为考察火花放电等离子体射流控制机翼气动力矩的效果,在NACA0021平直机翼模型上安装火花放电等离子体射流发生器,通过改变射流发生器安装位置、射流角度及加载电参数,研究其控制机翼模型气动力矩的性能及机理。在NACA0021机翼模型近前缘处,布置2个火花放电等离子体射流发生器,采用气动力测量技术,在来流风速为20 m/s时测得,攻角-4°~10°时,滚转力矩系数最大减小了0.0024,攻角为12°~16°时,滚转力矩系数最大增加了0.0021;偏航力矩系数最大减小了0.00097。实验研究结果表明:等离子体射流可改变机翼模型横航向气动力矩,并可通过改变射流角度和加载电压频率调节等离子体射流控制横向气动力矩的效果。To investigate the control effect of Spark Discharge Plasma Jets(SPJs) on the aerodynamic moments of a wing, SPJ generators were used for active flow control experimental study on an NACA0021 straight wing model. The location of SPJ generators along the chord of the airfoil, the jet flow direction relative to the chord, and the driving voltage parameters were changed to research the control effect and mechanism of SPJ generators on the aerodynamic moments of a wing model. The aerodynamic moments were measured with a six-component balance at a wind speed of 20 m/s. Two SPJ generators, arranged near the leading edge, reduced the rolling moment coefficient by a maximum of 0.0024 for angles of attack-4°~10°, but increased the rolling moment coefficient by a maximum of 0.0021 for angles of attack 12°~16°. The yaw moment coefficient was reduced by a maximum of 0.00097. The results show that aerodynamic moments control of wings can be realized using SPJs. The control effect of SPJs on the aerodynamic moments is changeable by adjusting the driving voltage frequency and the jet flow direction relative to the chord.航空科学基金项目(20141368007);; 福建省自然科学基金项目(2010J01014

