Modeling and Experimental Study of Shape Memory Cable Net Structures

doi:10.3969/j.issn.1004-132X.2023.18.005

China Mechanical Engineering ›› 2023, Vol. 34 ›› Issue (18): 2186-2193.DOI: 10.3969/j.issn.1004-132X.2023.18.005

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Modeling and Experimental Study of Shape Memory Cable Net Structures

PAN Fengqun1;JIANG Xiangjun1;DU Jingli1;LIU Jia1;FAN Yesen2

1.Key Laboratory of Electronic Equipment Structural Design,Ministry of Education,Xidian University,Xi'an，710071
2.China Academy of Space Technology(Xi'an),Xi'an，710100

Online:2023-09-25 Published:2023-10-19

形状记忆索网结构模型建立及实验研究

潘逢群1;蒋翔俊1;杜敬利1;刘佳1;范叶森2

1.西安电子科技大学电子装备结构设计教育部重点实验室，西安，710071
2.中国空间技术研究院西安分院，西安，710100

通讯作者: 蒋翔俊（通信作者），男，1979年生，副教授。研究方向为大型天线结构优化、形状记忆合金、弹热制冷。E-mail:xjjiang@xidian.edu.cn。
作者简介:潘逢群，女，1980年生，博士研究生。研究方向为大型可展开天线结构优化、形状记忆合金。E-mail:fqpan@stu.xidian.edu.cn。
基金资助:
国家自然科学基金（51775406）；陕西省自然科学基金（2023-JC-ZD-29，2022JQ-561）；芜湖西电产学研合作专项（XWYCXY-012021017-HT）

Abstract

Abstract: In order to solve the problems of reduced surface accuracy caused by space environment during the operation of spaceborne cable net antenna in orbit, a shape memory cable net structure was proposed. The shape memory alloy wires were integrated with the cable net structure to form a shape memory cable net structure. The reflector of the cable mesh structure was adjusted by using the phase transformation characteristics of shape memory alloy to improve the in orbit performance. Experiments were carried out using a 2.2 m cable net structure model under normal temperature and high and low temperature. The experimental results show that the shape memory alloy wires have a relatively stable ability to adjust the surface accuracy of the cable net structures at room temperature. In high and low temperature environments, compared with ordinary cable net, shape memory cable net structure has higher surface accuracy. Shape memory alloy wires have a certain adjustment effect on the reflector of cable net structures.

Key words: shape memory cable net structure, thermal deformation, reflector adjustment, normal temperature experiment, high and low temperature experiment

摘要： 针对星载索网结构天线在轨运行时由于空间环境导致的型面精度降低的问题，提出形状记忆索网结构。将形状记忆合金丝与索网结构进行集成，构成形状记忆索网结构。利用形状记忆合金丝的相变特性对索网结构反射面进行调整，以改善其在轨性能。利用2.2 m索网结构模型开展了常温实验和高低温实验。实验结果表明，常温环境下，形状记忆合金丝对索网结构型面精度的调节能力比较稳定；高低温环境中，与普通索网相比，形状记忆索网结构型面精度较高，形状记忆合金丝对索网结构反射面具有一定的调节作用。

关键词: 形状记忆索网结构, 热变形, 反射面调节, 常温实验, 高低温实验

CLC Number:

V443

PAN Fengqun, JIANG Xiangjun, DU Jingli, LIU Jia, FAN Yesen. Modeling and Experimental Study of Shape Memory Cable Net Structures[J]. China Mechanical Engineering, 2023, 34(18): 2186-2193.

潘逢群, 蒋翔俊, 杜敬利, 刘佳, 范叶森. 形状记忆索网结构模型建立及实验研究[J]. 中国机械工程, 2023, 34(18): 2186-2193.

