Effects of Geometric Parameters on Performance of Counter-Flow Vectoring Nozzle in Subsonic Conditions

Journal of Propulsion Technology ›› 2014, Vol. 35 ›› Issue (3): 305-313.

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Effects of Geometric Parameters on Performance of Counter-Flow Vectoring Nozzle in Subsonic Conditions

College of Mechanical Engineering and Applied Electronics Technology, Beijing University of Technology, Beijing 100124, China;College of Mechanical Engineering and Applied Electronics Technology, Beijing University of Technology, Beijing 100124, China;College of Mechanical Engineering and Applied Electronics Technology, Beijing University of Technology, Beijing 100124, China

Published:2021-08-15

亚声速条件下外形参数对逆流矢量喷管性能影响的模拟研究

刘赵淼,徐迎丽,申峰

北京工业大学机械工程与应用电子技术学院,北京 100124;北京工业大学机械工程与应用电子技术学院,北京 100124;北京工业大学机械工程与应用电子技术学院,北京 100124

作者简介:刘赵淼(1970—) ,女,博士,教授,研究领域为计算流体力学和微流体力学。E-mail:lzm@bjut.edu.cn
基金资助:
北京市自然科学基金重点项目,北京市教育委员会科技计划重点项目(KZ201210005003)。

Abstract

Abstract: To provide a theoretical basis for the selection of counter-flow thrust vectoring nozzle geometry,numerical simulation method was applied to study the internal flow structure and performance of the counter-flow thrust vectoring nozzle with suction angle, suction collar horizontal height and vertical height in zero attack angle and subsonic conditions. The changes of thrust vector angle, resultant thrust ratio, and secondary mass flow ratio were obtained. Research results indicate that both suction angle and collar vertical height have less effects on the change of the counter-flow vectored nozzle thrust vector angle. And when suction angle and collar vertical height changes respectively, the angular deviation between their maximum and minimum vector angle is not more than 0.35°. Resultant thrust ratio decreases with the increasing of suction angle and collar vertical height. When suction angle changes, resultant thrust ratio is about 0.778and the change value is not more than 0.001. Resultant thrust ratio is in the range from 0.77to 0.84as vertical height changes. Mass flow ratio is less affected by suction angle and collar vertical height. Jet attachment easily occurs when horizontal height is too small. With increasing of horizontal height, thrust vector angle increases, and it can achieve the maximum value 7°. On the contrary, resultant thrust ratio decreases and it is in the range of 0.75~0.87. During the procedure of increasing horizontal height, suction flow shifts up to 2% from co-flow to counter-flow and mass flow ratio increases. The overall performance of thrust vectoring nozzle significantly decreases compared with no outflow.

Key words: Counter-flow; Vectoring nozzle; Suction angle; Horizontal height; Vertical height

摘要： 为逆流矢量喷管几何构型选取提供理论依据,采用数值模拟方法研究了零攻角亚音速条件下抽吸角、横向高度及垂直段高度等外套管外形参数对逆流推力矢量喷管内部流动结构及矢量性能的影响,得到了推力矢量角、合成推力系数、二次流流量比等随外形参数的变化规律。研究结果表明:抽吸角及外套管垂直段高度对逆流矢量喷管的推力矢量角变化均无大的影响,且抽吸角及外套管垂直段高度分别变化时,两者的最大矢量角和最小矢量角的角度差均不超过0.35°,合成推力系数均随两者增大而减小,抽吸角变化时合成推力系数在0.778左右,其变化值不超过0.001,垂直段高度变化时合成推力系数范围为0.77~0.84,而流量比受抽吸角及垂直段高度变化的影响均微小；横向高度较小时,主流易发生附体,随其增大,推力矢量角增加,最大值达7°,而合成推力系数随之减小,范围为0.75~0.87,抽吸二次流流向由同向转变为逆向,流量增大,最大流量比为2%；推力矢量喷管的整体性能较无外流时明显下降。 

关键词: 逆流;矢量喷管;抽吸角;横向高度;垂直段高度 

LIU Zhao-miao, XU Ying-li, SHEN Feng. Effects of Geometric Parameters on Performance of Counter-Flow Vectoring Nozzle in Subsonic Conditions[J]. Journal of Propulsion Technology, 2014, 35(3): 305-313.

刘赵淼,徐迎丽,申峰. 亚声速条件下外形参数对逆流矢量喷管性能影响的模拟研究[J]. 推进技术, 2014, 35(3): 305-313.

References

[1] 范文正,李明.推力矢量喷管现状和发展趋势[J].航空科学技术,2006,1:21-22.
[2] 贾东兵,周吉利,邓洪伟.固定几何气动矢量喷管技术综述[J].航空发动机,2012,8(6):29-33-42.
[3] 宋亚飞,高峰,何至林.流体推力矢量技术[J].飞航导弹,2010,1:71-75.
[4] Deere K A.Summary of Fluidic Thrust Vectoring Research Conducted at NASA Langley Research Center[R].AIAA 2003-3800.
[5] 张相毅,王如根,周敏,等.单缝和双缝射流注入对二元喷管推力矢量的影响[J].推进技术,2007,8(6):629-632.(ZHANG Xiang-yi,WANG Ru-gen,ZHOU Min,et al.Effects of Single and Dual Injection Ports on Thrust Vector for 2D Nozzle[J].Journal of Propulsion Technology,2007,8(6):629-632.)
[6] 王菲,额日其太,李家军,等．二元喉道倾斜矢量喷管的数值模拟[J].北京航空航天大学学报,2010,36(4):388-390,3.
[7] Forliti D J, Strykowski P J.Flow Control Applications Using Countercurrent Shear[C].India,Kanpur:International Symposium on Recent Advances in Experimental Fluid Mechanics,2000.
[8] Rajavolu P P.Study of Confinement Effects in Countercurrent Shear Layers[D].Buffalo:the State University of New York at Buffalo,2007.
[9] Gillgrist R D,Forliti D J, Strykowski P J.On the Mechanisms Affecting Fluidic Vectoring Using Suction [J].Journal of Fluids Engineering,2007,9:91-99.
[10] Flamm J D.Experimental Study of a Nozzle Using Fluidic Counterflow for Thrust Vectoring[R].AIAA 98-3255.
[11] Dores D, Madruga S M, Krothapalli A, et al.Characterization of a Counterflow Thrust Vectoring Scheme on a Gas Turbine Engine Exhaust Jet[R].AIAA 2006-3516.
[12] Dores D.Feedback Control For Counterflow Thrust Vectoring with a Turbine Engine Experiment Design and Robust [D].Florida:The Florida State University,2005.
[13] 汪明生,杨建军.几何参数对逆流矢量喷管性能的影响研究[J].火箭推进, 2009,5(2):30-36.
[14] 汪明生,杨建军.逆流推力矢量喷管基本流动特征的数值研究[J].航空学报,2008,9(4):769-775.
[15] 邹欣华,王强.不同飞行条件下反流控制矢量喷管的内流特性[J].北京航空航天大学学报,2011,7(2):227-230,236.

Effects of Geometric Parameters on Performance of Counter-Flow Vectoring Nozzle in Subsonic Conditions

亚声速条件下外形参数对逆流矢量喷管性能影响的模拟研究

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