can be applied in the optimum design of a spacecraft to improve the dynamic analysis efficiency. This research provides a theoretical basis and technical support for practical structural design.

Translated title of the contribution	Dynamic Optimum Design of Lunar Lander Based on Impulse Substructuring Technique
Original language	Chinese (Traditional)
Pages (from-to)	969-976
Number of pages	8
Journal	Yuhang Xuebao/Journal of Astronautics
Volume	39
Issue number	9
DOIs	https://doi.org/10.3873/j.issn.1000-1328.2018.09.004
Publication status	Published - 30 Sept 2018

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10.3873/j.issn.1000-1328.2018.09.004

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title = "基于脉冲子结构的探测器结构动力学优化设计",

abstract = "To overcome the shortcomings of using the time-consuming refined model in the dynamic optimum design of the complex structures, the efficient and accurate dynamic responses prediction method named the impulse based substructuring (IBS) method is introduced. Meanwhile, a dynamic optimum design process considering the structural dynamic responses is proposed and the structure of the solar wings of a lunar lander is optimized. After the optimum design process, the structural design parameters of the solar wings are obtained. The dynamic performance of the solar wings and the dynamics environment of the critical locations of the lunar lander are improved. The results indicate that the IBS method can be applied in the optimum design of a spacecraft to improve the dynamic analysis efficiency. This research provides a theoretical basis and technical support for practical structural design.",

keywords = "Dynamic optimum design, Impulse based substructuring method, Lunar lander, Solar wings, Structural dynamic analysis",

author = "Chen, {Shu Lin} and Li Liu and Chen, {Zhao Yue} and Yue, {Zhen Jiang} and Sun, {Hao Ran}",

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T1 - 基于脉冲子结构的探测器结构动力学优化设计

AU - Chen, Shu Lin

AU - Liu, Li

AU - Chen, Zhao Yue

AU - Yue, Zhen Jiang

AU - Sun, Hao Ran

PY - 2018/9/30

Y1 - 2018/9/30

N2 - To overcome the shortcomings of using the time-consuming refined model in the dynamic optimum design of the complex structures, the efficient and accurate dynamic responses prediction method named the impulse based substructuring (IBS) method is introduced. Meanwhile, a dynamic optimum design process considering the structural dynamic responses is proposed and the structure of the solar wings of a lunar lander is optimized. After the optimum design process, the structural design parameters of the solar wings are obtained. The dynamic performance of the solar wings and the dynamics environment of the critical locations of the lunar lander are improved. The results indicate that the IBS method can be applied in the optimum design of a spacecraft to improve the dynamic analysis efficiency. This research provides a theoretical basis and technical support for practical structural design.

AB - To overcome the shortcomings of using the time-consuming refined model in the dynamic optimum design of the complex structures, the efficient and accurate dynamic responses prediction method named the impulse based substructuring (IBS) method is introduced. Meanwhile, a dynamic optimum design process considering the structural dynamic responses is proposed and the structure of the solar wings of a lunar lander is optimized. After the optimum design process, the structural design parameters of the solar wings are obtained. The dynamic performance of the solar wings and the dynamics environment of the critical locations of the lunar lander are improved. The results indicate that the IBS method can be applied in the optimum design of a spacecraft to improve the dynamic analysis efficiency. This research provides a theoretical basis and technical support for practical structural design.

KW - Dynamic optimum design

KW - Impulse based substructuring method

KW - Lunar lander

KW - Solar wings

KW - Structural dynamic analysis

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基于脉冲子结构的探测器结构动力学优化设计

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