References

［1］SHEN Z X, LI H J, LIU X N, et al. Thermal-structural Dynamic Analysis of a Satellite Antenna with the Cable-network and Hoop-truss Supports［J］. Journal of Thermal Stresses, 2019, 42 (11):1339-1356.
［2］任伟峰, 何柏岩, 聂锐. 环形桁架天线展开动力学分析［J］. 中国机械工程, 2019, 30(24):2945-2952.
REN Weifeng, HE Baiyan, NIE Rui. Deployment Forward Dynamics Analysis of Hoop Truss Antennas［J］. China Mechanical Engineering, 2019, 30(24):2945-2952.
［3］曾祥, 周怡君,袁伟钦,等. 基于Twin-Bennett机构固面可展开天线的优化设计［J］. 中国机械工程, 2021, 32(11):1361-1369.
ZENG Xiang, ZHOU Yijun, YUAN Weiqin, et al. Optimal Design of Solid Surface Deployable Antennas Based on Twin-Bennett Linkage［J］. China Mechanical Engineering, 2021, 32(11):1361-1369.
［4］NIE R, HE B Y, YAN S Z, et al. Design Optimazation of Mesh Antennas for On-orbit Thermal Effects［J］. International journal of Mechanical Sciences, 2020, 175.
［5］WANG X Y, ZHENG W P, HU Y R. Active Flatness Control of Space Membrane Structures Using Discrete Boundary SMA Actuators［C］∥Proceedings of the IEEE/ASME International Conference on Advanced Intelligent Mechatronics. Xian, 2008:1108-1113.
［6］SONG X S, TAN S J, WANG E M, et al. Active Shape Control of an Antenna Reflector Using Piezoelectric Actuators［J］. Journal of Intelligent Material Systems and Structures, 2019, 30 (18/19):2733-2747.
［7］WANG Z W, LI T, CAO Y. Active Shape Adjustment of Cable Net Structures with PZT Actuators［J］. Aerospace Science and Technology, 2013, 26:160-168.
［8］PENG F, JIANG X X, HU Y R, et al. Actuation Precision Control of SMA Actuators Used for Shape Control of Inflatable SAR Antenna［J］. Acta Astronautica, 2008, 63(5/6):578-585.
［9］LIU Y J, DU H Y, LIU L W, et al. Shape Memory Polymers and Their Composites in Aerospace Applications:a Review［J］. Smart Materials and Structures, 2014, 23(2):023001.
［10］BINETTE P, DANO M L, GENDRON G. Active Shape Control of Composite Structures under Thermal Loading［J］. Smart Materials and Structures, 2009, 18(2):025007.
［11］寻广彬. 星载径向肋索网天线结构设计分析与形状主动控制［D］. 大连：大连理工大学, 2019.
XUN Guangbin. Structural Design Analysis and Active Shape Control of Spaceborne Radial Ribbed Cable Mesh Antennas［D］. Dalian:Dalian University of Technology, 2019.
［12］JIANG X J, PAN F Q, FAN Y S, et al. Active Adjustment of Surface Accuracy for a Large Cable-net Structure by SMA［J］. Materials, 2019, 12(16):2619.
［13］PAN Fengqun, JIANG Xiangjun, DONG Xingkun, et al. Optimization Design of Surface Accuracy of SMC Structure Driven by Space Thermal Radiation［J］. Journal of Intelligent Material Systems and Structures, 2023, 34(3):279-291.
［14］OEHLER S D, HARTL D J, LOPEZ R, et al. Design Optimization and Uncertainty Analysis of SMA Morphing Structures［J］. Smart Materials and Structures, 2012, 21:094016.
［15］潘逢群, 蒋翔俊, 范叶森, 等. 形状记忆索网结构型面精度优化设计［J］. 机械工程学报, 2020, 56(9):1-8.
PAN Fengqun, JIANG Xiangjun, FAN Yesen, et al. Optimization Design of Structural Surface Precision of Shape Memory Cable Mesh［J］. Journal of Mechanical Engineering, 2020, 56(9):1-8.
［16］BRINSON L C. One-dimensional Constitutive Behavior of SMAs:Thermomechanical Derivation with Non-constant Material Functions and Redefined Martensite Internal Variable［J］. Journal of Intelligent Material Systems and Structures, 1993, 4(2):229-242.

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Modeling and Experimental Study of Shape Memory Cable Net Structures

形状记忆索网结构模型建立及实验研究

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