A Shape-Memory Deployable Subsystem with a Large Folding Ratio in China's Tianwen-1 Mars Exploration Mission

被引：18

作者：

Zeng, Chengjun ^{[1
]}

Liu, Liwu ^{[1
]}

Du, Yang ^{[1
]}

Yu, Miao ^{[1
,2
]}

Xin, Xiaozhou ^{[1
]}

Liu, Tianzhen ^{[3
]}

Xu, Peilei ^{[1
]}

Yan, Yu ^{[1
]}

Zhang, Dou ^{[1
]}

Dai, Wenxu ^{[1
]}

Lan, Xin ^{[1
,3
]}

Zhang, Fenghua ^{[3
]}

Wang, Linlin ^{[3
]}

Wan, Xue ^{[3
]}

Bian, Wenfeng ^{[4
]}

Liu, Yanju ^{[1
]}

Leng, Jinsong ^{[3
]}

机构：

[1] Harbin Inst Technol, Dept Astronaut Sci & Mech, Harbin 150001, Peoples R China

[2] Shanghai Inst Satellite Engn, Shanghai 201109, Peoples R China

[3] Harbin Inst Technol, Ctr Composite Mat & Struct, Harbin 150080, Peoples R China

[4] Harbin Inst Technol, Dept Civil Engn, Weihai 264209, Peoples R China

来源：

ENGINEERING | 2023年 / 28卷

基金：

中国国家自然科学基金;

关键词：

Flexible deployable structure; Shape memory polymer composite; Mars exploration; Temperature telemetry; On-orbit deployment; COMPOSITES;

D O I：

10.1016/j.eng.2023.01.005

中图分类号：

T [工业技术];

学科分类号：

08 ;

摘要：

Once China's Tianwen-1 Mars probe arrived in a Mars orbit after a seven-month flight in the deep cold space environment, it would be urgently necessary to monitor its state and the surrounding environment. To address this issue, we developed a flexible deployable subsystem based on shape memory polymer composites (SMPC-FDS) with a large folding ratio, which incorporates a camera and two temperature telemetry points for monitoring the local state of the Mars orbiter and the deep space environment. Here, we report on the development, testing, and successful application of the SMPC-FDS. Before reaching its Mars remote-sensing orbit, the SMPC-FDS is designed to be in a folded state with high stiffness; after reaching orbit, it is in a deployed state with a large envelope. The transition from the folded state to the deployed state is achieved by electrically heating the shape memory polymer composites (SMPCs); during this process, the camera on the SMPC-FDS can capture the local state of the orbiter from multiple angles. Moreover, temperature telemetry points on the SMPC-FDS provide feedback on the environment temperature and the temperature change of the SMPCs during the energization process. By simulating a Mars on-orbit space environment, the engineering reliability of the SMPC-FDS was comprehensively verified in terms of the material properties, structural dynamic performance, and thermal vacuum deployment feasibility. Since the launch of Tianwen-1 on 23 July 2020, scientific data on the temperature environment around Tianwen-1 has been successfully acquired from the telemetry points on the SMPCFDS, and the local state of the orbiter has been photographed in orbit, showing the national flag of China fixed on the orbiter. (c) 2023 THE AUTHORS. Published by Elsevier LTD on behalf of Chinese Academy of Engineering and Higher Education Press Limited Company. This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/).