刘汝兵

林麒

牛中国

王晓光

王萌萌

郝明

English

Xiamen University Institutional Repository

? 33?? 3?    Vol.33   No.3 ?    ?    ?    ?  2016?  3  ?    Mar.   2016 ENGINEERING  MECHANICS 232 ?????????????????????2014-07-20??????2015-04-01 ?????????????(20141368007)????????????(2010J01014) ??????  ?(1954?)????????????????????????????(E-mail: qilin@xmu.edu.cn). ????????(1984?)???????????????????????????(E-mail: lrb@sa.buaa.edu.cn)? ???(1980?)???????????????????????????(E-mail: nzg9527@163.com)? ???(1988?)?????????????????????????????(E-mail: mengmeng2011xmu@gmail.com)? ?  ?(1990?)???????????????????????????(E-mail: hmok000@163.com)? ???(1984???????????????????????????????(E-mail: xgwang@xmu.edu.cn). ?????1000-4750(2016)03-0232-07  ???????????????????  ??? 1,2???? 3???? 1??  ? 1??  ? 1,2???? 1 (1. ???????????????? 361005?2. ??????????????????? 361005? 3. ??????????????? 150001) ?  ???????????????????????????? NACA0021????????????????????????????????????????????????????????????????????? NACA0021??????????? 2??????????????????????????????? 20 m/s???????4°~10°????????????? 0.0024???? 12°~16°????????????? 0.0021???????????? 0.00097???????????????????????????????????????????????????????????????????? ?????????????????????????????? ??????V211.7     ??????A        doi: 10.6052/j.issn.1000-4750.2014.07.0631 AERODYNAMIC MOMENTS CONTROL OF  WING MODEL USING PLASMA JET LIU Ru-bing1,2 , NIU Zhong-guo3 , WANG Meng-meng1 , HAO Ming1 , LIN Qi1,2 , WANG Xiao-guang1 (1. School of Physics and Mechanical & Electrical Engineering, Xiamen University, Xiamen 361005, China; 2. Fujian Key Laboratory of Plasma and Magnetic Resonance, Xiamen 361005, China; 3. Aerodynamics Research Institute, AVIC, Harbin 150001, China) Abstract:  To investigate the control effect of Spark Discharge Plasma Jets (SPJs) on the aerodynamic moments of a wing, SPJ generators were used for active flow control experimental study on an NACA0021 straight wing model. The location of SPJ generators along the chord of the airfoil, the jet flow direction relative to the chord, and the driving voltage parameters were changed to research the control effect and mechanism of SPJ generators on the aerodynamic moments of a wing model. The aerodynamic moments were measured with a six-component balance at a wind speed of 20 m/s. Two SPJ generators, arranged near the leading edge, reduced the rolling moment coefficient by a maximum of 0.0024 for angles of attack ?4°~10°, but increased the rolling moment coefficient by a maximum of 0.0021 for angles of attack 12°~16°. The yaw moment coefficient was reduced by a maximum of 0.00097. The results show that aerodynamic moments control of wings can be realized using SPJs. The control effect of SPJs on the aerodynamic moments is changeable by adjusting the driving voltage frequency and the jet flow direction relative to the chord. Key words:  plasma jet; spark discharge; wing; aerodynamic performance; aerodynamic moments control   ?    ?    ?    ? 233  ???????????????????????????[1?2]???????????????[3?4]?????????????????????????????????????????????????????????????????[5?6]????????????????? ? ? ? ? ? ? ? (DBD: Dielectric Barrier Discharges)???????????????????????????????????????????????????????????????[7]?????????????????????????????????????[8?12]? ???????????????????????? DBD ???????[8?12]??????????????????????????? ??[7]???????????????????????????????????DBD???????????????????? 10 m/s?????????????????????????? ??[13]?????????????????????????????????????????? SPJ (Spark Discharge Plasma Jet)?????????????????????????2003??????????????????????????????????????????[14]????????????????????????????????????????????????????????????????????????[13?16]?????????[16]?????????[16?17]?????????[18]???? ,??????? [19]?NASA[19]??????    ? [20 ? 21]???????????????(ONERA)[22?24]??? Ulsan??[25]???????????[26]???????[27]???????[28]????????????????????????????????????????????????????????????????????????[22?24]????[16?18,20]?????????????? ??????????????????????????????????????????????????????????????????????? ??? NACA0021 ???????????????????????? 20 m/s?????????????????????????????????????????????????NACA0021??????????????? 1  ???? 1.1  ???????????? ? 