共轴刚性旋翼气动干扰特性风洞试验研究
|
摘要
针对共轴刚性旋翼上下旋翼间复杂气动干扰问题,利用4 m直径共轴刚性旋翼缩比模型开展了悬停及前飞状态风洞试验研究。试验中,采用两套六分量天平对共轴刚性旋翼的上下旋翼进行分开测力,并测量了相同操纵量输入时的孤立单旋翼气动力。通过分析双旋翼状态下的上下旋翼与孤立单旋翼的气动力的对比结果,研究了共轴刚性旋翼在悬停及前飞状态下的气动干扰特性。在此基础上,还进行了升力偏置对气动干扰影响的试验研究。结果表明:随着旋翼前进比的增大,上下旋翼之间的气动干扰逐渐减弱,共轴刚性旋翼的非对称气动干扰会使得双旋翼升力偏置增大。
The wind tunnel of a 4 m -diameter coaxial rigid model rotor is conducted to investigate the aero-dynamic interaction characteristics. Both coaxial and single rotor are tested,and the upper and lower rotor forces are measured independently. The force distribution of the coaxial rotor is analyzed. The aerodynamic forces and lift offset characteristics of coaxial and single rotor are compared. Simultaneity,the free wake method is used to analyze the tip vortex wake characteristic under interference. It is shown that the coaxial rigid rotor interaction is weaken as advance ratio increases,and the coaxial rigid rotor lift offset increases due to the asymmetry aerodynamic interaction.
The wind tunnel of a 4 m -diameter coaxial rigid model rotor is conducted to investigate the aero-dynamic interaction characteristics. Both coaxial and single rotor are tested,and the upper and lower rotor forces are measured independently. The force distribution of the coaxial rotor is analyzed. The aerodynamic forces and lift offset characteristics of coaxial and single rotor are compared. Simultaneity,the free wake method is used to analyze the tip vortex wake characteristic under interference. It is shown that the coaxial rigid rotor interaction is weaken as advance ratio increases,and the coaxial rigid rotor lift offset increases due to the asymmetry aerodynamic interaction.
引文
[1]BURGESS R K.Development of the ABC rotor[C]//The 27th Annual National V/STOL Forum of the American Helicopter Society.Washington,D C:AHS,1971:1-16.
[2]SCHMAUS J,CHOPRA I.Performance and loads prediction for a high advance ratio coaxial helicopter[C]//56th AIAA/ASCE/AHS/ASC Structures,Structural Dynamics,and Materials Conference.Kissimmee:AIAA,2015:1-17.
[3]LORBER P,BOWLES P.Wind tunnel testing for the SB1 defiant TM joint multi-role technology demon-strator[C]//American Helicopter Society 73rd Ann-ual Forum.Texas:AHS,2017:1-18.
[4]YEO H,JOHNSON W.Investigation of maximum blade loading capability of lift-offset rotors[C]//Amer-ican Helicopter Society 69th Annual Forum.Phoenix:AHS,2013:1-16.
[5]SCHMAUS J,CHOPRA I.Aeromechanics for a high advance ratio coaxial helicopter[C]//American Helicopter Society 71st Annual Forum.Virginia:AHS,2015:1-15.
[6]PAGLINO V M,BENO E A.Full-scale wind-tunnel investigation of the advancing blade concept rotor system[R].USAAMRDL Technical Report,1971:71-25.
[7]VINCENT M.Forward flight performance of a coaxial rigid rotor[C]//The 27th Annual National V/STOL Forum of the American Helicopter Society.Washington,DC:AHS,1971:1-15.
[8]FELKER F F.Performance and loads data from a wind tunnel test of a full-scale coaxial hingeless rotor helicopter[R].NASA-TM-81329,1981.
[9]WALSH D.WEINER S.Development testing of the sikorsky X2 technology demonstrator[C]//American Helicopter Society 65th Annual Forum.Grapevine:AHS,2009:1-11.
[10]LORBER P,LAW G.Overview of S-97 RAIDER(TM)scale model tests[C]//American Helicopter Society 72nd Annual Forum.West Palm Beach:AHS,2016:1-17.
[11]MCALISTER K.Experimental study of a hovering coaxial rotor with highly twisted blades[C]//Ame-rican Helicopter Society 64th Annual Forum.Montreal Canada:AHS,2008:1-17.
