A Computational Study of Thrust Vectoring Control Using Dual Throat Nozzle 被引量：7

A Computational Study of Thrust Vectoring Control Using Dual Throat Nozzle

导出

摘要 Dual throat nozzle (DTN) is fast becoming a popular technique for thrust vectoring. The DTN is designed with two throats, an upstream minimum and a downstream minimum at the nozzle exit, with a cavity in between the upstream throat and exit. In the present study, a computational work has been carried out to analyze the performance of a dual throat nozzle at various mass flow rates of secondary flow and nozzle pressure ratios (NPR). Two-dimensional, steady, compressible Navier-Stokes equations were solved using a fully implicit finite volume scheme. The present computational results were validated with available experimental data. Based on the present results, the control effectiveness of thrust-vectoring is discussed in terms of the thrust coefficient and the coefficient of discharge. Dual throat nozzle （DTN） is fast becoming a popular technique for thrust vectoring. The DTN is designed with two throats, an upstream minimum and a downstream minimum at the nozzle exit, with a cavity in between the upstream throat and exit. In the present study, a computational work has been carried out to analyze the performance of a dual throat nozzle at various mass flow rates of secondary flow and nozzle pressure ratios （NPR）. Two-dimensional, steady, compressible Navier-Stokes equations were solved using a fully implicit finite volume scheme. The present computational results were validated with available experimental data. Based on the present results, the control effectiveness of thrust-vectoring is discussed in terms of the thrust coefficient and the coefficient of discharge.

作者 Choon Sik Shin Heuy Dong Kim Toshiaki Setoguchi Shigeru Matsuo

机构地区 Department of Mechanical Engineering Department of Mechanical Engineering

出处《Journal of Thermal Science》 SCIE EI CAS CSCD 2010年第6期486-490,共5页 热科学学报（英文版）

关键词推力矢量控制计算结果双喷嘴 STOKES方程推力矢量技术有限体积格式服务机构实验数据 Compressible Flow, Dual Throat Nozzle, Thrust Vector Control, Shock Wave, Supersonic Flow

分类号 V233.2 [航空宇航科学与技术—航空宇航推进理论与工程]

引文网络
相关文献

参考文献12

1Bursey, R. and Dickinson, R.: Flight Test Results of the F-15 SMTD Thrust Vectoring/Thrust Reversing Exhaust Nozzle, AIAA Paper, 90-1906, Orlando, FL, USA, (1990).
2Regeniee, V., Gatlin, D., Kempel, R. and Matheny, N.: The F-18 High Alpha Research Vehicle: A High Angle- of-Attack Testbed Aircraft, NASA TM, 104253, Spring- field, VA, USA, (1992).
3Jung, S. J., Kim, H. D., Alan, J. M. and Jung, D. H.: Study of the Thrust Vector Control Using a Secondary Flow Injection, Proc. of The Korean Society of Propulsion Engineers(KSPE) Spring Annual Meeting, Seoul, Korea, pp. 14-15, (2002).
4Green, C. J. and Mc Cullough, M. Jr.: Liquid Injection Thrust Vector Control, AIAA Journal, Vol.1, No.3, pp.573-578, (1963).
5Jung, S. J., Kumar, V. R. S. and Kim, H. D.: A Study of Thrust-Vectoring Nozzle Flow Using Coflow-Counter- flow Concept, Proc. of The Korean Society of Mechanical Engineers(KSME) Fall Conference, Muju, Korea, pp.592-597, (2003).
6Flamm, J. D., Deere, K. A., Mason, M. L., Berrier, B. L. and Johnson, S. K.: Experimental Study of an Axisymmetric Dual Throat Fluidic Thrust Vectoring Nozzle for Supersonic Aircraft Application, AIAA Paper, 2007-5084, Hampton, VA, USA, (2007).
7Shin, C. S., Kim, H. D.: A Study on the Supersonic Flow Characteristics Through a Dual Throat Nozzle, Journal of The Korean Society of Propulsion Engineers(KSPE), (2010)(to be published).
8Berrier, Bobby L., Leavitt, Laurence D. and Bangert, Linda S.: Operating Characteristics of the Multiple Critical Venturi System and Secondary Calibration Nozzles Used for Weight-Flow Measurements in the Langley 16-Foot Transonic Tunnel, NASA TM-86405, Washington, D.C., USA, (1985).
9Giuliano, V. J. and Wing, David J.: Static Investigation of a Fixed-Aperture Exhaust Nozzle Employing Fluidic Injection for Multiaxis Thrust Vector Control, AIAA Paper, 97-3149, Hampton, VA, USA, (1997).
10Yagle, P. J., Miller, D. N., Ginn, K. B. and Hamstra, J. W. Demonstration of Fluidic Throat Skewing for Thrust Vectoring in Structurally Fixed Nozzles, 2000-GT-0013, Fort Worth, TX, USA, (2000).

