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

Issue:

2019年04期

Page:

16-25

Research Field:

研究与设计

Publishing date:

Info

Title:

Study on ignition technology of LO_X/LCH₄ attitude control engine

Author(s):

PAN Yili; ZHOU Haiqing; JI Lin; XU Hongbo

(Shanghai Engineering Research Center of Space Engine,Shanghai Institute of Space Propulsion,Shanghai 201112,China)

Keywords:

liquid oxygen and liquid methane;  electric ignition;  laser ignition;  attitude control engine

PACS:

V439

DOI:

-

Abstract:

In recent years,the propellant combination of liquid oxygen/liquid methane(LO_X/LCH₄)has become one of the important development directions of space chemical propulsion in the future due to its high specific impulse and excellent comprehensive performance.As a crucial technology of LO_X/LCH₄ attitude control engine,the ignition technology has an important influence on the starting reliability,response characteristics and impulse consistency of the engine.American and European countries have focused on the system integration and component technologies for the past few years,in which the United States has successfully conducted the system-level free flight test of LO_X/LCH₄ propulsion system.Technical demonstration of cryogenic propulsion system has been carried out in China,and research and development of main engine,attitude control engine and key components such as igniter,cryogenic tank and cryogenic valve have been conducted.In this paper,the ignition technology of LO_X/CH₄ attitude control engine was analyzed,screened and tested,and the feasibility of electric spark ignition and laser induced plasma ignition was verified.The experimental results show that both schemes can achieve reliable and repeatable ignition in a wide range of inlet conditions from gaseous phase to liquid phase,which prove that both ignition methods are feasible for LO_X/CH₄ engine.The boundary characteristics of spark energy,boundary characteristics of mixing ratio,response characteristics and impulse characteristics of reliable ignition are obtained,which provide a basis for the subsequent design of LO_X/CH₄ rocket engine.

References:

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Last Update: 2019-08-31