Article: Vibro-acoustic computation of irregular cavities using a combined analytical-finite element approach with application to vehicle interior acoustics Journal: International Journal of Vehicle Noise and Vibration (IJVNV) 2012 Vol.8 No.2 pp.136 - 151 Abstract: A combined analytical-finite element approach is developed for more accurate representation and time efficient calculation of the acoustic frequency response function (AFRF) of a three-dimensional vehicle cavity with planar irregularities. In the proposed approach, finite element method is only used for determining modal properties of the two-dimensional irregular shape, while the analytical terms provide the modal properties of the overall three-dimensional volume. Modal superposition method is then applied to compute AFRF for panel excitations at critical suspension attachment locations. Results show that the proposed approach out-performs the direct finite element method in terms of computational time efficiency. Moreover, the AFRF obtained using direct finite element method with finer mesh converges to that predicted by the combined analytical-finite element approach. Analysis also reveals that although the irregularities increase the number of cavity modes coupled with structural panel modes, AFRF may have lower magnitude than that of the simpler rectangular cavity model. Inderscience Publishers - linking academia, business and industry through research

Title: Vibro-acoustic computation of irregular cavities using a combined analytical-finite element approach with application to vehicle interior acoustics

Authors: Wael Elwali; Mingfeng Li; Teik C. Lim

Addresses: Vibro-Acoustics and Sound Quality Research Laboratory, School of Dynamic Systems, Mechanical Engineering, University of Cincinnati, 598 Rhodes Hall, P.O. Box 210072, Cincinnati, 45221-0072, OH, USA. ' Vibro-Acoustics and Sound Quality Research Laboratory, School of Dynamic Systems, Mechanical Engineering, University of Cincinnati, 598 Rhodes Hall, P.O. Box 210072, Cincinnati, 45221-0072, OH, USA. ' Vibro-Acoustics and Sound Quality Research Laboratory, School of Dynamic Systems, Mechanical Engineering, University of Cincinnati, 598 Rhodes Hall, P.O. Box 210072, Cincinnati, 45221-0072, OH, USA

Abstract: A combined analytical-finite element approach is developed for more accurate representation and time efficient calculation of the acoustic frequency response function (AFRF) of a three-dimensional vehicle cavity with planar irregularities. In the proposed approach, finite element method is only used for determining modal properties of the two-dimensional irregular shape, while the analytical terms provide the modal properties of the overall three-dimensional volume. Modal superposition method is then applied to compute AFRF for panel excitations at critical suspension attachment locations. Results show that the proposed approach out-performs the direct finite element method in terms of computational time efficiency. Moreover, the AFRF obtained using direct finite element method with finer mesh converges to that predicted by the combined analytical-finite element approach. Analysis also reveals that although the irregularities increase the number of cavity modes coupled with structural panel modes, AFRF may have lower magnitude than that of the simpler rectangular cavity model.

Keywords: vehicle NVH; vibro-acoustics analysis; irregular cavities; acoustic frequency response function; AFRF; finite element method; FEM; modal coupling; vehicle noise; vehicle vibration; modelling.

DOI: 10.1504/IJVNV.2012.046465

International Journal of Vehicle Noise and Vibration, 2012 Vol.8 No.2, pp.136 - 151

Published online: 29 Aug 2014 *

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Title: Vibro-acoustic computation of irregular cavities using a combined analytical-finite element approach with application to vehicle interior acoustics

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