高速压气机叶栅纳秒脉冲等离子体流动控制仿真研究

doi:10.7527/S1000-6893.2013.0441

流体力学与飞行力学

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高速压气机叶栅纳秒脉冲等离子体流动控制仿真研究

张海灯, 李应红, 吴云, 赵勤

空军工程大学等离子体动力学重点实验室, 陕西西安 710038

收稿日期:2013-08-08 修回日期:2013-10-28 出版日期:2014-06-25 发布日期:2014-04-11
通讯作者: 李应红，Tel.：029-84787527 E-mail：yinghong_li@126.com E-mail:yinghong_li@126.com
作者简介:张海灯男，硕士研究生。主要研究方向：压气机叶栅等离子体流动控制。 E-mail：zhanghaideng@126.com；李应红男，硕士，教授，博士生导师。主要研究方向：等离子体流动控制。Tel：029-84787527 E-mail：yinghong_li@126.com
基金资助:
国家自然科学基金（50906100，51336011）；高等学校全国优秀博士学位论文作者专项资金资助（201172）；陕西省科学技术研究发展计划（2013KJXX-83）

Simulation Research of Nanosecond Pulsed Plasma Actuation Flow Control on High Speed Compressor Cascade

ZHANG Haideng, LI Yinghong, WU Yun, ZHAO Qin

Science and Technology on Plasma Dynamics Laboratory, Air Force Engineering University, Xi'an 710038, China

Received:2013-08-08 Revised:2013-10-28 Online:2014-06-25 Published:2014-04-11
Supported by:
National Natural Science Foundation of China (50906100,51336011); A Foundation for the Author of National Excellent Doctoral Dissertation of PR China (201172); Science and Technology Research Development Program of Shaanxi Provience(2013KJXX-83)

摘要/Abstract

摘要：

为研究纳秒脉冲等离子体气动激励在高亚声速来流条件下抑制压气机叶栅流动的分离机制，建立了基于唯象学的模拟纳秒脉冲介质阻挡等离子体气动激励特性的热源模型，在微秒量级时间尺度上分析研究了纳秒脉冲等离子体气动激励对叶栅通道流动结构的影响机制，并初步探究了纳秒脉冲等离子体气动激励的流动控制规律。研究结果表明：基于唯象学的热源模型能够较好地模拟纳秒脉冲等离子体气动激励诱导产生冲击波的气动特性；纳秒脉冲等离子体气动激励诱导产生的冲击波在高亚声速来流条件下能够对叶栅通道流动结构产生较大影响，其影响规律与激励特征和流场特性有关；高亚声速来流条件下，在叶栅通道中施加纳秒脉冲等离子体气动激励能够降低通道出口总压损失，改变流场结构。

关键词: 高亚声速, 纳秒脉冲, 冲击波, 流动结构, 流动分离

Abstract:

In order to research the mechanism of nanosecond pulsed plasma aerodynamic actuation flow control on a high subsonic speed compressor cascade, a heat source model based on phenomenology is established to simulate the characteristics of nanosecond pulsed dielectric barrier discharge. The influence of nanosecond pulsed plasma aerodynamic actuation on a compressor cascade flow field is studied in detail from a microsecond time scale perspective, and a preliminary research on the nanosecond pulsed plasma aerodynamic actuation flow control is performed. The results are: the heat source model based on phenomenology is successful in modeling the aerodynamic performance of the shock wave produced by nanosecond pulsed plasma aerodynamic actuation; under the condition of high subsonic speed, the shock wave produced by the nanosecond pulsed plasma aerodynamic actuation still has a dramatic impact on the structure of the compressor cascade flow field, and the impact is influenced by the actuation feature and the characteristics of the flow field; although the inlet flow is high subsonic speed, the nanosecond pulsed plasma aerodynamic actuation is capable of decreasing the total pressure loss at the outlet plane of the compressor cascade passage, and changing the structure of the flow field.

Key words: high subsonic speed, nanosecond pulse, shock wave, flow structure, flow separation

中图分类号:

V211.24

张海灯, 李应红, 吴云, 赵勤. 高速压气机叶栅纳秒脉冲等离子体流动控制仿真研究[J]. 航空学报, 2014, 35(6): 1560-1570.

ZHANG Haideng, LI Yinghong, WU Yun, ZHAO Qin. Simulation Research of Nanosecond Pulsed Plasma Actuation Flow Control on High Speed Compressor Cascade[J]. ACTA AERONAUTICAET ASTRONAUTICA SINICA, 2014, 35(6): 1560-1570.

参考文献

[1] Li Y H, Wu Y, Liang H, et al. Theory of enhancing the inhibition of flow separation with plasma shock flow control[J]. Chinese Science Bulletin, 2010, 55(31): 3060-3068.(in Chinese) 李应红, 吴云, 梁华, 等. 提高抑制流动分离能力的等离子体冲击流动控制原理[J]. 科学通报, 2010, 55(31): 3060-3068.

[2] Roupassov D V, Nikipelov A A, Nudnova M M, et al. Flow separation control by plasma actuator with nanosecond pulse periodic discharge, AIAA-2008-1367. Reston: AIAA, 2008.

[3] Kelley C L, Bowles P, Cooney J, et al. High Mach number leading-edge flow separation control using AC DBD plasma actuators, AIAA-2012-0906. Reston: AIAA, 2012.

