«Previous Article|Table of Contents|Next Article»

《火箭推进》[ISSN:1672-9374/CN:CN 61-1436/V]

Issue:

2012年03期

Page:

65-73

Research Field:

测控与试验

Publishing date:

Info

Title:

Design of measurement and control system for Hall electric propulsion longevity test bed

Author(s):

QIU Gang¹;  KANG Xiao-lu¹;  QIAO Cai-xia¹;  FENG Yan²

1. Shanghai Institute of Space Propulsion, Shanghai 200233, China;

Keywords:

Hall electric propulsion;  measurement and control system;  Delpi 7

PACS:

V439＋.4-34

DOI:

-

Abstract:

In allusion to the actual measurement and control requirements for Hall electric propulsion longevity test bed, IPC+DAQ 2205+PCI 1721 based hardware and Delphi 7+SQL based software of measurement and control system are built up and dissertated in detail in this paper. The high-performance data acquisition card DAQ 2205 and analog controlled quantity output card PCI 1721, both based on PCI bus, are used to realize the data aquisition and analog controlled quantity output for the measurement and control system. Multi-tasking and rapid response requirements are met by multi-threaded programming architecture. The running tests of the measurement and control system show that the control precision, response speed, reliability and friendly human-computer interaction can meet the specific requirements of longevity experiment for the Hall electric thruster.

References:

[1]GULCZINSKI F S, SPORES R A. Analysis of Hall-effect thrusters and ion engines for orbit transfer mission, AIAA 1996-2973[R]. USA：AIAA, 1996.
[2]LEIFER Stephanie, NOCA Muriel. Negative C3 launch options for solar system exploration, AIAA1998-3925[R]. USA：AIAA, 1998.
[3]GULCZINSKI F S, SPORES RA. In-space propulsion, AIAA 2003-2588[R]. USA：AIAA, 2003.
[4]RANDOLPH T M. Qualification of commercial electric propulsion systems for deep space mission, IEPC-2007-271[R]. Italy: IEPC, 2007.
[5]张乾鹏. 霍尔推力器等离子体羽流特性研究[D]. 上海: 上海航天技术研究院, 2010.
[6]GRYS Kristi de, WELANDER Ben, DIMICCO John, et al. 4.5 kW Hall thruster system qualification status, AIAA 2005-3682[R]. USA: AIAA, 2005.
[7]张乾鹏, 康小录. 用Xe和Kr作为霍尔电推进工质的比较[J]. 推进技术, 2011, 32(6): 828-834.
[8] 张乾鹏. 霍尔推力器羽流离子能量实验研究[J]. 火箭推进, 2010, 36(3): 10-14.
[9]汪礼胜, 唐德礼. 阳极层推力器的研究现状与发展趋势[J]. 火箭推进, 2006, 32(1): 24-29.
[10]宁中喜, 张世强, 于达仁. 低功率变截面通道霍尔推力器电离特性[J]. 推进技术, 2011(6): 794-798.
[11] 张斌, 毛根旺, 胡松启, 等. 固体微推力器气粒两相羽流场的数值模拟[J]. 固体火箭技术, 2011(3): 314-318.
[12]牛禄, 王宏伟, 杨威. 用于微小卫星推进装置等离子体推力器[J]. 上海航天, 2004(5): 39-43.
[13] 张红军, 王萍萍, 邱景辉, 等. 小型化电子回旋谐振微波离子推进器研究[J]. 宇航学报, 2007, 28(4): 209-213.
[14]Kurt A,Thomas E,Boris J,et al.Thruster stand for electric propulsion performance evaluation[J].Review of Scientific Instruments, 2006(77):1-9.
[15]John B. Advanced ion propulsion systems for affordable deep-space missions[J]. Acta Astronautica, 2003, 52(2-6): 309-316.
[16]Shufan W, Steyn W, Bordany R.In-orbit thruster calibra- tion techniques and experiment results with UoSAT-12[J]. Control Engineering Practice, 2004(12): 87-98.

Memo

Memo:

-

Common functions

Last Update: 1900-01-01