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Measurements and modelling of dynamic stiffness of a railway vehicle primary suspension element and its use in a structure-borne noise transmission model

Measurements and modelling of dynamic stiffness of a railway vehicle primary suspension element and its use in a structure-borne noise transmission model
Measurements and modelling of dynamic stiffness of a railway vehicle primary suspension element and its use in a structure-borne noise transmission model
The noise inside railway vehicles is transmitted by both structure-borne and airborne paths and, although there are many sources, the rolling noise is often the most important. This paper focuses on the structure-borne transmission of rolling noise in a metro vehicle. Measurements are presented first of the vertical and lateral dynamic stiffness of a primary suspension element consisting of conical rubber/metal elements. Results are presented for various constant preloads over the frequency range 60-600 Hz. An analytical model of the suspension element is also developed, based on a mass-spring system and including wave motion within the rubber elements. The dynamic stiffness results are used in a finite element model of the running gear, consisting of the bogie frame, wheelsets and suspension elements. The excitation is provided by the combined wheel/rail roughness at the contact point. This model is used to calculate the blocked forces at the connection points between the secondary suspension elements and the car body. The blocked forces are combined with measured vibro-acoustic transfer functions from these mounting points to the vehicle interior to determine the structure-borne noise inside the vehicle. The proposed methodology is validated against measurements during operation in terms of acceleration levels, blocked forces and structure-borne noise levels inside the vehicle, showing reasonably good agreement. Including the dynamic stiffness for the primary suspension leads to improved agreement between 100 and 500 Hz compared with using a constant stiffness.
FE method, Primary suspension, dynamic stiffness, structure-borne noise transmission
0003-682X
Liu, Xiaowan
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Thompson, David
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Squicciarini, Giacomo
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Rissmann, Martin
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Bouvet, Pascal
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Xie, Gang
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Martínez-Casas, J.
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Carballeira, Javier
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Lopez Arteaga, Ines
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Garralaga, Miguel
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Chover, José
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Liu, Xiaowan
85bbaeb6-7fb2-429b-8f29-3a889480d2fd
Thompson, David
bca37fd3-d692-4779-b663-5916b01edae5
Squicciarini, Giacomo
c1bdd1f6-a2e8-435c-a924-3e052d3d191e
Rissmann, Martin
085d551d-c0ca-4aa9-ba28-a62eaa725bc2
Bouvet, Pascal
1c215149-9fd3-4604-a39d-b27d6ee9f6f4
Xie, Gang
e0263fb8-0c53-4790-97ee-273424cfd0c0
Martínez-Casas, J.
0dc0fd56-e99b-4fb3-a20d-029ef73b0fd7
Carballeira, Javier
0fa87fc5-759c-4a2d-8424-6c754e55e31b
Lopez Arteaga, Ines
1f5140b0-2710-4e90-aac1-b4e27de2d7a7
Garralaga, Miguel
bd100032-49d7-4706-be39-71c23b3dfc39
Chover, José
43773601-ecae-4f3e-9941-a64ce6f08ca7

Liu, Xiaowan, Thompson, David, Squicciarini, Giacomo, Rissmann, Martin, Bouvet, Pascal, Xie, Gang, Martínez-Casas, J., Carballeira, Javier, Lopez Arteaga, Ines, Garralaga, Miguel and Chover, José (2021) Measurements and modelling of dynamic stiffness of a railway vehicle primary suspension element and its use in a structure-borne noise transmission model. Applied Acoustics, 182, [108232]. (doi:10.1016/j.apacoust.2021.108232).

Record type: Article

Abstract

The noise inside railway vehicles is transmitted by both structure-borne and airborne paths and, although there are many sources, the rolling noise is often the most important. This paper focuses on the structure-borne transmission of rolling noise in a metro vehicle. Measurements are presented first of the vertical and lateral dynamic stiffness of a primary suspension element consisting of conical rubber/metal elements. Results are presented for various constant preloads over the frequency range 60-600 Hz. An analytical model of the suspension element is also developed, based on a mass-spring system and including wave motion within the rubber elements. The dynamic stiffness results are used in a finite element model of the running gear, consisting of the bogie frame, wheelsets and suspension elements. The excitation is provided by the combined wheel/rail roughness at the contact point. This model is used to calculate the blocked forces at the connection points between the secondary suspension elements and the car body. The blocked forces are combined with measured vibro-acoustic transfer functions from these mounting points to the vehicle interior to determine the structure-borne noise inside the vehicle. The proposed methodology is validated against measurements during operation in terms of acceleration levels, blocked forces and structure-borne noise levels inside the vehicle, showing reasonably good agreement. Including the dynamic stiffness for the primary suspension leads to improved agreement between 100 and 500 Hz compared with using a constant stiffness.

Text
Xiaowan Liu, David Thompson, Giacomo Squicciarini_ Measurements and modelling of dynamic stiffness of a railway vehicle primary suspension element and its use in - Accepted Manuscript
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Accepted/In Press date: 7 June 2021
e-pub ahead of print date: 17 June 2021
Published date: November 2021
Additional Information: Funding Information: The work presented in this paper has received funding from the Shift2Rail Joint Undertaking under the European Union’s Horizon 2020 research and innovation programme (grant agreement no. 777564). The contents of this publication only reflect the authors’ views and the Joint Undertaking is not responsible for any use that may be made of the information contained in the paper. Funding Information: The work presented in this paper has received funding from the Shift2Rail Joint Undertaking under the European Union's Horizon 2020 research and innovation programme (grant agreement no. 777564). The contents of this publication only reflect the authors? views and the Joint Undertaking is not responsible for any use that may be made of the information contained in the paper. The authors are grateful to CAF (Construcciones y Auxiliar de Ferrocarriles), and especially to Ainara Guiral, for assistance with information on the vehicles. The authors are also grateful to Francisco D. Denia and Juan Giner-Navarro from UPV, Bruno Delescluse from Vibratec, Juli?n Mart?n Jarillo and Juan Moreno Garc?a-Loygorri from Metro de Madrid for their assistance with the measurements. Publisher Copyright: © 2021 Elsevier Ltd
Keywords: FE method, Primary suspension, dynamic stiffness, structure-borne noise transmission

Identifiers

Local EPrints ID: 449894
URI: http://eprints.soton.ac.uk/id/eprint/449894
ISSN: 0003-682X
PURE UUID: c88dd6fb-93c7-402a-8452-26a0008a6526
ORCID for David Thompson: ORCID iD orcid.org/0000-0002-7964-5906
ORCID for Giacomo Squicciarini: ORCID iD orcid.org/0000-0003-2437-6398

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Date deposited: 24 Jun 2021 16:30
Last modified: 17 Mar 2024 06:38

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Contributors

Author: Xiaowan Liu
Author: David Thompson ORCID iD
Author: Martin Rissmann
Author: Pascal Bouvet
Author: Gang Xie
Author: J. Martínez-Casas
Author: Javier Carballeira
Author: Ines Lopez Arteaga
Author: Miguel Garralaga
Author: José Chover

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