Research on Power System Development of Chinese Deep Space Exploration

LEI Yingjun, ZHU Liyin, ZHANG Wenjia

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PDF(710 KB)
Journal of Deep Space Exploration ›› 2020, Vol. 7 ›› Issue (1) : 35-40,46. DOI: 10.15982/j.issn.2095-7777.2020.20190712001
Guest Editor:Professor LUO Zhifu,China Institute of Atomic Energy

Research on Power System Development of Chinese Deep Space Exploration

  • LEI Yingjun, ZHU Liyin, ZHANG Wenjia
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Abstract

Aiming at the key tasks of deep space exploration such as lunar exploration,small celestial exploration,Mars exploration,Jupiter and interplanetary exploration in China,the specific requirements of the power system are proposed based on the analysis of the characteristics of individual detection missions. Finally,the power system requirements of all deep space exploration missions are summarized. the main development requirements of power system for deep space exploration missions in China are proposed,including wide temperature anti-irradiation solar array,light and small intelligent power control device,high power density power system topology,high efficiency and high reliability thermoelectric conversion technology,providing reference for the research and design of deep space exploration power system.

Keywords

deep space exploration / space power system / lunar exploration / Mars exploration

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LEI Yingjun, ZHU Liyin, ZHANG Wenjia. Research on Power System Development of Chinese Deep Space Exploration. Journal of Deep Space Exploration, 2020, 7(1): 35‒40,46 https://doi.org/10.15982/j.issn.2095-7777.2020.20190712001