同被引文献52

1ZHU Laitao,LI Yong,ZHANG Junxiang,WU Jing,TAI Xiao,ZHOU Jianguo.Application of Contact Graph Routing in Satellite Delay Tolerant Networks[J].空间科学学报,2015,35(1):116-125. 被引量：5
2金捷,赵景芸,张明恒,赖传兴.轴对称矢量喷管内流特性的模型试验[J].推进技术,2005,26(2):144-146. 被引量：13
3李晓明,伏宇.轴对称矢量喷管机构优化设计[J].燃气涡轮试验与研究,2006,19(3):1-5. 被引量：15
4谭慧俊,陈智.二元双喉道射流推力矢量喷管的数值模拟研究[J].航空动力学报,2007,22(10):1678-1684. 被引量：22
5王莉,袁茹,王三民,杨鑫.温固耦合下轴对称推力矢量喷管驱动机构的运动精度分析[J].机械科学与技术,2008,27(6):752-756. 被引量：10
6汪明生,杨平.双喉道推力矢量喷管的内流特性研究[J].推进技术,2008,29(5):566-572. 被引量：14
7王玉新.轴对称推力矢量喷管运动奇异性分析[J].航空动力学报,2009,24(1):162-168. 被引量：5
8林培基,高峰.推力矢量对防空导弹作战效能的影响[J].飞航导弹,2009(1):56-57. 被引量：14
9卿太木,廖华琳,朱川.轴对称双喉道流体控制矢量喷管三维数值模拟[J].燃气涡轮试验与研究,2009,22(3):14-18. 被引量：5
10梁利华,宁继鹏,史洪宇.基于AMESim与ADAMS联合仿真技术的减摇鳍液压系统仿真研究[J].机床与液压,2009,37(8):200-202. 被引量：16

引证文献7

1赵晨.能耗自选演进机制的延迟容忍网络路由算法[J].计算机系统应用,2017,26(2):158-162. 被引量：2
2夏雪峰,高峰,黄桂彬,杨文佳.双喉道推力矢量喷管研究进展[J].航空工程进展,2017,8(3):249-255. 被引量：2
3张昊,王汉平,窦建中.轴对称矢量喷管运动机构多学科耦合仿真[J].兵器装备工程学报,2018,39(2):30-35. 被引量：3
4夏雪峰,高峰,黄桂彬.旁路式双喉道喷管气动矢量特性数值研究[J].航空工程进展,2017,8(4):423-430. 被引量：1
5柳亚冰,符大伟,蔡常鹏,孙丰勇,张海波.轴对称矢量喷管空间运动学建模仿真[J].航空发动机,2020,46(6):34-40. 被引量：5
6夏雪峰,高峰,张倩,马岑睿.扩张段射流对旁路式双喉道喷管矢量特性的影响研究[J].空气动力学学报,2021,39(4):51-58. 被引量：1
7王新恺,项坤,田晶,赵建策,李文灏,庞博文.轴对称矢量喷管平移控制系统运动学建模仿真[J].机械科学与技术,2024,43(4):729-736.