[12]CAMERON C,KARPATNE A,SIROHI J.Performance and vibratory hub loads of a mach-scale coaxial rotor in hover[C]//American Helicopter Soci-ety 70th Annual Forum.Montreal Canada:AHS,2014:1-9.
[13]SINGH R,KANG H.Computational investigations of transient loads and blade deformations on coaxial rotor systems[C]//The 33rd AIAA Applied Aerody-namics Conference.Dallas:AIAA,2015:1-11.
[14]CAMERON C,SIROHI J,UEHARA D.Transient hub loads and blade deformation of a mach-scale coa-xial rotor in hover[C]//56th AIAA/ASCE/AHS/ASC Structures,Structural Dynamics,and Materials Conference.Kissimmee:AIAA,2015:1-11.
[15]CAMERON C,SIROHI J.Performance and loads of a model coaxial rotor part I:Wind tunnel testing[C]//American Helicopter Society 72nd Annual Forum.West Palm Beach:AHS,2016:1-15.
[16]FEIL R,RAULEDER J.Aeromechanics analysis of a coaxial rotor system in hover and high-advance-ratio forward flight[C]//The AIAA Applied Aerody-namics Conference.Washington:AIAA,2016:1-19.
[17]邓彦敏,陶然,胡继忠.共轴式直升机上下旋翼之间气动干扰的风洞实验研究[J].航空学报,2003,24(1):10-14.DENG Yanmin,TAO Ran,HU Jizhong.Experimen-tal investigation of the aerodynamic interaction be-tween upper and lower rotors of a coaxial helicopter[J].Acta Aeronautica et Astronautica Sinica,2003,24(1):10-14.
[18]马杨超,于世美,邓彦敏.共轴式双旋翼悬停诱导速度场的PIV试验研究[J].实验流体力学,2012,26(1):16-20.MA Yangchao,YU Shimei,DENG Yanmin.PIV ex-perimental investigation of coaxial rotor induced veloci-ty field in hover[J].Journal of Experimental in Fluid Mechanics,2012,26(1):16-20.
[19]叶靓,徐国华.共轴式双旋翼悬停流场和气动力的CFD计算[J].空气动力学学报,2012,30(4):437-442.YEI Liang,XU Guohua.Calculation on flow field and aerodynamic force of coaxial rotors in hover with CFDmethod[J].Acta Aerodynamica Sinica,2012,30(4):437-442.
[20]李文浩.复合式高速直升机旋翼/机身气动干扰特性的CFD分析[D].南京:南京航空航天大学,2012.LI Wenhao.Analysis on aerodynamic interactions of the compound high-speed helicopter rotor/fuselage ba-sed on CFD[D].Nanjing:Nanjing University of Aer-onautics and Astronautics,2012.
[21]张银.复合式共轴刚性旋翼直升机气动干扰及飞行特性分析[D].南京:南京航空航天大学,2014.ZHANG Yin.Research on aerodynamic interaction and flight characteristics of compound helicopter with rigid coaxial rotor[D].Nanjing:Nanjing University of Aeronautics and Astronautics,2014.
[22]JOHNSON W.A general free wake geometry calculation for wings and rotors[C]//American Heli-copter Society 72nd Annual Forum.Texas:AHS,2014:1-17.
[2]SCHMAUS J,CHOPRA I.Performance and loads prediction for a high advance ratio coaxial helicopter[C]//56th AIAA/ASCE/AHS/ASC Structures,Structural Dynamics,and Materials Conference.Kissimmee:AIAA,2015:1-17.
[3]LORBER P,BOWLES P.Wind tunnel testing for the SB1 defiant TM joint multi-role technology demon-strator[C]//American Helicopter Society 73rd Ann-ual Forum.Texas:AHS,2017:1-18.
[4]YEO H,JOHNSON W.Investigation of maximum blade loading capability of lift-offset rotors[C]//Amer-ican Helicopter Society 69th Annual Forum.Phoenix:AHS,2013:1-16.
[5]SCHMAUS J,CHOPRA I.Aeromechanics for a high advance ratio coaxial helicopter[C]//American Helicopter Society 71st Annual Forum.Virginia:AHS,2015:1-15.
[6]PAGLINO V M,BENO E A.Full-scale wind-tunnel investigation of the advancing blade concept rotor system[R].USAAMRDL Technical Report,1971:71-25.
