快速声散射方法(FSM)是一种基于无流动Helmholtz方程边值问题的声散射预测工具,具有快速、灵活的特点.以航空发动机消声短舱的声学设计为背景,用该方法对变截面管道声传播特性进行数值模拟研究,用直接边界元方法(DBEM)进行数值求解,避免了求解管口反射系数,有效地提高了计算速度.数值研究了刚性壁面和不同位置壁面声衬组合对变截面圆环管道形状声传播的影响,并分析了管道厚度对散射声场的影响,数值结果与声类比方法结果进行了相互验证.最后,还对一种真实转子声源进行了管道声散射的数值研究,结果表明本方法在航空发动机声学设计中具有工程应用价值.
The fast scattering method (FSM) is a fast and flexible way to predict the sound propagation and radiation from a ducted-fan by solving the Helmholtz equation with specific boundary conditions and no flow. For the design of the ducted-fan acoustic liner, the method is applied to the simulation of sound propagation in a varying cross-section duct. The time harmonic and linearized acoustic equation is employed in the present study, and the flow field is assumed to be a uniform flow from the far field. By introducing a 3D Lorentz transformation, the acoustic scattering problem with flow is transformed to a problem of no flow described by the exterior Helmholtz equation with specific boundary conditions. The direct boundary element method (DBEM) is used for solving the homogeneous linear Helmholtz equation, which can avoid solving the reflection coefficients at the inlet and outlet duct surfaces and thus save much computational time. In addition, the effects of different impedances of the liner in a varying cross-section ducted-fan on sound propagation are also investigated. A comparison of numerical results by using the fast scattering method and by using the acoustic analogy method is also performed. Finally, the method is applied to an examination of the noise reduction by the duct liner in a real high-speed rotor. The results demonstrate that the fast scattering method is suitable for application to the design of a duct liner in aero engines.
[1] Myers M K.Boundary integral formulations for ducted fan radiation calculations.CEAS/AIAA Paper 95-076,1995.
[2] Myers M K,Kosanchick M III.Computation of sound radiation from a fan in a short lined duct.AIAA-1997-1711,1997.
[3] Myers M K.Radiation of sound from a point source in a short duct. 2nd CAA Workshop on Benchmark Problems.1997:19-26.
[4] Dunn M H,Tweed J,Farassat F.The prediction of ducted fan engine noise via a boundary integral equation method.AIAA-1996-1770,1996.
[5] Dunn M H,Tweed J,Farassat F.The application of a boundary integral equation method to the prediction of ducted fan engine noise.Journal of Sound and Vibration,1999,227(5):1019-1048.
[6] Dunn M H.TBIEM3D-a computer program for predicting ducted fan engine noise.NASA CR-97-206232,1997.
[7] Dunn M H,Farassat F.Liner optimization studies using the ducted fan noise prediction code TBIEM3D.AIAA-1998-2310,1998.
[8] Yang B,Wang T Q.An approach to predict ducted fan noise by boundary integral equation method.AIAA-2005- 3068,2005.
[9] Wang T Q,Yang B.A study on the prediction of the ducted fan noise.AIAA-2005-3069,2005.
[10] Dunn M H,Tinetti A F.Aeroacoustic scattering via the equivalent source method.AIAA-2004-2937,2004.
[11] Tinetti A F,Dunn M H.Aeroacousitc noise prediction using the fast scattering code.AIAA-2005-3061,2005.
[12] Rienstra W,Eversman W.A numerical comparison between the multiple-scales and finite-element solution for sound propagation in lined flow ducts.Journal of Fluid Mechanics,2001,437:367-384.
[13] Wang T Q,Yang B,Yang Z G.Prediction of sound propagation/radiation of ducted-fan by using BEM based on acoustic analogy theory.Journal of Engineering Thermophysics,2003,24(3):403-405.(in Chinese) 王同庆,杨兵,杨志刚.用基于声类比的边界元计算管道风扇的管道声传播和辐射.工程热物理学报,2003,24(3):403-405.
[14] Jin P.Fan/compressor duct lining acoustic design experiment research.Beijing: School of Jet Propulsion, Beihang University, 2005.(in Chinese) 金鹏.风扇/压气机管道声衬声学设计实验研究.北京:北京航空航天大学能源与动力工程学院,2005.
[15] Yang B,Wang T Q.Acoustic liner optimization studies by finite duct model.Journal of Engineering Theromophysics,2008,29(4):591-594.(in Chinese) 杨兵,王同庆.有限长管道声衬的参数优化设计研究.工程热物理学报,2008,29(4):591-594.