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The sound radiation from a periodic array of railway sleepers using a wavenumber domain method

The sound radiation from a periodic array of railway sleepers using a wavenumber domain method
The sound radiation from a periodic array of railway sleepers using a wavenumber domain method
Rolling noise, radiated by the vibration of the wheels, and the track, is an important source of noise from railway operations. In ballasted track the sleepers supporting the rails form an important source of noise at low frequencies. There are difficulties to calculate their sound radiation using numerical models due to their discrete periodic nature and the infinite extent of the track. For the rail, which has invariant geometry in the axial direction, the wavenumber domain (2.5D) finite element or boundary element method can be used to calculate the vibration and noise radiation. However, the 2.5D method cannot be used directly to predict the vibration and sound radiation of railway sleepers due to their discrete spacing. In this work, the discrete spacing of the sleepers in the spatial domain is introduced into the 2.5D method by applying a series of rectangular windows according to the sleeper width and spacing. The vibration of the sleepers in the wavenumber domain is obtained by applying a spatial Fourier transform to the product of these windows and the rail transfer mobility, also allowing for the ratio between the sleeper vibration and the rail vibration. The sleeper radiation obtained from the proposed approach is compared with the result obtained from the Rayleigh integral method, showing good agreement. The mobilities of the sleepers in the wavenumber domain are used to explain the effect of the sleeper spacing on the sound radiation. The spectrum of response in the wavenumber domain contains multiple waves, shifted in wavenumber by multiples of 2π⁄L, where L is the sleeper spacing. At low frequency, only the fundamental wave corresponding to the rail wavenumber radiates power to the far field; the ratio of the sound power of discrete sleepers to that of continuous sleepers is shown to be equal to the square of the width-to-spacing ratio. As the frequency increases, new wave branches enter the acoustic wavenumber range, leading to peaks in the radiation efficiency. At high frequency, the ratio of the sound powers converges to a constant value equal to the ratio of areas.
2.5D, boundary element method, railway track, sleeper radiation, wavenumber domain, window function, Sleeper radiation, Windows, Boundary element method, Wavenumber, Railway track
0022-460X
Li, Hui
37fd0f10-ba76-442b-90b7-03b9a92f1581
Xiao, Xinbiao
17694d1b-3dac-4c40-98de-bea4ea24a1de
Thompson, David
bca37fd3-d692-4779-b663-5916b01edae5
Squicciarini, Giacomo
c1bdd1f6-a2e8-435c-a924-3e052d3d191e
Li, Hui
37fd0f10-ba76-442b-90b7-03b9a92f1581
Xiao, Xinbiao
17694d1b-3dac-4c40-98de-bea4ea24a1de
Thompson, David
bca37fd3-d692-4779-b663-5916b01edae5
Squicciarini, Giacomo
c1bdd1f6-a2e8-435c-a924-3e052d3d191e

Li, Hui, Xiao, Xinbiao, Thompson, David and Squicciarini, Giacomo (2023) The sound radiation from a periodic array of railway sleepers using a wavenumber domain method. Journal of Sound and Vibration, 561, [117818]. (doi:10.1016/j.jsv.2023.117818).

Record type: Article

Abstract

Rolling noise, radiated by the vibration of the wheels, and the track, is an important source of noise from railway operations. In ballasted track the sleepers supporting the rails form an important source of noise at low frequencies. There are difficulties to calculate their sound radiation using numerical models due to their discrete periodic nature and the infinite extent of the track. For the rail, which has invariant geometry in the axial direction, the wavenumber domain (2.5D) finite element or boundary element method can be used to calculate the vibration and noise radiation. However, the 2.5D method cannot be used directly to predict the vibration and sound radiation of railway sleepers due to their discrete spacing. In this work, the discrete spacing of the sleepers in the spatial domain is introduced into the 2.5D method by applying a series of rectangular windows according to the sleeper width and spacing. The vibration of the sleepers in the wavenumber domain is obtained by applying a spatial Fourier transform to the product of these windows and the rail transfer mobility, also allowing for the ratio between the sleeper vibration and the rail vibration. The sleeper radiation obtained from the proposed approach is compared with the result obtained from the Rayleigh integral method, showing good agreement. The mobilities of the sleepers in the wavenumber domain are used to explain the effect of the sleeper spacing on the sound radiation. The spectrum of response in the wavenumber domain contains multiple waves, shifted in wavenumber by multiples of 2π⁄L, where L is the sleeper spacing. At low frequency, only the fundamental wave corresponding to the rail wavenumber radiates power to the far field; the ratio of the sound power of discrete sleepers to that of continuous sleepers is shown to be equal to the square of the width-to-spacing ratio. As the frequency increases, new wave branches enter the acoustic wavenumber range, leading to peaks in the radiation efficiency. At high frequency, the ratio of the sound powers converges to a constant value equal to the ratio of areas.

Text
2.5D sleepers-Final Version - Accepted Manuscript
Restricted to Repository staff only until 23 May 2025.
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More information

Accepted/In Press date: 23 May 2023
e-pub ahead of print date: 24 May 2023
Published date: 29 September 2023
Additional Information: Funding Information: This work has been funded by the National Natural Science Foundation of China (No. U1934203 ), and the Sichuan Science and Technology Program (2020YJ0076). Publisher Copyright: © 2023
Keywords: 2.5D, boundary element method, railway track, sleeper radiation, wavenumber domain, window function, Sleeper radiation, Windows, Boundary element method, Wavenumber, Railway track

Identifiers

Local EPrints ID: 477785
URI: http://eprints.soton.ac.uk/id/eprint/477785
ISSN: 0022-460X
PURE UUID: f7182f94-bd9d-4f28-a37e-3a2fd9207532
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: 14 Jun 2023 16:46
Last modified: 17 Mar 2024 03:27

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Contributors

Author: Hui Li
Author: Xinbiao Xiao
Author: David Thompson ORCID iD

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