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A framework to predict the airborne noise inside railway vehicles with application to rolling noise

A framework to predict the airborne noise inside railway vehicles with application to rolling noise
A framework to predict the airborne noise inside railway vehicles with application to rolling noise
A framework is described for predicting the airborne noise inside railway vehicles which is applied to rolling noise sources. Statistical energy analysis (SEA) is used to predict the interior noise by subdividing the train cabin into several subsystems. The dissipation loss factors are obtained from the measured reverberation time in the train cabin. The power input to the interior SEA model is obtained from the external noise sources by multiplying the incident sound power on the external surfaces with measured transmission coefficients of the train floor and sidewalls. The sound power incident on the train floor is calculated by using an equivalent source model for the wheels and track together with an SEA model of the region below the floor. The incident sound power on the sides is obtained by using a waveguide boundary element (2.5D BE) method. The procedure is applied to a Spanish metro train vehicle running in the open field for which rolling noise is the main external noise source. The procedure is verified by field measurements of sound pressure beneath the carriage, on the sidewalls and inside the vehicle. The sensitivity of the results to changes in interior absorption is also studied, including the effect of passengers.
Railway vehicle, interior noise, statistical energy analysis, 2.5D boundary element method, rolling noise
0003-682X
Li, Hui
cd351a7f-09cb-4e44-9ea4-e77594f4d4f5
Thompson, David
bca37fd3-d692-4779-b663-5916b01edae5
Squicciarini, Giacomo
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Liu, Xiaowan
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Rissmann, Martin
085d551d-c0ca-4aa9-ba28-a62eaa725bc2
Bouvet, Pascal
1c215149-9fd3-4604-a39d-b27d6ee9f6f4
D. Denia, Francisco
247187d6-f5bd-41cd-a253-5f7d2d2dbc06
Baeza, Luis
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Jarillo, Julián Martín
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García-Loygorri, Juan Moreno
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Li, Hui
cd351a7f-09cb-4e44-9ea4-e77594f4d4f5
Thompson, David
bca37fd3-d692-4779-b663-5916b01edae5
Squicciarini, Giacomo
c1bdd1f6-a2e8-435c-a924-3e052d3d191e
Liu, Xiaowan
85bbaeb6-7fb2-429b-8f29-3a889480d2fd
Rissmann, Martin
085d551d-c0ca-4aa9-ba28-a62eaa725bc2
Bouvet, Pascal
1c215149-9fd3-4604-a39d-b27d6ee9f6f4
D. Denia, Francisco
247187d6-f5bd-41cd-a253-5f7d2d2dbc06
Baeza, Luis
6ec5eb71-1dfb-453e-b816-e168859b551a
Jarillo, Julián Martín
9720fb07-7d95-4e4e-9ea8-ab5b62ad654d
García-Loygorri, Juan Moreno
2ae985fb-9a39-4188-913d-f086ba9e6d2c

Li, Hui, Thompson, David, Squicciarini, Giacomo, Liu, Xiaowan, Rissmann, Martin, Bouvet, Pascal, D. Denia, Francisco, Baeza, Luis, Jarillo, Julián Martín and García-Loygorri, Juan Moreno (2021) A framework to predict the airborne noise inside railway vehicles with application to rolling noise. Applied Acoustics, 179, [108064]. (doi:10.1016/j.apacoust.2021.108064).

Record type: Article

Abstract

A framework is described for predicting the airborne noise inside railway vehicles which is applied to rolling noise sources. Statistical energy analysis (SEA) is used to predict the interior noise by subdividing the train cabin into several subsystems. The dissipation loss factors are obtained from the measured reverberation time in the train cabin. The power input to the interior SEA model is obtained from the external noise sources by multiplying the incident sound power on the external surfaces with measured transmission coefficients of the train floor and sidewalls. The sound power incident on the train floor is calculated by using an equivalent source model for the wheels and track together with an SEA model of the region below the floor. The incident sound power on the sides is obtained by using a waveguide boundary element (2.5D BE) method. The procedure is applied to a Spanish metro train vehicle running in the open field for which rolling noise is the main external noise source. The procedure is verified by field measurements of sound pressure beneath the carriage, on the sidewalls and inside the vehicle. The sensitivity of the results to changes in interior absorption is also studied, including the effect of passengers.

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A framework to predict the airborne noise inside railway vehicles with application to rolling noise - Accepted Manuscript
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Accepted/In Press date: 22 March 2021
e-pub ahead of print date: 14 April 2021
Keywords: Railway vehicle, interior noise, statistical energy analysis, 2.5D boundary element method, rolling noise

Identifiers

Local EPrints ID: 469893
URI: http://eprints.soton.ac.uk/id/eprint/469893
ISSN: 0003-682X
PURE UUID: f5141836-ca1c-4bf3-815a-319aa138d6bc
ORCID for David Thompson: ORCID iD orcid.org/0000-0002-7964-5906
ORCID for Giacomo Squicciarini: ORCID iD orcid.org/0000-0003-2437-6398

Catalogue record

Date deposited: 28 Sep 2022 16:37
Last modified: 17 Mar 2024 07:29

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Contributors

Author: Hui Li
Author: David Thompson ORCID iD
Author: Xiaowan Liu
Author: Martin Rissmann
Author: Pascal Bouvet
Author: Francisco D. Denia
Author: Luis Baeza
Author: Julián Martín Jarillo
Author: Juan Moreno García-Loygorri

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