论文信息 - Numerical Simulation of Reverberant Acoustic Field Environment Test Based on Reciprocity Theorem

Numerical Simulation of Reverberant Acoustic Field Environment Test Based on Reciprocity Theorem

The aim of this paper is to present the formulation and application of the coupled structural finite element and acoustic boundary element algorithm to analysis the structure subjected to noise-induced vibration from acoustic loads experienced during launch environment. Firstly, the traditional numerical simulation of a reverberant field as a launch acoustic environment was introduced. Secondly, based on the reciprocity theorem used in coupled FE-BE model, as well as the principle of stochastic analysis, the output response power spectrum density of the coupling model subjected to reverberant environment can be calculate by the mathematical formulation deduced. In order to verify the accuracy and efficiency of the proposed method, the simulation results based on the reciprocity theorem were compared with the solutions obtained using the traditional method. Good agreement results show that using the reciprocity theorem to analyze reverberant acoustic field environment is feasible and effective.

Jun Wang | Jinghui Zhang | Wei Ning

[1] J. Bendat,et al. Random Data: Analysis and Measurement Procedures , 1987 .

[2] R S Langley,et al. On the diffuse field reciprocity relationship and vibrational energy variance in a random subsystem at high frequencies. , 2007, The Journal of the Acoustical Society of America.

[3] Frank Fahy,et al. Some applications of the reciprocity principle in experimental vibroacoustics , 2003 .

[4] Nickolas Vlahopoulos,et al. NUMERICAL APPROACH FOR COMPUTING NOISE-INDUCED VIBRATION FROM LAUNCH ENVIRONMENTS , 1998 .

[5] M. P. Norton,et al. Fundamentals of Noise and Vibration Analysis for Engineers , 1990 .

[6] A. Norris,et al. Acoustic reciprocity for fluid‐structure problems , 1993 .

[7] P. Sas,et al. Vibro‐acoustical modal analysis: Reciprocity, model symmetry, and model validity , 1996 .

[8] Michael Möser,et al. Structure-borne Sound , 2009 .

[9] M. P. Norton,et al. Fundamentals of Noise and Vibration Analysis for Engineers, 2nd Edition , 2007 .

[10] P. Remington. Structure-Borne Sound: Structural Vibrations and Sound Radiation at Audio Frequencies (3rd Edition) , 2005 .

[11] Nickolas Vlahopoulos,et al. Numerical implementation and applications of a coupling algorithm for structural-acoustic models with unequal discretization and partially interfacing surfaces , 1999 .