Broadband low-frequency sound transmission loss improvement of double walls with Helmholtz resonators
Broadband low-frequency sound transmission loss improvement of double walls with Helmholtz resonators
Helmholtz resonators are commonly used as narrowband sound absorbers in room acoustics applications. Previous research has shown that Helmholtz resonators can also be used to improve the sound transmission loss of double walls. The focus of this paper is the broadband improvement of the transmission loss of double walls in the low frequency region by tuning the Helmholtz resonators inside the cavity to frequencies lower or higher than the mass-air-mass resonance frequency of the double wall. A new analytical model using the effective material parameters (bulk modulus and density) of a fluid volume containing Helmholtz resonators is developed to describe the vibro-acoustic behavior of double walls with Helmholtz resonators. Using this model it can be shown that by tuning the Helmholtz resonators properly, the mass-air-mass resonance frequency of the unmodified double wall can be shifted significantly, leading to an improvement of the transmission loss of the double wall roughly between the mass-air-mass resonance frequency and the resonance frequency of the resonators. This improvement, however, comes along with a decrease of the transmission loss at high frequencies due to a decoupling of the Helmholtz resonators which is also covered by the proposed analytical model. Parametric studies are performed to identify relevant design parameters to optimize the transmission loss improvement by the Helmholtz resonators. Finally, experimental results of different double wall designs with integrated Helmholtz resonators are presented to validate the proposed analytical model and demonstrate the effectiveness under diffuse field incidence.
Resonance frequency, Filling ratio, Effective bulk modulus, Effective density, Analytical model, Sound intensity measurement
Langfeldt, F.
2bf86877-f2cd-4c35-be0f-e38a718a915c
Hoppen, Hannah
f609ed2b-6b7a-4a2e-89c9-45fd11ee50a0
Gleine, Wolfgang
6b99025f-b44a-46a8-b699-ec25962c7e75
23 June 2020
Langfeldt, F.
2bf86877-f2cd-4c35-be0f-e38a718a915c
Hoppen, Hannah
f609ed2b-6b7a-4a2e-89c9-45fd11ee50a0
Gleine, Wolfgang
6b99025f-b44a-46a8-b699-ec25962c7e75
Langfeldt, F., Hoppen, Hannah and Gleine, Wolfgang
(2020)
Broadband low-frequency sound transmission loss improvement of double walls with Helmholtz resonators.
Journal of Sound and Vibration, 476, [115309].
(doi:10.1016/j.jsv.2020.115309).
Abstract
Helmholtz resonators are commonly used as narrowband sound absorbers in room acoustics applications. Previous research has shown that Helmholtz resonators can also be used to improve the sound transmission loss of double walls. The focus of this paper is the broadband improvement of the transmission loss of double walls in the low frequency region by tuning the Helmholtz resonators inside the cavity to frequencies lower or higher than the mass-air-mass resonance frequency of the double wall. A new analytical model using the effective material parameters (bulk modulus and density) of a fluid volume containing Helmholtz resonators is developed to describe the vibro-acoustic behavior of double walls with Helmholtz resonators. Using this model it can be shown that by tuning the Helmholtz resonators properly, the mass-air-mass resonance frequency of the unmodified double wall can be shifted significantly, leading to an improvement of the transmission loss of the double wall roughly between the mass-air-mass resonance frequency and the resonance frequency of the resonators. This improvement, however, comes along with a decrease of the transmission loss at high frequencies due to a decoupling of the Helmholtz resonators which is also covered by the proposed analytical model. Parametric studies are performed to identify relevant design parameters to optimize the transmission loss improvement by the Helmholtz resonators. Finally, experimental results of different double wall designs with integrated Helmholtz resonators are presented to validate the proposed analytical model and demonstrate the effectiveness under diffuse field incidence.
Text
JSV-D-20-00065
- Accepted Manuscript
More information
Accepted/In Press date: 7 March 2020
e-pub ahead of print date: 10 March 2020
Published date: 23 June 2020
Keywords:
Resonance frequency, Filling ratio, Effective bulk modulus, Effective density, Analytical model, Sound intensity measurement
Identifiers
Local EPrints ID: 455627
URI: http://eprints.soton.ac.uk/id/eprint/455627
ISSN: 0022-460X
PURE UUID: 658fb867-070c-48af-bd21-183ae665224d
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Date deposited: 29 Mar 2022 16:47
Last modified: 17 Mar 2024 07:08
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Contributors
Author:
Hannah Hoppen
Author:
Wolfgang Gleine
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