引用

页码：49 / 57

页数：9

共 39 条

[1] A Shape-Memory Deployable Subsystem with a Large Folding Ratio in China's Tianwen-1 Mars Exploration Mission
Chengjun Zeng
Liwu Liu
Yang Du
Miao Yu
Xiaozhou Xin
Tianzhen Liu
Peilei Xu
Yu Yan
Dou Zhang
Wenxu Dai
Xin Lan
Fenghua Zhang
Linlin Wang
Xue Wan
Wenfeng Bian
Yanju Liu
Jinsong Leng
Engineering, 2023, (09) : 49 - 57
[2] Tianwen-1 and China's Mars exploration program
Weijie Zhao
National Science Review, 2021, 8 (02) : 170 - 173
[3] Tianwen-1 and China's Mars exploration program
Zhao, Weijie
Pan, Yongxin
Wang, Chi
NATIONAL SCIENCE REVIEW, 2021, 8 (02)
[4] Scientific objectives and payloads of Tianwen-1, China's first Mars exploration mission
Zou Yongliao
Zhu Yan
Bai Yunfei
Wang Lianguo
Jia Yingzhuo
Shen Weihua
Fan Yu
Liu Yang
Wang Chi
Zhang Aibing
Yu Guobin
Dong Jihong
Shu Rong
He Zhiping
Zhang Tielong
Du Aimin
Fan Mingyi
Yang Jianfeng
Zhou Bin
Wang Yi
Peng Yongqing
ADVANCES IN SPACE RESEARCH, 2021, 67 (02) : 812 - 823
[5] Mars Orbiter magnetometer of China's First Mars Mission Tianwen-1
Liu, Kai
Hao, XinJun
Li, YiRen
Zhang, TieLong
Pan, ZongHao
Chen, ManMing
Hu, XiaoWen
Li, Xin
Shen, ChengLong
Wang, YuMing
EARTH AND PLANETARY PHYSICS, 2020, 4 (04) : 384 - 389
[6] Mars Orbiter magnetometer of China's First Mars Mission Tianwen-1
KaiLiu
XinJun Hao
YiRen Li
TieLong Zhang
ZongHao Pan
ManMing Chen
XiaoWen Hu
Xin Li
ChengLong Shen
YuMing Wang
Earth and Planetary Physics, 2020, (04) : 384 - 389
[7] High Resolution Imaging Camera (HiRIC) on China’s First Mars Exploration Tianwen-1 Mission
Qingyu Meng
Dong Wang
Xiaodong Wang
Wei Li
Xianwei Yang
Dejie Yan
Yang Li
Zhirui Cao
Qi Ji
Tianyu Sun
Wei Yan
Kejun Wang
Xiaobo Li
Jingtao Huang
Zheng Wang
Weiguo Zhao
Yan Wang
Yunfeng He
Xianpeng Hao
Wenguang Liu
Bowei Zhang
Pengji Zhou
Yunhui Li
Haibo Zhao
Lin Lu
Hainan Guan
Dali Zhou
Fanlu Wu
Fan Zhang
Shiyu Zhu
Jihong Dong
Space Science Reviews, 2021, 217
[8] Entry, Descent, and Landing of China's Tianwen-1 Mars Mission
Sun, Zezhou
Rao, Wei
SPACE-SCIENCE & TECHNOLOGY, 2022, 2022
[9] High Resolution Imaging Camera (HiRIC) on China's First Mars Exploration Tianwen-1 Mission
Meng, Qingyu
Wang, Dong
Wang, Xiaodong
Li, Wei
Yang, Xianwei
Yan, Dejie
Li, Yang
Cao, Zhirui
Ji, Qi
Sun, Tianyu
Yan, Wei
Wang, Kejun
Li, Xiaobo
Huang, Jingtao
Wang, Zheng
Zhao, Weiguo
Wang, Yan
He, Yunfeng
Hao, Xianpeng
Liu, Wenguang
Zhang, Bowei
Zhou, Pengji
Li, Yunhui
Zhao, Haibo
Lu, Lin
Guan, Hainan
Zhou, Dali
Wu, Fanlu
Zhang, Fan
Zhu, Shiyu
Dong, Jihong
SPACE SCIENCE REVIEWS, 2021, 217 (03)
[10] The MarSCoDe Instrument Suite on the Mars Rover of China's Tianwen-1 Mission
Xu, Weiming
Liu, Xiangfeng
Yan, Zhixin
Li, Luning
Zhang, Zhenqiang
Kuang, Yaowu
Jiang, Hao
Yu, Hongxuan
Yang, Fan
Liu, Chongfei
Wang, Tingting
Li, Changkun
Jin, Yanfei
Shen, Jiayi
Wang, Botao
Wan, Wenzhi
Chen, Jun
Ni, Shenghao
Ruan, Yunpeng
Xu, Rui
Zhang, Changxing
Yuan, Ziyong
Wan, Xiong
Yang, Yichao
Li, Zhaohui
Shen, Yuanting
Liu, Dingzhen
Wang, Binyong
Yuan, Rujun
Bao, Tao
Shu, Rong
SPACE SCIENCE REVIEWS, 2021, 217 (05)

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