平面感应式脉冲等离子体推力器高速脉冲气体供给阀的试验验证

doi:10.3969/j.issn.1674-1579.2018.03.008

空间控制技术与应用 ›› 2018, Vol. 44 ›› Issue (3): 50-55.doi: 10.3969/j.issn.1674-1579.2018.03.008

平面感应式脉冲等离子体推力器高速脉冲气体供给阀的试验验证

郭大伟，程谋森，李小康,车碧轩

国防科技大学，长沙 410073.

出版日期:2018-06-26 发布日期:2018-07-16
作者简介:作者简介：郭大伟（1987—），男，博士研究生，研究方向为微量脉冲气体供给技术；程谋森（1971—），男，教授，研究方向为束能与电磁推进技术；李小康（1983—），男，讲师，研究方向为束能与电磁推进技术；车碧轩（1990—），男，博士研究生，研究方向为磁流体力学仿真.
基金资助:
国家自然科学基金（51306203）、载人航天领域预先研究项目(0503)和湖南省自然科学基金青年基金(2018JJ3592).

Experiment Validation of a Novel Fast Pulsed Gas Valve for Inductive Pulsed Plasma Thruster

GUO Da-Wei, CHENG Mou-Sen, LI Xiao-Kang, CHE Bi-Xuan

National University of Defense Technology, Changsha 410073, China

Online:2018-06-26 Published:2018-07-16
Supported by:
Supported by National Natural Science Foundation of China(51306203),The Chinese Manned Space Engineering(0503),Natural Science Foundation of Hunan Province（2018JJ3592）.

摘要/Abstract

摘要： 摘要：本文针对国防科技大学的平面感应脉冲等离子体推力器（IPPT）原型机，设计了一种基于感应涡流斥力原理的快速脉冲气体供给阀.该阀采用截锥型铍青铜簧片作为执行构件，依靠簧片开启过程中弹性变形产生的弹力提供闭合所需回复力，避免了使用额外的回复力机构,使阀整体结构得到极大简化.性能测试结果表明，该阀的动作延迟时间小于35 μs.在阀腔气体压力为100 kPa时，最大单脉冲供气量为2.5 mg.响应特性和供气量特性均满足目前IPPT原型机的需求.此外，该阀可通过调节初始充电电压和阀腔气体压力实现供气量调节.该阀可以为后续推力器原型机多工况性能试验提供有力支持.

关键词: 关键词：高速脉冲阀, 响应特性, 供气量, 感应式脉冲等离子体推力器, 磁推进

Abstract: Abstract： A prototype inductive pulsed plasma thruster (IPPT) has been developed in the National University of Defense Technology. In order to support the thruster experimental research, a novel fast pulsed gas valve based on eddy current repulsion mechanism is designed and tested in this paper. A new and important design feature is the use of a conical diaphragm as the action part, which greatly contributes to the virtue of simplicity for adopting the resultant force of the diaphragm deformation as the closing force. Experiments are performed over a range of capacitor charge voltages and working gas pressures, and the results reveal that the delay before the valve action is less than 35 μs. The throughput of the valve, which has an upper limit of 2.5 mg argon with a fixed gas pressure of 100 kPa, can be easily regulated by adjusting the charge voltage and the gas pressure. The valve will become a useful tool to facilitate the IPPT research.

Key words: Keywords： fast pulsed valve；response characteristics；throughput characteristics；inductive pulsed plasma thruster, magnetic propulsion

中图分类号:

中图分类号： V439

郭大伟, 程谋森, 李小康, 车碧轩. 平面感应式脉冲等离子体推力器高速脉冲气体供给阀的试验验证[J]. 空间控制技术与应用, 2018, 44(3): 50-55.

GUO Da-Wei, CHENG Mou-Sen, LI Xiao-Kang, CHE Bi-Xuan. Experiment Validation of a Novel Fast Pulsed Gas Valve for Inductive Pulsed Plasma Thruster[J]. , 2018, 44(3): 50-55.

参考文献

参考文献［1］POLZIN K A. Comprehensive review of planar pulsed inductive plasma thruster research and technology［J］. Journal of Propulsion and Power, 2011,27(3): 513531. ［2］程谋森, 李小康, 车碧轩, 等. 感应式脉冲等离子体推力器技术研究综述［J］. 空间控制技术与应用, 2017, 43(5): 16. CHENG M S, LI X K, CHE B X, et al. Review of technology and research on inductive pulsed plasma thruster［J］. Aerospace Control and Application, 2017, 43(5): 16. ［3］DAILEY C L, LOVBERG R H. The PITMkV pulsed inductive thruster［D］. NASACR 191155, 1993. ［4］RUSSELL D, POYLIO J H, GOLDSTEIN W, et al. The Mark VIpulsed inductive thruster［C］ ∥Space Conference and Exhibit. San Diego, California: AIAA20046054, 2004. ［5］DAILEY C L, LOVBERG R H. Pulsed inductive thruster component technology［D］. ADA181068, 1987. ［6］POYLIO J H, RUSSELL D, GOLDSTEIN W, et al. Pulsed inductive thruster: flightscale proof of concept demonstrator［C］∥40th AIAA/ASME/SAE/ASEE Joint Propulsion Conference and Exhibit. Fort Lauderdale, Florida: AIAA20043640, 2004. ［7］DAILEY C L. Thrust measurement for a pulsed inductivethrusters［D］. AD702498, 1970. ［8］DAILEY C L, LOVBERG R H. Pulsed electromagnetic thruster［D］. AD735721, 1971. ［9］DAILEY C L, LOVBERG R H. Pulsed inductive thruster development［D］.ADA094884, 1979. ［10］郭大伟,程谋森,杨雄,等.高速重复脉冲式径向流动微量气体供给阀:中国, ZL201610413918.8［P］. 2017. 11. 28. GUO D W, MOU S C, YANG X, et al. Fast repetitive pulsed gas valve withtoroidal orifice: China, ZL201610413918.8［P］. 2017. 11. 28. ［11］刘玉魁.真空工程设计［M］. 北京：化学工业出版社, 2016：737738. LIU Y K. Design of vacuum engineering［M］. Beijing: Chemical Industry Press, 2016：737738. ［12］徐华舫. 空气动力学基础（下册）［M］.北京: 北京航空学院出版社, 1987： 7, 19. XU H F. Fundamentals of aerodynamics (Volume two)［M］. Beijing: Beijing University of Aeronautics and Astronautics Press, 1987: 7, 19.

[1]	尹文娟, 魏延明, 王健. 双组元统一推进系统气路动态特性分析[J]. 空间控制技术与应用, 2019, 45(2): 72-.
[2]	程谋森, 李小康, 车碧轩, 郭大伟. 感应式脉冲等离子体推力器技术综述[J]. 空间控制技术与应用, 2017, 43(5): 1-6.
[3]	尹文娟, 魏延明. 双组元统一推进系统气路稳定性分析[J]. 空间控制技术与应用, 2014, 40(6): 58-62.
[4]	姜华，陈健，汪旭东. 拍合式电磁阀动态响应仿真分析与试验验证[J]. 空间控制技术与应用, 2013, 39(4): 23-27.
[5]	尹文娟, 魏延明. 减压阀动态响应特性与稳定性研究[J]. 空间控制技术与应用, 2013, 39(3): 24-29.

平面感应式脉冲等离子体推力器高速脉冲气体供给阀的试验验证

Experiment Validation of a Novel Fast Pulsed Gas Valve for Inductive Pulsed Plasma Thruster

PDF (PC)

赞

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 5

Metrics

本文评价

推荐阅读 0