A theoretical study of the fundamental torsional wave in buried pipes for pipeline condition assessment and monitoring
A theoretical study of the fundamental torsional wave in buried pipes for pipeline condition assessment and monitoring
Waves that propagate at low frequencies in buried pipes are of considerable interest in a variety of practical scenarios, for example leak detection, remote pipe detection, and pipeline condition assessment and monitoring. Whilst there has been considerable research and commercial attention on the accurate location of pipe leakage for many years, the various causes of pipe failures and their identification, have not been well documented; moreover, there are still a number of gaps in the existing knowledge. Previous work has focused on two of the three axisymmetric wavetypes that can propagate: the s=1, fluid-dominated wave; and the s=2, shell-dominated wave. In this paper, the third axisymmetric wavetype, the s=0 torsional wave, is investigated. The effects of the surrounding soil on the characteristics of wave propagation and attenuation are analyzed for a compact pipe/soil interface for which there is no relative motion between the pipe wall and the surrounding soil. An analytical dispersion relationship is derived for the torsional wavenumber from which both the wavespeed and wave attenuation can be obtained. How torsional waves can subsequently radiate to the ground surface is then investigated. Analytical expressions are derived for the ground surface displacement above the pipe resulting from torsional wave motion within the pipe wall. A numerical model is also included, primarily in order to validate some of the assumptions made whilst developing the analytical solutions, but also so that some comparison in the results may be made. Example results are presented for both a cast iron pipe and an MDPE pipe buried in two typical soil types.
buried pipes, torsional wave, dispersion relationship, spiral fracture, ground surface vibration, condition monitoring, wave propagation
155-171
Muggleton, Jennifer
2298700d-8ec7-4241-828a-1a1c5c36ecb5
Kalkowski, Michal
6f0d01ef-7f44-459c-82a2-03f9e1275eda
Gao, Yan
23154085-596b-483e-8c31-79916fca87ea
Rustighi, Emiliano
9544ced4-5057-4491-a45c-643873dfed96
21 July 2016
Muggleton, Jennifer
2298700d-8ec7-4241-828a-1a1c5c36ecb5
Kalkowski, Michal
6f0d01ef-7f44-459c-82a2-03f9e1275eda
Gao, Yan
23154085-596b-483e-8c31-79916fca87ea
Rustighi, Emiliano
9544ced4-5057-4491-a45c-643873dfed96
Muggleton, Jennifer, Kalkowski, Michal, Gao, Yan and Rustighi, Emiliano
(2016)
A theoretical study of the fundamental torsional wave in buried pipes for pipeline condition assessment and monitoring.
Journal of Sound and Vibration, 374, .
(doi:10.1016/j.jsv.2016.03.035).
Abstract
Waves that propagate at low frequencies in buried pipes are of considerable interest in a variety of practical scenarios, for example leak detection, remote pipe detection, and pipeline condition assessment and monitoring. Whilst there has been considerable research and commercial attention on the accurate location of pipe leakage for many years, the various causes of pipe failures and their identification, have not been well documented; moreover, there are still a number of gaps in the existing knowledge. Previous work has focused on two of the three axisymmetric wavetypes that can propagate: the s=1, fluid-dominated wave; and the s=2, shell-dominated wave. In this paper, the third axisymmetric wavetype, the s=0 torsional wave, is investigated. The effects of the surrounding soil on the characteristics of wave propagation and attenuation are analyzed for a compact pipe/soil interface for which there is no relative motion between the pipe wall and the surrounding soil. An analytical dispersion relationship is derived for the torsional wavenumber from which both the wavespeed and wave attenuation can be obtained. How torsional waves can subsequently radiate to the ground surface is then investigated. Analytical expressions are derived for the ground surface displacement above the pipe resulting from torsional wave motion within the pipe wall. A numerical model is also included, primarily in order to validate some of the assumptions made whilst developing the analytical solutions, but also so that some comparison in the results may be made. Example results are presented for both a cast iron pipe and an MDPE pipe buried in two typical soil types.
Text
paper_surface wave s0 accepted version.docx
- Accepted Manuscript
More information
Accepted/In Press date: 28 March 2016
e-pub ahead of print date: 16 April 2016
Published date: 21 July 2016
Keywords:
buried pipes, torsional wave, dispersion relationship, spiral fracture, ground surface vibration, condition monitoring, wave propagation
Organisations:
Dynamics Group
Identifiers
Local EPrints ID: 391303
URI: http://eprints.soton.ac.uk/id/eprint/391303
ISSN: 0022-460X
PURE UUID: 49410d95-f944-475b-826c-0fd6bf20f42b
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Date deposited: 13 Apr 2016 09:40
Last modified: 15 Mar 2024 05:29
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Author:
Yan Gao
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