An investigation into the physical mechanisms of leak noise propagation in buried plastic water pipes: a wave dynamic stiffness approach
An investigation into the physical mechanisms of leak noise propagation in buried plastic water pipes: a wave dynamic stiffness approach
In buried plastic water pipes, the predominantly fluid-borne wave is of particular interest, as it plays a key role in the propagation of leak noise. Consequently, it has been studied by several researchers to determine the speed of wave propagation and its attenuation with distance. These features are encapsulated in the wavenumber. By examining the factors that govern the behaviour of this wavenumber, this paper presents an in-depth examination of the physical mechanisms of leak noise propagation. To achieve this, an alternative physics-based model for the wavenumber is developed, using the concept of the wave dynamic stiffnesses of the individual components within the pipe system, i.e., the water in the pipe, the pipe wall, and the surrounding medium. This facilitates a clear interpretation of the wave behaviour in terms of the physical properties of the system, especially the interface between the pipe and the surrounding medium, which can have a profound influence on the leakage of acoustic energy from the pipe wall into the external medium. Three systems with different types of surrounding medium are studied, and the factors that govern leak noise propagation in each case are identified. Experimental results on two distinct test sites from different parts of the world are provided to validate the approach using leak noise as an excitation mechanism.
buried plastic water pipes, leak noise wave propagation, predominantly fluid-borne wavenumber, wave dynamic stiffness
157-176
Scussel, Oscar
8053c543-be90-460c-83ed-4e3844074c93
Brennan, Michael J.
87c7bca3-a9e5-46aa-9153-34c712355a13
Muggleton, Jennifer M.
2298700d-8ec7-4241-828a-1a1c5c36ecb5
De Almeida, Fabricio C.L.
01273850-b785-4ffd-859b-5aa501ead4d3
Joseph, Phillip F.
9c30491e-8464-4c9a-8723-2abc62bdf75d
Gao, Yan
e6c9bd91-0023-4266-b018-d09bb3e322bb
March 2024
Scussel, Oscar
8053c543-be90-460c-83ed-4e3844074c93
Brennan, Michael J.
87c7bca3-a9e5-46aa-9153-34c712355a13
Muggleton, Jennifer M.
2298700d-8ec7-4241-828a-1a1c5c36ecb5
De Almeida, Fabricio C.L.
01273850-b785-4ffd-859b-5aa501ead4d3
Joseph, Phillip F.
9c30491e-8464-4c9a-8723-2abc62bdf75d
Gao, Yan
e6c9bd91-0023-4266-b018-d09bb3e322bb
Scussel, Oscar, Brennan, Michael J., Muggleton, Jennifer M., De Almeida, Fabricio C.L., Joseph, Phillip F. and Gao, Yan
(2024)
An investigation into the physical mechanisms of leak noise propagation in buried plastic water pipes: a wave dynamic stiffness approach.
Acoustics, 6 (1), .
(doi:10.3390/acoustics6010009).
Abstract
In buried plastic water pipes, the predominantly fluid-borne wave is of particular interest, as it plays a key role in the propagation of leak noise. Consequently, it has been studied by several researchers to determine the speed of wave propagation and its attenuation with distance. These features are encapsulated in the wavenumber. By examining the factors that govern the behaviour of this wavenumber, this paper presents an in-depth examination of the physical mechanisms of leak noise propagation. To achieve this, an alternative physics-based model for the wavenumber is developed, using the concept of the wave dynamic stiffnesses of the individual components within the pipe system, i.e., the water in the pipe, the pipe wall, and the surrounding medium. This facilitates a clear interpretation of the wave behaviour in terms of the physical properties of the system, especially the interface between the pipe and the surrounding medium, which can have a profound influence on the leakage of acoustic energy from the pipe wall into the external medium. Three systems with different types of surrounding medium are studied, and the factors that govern leak noise propagation in each case are identified. Experimental results on two distinct test sites from different parts of the world are provided to validate the approach using leak noise as an excitation mechanism.
Text
acoustics_2799618
- Author's Original
Text
acoustics-06-00009
- Version of Record
More information
Accepted/In Press date: 25 January 2024
e-pub ahead of print date: 1 February 2024
Published date: March 2024
Additional Information:
Funding information:
The authors are grateful for the financial support provided by the São Paulo Research Foundation (FAPESP) under grant numbers 2013/50412-3, 2018/25360-3, 2019/00745-2, and 2020/12251-1. Scussel is grateful for the support from Coordination for the Improvement of Higher Education Personnel (CAPES) under rant number 88887.374001/2019-00 and EPSRC under the project RAINDROP (EP/V028111/1). The authors would also like to thank the Brazilian water and waste management company Sabesp for part-funding this work and for providing one of the test rigs.
Publisher Copyright:
© 2024 by the authors.
Keywords:
buried plastic water pipes, leak noise wave propagation, predominantly fluid-borne wavenumber, wave dynamic stiffness
Identifiers
Local EPrints ID: 488177
URI: http://eprints.soton.ac.uk/id/eprint/488177
ISSN: 2624-599X
PURE UUID: 7cda16f9-b3ea-4d87-93df-c4c9f02b1a1e
Catalogue record
Date deposited: 17 Mar 2024 07:20
Last modified: 13 Apr 2024 02:03
Export record
Altmetrics
Contributors
Author:
Michael J. Brennan
Author:
Fabricio C.L. De Almeida
Author:
Yan Gao
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics
