可展开结构地面试验装置吊架力优化

Q1 Arts and Humanities

International Journal of Space Structures Pub Date : 2021-03-26 DOI:10.1177/09560599211005099

Fei Lin, Chuanzhi Chen, Jinhua Zhou, Y. Dai

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引用次数: 1

摘要

采用悬架法模拟微重力环境时，一部分挂架力用来抵消重力场对可展开结构的影响，另一部分产生附加力，影响可展开结构的驱动力和精度。为了减少悬挂力的不利影响，避免建立复杂的有限元理论模型，提出了一种基于自适应遗传算法的MATLAB与Nastran联合仿真优化方法。然后对吊架受力进行优化，可展开结构的变形减小了49%。结果表明，该优化方法有效地减小了悬挂力的不利影响，效果良好。

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Hanger forces optimization of ground test device on deployable structure

When using suspension method to simulate the microgravity environment, part of the hanger forces are used to offset the influence of gravitational field on the deployable structure, while the other part produces additional forces that affect the driving forces and precision of the deployable structure. In order to reduce the adverse effect of hanger forces, and avoid the construction of complex finite element theoretical model, an optimization method based on adaptive genetic algorithm with MATLAB and Nastran co-simulation is proposed. Then, the hanger forces are optimized, and the deployable structure deformation has been reduced 49%. It suggests that the adverse effect of hanger forces has been effectively reduced and the proposed optimization method works well.

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来源期刊

International Journal of Space Structures Arts and Humanities-Conservation

CiteScore

2.00

自引率

0.00%

发文量

期刊介绍： The aim of the journal is to provide an international forum for the interchange of information on all aspects of analysis, design and construction of space structures. The scope of the journal encompasses structures such as single-, double- and multi-layer grids, barrel vaults, domes, towers, folded plates, radar dishes, tensegrity structures, stressed skin assemblies, foldable structures, pneumatic systems and cable arrangements. No limitation on the type of material is imposed and the scope includes structures constructed in steel, aluminium, timber, concrete, plastics, paperboard and fabric.