[4] Jonathan P, Nicholas J B. High-speed flow control with electrical discharges, AIAA-2011-3104. Reston: AIAA, 2011.

[5] Nishihara M, Takashima K, Rich J W, et al. Mach 5 bow shock control by a nanosecond pulse surface dielectric barrier discharge[J]. Physics of Fluids, 2011, 23(6): 066101.

[6] Kang S. Investigation of the three dimensional flow within a compressor cascade with and without tip clearance. Brussel: Department of Fluid Mechanics, Vrije University Brussels, 1993.

[7] Zhao X H, Li Y H, Wu Y, et al. Numerical investigation of flow separation control on a highly loaded compressor cascade by plasma aerodynamic actuation[J]. Chinese Journal of Aeronautics, 2012, 25(3): 349-360.

[8] Guo S, Lu H W, Chen F, et al. Vortex control and aerodynamic performance improvement of a highly loaded compressor cascade via inlet boundary layer suction[J]. Experiments in Fluids, 2013, 54(7): 1-11.

[9] Zhao X H, Wu Y, Li Y H, et al. Separation structure and plasma flow control on highly loaded compressor cascade[J]. Acta Aeronautica et Astronautica Sinica, 2012, 33(2): 208-219. (in Chinese) 赵小虎, 吴云, 李应红, 等.高负荷压气机叶栅分离结构及其等离子体流动控制研究[J]. 航空学报, 2012, 33(2): 208-219.

[10] Flitti A, Pancheshnyi S. Gas heating in fast pulseddischarges in N₂-O₂ mixtures[J]. The European Physical Journal Applied Physics, 2009, 45(2): 21001.

[11] Jonathan P, Bisek N J. Numerical simulation of nanosecond-pulse electrical discharges, AIAA-2012-1025. Reston: AIAA, 2012.

[12] Unfer T, Boeuf J P. Modelling of a nanosecond surface discharge actutator[J]. Journal of Physics D: Applied Physics, 2009, 42(19): 194017.

[13] Likhanskii A V, Shneider M N. Modeling of dielectric barrier discharge plasma actuators driven by repetitive nanosecond pulses[J]. Physics of Plasmas, 2007, 14(7): 073501.

[14] Zhu Y F, Wu Y, Cui W, et al. Modeling of plasma aerodynamic actuation driven by nanosecond SDBD discharge[J]. Journal of Physics D: Applied Physics, 2013, 46(35): 355205.

[15] Che X K, Shao T, Nie W S, et al. Numerical simulation on a nanosecond-pulse surface dielectric barrier discharge in near space[J]. Journal of Physics D: Applied Physics, 2012, 45(14): 145201.

[16] Bisek N J, Jonathan P. Computational and experimental analysis of Mach 5 air flow over a cylinder with a nanosecond pulse discharge, AIAA-2012-0816. Reston: AIAA, 2012.

[17] Bisek N J, Boyd I D, Jonathan P. Numerical study of plasma-assisted aerodynamic control for hypersonic vehicles[J]. Journal of Spacecraft and Rockets, 2009, 46(3): 568-576.

[18] Popov I B, Nikipelov A, Pancheshnyi S, et al. Experimental study and numerical simulation of flow separation control with pulsed nanosecond discharge actuator, AIAA-2013-0572. Reston: AIAA, 2013.

[19] Aleksandrov N L, Kindysheva S V, Nudnova M M, et al. Mechanism of ultra-fast heating in a non-equilibrium weakly ionized air discharge plasma in high electric fields[J]. Journal of Physics D: Applied Physics, 2010, 43(25): 255201.

[20] Starikovskii A Y, Nikipelov A A, Nudnova M M, et al. SDBD plasma actuator with Nanosecond pulse-periodic discharge[J]. Plasma Sources Science and Technology, 2009, 18(3): 034015.

[21] Valentin I G, Gerhard J P. Dynamics of dielectric barrier discharges in different arrangements[J]. Plasma Sources Science and Technology, 2012, 21(2): 024010.

[22] Takashima K, Zuzeek T, Lempert W R, et al. Characterization of a surface dielectric barrier discharge plasma sustained by repetitive nanosecond pulses[J]. Plasma Sources Science and Technology, 2011, 20(5): 055009.

[23] Alexander H, Robert M, Karsten L, et al. A new approach for compressor endwall contouring, ASME Paper, GT-2011-0458. New York: ASME, 2011.

[24] Zhong J J, Gao H Y, Wu H, et al. Experimental investigation of flow-field in turbine cascade with different exit Mach number[J]. Journal of Engineering Thermophysics, 2013, 34(1): 45-49. (in Chinese) 钟兢军, 高海洋, 武卉, 等.变马赫数涡轮平面叶栅流场的实验研究[J].工程热物理学报, 2013, 34(1): 45-49.

[25] Liu Y W, Lu L P, Fang L, et al. Modification of Spalart-Allmaras model with consideration of turbulence energy backscatter using velocity helicity[J]. Physics Letters A, 2011, 375(24): 2377-2381.

E-mail：hkxb@buaa.edu.cn

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主管单位：中国科学技术协会主办单位：中国航空学会北京航空航天大学

高速压气机叶栅纳秒脉冲等离子体流动控制仿真研究

Simulation Research of Nanosecond Pulsed Plasma Actuation Flow Control on High Speed Compressor Cascade

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