References

[1] 叶培建,彭兢. 深空探测与我国深空探测展望[J]. 中国工程科学,2006,8(10):13-18
YE P J,PENG J. Deep space exploration and its prospect in China[J]. Engineering Science,2006,8(10):13-18
[2] 叶培建,黄江川,孙泽洲,等. 中国月球探测器发展历程和经验初探[J]. 中国科学:技术科学,2014,44(6):543-558
YE P J,HUANG J C,SUN Z Z,et a1. The progress and experience in the development of Chinese lunar probe[J]. Sci Sin Tech,2014,44(6):543-558
[3] 叶培建,孙泽洲,饶炜. 嫦娥一号月球探测卫星研制综述[J]. 航天器工程,2007,16(6):9-10
YE P J,SUN Z Z,RAO W. Research and development of Chang’e-1[J]. Spacecraft Engineering,2007,16(6):9-10
[4] 孙泽洲,张廷新,张熇,等. 嫦娥三号探测器的技术设计与成就[J]. 中国科学:技术科学,2014,44(4):331-343
SUN Z Z,ZHANG T X,ZHANG H,et a1. The technical design and achievements of Chang’e-3 probe[J]. Sci Sin Tech,2014,44(4):331-343
[5] 申振荣,张伍,贾阳,等. 嫦娥三号巡视器及其技术特点分析[J]. 航天器工程,2015,24(5):8-13
SHEN Z R,ZHANG W,JIA Y,et al. System design and technical characteristics analysis of Chang’e-3 lunar rover[J]. Spacecraft Engineering,2015,24(5):8-13
[6] 孙泽州,张熇,吴学英,等. 月球着陆探测器任务分析研究[J]. 航天器工程,2010,19(5):12-16
SUN Z Z,ZHANG H,WU X Y,et al. Mission analysis of a lunar soft lander[J]. Spacecraft Engineering,2010,19(5):12-16
[7] 雷英俊,张明,井元良,等. 一种用于深空探测的航天器能源共用方法[J]. 航天器工程,2014,23(1):58-62
LEI Y J,ZHANG M,JING Y L,et al. A method of power sharing for deep space probe[J]. Spacecraft Engineering,2014,23(1):58-62
[8] KUBOTA T,HASHIMOTO T,SAWAI S,et al. An autonomous navigation and guidance system for MUSES-C asteroid landing[J]. Acta Astronautica,2003,52(2):125-131
[9] ACCOMAZZO A,FERRI P,LODIOT S,et al. Rosetta operations at the comet[J]. Acta Astronautica,2015,115:434-441
[10] CARDELL G,ULLOA-SEVERINO A,GROSS M. The design and operation of the Dawn power system[C]//Proceedings of the 10th annual international energy conversion engineering conference. Washington D.C.:AIAA,2012:414-420.
[11] JENSEN H,LAURSEN J.Power conditioning unit for Rosetta/Mars express[C] //Proceedings of the 6th European space power conference. Paris:ESA,2002:249-257.
[12] WITASSE O. Jupiter Icy Moons Explorer(JUICE),IAC-16-A7.2.4[C]//67th International Astronautical Congress. Paris:IAF,2016.
[13] 刘治钢,蔡晓东,陈琦,等. 采用MPPT 技术的国外深空探测器电源系统综述[J]. 航天器工程,2011,20(5):105-110
LIU Z C,CAI X D,CHEN Q,et al. Overview of space power system design using MPPT for deep space spacecraft[J]. Spacecraft Engineering,2011,20(5):105-110
[14] 曾毅,崔波. 一种新的航天器电源系统拓扑[J]. 航天器工程,2009,18(5):95-99
ZENG Y,CUI B. A novel topology of spacecraft electric power system[J]. Spacecraft Engineering,2009,18(5):95-99
[15] 褚英志,李秀伟,周晓东. 火星探测关键技术分析[J]. 测试技术学报,2007,21(6):63-66
CHU Y Z,LI X W,ZHOU X D. Key technology analysis for Mars explorationl[J]. Journal of Test and Measurement Technology,2007,21(6):63-66
[16] 刘治钢,王飞,陈燕,等. 火星表面环境对太阳电池阵设计影响分析与对策[J]. 航天器工程,2016,25(2):39-45
LIU Z G,WANG F,CHEN Y,et al. Impact analysis and solution of solar array design in martian surface environment[J]. Spacecraft Engineering,2016,25(2):39-45
[17] BARLOW N G. 火星:关于其内部、表面和大气的引论[M]. 北京:科学出版社,2010:17-20.
BARLOW N G. Mars:an introduction to its interior,surface and atmospherel,M]. Beijing:Science Press,2010:17-20.
[18] LOCHE D.Mars express and venus express power subsystem in-flight behavior[C]//Proceedings of the 8th European Space Power Conference. Paris:ESA,2008:1-7.
[19] JOHNSON T V,YEATES C M,COLIN GALILEO L. Exploration of Jupiter’s system,NASA SP-479[R].Washington D.C.:NASA,1985.
[20] MELTZER M. Mission to Jupiter:a history of the Galileo project,NASA SP-2007-4231[R].Washington D.C.:NASA,2007.
[21] KOWALKOWSKI T,JOHANNESEN J,LAM T. Launch period development for the Juno mission to Jupiter[C]//AIAA/AAS Astrodynamics Specialist Conference and Exhibit. Washington D.C:AIAA,2008:1-13.
[22] DAWSON S F,STELLA P,ALPINE W. JU-NO photovoltaic power at Jupiter[C]//10th International Energy Conversion Engineering Conference. Washington D.C.:AIAA,2012.
[23] 张磊,田百义,周文艳,等. 木星系多目标探测轨道设计研究[J]. 航天器工程,2018,27(1):31-36
ZHANG L,BAIYI T,ZHOU W Y,et al. Research on Jovian system tour trajectory design[J]. Spacecraft Engineering,2018,27(1):31-36
[24] The JUICE Science Study Team.JUICE exploring the Emergence of habitable worlds around gas giants[R]. Paris:ESA,2011.
[25] WITASSE O. Jupiter icy Moons explorer(JUICE)[C]//67th International Astronautical Congress. Paris:IAF,2016.
[26] 王建昭,田岱,张庆祥,等. 木星环绕探测任务中的内带电风险评估[J]. 深空探测学报,2017,4(6):564-570
WANG J Z,TIAN D,ZHANG Q X,et al. Internal charging evaluation in Jupiter exploration mission[J]. Journal of Deep Space Exploration,2017,4(6):564-570
[27] 张文佳,刘治钢,张晓峰,等. 一种深空探测器太阳能电池系统设计方法:中国,201910291479.9[P]. 2019-04-12.
ZHANG W J,LIU Z G,ZHANG X F,et al.A Design method for solar array system of deep space exploration:China,201910291479.9[P]. 2019-04-12.
[28] 马世俊. 卫星电源技术[M]. 北京:中国宇航出版社,2001: 254-255.
MA S J. Satellite power technology[M]. Beijing:China Astronautics Press,2001:254-255.
[29] 李国欣. 航天器电源系统技术概论[M]. 北京:中国宇航出版社,2008.
LI G X.Spacecraft power system technology[M]. Beijing:China Astronautics Press,2008.
[30] 张建中,任保国,王泽深. 放射性同位素温差发电器在深空探测中的应用[J]. 宇航学报,2008,29(2):45-47
ZHANG J Z,REN B G,WANG Z S. Study on radioisotope thermoelectric generators in deep space exploration program[J]. Journal of Astronautics,2008,29(2):45-47
[31] 康海波. 同位素电源系统研究进展[J]. 电源技术,2011,35(8):1031-1033
KANG H B. Review of isotopic power system[J]. Chinese Journal of Power Sources,2011,35(8):1031-1033
[32] SCHMIDT G R,SUTLIFF T J,DUDZINSKI L A. Radioisotope power:a key technology for deep space exploration[M]. New York:InTech,201l.
[33] 侯欣宾,王立. 美国空间同位素能源装置发展现状[J]. 航天器工程,2007,16(2):41-49
HOU X B,WANG L. Introduction of USA space radioi sotope power systems[J]. Spacecraft Engineering,2007,16(2):41-49
[34] 蔡善钰,何舜尧. 空间放射性同位素电池发展回顾和新世纪应用前景[J]. 核科学与工程,2004,24(2):97-104
CAI S Y,HE S Y. Retrospection of development for radioisotope power systems in space and its prospect of application in new century[J]. Chinese Journal of Nuclear Science and Engineering,2004,24(2):97-104
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