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

Issue:

2023年02期

Page:

74-82

Research Field:

目次

Publishing date:

Info

Title:

Pressure control characteristics of switch-type storage and supply system regulated by Bang-Bang valve

Author(s):

GU Dalu;  ZENG Weiliang;  LEI Xiaofei;  JIN Hongrui

(Xi'an Aerospace Propulsion Institute, Xi'an 710100, China)

Keywords:

switch-type storage and supply system;  decompression module;  Bang-Bang valve;  pressure control characteristic;  decompression period

PACS:

V433

DOI:

-

Abstract:

In view of the technical difficulties of a radio-frequency ion electric propulsion xenon gas storage and supply system with long-term in-orbit and high precision decompression, a switch-type storage and supply system based on dual frictionless solenoid valve with Bang-Bang control is proposed.A pneumatic-control-electromagnetic-mechanical dynamic mathematical model of the decompression module is established, and a simulation model of working characteristics for the switch-type storage and supply system were established based on the AMESim platform is built.The variation of output pressure in the buffer tank with time for the decompression module of the storage and supply system is simulated.The effects of inlet pressure, buffer tank volume and intermediate chamber volume on pressure control characteristics are analyzed.The results show that the Bang-Bang valve can supply only a small amount of gas to the buffer tank during a decompression period by means of specific distributed switch control mode, which ensures that the output pressure of buffer tank can be continuously stable within the lower and upper limit of the set pressure, and achieves the long-term and high-precision decompression requirements of xenon gas from 550 kPa to 60 kPa.The inlet pressure has a great influence on the pressure control performance of decompression module.The higher the inlet pressure is, the lower the pressure control precision of storage and supply system is.The simulation results of decompression module of storage and supply system are in good agreement with the experimental results, which verifies the correctness of the simulation model and results.

References:

[1] 官长斌,沈岩,魏延明,等.面向空间电推力器的氙气供给系统发展综述及展望[J].宇航学报,2020,41(3):251-261.
[2] 胡竟,张天平,杨福全,等.电推力器气体比例流量控制技术的展望[J].真空与低温,2017,23(1):13-19.
[3] 谈萍,庞光庆,汤慧萍,等.霍尔电推进系统中的微流量控制器[J].功能材料,2010,41(S3):385-387.
[4] COREY R L,PIDGEON D J.Electric propulsion at space systems/loral[C]//31st International Electric Propulsion Conference.Ann Arbor,MI:University of Michigan,2009.
[5] VAN DER LIST M,VAN PUT P,YUCE V,et al.Next generation electrical propulsion feed systems and spin-off micro-propulsion components[C]//42nd AIAA/ASME/SAE/ASEE Joint Propulsion Conference and Exhibit.Reston,Virigina:AIAA,2006.
[6] FISHER J,WILSON A,KING D,et al.The development and qualification of a 4.5 kW Hall thruster propulsion system for GEO satellite applications[C]//27th International Electric Propulsion Conference.Pasadena,USA:[s.n.],2001.
[7] BARBARITS J.Xenon feed system development[C]//39th AIAA/ASME/SAE/ASEE Joint Propulsion Conference and Exhibit.Reston,Virigina:AIAA,2003.
[8] DANKANICH J,CARDIN J,DIEN A,et al.Advanced xenon feed system(AXFS)development and hot-fire texting[C]//45th AIAA/ASME/SAE/ASEE Joint Propulsion Conference and Exhibit.Reston,Virigina:AIAA,2009.
[9] AADLAND R,WILSON F,SCHWAB R,et al.Xenon propellant management system for 40 cm next generation ion thruster[C]//39th AIAA/ASME/SAE/ASEE Joint Propulsion Conference and Exhibit.Reston,Virigina:AIAA,2003.
[10] 汪旭东,李国岫,陈君,等.压电比例阀调节的氙气微推进系统流量特性仿真研究[J].推进技术,2019,40(12):2867-2873.
[11] GANAPATHI G,ENGELBRECHT C.Post-launch performance characterization of the xenon feed system on deep space one[C]//35th Joint Propulsion Conference and Exhibit.Reston,Virigina:AIAA,1999.
[12] 乔彩霞,康小录,邱刚,等.SJ-9A卫星霍尔电推进系统方案及飞行试验情况[C]//2014电力电子与航天技术高峰论坛.深圳:中国电工技术学会,2014.
[13] 蒲光荣,单磊,赵晓慧,等.泵压式多次起动发动机起动过程仿真研究[J].火箭推进,2019,45(5):17-24.
PU G R,SHAN L,ZHAO X H,et al.Simulation study on start-up processes of a multi-startup turbopump-fed rocket engine[J].Journal of Rocket Propulsion,2019,45(5):17-24.
[14] KOPPEL C,MARCHANDISE F,ESTUBLIER D.Robust pressure regulation system for the SMART-1 electric propulsion sub-system[C]//40th AIAA/ASME/SAE/ASEE Joint Propulsion Conference and Exhibit.Reston,Virigina:AIAA,2004.
[15] 贾光政,王宣银,刘昊,等.高压气动体积减压系统的Bang-Bang控制研究[J].液压与气动,2004(5):38-40.
[16] 贾光政,王宣银,吴根茂.高压气动容积减压系统研制[J].液压与气动,2003(8):14-16.
[17] 苟浩亮,潘海林.电推进系统压力调节单元的建模和分析[J].空间控制技术与应用,2008,34(5):49-52.
[18] 胡彬.基于Bang-Bang与PID控制的重型汽车ABS仿真研究与爆胎分析[D].石家庄:石家庄铁道大学,2014.
[19] 李明骏.集成Bang-Bang控制与常规控制的变工况控制:以电加热装置温度控制为例[D].北京:中国石油大学(北京),2016.
[20] 王宝龄.电磁电器设计基础[M].修订本.北京:国防工业出版社,1989.
[21] 袁洪滨,张民庆,孙彦堂.基于AMESim的直动式电磁阀动态仿真研究[J].火箭推进,2011,37(5):30-35.
YUAN H B,ZHANG M Q,SUN Y T.AMESim-based simulation analysis of dynamic characteristics of direct-acting solenoid valve[J].Journal of Rocket Propulsion,2011,37(5):30-35.
[22] 徐登伟,尤裕荣,袁洪滨,等.基于AMESim的先导膜片式电磁阀动态特性仿真[J].火箭推进,2017,43(4):41-45.
XU D W,YOU Y R,YUAN H B,et al.AMESim-based simulation analysis on dynamic characteristics of pilot-operated diaphragm solenoid valve[J].Journal of Rocket Propulsion,2017,43(4):41-45.

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