1???????????????????????????????????????????????AC/AC???????????????          ? 1  ???????????? Fig.1  Plasma jet experimental set-up ?????????? AC/AC ?????????(????? DPO2012)??????????????????????????????240 Hz~20 kHz??????? 5%~50%?????????????????????????? ? 2?????????????????????????????????????????????????? I?II?III ???????????????????? D=5 mm???Δ=8 mm(??? 157.08 mm3)???????? III?????? 0.7 mm????????? 0.7 mm????????????? II ? 0.7 mm?????? 0.3 mm????????????? I??????? III????????? ???????????? 300 Hz?600 Hz?900 Hz??????? 5%?10%?15%?? 3??? 600 Hz???? 10%?????????? U?????????????????????????? 2 mm????????? ?? 220 V/50 Hz ??? AC/AC ?????? ?????? ??? ?????? ??? 234 ?    ?    ?    ?          ? 2  ???????????????? Fig.2  Spark discharge plasma jet generator ????/(m/s) ? 3  ?????????? Fig.3  Average velocity of plasma jet flow 1.2  ?????? ????????????????????????????? (?? 4)??????NACA0021??? 2L=750 mm??? c=250 mm?????????????????? FL-5 ?????????????????????????? 1.5 m??????? 1.95 m???????0.19%????????? 53 m/s?  (a) ???  (b) ???????? ? 4  ???? Fig.4  Airfoil model ????? FL-5???? DBM-1?????????????6 ?????????????????? GJB 1061-91???????????????? 2  ??????? 2.1  ???????????????? ??? 4(b)????????????????????????????????????(x/c?y/L)?????θ (????????????????)???????????????????????????????? 1??? ? 1  ????????? Table 1  Configurations of SPJ generators  ??????x/c/(%) ????y/L/(%)???? θ/(°) ??????U/kV ????/(m/s) I 15 52 68 60 37.5 18.6 II 45 52 68 60 40.0 18.8 III 15 52 68 45 37.5 18.6 ??????????????f =300 Hz????τ =10%???????20 m/s????????4°~16°????????????Cl???????Cn(????5~?8)? ??????????????????? 2.1.1  ???????????? ??????????????????????????????????????????????? ?5??????????????x/c =15%?x/c =45%?(???1??I?II????)???????????????????Cl?Cn???????????? ON OFFl l lC C CΔ = −              (1) nON OFFn nC C CΔ = −              (2) ??? OFFlC ? ONlC ??????????????????????? OFFnC ? ONnC ??????????????????????? ??5(a)?????????????x/c=15%??????4°~10°??Cl????Cl?????????????????? lCΔ ????0.0005???????10°?????????????????????????????????????????????????????????????? III ???? ?? ?? ?? ??? I ??? II D Δ  ?    ?    ?    ? 235 ???????11°??Cl???????????????????????????????????14°?16°?ΔCl?0.002??????????????????????????????????????????????????????????????????????????  (a) ??????Cl???  (b) ?????? Cn??? ? 5  ???? I?II?ΔCl?ΔCn?α???? Fig.5  ΔCl?ΔCn vs α at states of I & II ??????????x/c =45%??????????????????Cl???????????16°?? lCΔ ????0.0006?????????????????????????????? ??5(b)??????6°~16°???????????????????????Cn??????x/c =45%????????????????????? x/c =15%???????ΔCn???0.0004?????4°~4°?????x/c =45%?????????????Cn???????????????????????????x/c =15%??????????????4°????ΔCn????0.00046? ???????????????????????????????????????????? 12°??????????????????? ?????????????????????????????????????????????????????????????????????????????????????????? 2.1.2  ???????????? ???????????????????????????????? ? 6 ??????θ =45°?θ =60°?????(??? 1?? III? I????)????????????????? Cl?Cn???????? =45°=60°?4 0 4 8 12 16?0.003?0.002?0.0010.0000.0010.0020.003?? /(°)  (a) ?????? Cl?? ?????????Cn (b) ?????? Cn?? ? 6  ???? III?I?ΔCl?ΔCn?α???? Fig.6  ΔCl?ΔCn vs α at states of III & I ? 6(a)???????????????????????????????????????? 12°????????? ???12°????????????????Cl ????????????????????θ =45°?????????????? lCΔ ???? 0.002?????? 0°~10°?????????????????????????? ???? 12°~16°????????????????????????????????????????????θ=45°??????????????ΔCl?????? 0.0015? ?6(b)???????0°~16°?????????????????????θ =60°??????Cn?????????????????θ =45°???????????????????????????Cn?????????????????????θ=60°???? nCΔ ????0.00068? 236 ?    ?    ?    ?  ?????????????????????????????????????? Cl ??????? Cn?????????????????????θ?????????????????????? 2.2  ????????????????? ????????????????????????????????????????????????????????????? ?2????????????????????????????U???f ????τ ?????? ???? 2.1 ??????????????????? x/c =15%?y/L =52%?68%????????? θ =45°? ? 2  ???????? Table 2  Electrical parameters of SPJ actuators ?? f/ Hz ???τ/(%) ?????? U/ kV ????/(m/s)300 10 37.5 18.6 600 10 45 21.1 900 10 50 22.3 300 5 42.5 14.3 300 15 35 13.8 2.2.1  ?????????????? ????????????? f???????????????????(?? 7)?  (a) ??????Cl?? ?? /(°)?????????Cn?4 0 4 8 12 16?0.0015?0.0010?0.00050.0000300 Hz600 Hz900 Hz (b) ?????? Cn?? ? 7  ???? f?ΔCl?ΔCn?α???? Fig.7  ΔCl?ΔCn vs α at different frequencies f  ? 7(a)??????? τ ?????????f???????????? Cl ????????????????????12°????????????????????12°??Cl????????????????12°??Cl?????????????? f ?600 Hz?900 Hz???????????????????????????f=300 Hz????f =600 Hz????Cl?????????12°??lCΔ ???0.0024????12°??ΔCl???0.0021? ??τ???f??????????????????????? Cn??????????????????(? 7(b))?????????4°?4°?6°??????????????????????????????? f =600 Hz ????????????????? nCΔ ??? 0.00097? ???????????? f ??????????????????????????????????????????????? f ?????? 2.2.2  ??????????????? ?????? f ???????? τ??????????????????????????????????(?? 8)????????? ?? 7 ??????????????? 12°????Cl???? lCΔ ??? 0.0021????12°??Cl????ΔCl??? 0.0018??????????????????????(?? 8(a))? ?????????? Cn??????????????? τ?????????????? 8(b)????−4°?2°?4°?14°??τ=10%???????????????? 0°?2°?16°???? τ=5%?????????????  (a) ?????? Cl??  ?    ?    ?    ? 237  (b) ?????? Cn?? ? 8  ????? τ ?ΔCl?ΔCn?α???? Fig.8  ΔCl?ΔCn vs α at different duty cycles τ ??????????? f ?????????????????????f = 600Hz???????? Cl?Cn?????????τ ????????????? f???????????????????? 2.3  ?????? ???????????????????????????????x/c =15%?y/L =52%?68%? θ =45°? f =300 Hz? τ = 10%?????U=37.5 kV??????????????? ?9???2°~16°???????????????????CL?????CD????????LON OFFL LC C CΔ = − ? D ON OFFD DC C CΔ = − ?? OFFLC ?OFFDC ? ONLC ? ONDC ????????????????????????? ONLL//(%)CC??????? (a) ???? CL?? OFFDD//(%)CC??????? (b) ???? CD?? ? 9  ???????????????? Fig.9  Variation of lift and drag coefficients ?10???????4°~16°??????????????????CL/CD?Cl????? ??????????????????????2.1.2???????????????????????12°?????????9????   ??12°??????????????????????????????????????????????????????????????(?10)?????????5.1%? ?????????Cl???CL/CDONL D/C COFFL D/C C ?10  ?????????Cl?CL/CD??? Fig.10  Variation of Cl and CL/CD ???????????????????????????????????Cl??(?10)??????????????? ???12°???????????????????????????????????????(?9(a))????????????????Cl??? ??????????????????????9(b)?????????????????2°~16°??CD???????????????CD???????????????CD?????????????????????????????????????????????????????????Cn??(?8(b))? 3  ?? (1) ???????? 2 ???????????????????????????????????????????12°?????????????????? 0.0024????12°?????????????????? 0.0021?????????????? 0.00097? (2) ???????????????????????????????????????????? (3) ?????????????????????????????????? 238 ?    ?    ?    ?  (4) ??????????????????????????????????????????? ????? [1] Wang J J, Choi K S, Feng L H, et al. Recent developments in DBD plasma flow control [J]. Progress in Aerospace Sciences, 2013, 62: 52?78. [2] ???, ??. ??????????????[J]. ????????(?????), 2012, 13(3): 1?5. Li Yinghong, Wu Yun. Progress of research on plasma flow control technology [J]. Journal of Air Force Engineering University (Natural Science Edition), 2012, 13(3): 1?5. (in Chinese) [3] ???, ???, ???, ?. ???????????????????????????[J]. ????, 2012, 29(8): 360?365. Du Xiqi, Jiang Zengyan, Tong Shengxi, et al. Experimental study on control of separated flow over civil aircraft aft-body and drag reduction mechanism by using vortex generator [J]. Engineering Mechanics, 2012, 29(8): 360?365. (in Chinese) [4] ???, ???, ???, ?. ???????????[J]. ????, 2014, 31(8): 217?222. Xue Dawen, Chen Zhihua, Sun Xiaohui, et al. Mirco-ramp control of the boundary separation induced by the flow past an airfoil [J]. Engineering Mechanics, 2014, 31(8): 217?222. (in Chinese) [5] ???, ???, ??. ??????????[J]. ??????, 2010, 21(5): 2?6. Zhan Peiguo, Chen Yahong, Zhao Xin. A review of active flow control technology [J]. Aeronautical Science & Technology, 2010, 21(5): 2?6. (in Chinese) [6] ??, ???. ????????????????????[J]. ????, 2014, 31(12): 234?240. Zhang Qing, Ye Zhengyin. Study on a new method for suppression of vertical tail buffeting using inflatable bumps [J]. Engineering Mechanics, 2014, 31(12): 234?240. (in Chinese) [7] ??, ???, ??, ?. ????????????[J]. ????, 2013, 30(5): 277?281. He Wei, Niu Zhongguo, Pan Bo, et al. Study on experiments for suppressing wingtip vortices with plasma [J]. Engineering Mechanics, 2013, 30(5): 277?281. (in Chinese) [8] Javier Lopera, Terry T Ng, Mehul P Patel, et al. Aerodynamic control of 1303 UAV using windward surface plasma actuators on a separation ramp [R]. Reston, USA: AIAA, 2007.  [9] Mehul P Patel, Terry T Ng, Srikanth Vasudevan, et al. Plasma actuators for hingeless aerodynamic control of an unmanned air vehicle [R]. Reston, USA: AIAA, 2006. [10] Nelson Robert C, Corke Thomas C, He Chuan, et al. Modification of the flow structure over a UAV wing for roll control [R]. Reston, USA: AIAA, 2007. [11] ??, ???, ??, ?. ???????????????????????????[J]. ?????2012, 33(10): 1781?1790. Du Hai, Shi Zhiwei, Geng Xi, et al. Experimental study of directional-lateral aerodynamic moment control of micro air vehicle by plasma actuators [J]. Acta Aeronautica et Astronautica Sinica, 2012, 33(10): 1781?1790. (in Chinese) [12] ??, ???, ???, ?. ??????????????????????[J]. ????, 2013, 34(9): 2038?2046. Du Hai, Shi Zhiwei, Ni Fangyuan, et al. Aerodynamic moment control of flying wing vehicle using plasma actuators [J]. Acta Aeronautica et Astronautica Sinica, 2013, 34(9): 2038?2046. (in Chinese) [13] ???, ??. ??????????????????????[J]. ????, 2013, 36(6): 142?145, 150. Wang Mengmeng, Lin Qi. Recent developments in synthetic jet technology and flow control application [J]. Mechanical & Electrical Technology, 2013, 36(6): 142?145, 150. (in Chinese) [14] Grossman K R, Cybyk B Z, VanWie D M, et al. SparkJet actuators for flow control [R]. Reston, USA: AIAA, 2003. [15] Popki S H, Cybyk B Z, Land III H B, et al. Recent performance-based advances in SparkJet actuator design for supersonic flow applications [R]. Reston, USA: AIAA, 2013. [16] Emerick II T M, Ali M Y, Foster C H, et al. SparkJet actuator characterization in supersonic crossflow [R]. Reston, USA: AIAA, 2012.  [17] Emerick T, Ali M Y, Foster C, et al. SparkJet characterizations in quiescent and supersonic flow fields [J]. Experiments in Fluids, 2014, 55(12): 1858. [18] Greene B R, Clemens N T, Micka D. Control of shock boundary layer interaction using pulsed plasma jets [R]. Reston, USA: AIAA, 2013. [19] Golbabaei-Asl M, Knight D, Anderson K, et al. SparkJet efficiency [R]. Reston, USA: AIAA, 2013. [20] Ostman R J, Herges T G, Craig Dutton J, et al. Effect on high-speed boundary-layer characteristics from plasma actuators [R]. Reston, USA: AIAA, 2013. [21] Todd M Reedy, Nachiket V Kale, Craig Dutton J, et al. Experimental characterization of a pulsed plasma jet [J]. AIAA Journal, 2013, 51(8): 2027?2031. [22] Caruana D, Barricau P, Gleyzes C. Separation control with plasma synthetic jet actuators [J]. International Journal of Aerodynamics, 2013, 3(1): 71?83. [23] Belinger A, Naud´e N, Cambronne J P, et al.  Plasma synthetic jet actuator: electrical and optical analysis of the discharge [J]. Journal of Physics D: Applied Physics, 2014, 47(34): 1?11. [24] Sary G, Dufour G, Rogier F, et al. Modeling and parametric study of a plasma synthetic jet for flow control [J]. AIAA Journal, 2014, 52(8): 1591?1603. [25] Shin J. Characteristics of high speed electro-thermal jet activated by pulsed DC discharge [J]. Chinese Journal of Aeronautics, 2010, 23(5): 518?522. [26] ???. ????????????????????[D]. ??: ????????, 2012. Zhu Chenyu. Experimental research and parameters optimization on high-performance zero-mass-jet actuator [D]. Nanjing: Master thesis, Nanjing University of Aeronautics and Astronautics, 2012. (in Chinese) [27] Jin Di, Li Yinghong, Jia Min, et al. Experimental characterization of the plasma synthetic jet actuator [J]. Plasma Science and Technology. 2013, 15(10): 1034. [28] Wang Lin, Xia Zhixun, Luo Zhenbing, et al. Three-electrode plasma synthetic jet actuator for high- speed flow control [J]. AIAA Journal, 2014, 52(4): 879?882. 

AERODYNAMIC MOMENTS CONTROL OF WING MODEL USING PLASMA JET

https://dspace.xmu.edu.cn/bitstream/handle/2288/162744/%e7%ad%89%e7%a6%bb%e5%ad%90%e4%bd%93%e5%b0%84%e6%b5%81%e6%8e%a7%e5%88%b6%e6%9c%ba%e7%bf%bc%e6%b0%94%e5%8a%a8%e5%8a%9b%e7%9f%a9%e7%9a%84%e5%ae%9e%e9%aa%8c%e7%a0%94%e7%a9%b6.pdf?sequence=1&isAllowed=y

AERODYNAMIC MOMENTS CONTROL OF WING MODEL USING PLASMA JET

Abstract

Similar works

Full text

Available Versions

Xiamen University Institutional Repository