Surface Charging Controlling of the Chinese Space Station with Hollow Cathode Plasma Contactor 被引量：1

Surface Charging Controlling of the Chinese Space Station with Hollow Cathode Plasma Contactor

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摘要 A highly charged manned spacecraft threatens the life of an astronaut and extravehicular activity, which can be effectively reduced by controlling the spacecraft surface charging. In this article, the controlling of surface charging on Chinese Space Station （CSS） is investigated, and a method to reduce the negative potential to the CSS is the emission electron with a hollow cathode plasma eontactor. The analysis is obtained that the high voltage （HV） solar array of the CSS collecting electron current can reach 4.5 A, which can be eliminated by emitting an adequate electron current on the CSS. The theoretical analysis and experimental results are addressed, when the minimum xenon flow rate of the hollow cathode is 4.0 sccm, the emission electron current can neutralize the collected electron current, which ensures that the potential of the CSS can be controlled in a range of less than 21 V, satisfied with safety voltage. The results can provide a significant reference value to define a flow rate to the potential controlling programme for CSS. A highly charged manned spacecraft threatens the life of an astronaut and extravehicular activity, which can be effectively reduced by controlling the spacecraft surface charging. In this article, the controlling of surface charging on Chinese Space Station （CSS） is investigated, and a method to reduce the negative potential to the CSS is the emission electron with a hollow cathode plasma eontactor. The analysis is obtained that the high voltage （HV） solar array of the CSS collecting electron current can reach 4.5 A, which can be eliminated by emitting an adequate electron current on the CSS. The theoretical analysis and experimental results are addressed, when the minimum xenon flow rate of the hollow cathode is 4.0 sccm, the emission electron current can neutralize the collected electron current, which ensures that the potential of the CSS can be controlled in a range of less than 21 V, satisfied with safety voltage. The results can provide a significant reference value to define a flow rate to the potential controlling programme for CSS.

作者蒋锴王先荣秦晓刚杨生胜杨威赵呈选陈益峰史亮汤道坦谢侃

机构地区 Science and Technology on Vacuum Technology and Physics Laboratory School of Aerospace Engineering

出处《Plasma Science and Technology》 SCIE EI CAS CSCD 2016年第7期727-731,共5页 等离子体科学和技术（英文版）

关键词 active potential control hollow cathode space station PLASMA solar array active potential control, hollow cathode, space station, plasma, solar array

分类号 V442 [航空宇航科学与技术—飞行器设计] O539 [理学—等离子体物理]

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Surface Charging Controlling of the Chinese Space Station with Hollow Cathode Plasma Contactor 被引量：1

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