[7]VINCENT M.Forward flight performance of a coaxial rigid rotor[C]//The 27th Annual National V/STOL Forum of the American Helicopter Society.Washington,DC:AHS,1971:1-15.
[8]FELKER F F.Performance and loads data from a wind tunnel test of a full-scale coaxial hingeless rotor helicopter[R].NASA-TM-81329,1981.
[9]WALSH D.WEINER S.Development testing of the sikorsky X2 technology demonstrator[C]//American Helicopter Society 65th Annual Forum.Grapevine:AHS,2009:1-11.
[10]LORBER P,LAW G.Overview of S-97 RAIDER(TM)scale model tests[C]//American Helicopter Society 72nd Annual Forum.West Palm Beach:AHS,2016:1-17.
[11]MCALISTER K.Experimental study of a hovering coaxial rotor with highly twisted blades[C]//Ame-rican Helicopter Society 64th Annual Forum.Montreal Canada:AHS,2008:1-17.
[12]CAMERON C,KARPATNE A,SIROHI J.Performance and vibratory hub loads of a mach-scale coaxial rotor in hover[C]//American Helicopter Soci-ety 70th Annual Forum.Montreal Canada:AHS,2014:1-9.
[13]SINGH R,KANG H.Computational investigations of transient loads and blade deformations on coaxial rotor systems[C]//The 33rd AIAA Applied Aerody-namics Conference.Dallas:AIAA,2015:1-11.
[14]CAMERON C,SIROHI J,UEHARA D.Transient hub loads and blade deformation of a mach-scale coa-xial rotor in hover[C]//56th AIAA/ASCE/AHS/ASC Structures,Structural Dynamics,and Materials Conference.Kissimmee:AIAA,2015:1-11.
[15]CAMERON C,SIROHI J.Performance and loads of a model coaxial rotor part I:Wind tunnel testing[C]//American Helicopter Society 72nd Annual Forum.West Palm Beach:AHS,2016:1-15.
[16]FEIL R,RAULEDER J.Aeromechanics analysis of a coaxial rotor system in hover and high-advance-ratio forward flight[C]//The AIAA Applied Aerody-namics Conference.Washington:AIAA,2016:1-19.
[17]邓彦敏,陶然,胡继忠.共轴式直升机上下旋翼之间气动干扰的风洞实验研究[J].航空学报,2003,24(1):10-14.DENG Yanmin,TAO Ran,HU Jizhong.Experimen-tal investigation of the aerodynamic interaction be-tween upper and lower rotors of a coaxial helicopter[J].Acta Aeronautica et Astronautica Sinica,2003,24(1):10-14.
[18]马杨超,于世美,邓彦敏.共轴式双旋翼悬停诱导速度场的PIV试验研究[J].实验流体力学,2012,26(1):16-20.MA Yangchao,YU Shimei,DENG Yanmin.PIV ex-perimental investigation of coaxial rotor induced veloci-ty field in hover[J].Journal of Experimental in Fluid Mechanics,2012,26(1):16-20.
[19]叶靓,徐国华.共轴式双旋翼悬停流场和气动力的CFD计算[J].空气动力学学报,2012,30(4):437-442.YEI Liang,XU Guohua.Calculation on flow field and aerodynamic force of coaxial rotors in hover with CFDmethod[J].Acta Aerodynamica Sinica,2012,30(4):437-442.
[20]李文浩.复合式高速直升机旋翼/机身气动干扰特性的CFD分析[D].南京:南京航空航天大学,2012.LI Wenhao.Analysis on aerodynamic interactions of the compound high-speed helicopter rotor/fuselage ba-sed on CFD[D].Nanjing:Nanjing University of Aer-onautics and Astronautics,2012.
[21]张银.复合式共轴刚性旋翼直升机气动干扰及飞行特性分析[D].南京:南京航空航天大学,2014.ZHANG Yin.Research on aerodynamic interaction and flight characteristics of compound helicopter with rigid coaxial rotor[D].Nanjing:Nanjing University of Aeronautics and Astronautics,2014.
[22]JOHNSON W.A general free wake geometry calculation for wings and rotors[C]//American Heli-copter Society 72nd Annual Forum.Texas:AHS,2014:1-17.
© 2004-2018 中国地质图书馆版权所有 京ICP备05064691号 京公网安备11010802017129号 地址:北京市海淀区学院路29号 邮编:100083 电话:办公室:(+86 10)66554848;文献借阅、咨询服务、科技查新:66554700 |