Numerical mode matching for sound propagation in silencers with granular material
Numerical mode matching for sound propagation in silencers with granular material
This work presents an efficient numerical approach based on the combination of the mode matching technique and the finite element method (FEM) to model the sound propagation in silencers containing granular material and to evaluate their acoustic performance through the computation of transmission loss (TL). The methodology takes into account the presence of three-dimensional (3D) waves and the corresponding higher order modes, while reducing the computational expenditure of a full 3D FEM calculation. First, the wavenumbers and transversal pressure modes associated with the silencer cross section are obtained by means of a two-dimensional FEM eigenvalue problem, which allows the consideration of arbitrary transversal geometries and material heterogeneities. The numerical approach considers the possibility of using different filling levels of granular material, giving rise to cross sections with abrupt changes of properties located not only in the usual central perforated passage, but also in the transition between air and material, that involves a significant change in porosity. After solving the eigenvalue problem, the acoustic fields (acoustic pressure and axial velocity) are coupled at geometric discontinuities between ducts through the compatibility conditions to obtain the complete solution of the wave equation and the acoustic performance (TL). The granular material is analysed as a potential alternative to the traditional dissipative silencers incorporating fibrous absorbent materials. Sound propagation in granular materials can be modelled through acoustic equivalent properties, such as complex and frequency dependent density and speed of sound. TL results computed by means of the numerical approach proposed here show good agreement with full 3D FEM calculations and experimental measurements. As expected, the numerical mode matching outperforms the computational expenditure of the full 3D FEM approach. Different configurations have been studied to determine the influence on the TL of several parameters such as the size of the material grains, the filling level of the chamber, the granular material porosity and the geometry of the silencer cross section.
Computational performance, Finite element method, Granular material, Numerical mode matching, Silencer, Sound attenuation
233-246
Sánchez-Orgaz, E.M.
13a66172-8b1f-474f-a3e1-137da7e5536c
Denia, F.D.
5a64479b-10d6-482b-8f25-dc5b4ef39780
Baeza, L.
09dc5565-ad4b-49af-a104-d4b6ad28e1b0
Kirby, Ray
d76e296b-975b-43b8-b9ce-a22a83346fe8
1 April 2019
Sánchez-Orgaz, E.M.
13a66172-8b1f-474f-a3e1-137da7e5536c
Denia, F.D.
5a64479b-10d6-482b-8f25-dc5b4ef39780
Baeza, L.
09dc5565-ad4b-49af-a104-d4b6ad28e1b0
Kirby, Ray
d76e296b-975b-43b8-b9ce-a22a83346fe8
Sánchez-Orgaz, E.M., Denia, F.D., Baeza, L. and Kirby, Ray
(2019)
Numerical mode matching for sound propagation in silencers with granular material.
Journal of Computational and Applied Mathematics, 350, .
(doi:10.1016/j.cam.2018.10.030).
Abstract
This work presents an efficient numerical approach based on the combination of the mode matching technique and the finite element method (FEM) to model the sound propagation in silencers containing granular material and to evaluate their acoustic performance through the computation of transmission loss (TL). The methodology takes into account the presence of three-dimensional (3D) waves and the corresponding higher order modes, while reducing the computational expenditure of a full 3D FEM calculation. First, the wavenumbers and transversal pressure modes associated with the silencer cross section are obtained by means of a two-dimensional FEM eigenvalue problem, which allows the consideration of arbitrary transversal geometries and material heterogeneities. The numerical approach considers the possibility of using different filling levels of granular material, giving rise to cross sections with abrupt changes of properties located not only in the usual central perforated passage, but also in the transition between air and material, that involves a significant change in porosity. After solving the eigenvalue problem, the acoustic fields (acoustic pressure and axial velocity) are coupled at geometric discontinuities between ducts through the compatibility conditions to obtain the complete solution of the wave equation and the acoustic performance (TL). The granular material is analysed as a potential alternative to the traditional dissipative silencers incorporating fibrous absorbent materials. Sound propagation in granular materials can be modelled through acoustic equivalent properties, such as complex and frequency dependent density and speed of sound. TL results computed by means of the numerical approach proposed here show good agreement with full 3D FEM calculations and experimental measurements. As expected, the numerical mode matching outperforms the computational expenditure of the full 3D FEM approach. Different configurations have been studied to determine the influence on the TL of several parameters such as the size of the material grains, the filling level of the chamber, the granular material porosity and the geometry of the silencer cross section.
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More information
e-pub ahead of print date: 6 November 2018
Published date: 1 April 2019
Keywords:
Computational performance, Finite element method, Granular material, Numerical mode matching, Silencer, Sound attenuation
Identifiers
Local EPrints ID: 428137
URI: http://eprints.soton.ac.uk/id/eprint/428137
ISSN: 0377-0427
PURE UUID: cdc63067-546c-4853-bd2d-01f61885065e
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Date deposited: 12 Feb 2019 17:30
Last modified: 17 Mar 2024 12:16
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Contributors
Author:
E.M. Sánchez-Orgaz
Author:
F.D. Denia
Author:
L. Baeza
Author:
Ray Kirby
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