An efficient analytical model for baffled, multi-celled membrane-type acoustic metamaterial panels
An efficient analytical model for baffled, multi-celled membrane-type acoustic metamaterial panels
A new analytical model for the oblique incidence sound transmission loss prediction of baffled panels with multiple subwavelength sized membrane-type acoustic metamaterial (MAM) unit cells is proposed. The model employs a novel approach via the concept of the effective surface mass density and approximates the unit cell vibrations in the form of piston-like displacements. This yields a coupled system of linear equations that can be solved efficiently using well-known solution procedures. A comparison with results from finite element model simulations for both normal and diffuse field incidence shows that the analytical model delivers accurate results as long as the edge length of the MAM unit cells is smaller than half the acoustic wavelength. The computation times for the analytical calculations are 100 times smaller than for the numerical simulations. In addition to that, the effect of flexible MAM unit cell edges compared to the fixed edges assumed in the analytical model is studied numerically. It is shown that the compliance of the edges has only a small impact on the transmission loss of the panel, except at very low frequencies in the stiffness-controlled regime. The proposed analytical model is applied to investigate the effect of variations of the membrane prestress, added mass, and mass eccentricity on the diffuse transmission loss of a MAM panel with 120 unit cells. Unlike most previous investigations of MAMs, these results provide a better understanding of the acoustic performance of MAMs under more realistic conditions. For example, it is shown that by varying these parameters deliberately in a checkerboard pattern, a new anti-resonance with large transmission loss values can be introduced. A random variation of these parameters, on the other hand, is shown to have only little influence on the diffuse transmission loss, as long as the standard deviation is not too large. For very large random variations, it is shown that the peak transmission loss value can be greatly diminished.
Baffled, Diffuse, Effective mass, Membrane, Metamaterial, Transmission loss
359-375
Langfeldt, F.
2bf86877-f2cd-4c35-be0f-e38a718a915c
Gleine, W.
6b99025f-b44a-46a8-b699-ec25962c7e75
von Estorff, O.
7b2f7283-9bab-49e4-9ac8-baaa061e769d
17 March 2018
Langfeldt, F.
2bf86877-f2cd-4c35-be0f-e38a718a915c
Gleine, W.
6b99025f-b44a-46a8-b699-ec25962c7e75
von Estorff, O.
7b2f7283-9bab-49e4-9ac8-baaa061e769d
Langfeldt, F., Gleine, W. and von Estorff, O.
(2018)
An efficient analytical model for baffled, multi-celled membrane-type acoustic metamaterial panels.
Journal of Sound and Vibration, 417, .
(doi:10.1016/j.jsv.2017.12.018).
Abstract
A new analytical model for the oblique incidence sound transmission loss prediction of baffled panels with multiple subwavelength sized membrane-type acoustic metamaterial (MAM) unit cells is proposed. The model employs a novel approach via the concept of the effective surface mass density and approximates the unit cell vibrations in the form of piston-like displacements. This yields a coupled system of linear equations that can be solved efficiently using well-known solution procedures. A comparison with results from finite element model simulations for both normal and diffuse field incidence shows that the analytical model delivers accurate results as long as the edge length of the MAM unit cells is smaller than half the acoustic wavelength. The computation times for the analytical calculations are 100 times smaller than for the numerical simulations. In addition to that, the effect of flexible MAM unit cell edges compared to the fixed edges assumed in the analytical model is studied numerically. It is shown that the compliance of the edges has only a small impact on the transmission loss of the panel, except at very low frequencies in the stiffness-controlled regime. The proposed analytical model is applied to investigate the effect of variations of the membrane prestress, added mass, and mass eccentricity on the diffuse transmission loss of a MAM panel with 120 unit cells. Unlike most previous investigations of MAMs, these results provide a better understanding of the acoustic performance of MAMs under more realistic conditions. For example, it is shown that by varying these parameters deliberately in a checkerboard pattern, a new anti-resonance with large transmission loss values can be introduced. A random variation of these parameters, on the other hand, is shown to have only little influence on the diffuse transmission loss, as long as the standard deviation is not too large. For very large random variations, it is shown that the peak transmission loss value can be greatly diminished.
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Published date: 17 March 2018
Additional Information:
Funding Information:
Parts of this work have been performed under the framework of the LuFo IV-4 project Comfortable Cabin for Low-Emission Aircraft (COCLEA), funded by the Federal Ministry for Economic Affairs and Energy (grant number: 20K1102D ). The financial support is gratefully acknowledged by the authors.
Publisher Copyright:
© 2017 Elsevier Ltd
Copyright:
Copyright 2018 Elsevier B.V., All rights reserved.
Keywords:
Baffled, Diffuse, Effective mass, Membrane, Metamaterial, Transmission loss
Identifiers
Local EPrints ID: 455449
URI: http://eprints.soton.ac.uk/id/eprint/455449
ISSN: 0022-460X
PURE UUID: 161115dd-c504-45f8-82af-fb09c102f0e8
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Date deposited: 22 Mar 2022 17:35
Last modified: 18 Mar 2024 04:05
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Author:
W. Gleine
Author:
O. von Estorff
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