二级引证文献13

1王国玲,杨文忠,张振宇,夏扬波,殷亚博,杨慧婷.移动传感网中基于虚拟货币的路由策略[J].计算机应用,2018,38(9):2587-2592. 被引量：1
2张凯,李琦,汪明生.内膨胀式推力矢量喷管及其性能研究[J].机械制造与自动化,2019,48(4):39-41.
3张海波,蔡常鹏,姜尚彬.轴对称矢量喷管作动系统矢量偏转受载特性研究[J].南京航空航天大学学报,2020,52(4):523-531. 被引量：2
4佟川,李昂贤,王启材,张琦祥,许兰迪,王炫.基于Coanda效应的无源流体推力矢量喷管研究[J].科技资讯,2021,19(9):94-96. 被引量：1
5夏雪峰,高峰,张倩,马岑睿.扩张段射流对旁路式双喉道喷管矢量特性的影响研究[J].空气动力学学报,2021,39(4):51-58. 被引量：1
6庞海.基于DTN算法的采摘机器人控制系统可行性研究[J].农机化研究,2022,44(5):119-123. 被引量：1
7王建明,夏瑄泽,刘晓东,王成军.新型引射式逆流控制矢量喷管的气动性能[J].滨州学院学报,2022,38(2):5-12.
8Changpeng CAI,Yerong PENG,Qiangang ZHENG,Haibo ZHANG.Vector deflection stability control of aero-engine based on linear active disturbance rejection[J].Chinese Journal of Aeronautics,2022,35(8):221-235. 被引量：2
9王建明,夏瑄泽,刘晓东.单侧延伸壁面逆流控制矢量喷管的气动性能研究[J].设备管理与维修,2022(17):24-27.
10李有德,昝风彪,赵志刚,邓俊飞.轴对称矢量喷管喉道运动学精度分析及实验[J].机械科学与技术,2023,42(4):651-656. 被引量：1

1吴涛.更锋利的格斗短刃世界第四代近距空空导弹评析[J].现代兵器,2006,0(11):38-42. 被引量：2
2宋振峰.推力矢量技术在空空导弹上的应用[J].航空兵器,1993(3):26-28. 被引量：4
3Dong, Jian-Wei, Xu, Wei-Lin, Deng, Jun, Liu, Shan-Jun, Wang, Wei, Qu, Jing-Xue.NUMERICAL SIMULATION OF TURBULENT FLOW THROUGH THROAT-TYPE ENERGY-DISSIPATORS[J].Journal of Hydrodynamics,2002,14(3):135-138. 被引量：9
4匡中.排队论在医院管理中的应用[J].中国卫生统计,1993,10(3):54-54. 被引量：2
5CHENG YALI.the Perfect Time For CIFTIS[J].China International Business,2012(5):27-27.
6Nithurshan Nadarajah,Benjamin Steven Vien,Wing Kong Chiu,L. R. Francis Rose.Computational Study of the A0 Scattered Field Due to an Edge Delamination[J].Journal of Mechanics Engineering and Automation,2015,5(4):229-236.
7栗晶,蒋贵丰,柳朝晖,郑楚光.气固两相对撞流颗粒运动特性分析[J].工程热物理学报,2014,35(11):2210-2215. 被引量：6
8C. HEILIGER,N. B. KAYE,F. Y. TESTIK.A computational study of the role of particle size standard deviation on the collision frequency in differential settling[J].International Journal of Sediment Research,2013,28(1):34-45. 被引量：1
9黄大明,黄世伟,覃频频.汽车维修排队系统的确定与优化[J].广西大学学报（自然科学版）,1998,23(4):388-392. 被引量：5
10吴访升,武晓松,高乃同,徐诚.应用TVD有限体积格式模拟枪弹绕流[J].南京理工大学学报,1996,20(5):417-420.

Journal of Thermal Science

2010年第6期

浏览历史

内容加载中请稍等...

A Computational Study of Thrust Vectoring Control Using Dual Throat Nozzle 被引量：7

参考文献12

同被引文献52

引证文献7

二级引证文献13

相关作者

相关机构

相关主题

浏览历史