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Plate-type acoustic metamaterials with strip masses

Plate-type acoustic metamaterials with strip masses
Plate-type acoustic metamaterials with strip masses
Plate-type acoustic metamaterials (PAM) consist of a thin plate with periodically added masses. Similar to membrane-type acoustic metamaterials, PAM exhibit anti-resonances at low frequencies at which the transmission loss can be much higher than the mass-law without requiring a pretension. Most PAM designs previously investigated in literature require the addition of up to thousands of masses per square meter. This makes manufacturing of such PAM prohibitively expensive for most applications. In this contribution, a much simpler PAM design with strip masses is investigated. An analytical model is derived which can be used to estimate the modal properties, effective mass, and oblique incidence sound transmission loss of PAM with strip masses. For high strip masses (compared to the baseplate), this analytical model can be simplified to yield explicit expressions to directly calculate the resonance and anti-resonance frequencies of such PAM. The analytical model is verified using numerical simulations and laboratory measurement results are presented to demonstrate the performance of PAM with strip masses under diffuse field excitation and finite sample size conditions.
0001-4966
3727-3738
Langfeldt, Felix
2bf86877-f2cd-4c35-be0f-e38a718a915c
Gleine, Wolfgang
6b99025f-b44a-46a8-b699-ec25962c7e75
Langfeldt, Felix
2bf86877-f2cd-4c35-be0f-e38a718a915c
Gleine, Wolfgang
6b99025f-b44a-46a8-b699-ec25962c7e75

Langfeldt, Felix and Gleine, Wolfgang (2021) Plate-type acoustic metamaterials with strip masses. Journal of the Acoustical Society of America, 149 (6), 3727-3738. (doi:10.1121/10.0005112).

Record type: Article

Abstract

Plate-type acoustic metamaterials (PAM) consist of a thin plate with periodically added masses. Similar to membrane-type acoustic metamaterials, PAM exhibit anti-resonances at low frequencies at which the transmission loss can be much higher than the mass-law without requiring a pretension. Most PAM designs previously investigated in literature require the addition of up to thousands of masses per square meter. This makes manufacturing of such PAM prohibitively expensive for most applications. In this contribution, a much simpler PAM design with strip masses is investigated. An analytical model is derived which can be used to estimate the modal properties, effective mass, and oblique incidence sound transmission loss of PAM with strip masses. For high strip masses (compared to the baseplate), this analytical model can be simplified to yield explicit expressions to directly calculate the resonance and anti-resonance frequencies of such PAM. The analytical model is verified using numerical simulations and laboratory measurement results are presented to demonstrate the performance of PAM with strip masses under diffuse field excitation and finite sample size conditions.

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JASA-06297 - Accepted Manuscript
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Accepted/In Press date: 10 May 2021
Published date: 2 June 2021

Identifiers

Local EPrints ID: 455624
URI: http://eprints.soton.ac.uk/id/eprint/455624
ISSN: 0001-4966
PURE UUID: 3377bb26-9aaf-4c01-a109-efbe3182d33b
ORCID for Felix Langfeldt: ORCID iD orcid.org/0000-0003-2380-2746

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Date deposited: 29 Mar 2022 16:47
Last modified: 17 Mar 2024 04:11

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Contributors

Author: Felix Langfeldt ORCID iD
Author: Wolfgang Gleine

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