Studies on Distribution Characteristics of CurrentDensity on Anode Wall of Ion Thruster

doi:10.13675/j.cnki. tjjs. 180696

Journal of Propulsion Technology ›› 2019, Vol. 40 ›› Issue (11): 2633-2640.DOI: 10.13675/j.cnki. tjjs. 180696

• Electric Propulsion and Other Advanced Propulsion • Previous Articles

Studies on Distribution Characteristics of CurrentDensity on Anode Wall of Ion Thruster

Science and Technology on Vacuum Technology and Physics Laboratory,Lanzhou Institute of Physics,Lanzhou 730000,China

Published:2021-08-15

离子推力器放电室阳极壁面电流密度分布特性研究

宋莹莹¹,顾左¹,王蒙¹,赖承祺¹,郭伟龙¹

兰州空间技术物理研究所真空技术与物理重点实验室

作者简介:宋莹莹，硕士，研究领域为空间电推进技术与工程。E-mail：songyzly@163.com

Abstract

Abstract: In order to accurately grasp the current density distribution characteristics on the anode wall surface of the ion thruster discharge chamber, and to deeply understand the plasma motion characteristics near the anode wall, a specific implementation scheme for the near-anode wall plasma diagnosis was designed. Based on LIPS-200 ion thruster, plasma diagnostic test near the anode wall was carried out. The plasma parameters near the main magnetic pole were obtained, and the wall current density characteristics near the main magnetic poles were also obtained. The test results show that the plasma characteristics near the main magnetic pole at the anode wall of the LIPS-200 ion thruster are as follows: the plasma density range is from to , the electron temperature ranges from to , and the wall current density ranges from to . The electron temperature of the wall of the cylinder section is lower than that of the cone section, but the current density is higher, especially at the position of the middle pole piece，which is 3 times of the current density at the cathode pole piece and 2 times of the current density at the screen pole piece. The anode current is mainly lost at the middle pole piece of the discharge chamber.

Key words: Ion thruster;Anode wall;Current density distribution;Plasma diagnosis

摘要： 为了准确掌握离子推力器放电室阳极壁面电流密度分布特性，并深入理解阳极壁面处等离子体运动特性，设计了近阳极壁面等离子体诊断的具体实施方案，并基于LIPS-200离子推力器开展了近阳极壁面处等离子体诊断试验研究，得到了主要磁极附近壁面等离子体参数，并得到阳极壁面吸收电流密度分布特性。试验结果表明：LIPS-200离子推力器阳极壁面处主要磁极附近的等离子体密度范围为，测试点的电子温度范围为，壁面电流密度范围为；柱段壁面电子温度相对锥段较低，但电流密度较大，尤其在中间极靴位置电流密度最大，约为阴极极靴处电流密度的3倍，约为屏栅极靴处电流密度的2倍，阳极电流主要在放电室中间极靴处发生损失。

关键词: 离子推力器;阳极壁面;电流密度分布;等离子体诊断

SONG Ying-ying¹,GU Zuo¹,WANG Meng¹,LAI Cheng-qi¹,GUO Wei-long¹. Studies on Distribution Characteristics of CurrentDensity on Anode Wall of Ion Thruster[J]. Journal of Propulsion Technology, 2019, 40(11): 2633-2640.

宋莹莹,顾左,王蒙,赖承祺,郭伟龙. 离子推力器放电室阳极壁面电流密度分布特性研究[J]. 推进技术, 2019, 40(11): 2633-2640.

References

[1] Arakawa Y, Hamatani C. Analysis of Plasma Loss in a Ring-Cusp Ion Thruster[R]. AIAA87-1079.
[2] Sengupta A， Goebel D， Fitzgerald D， et al. Experimentally Determined Neutral Density and Plasma Parameters in a 30cm Ion Engine[R]. AIAA2004-3613.
[3] Sengupta A， Goebel D， Owens A G. Langmuir Probe Studies of Magnetic Confinement in an Ion Thruster Discharge Plasma[J]. Journal of Propulsion and Power， 2009， 25(2): 387-396.
[4] Herman D A， Gallimore A D. Comparison of Discharge Plasma Parameters in a 30cm NSTAR Type Ion Engine with and Without Beam Extraction[R]. AIAA2003-5162.
[5] Herman D A， Gallimore A D. Discharge Chamber Plasma Potential Mapping of a 40cm NEXT-Type Ion Engine [R]. AIAA2005-4251.
[6] Yamamoto N， Tomita K， Sugita K， et al. Measurement of Xenon Plasma Properties in an Ion Thruster Using Laser Thomson Scattering Technique[J]. Review of Scientific Instruments, 2012， 83（7）.
[7] Yamamoto N， Iwamoto M， Morita T， et al. Measurement of Electron and Neutral Atom Density Downstream of an Electric Propulsion[R]. AIAA2016-5036.
[8] Williams G JJr， Smith T B， Domonkos M T， et al. Laser-Induced Fluorescence Characterization of Ions Emitted from Hollow Cathodes[J]. IEEE Transactions on Plasma Science， 2000， 28(5): 1664-1675.
[9] 叶超，宁兆元，江美福，等. 低气压低温等离子体诊断原理与技术[M]. 北京：科学出版社， 2010.
[10] 王晓冬，张杨，王庆，等. 朗缪尔探针低温低压等离子体诊断[J]. 真空科学与技术学报， 2013， 33(10): 995-997.
[11] 菅井秀朗. 等离子体电子工程学[M]. 北京：科学出版社， 2002.
[12] Mahalingam S， Menart J A， Choi Yongjun， et al. Fully Coupled Electric Field/PIC-MCC Simulation Results of the Plasma in the Discharge Chamber of an Ion Engine[R]. AIAA2011-6071.
[13] Menart J A， Godar T， Ren Junxue， et al. Computational Speed-Up Techniques for a PIC-MCC Computer Model for Use in Modeling the Plasma in an Ion Engine Discharge Chamber[R]. AIAA2014-3613.
[14] 邹秀. 低温等离子体磁鞘特性的研究[D]. 大连：大连理工大学， 2005.
[15] 邹秀，刘惠平，谷秀娥. 磁化等离子体的鞘层结构[J]. 物理学报， 2008， 57: 5111-5116.
[16] 吴立其. 弱磁场中探针特性实验研究[D]. 合肥：中国科学技术大学， 2002.
[17] Goebel D M， Katz I. Fundamentals of Electric Propulsion: Ion and Hall Thrusters[M]. Pasadena: Jet Propusion Laboratory California Institute of Technology， 2008.
[18] Lieberman M A， Lichtenberg A J. Principles of Plasma Discharges and Materials Processing[M]. Hoboken: John Wiley & Sons， 1976.
[19] 顾左. 20cm Kaufman 氙离子推力器优化设计[D]. 兰州:兰州空间技术物理研究所， 2008.

Studies on Distribution Characteristics of CurrentDensity on Anode Wall of Ion Thruster

离子推力器放电室阳极壁面电流密度分布特性研究

PDF

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 0

Recommended Articles

Metrics

Comments