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

Issue:

2023年06期

Page:

90-99

Research Field:

目次

Publishing date:

Info

Title:

Analysis of optimum performance and maximum state control law of PATR engine

Author(s):

MA Wenyou¹;  MA Yuan¹;  MA Haibo¹;  YU Xuanfei²;  WU Yizhen¹

1.Xi'an Aerospace Propulsion Institute, Xi'an 710100, China; 2.School of Aerospace, Northwestern Polytechnical University, Xi'an 710072, China

Keywords:

pre-cooling combined cycle engine;  PATR;  control law;  optimum performance state;  maximum thrust state;  maximum specific impulse state

PACS:

V236

DOI:

-

Abstract:

In order to study the control law of the maximum state(the maximum thrust state and the maximum specific impulse state)of the pre-cooling air turbine rocket engine(PATR), a steady state variable condition model of PATR was established, and the influence of the control parameter on the performance parameters of the engine was studied.The optimal performance state(maximum thrust state and specific impulse state at the same time)of the engine was given on the premise that the total hydrogen flow rate is proposed.On this basis, the control laws of the maximum thrust state and the maximum specific impulse state of the engine were proposed, and the flight envelope of the engine in the maximum thrust state and the maximum specific impulse state were given, respectively.The results show that the thrust of PATR engine will increase with the increase of main combustion chamber temperature, helium turbine inlet temperature and nozzle throat area when the total hydrogen flow rate is constant.When the temperature of the main combustion chamber, the inlet temperature of the helium turbine and the throat area of the nozzle are constant, the thrust increases with the increase of the total hydrogen flow.The optimal performance state control law of PATR engine with given total hydrogen flow rate is as follows: the sum of the residual gas coefficient of the precombustion chamber and the main combustion chamber is equal to 1, the inlet temperature of the helium turbine and the throat area of the tail nozzle get the maximum value, and the thrust and specific impulse of the engine reach the maximum at the same time, and the engine is in the optimal performance state.The maximum thrust state control rules of the PATR engine are as follows.The sum of the residual gas coefficient of the precombustion chamber and the main combustion chamber is equal to 1, the maximum value of the inlet temperature of the helium turbine and the throat area of the tail nozzle are obtained respectively.The total hydrogen flow rate should be increased as far as possible, when the total hydrogen flow rate is increased, the engine will touch the air compressor conversion speed or the maximum pressure boundary of the helium circuit.Safety boundary contact order is determined by engine characteristics and flow conditions.The maximum specific impulse state control law of PATR engine is as follows. The sum of the residual gas coefficient of the precombustion chamber and the main combustion chamber is equal to 1, the maximum of the inlet temperature of the helium turbine and the throat area of the tail nozzle are obtained, and the total hydrogen flow rate should be reduced as far as possible, when the total hydrogen flow rate is reduced, the engine will touch the surge boundary of the air compressor or the maximum temperature boundary of the precooler material.Safety boundary contact sequence is also determined by engine characteristics and incoming flow conditions.

References:

[1] 邹正平,王一帆,额日其太,等.高超声速强预冷航空发动机技术研究进展[J].航空发动机,2021,47(4):8-21.
[2] 马晓秋.预冷吸气组合发动机研究进展与关键技术分析[J].科技导报,2020,38(12):85-95.
[3] 陈操斌,郑日恒,马同玲,等.带有闭式布雷顿循环的预冷发动机特性研究[J].推进技术,2021,42(8):1749-1760.
[4] 姚尧,王占学,张晓博,等.液氢预冷吸气式发动机建模与循环特性分析[J].推进技术,2022,43(4):26-36.
[5] 唐靖博,杨庆春,徐旭.预冷组合循环发动机吸气式模态建模与性能分析[J].推进技术,2022,43(9):20-33.
[6] 董芃呈,唐海龙,陈敏.高超声速预冷发动机总体性能研究[J].航空动力,2020(3):23-26.
[7] VARVILL R,BOND A.The SKYLON spaceplane[C]//46th IAF Congress.Oslo:IAF,1995.
[8] MURRAY J J,GUHA A,BOND A.Overview of the development of heat exchangers for use in air-breathing propulsion pre-coolers[J].Acta Astronautica,1997,41(11):723-729.
[9] WILCOX E C,TROUT A M.Analysis of thrust augmentation of turbojet engines by water injection at compressor inlet including charts for calculating compression processes with water injection[R].NACA-TR-1006.
[10] WILLENS D.Liquid Injection on turbojet engines for high speed aircraft[Z].1955.
[11] SOHN R L.Theoretical and experimental studies of precompressor evaporative cooling for application to the turbojet engine in high altitude supersonic flight[R].WADC-TR-56-477.
[12] TANATSUGU N,SATO T,BALEPIN V,et al.Development study on ATREX engine[C]//Space Plane and Hypersonic Systems and Technology Conference.Reston,Virigina:AIAA,1996.
[13] SATO T,KOBAYASHI H,TANATSUGU N,et al.Development study of the precooler of the ATREX engine[C]//12th AIAA International Space Planes and Hypersonic Systems and Technologies.Reston,Virigina:AIAA,2003.
[14] 张蒙正,刘典多,马海波,等.PATR发动机关键技术与性能提升途径初探[J].推进技术,2018,39(9):1921-1927.
[15] 朱岩,马元,张蒙正.预冷空气涡轮火箭发动机氦循环系统的参数特性[J].航空动力学报,2018,33(8):2016-2024.
[16] 罗佳茂,杨顺华,母忠强,等.预冷型组合循环发动机技术[J].空气动力学学报,2022,40(1):190-207.
[17] 吴弈臻,马元,黄乐萍,等.预冷组合发动机中波瓣混流器对氢气/空气掺混性能影响[J].火箭推进,2021,47(6):76-85.
WU Y Z,MA Y,HUANG L P,et al.Influence of lobe mixer in pre-cooling air turbo rocket engine on hydrogen/air mixing performance[J].Journal of Rocket Propulsion,2021,47(6):76-85.
[18] 马文友,张文胜,马元,等.基于控制规律的PATR发动机典型工况点速度与高度特性分析[J].火箭推进,2022,48(6):35-43.
MA W Y,ZHANG W S,MA Y,et al.Analysis of velocity and altitude characteristics at typical operating conditions based on control law of PATR engine[J].Journal of Rocket Propulsion,2022,48(6):35-43.
[19] 玉选斐.预冷吸气式组合推进系统热力循环及控制规律研究[D].哈尔滨:哈尔滨工业大学,2020.
YU X F.Research on thermodynamic cycle and control law of precooled airbreathing propulsion system[D].Harbin:Harbin Institute of Technology,2020.
[20] 高远,陈玉春,史新兴.深冷组合发动机吸气模态最大状态控制规律研究[J].推进技术,2020,41(12):2659-2669.
[21] 胡骏.航空叶片机原理[M].2版.北京:国防工业出版社,2014.

Memo

Memo:

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Common functions

Last Update: 1900-01-01