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Mitigation of railway induced ground vibration by heavy masses next to the track

Mitigation of railway induced ground vibration by heavy masses next to the track
Mitigation of railway induced ground vibration by heavy masses next to the track
The effectiveness of heavy masses next to the track as a measure for the reduction of railway induced ground vibration is investigated by means of numerical simulations. It is assumed that the heavy masses are placed in a continuous row along the track forming a wall. Such a continuous wall could be built as a gabion wall and also used as a noise barrier. Since the performance of mitigation measures on the transmission path strongly depends on local ground conditions, a parametric study is performed for a range of possible designs in a set of different ground types. A two-and-a-half dimensional coupled finite element–boundary element methodology is used, assuming that the geometry of the problem is uniform in the direction along the track. It is found that the heavy masses start to be effective above the mass–spring resonance frequency which is determined by the dynamic stiffness of the soil and the mass of the wall. At frequencies above this resonance frequency, masses at the soil?s surface hinder the propagation of surface waves. It is therefore beneficial to make the footprint of the masses as large and stiff as possible. For homogeneous soil conditions, the effectiveness is nearly independent of the distance behind the wall. In the case of a layered soil with a soft top layer, the vibration reduction strongly decreases with increasing distance from the wall.
ground-borne vibration, heavy masses, gabion wall, 2.5D modelling, coupled finite element–boundary element models
0267-7261
158-170
Dijckmans, A.
b37d2437-74fb-4ce7-a26d-56712b873ca7
Coulier, P.
93733f1d-0868-4f2f-87ed-96c003647ec4
Jiang, J.
0386a615-0f81-4824-a5a1-dea2b2735a4a
Toward, M.G.R.
1d10e993-e6ef-449d-bccb-1f8198169bee
Thompson, D.J.
bca37fd3-d692-4779-b663-5916b01edae5
Degrande, G.
c79408b0-fe8a-4b0c-a2e2-347ccd2e052a
Lombaert, G.
4e069245-6ec6-40fe-a767-46eabf4dcc2b
Dijckmans, A.
b37d2437-74fb-4ce7-a26d-56712b873ca7
Coulier, P.
93733f1d-0868-4f2f-87ed-96c003647ec4
Jiang, J.
0386a615-0f81-4824-a5a1-dea2b2735a4a
Toward, M.G.R.
1d10e993-e6ef-449d-bccb-1f8198169bee
Thompson, D.J.
bca37fd3-d692-4779-b663-5916b01edae5
Degrande, G.
c79408b0-fe8a-4b0c-a2e2-347ccd2e052a
Lombaert, G.
4e069245-6ec6-40fe-a767-46eabf4dcc2b

Dijckmans, A., Coulier, P., Jiang, J., Toward, M.G.R., Thompson, D.J., Degrande, G. and Lombaert, G. (2015) Mitigation of railway induced ground vibration by heavy masses next to the track. Soil Dynamics and Earthquake Engineering, 75, 158-170. (doi:10.1016/j.soildyn.2015.04.003).

Record type: Article

Abstract

The effectiveness of heavy masses next to the track as a measure for the reduction of railway induced ground vibration is investigated by means of numerical simulations. It is assumed that the heavy masses are placed in a continuous row along the track forming a wall. Such a continuous wall could be built as a gabion wall and also used as a noise barrier. Since the performance of mitigation measures on the transmission path strongly depends on local ground conditions, a parametric study is performed for a range of possible designs in a set of different ground types. A two-and-a-half dimensional coupled finite element–boundary element methodology is used, assuming that the geometry of the problem is uniform in the direction along the track. It is found that the heavy masses start to be effective above the mass–spring resonance frequency which is determined by the dynamic stiffness of the soil and the mass of the wall. At frequencies above this resonance frequency, masses at the soil?s surface hinder the propagation of surface waves. It is therefore beneficial to make the footprint of the masses as large and stiff as possible. For homogeneous soil conditions, the effectiveness is nearly independent of the distance behind the wall. In the case of a layered soil with a soft top layer, the vibration reduction strongly decreases with increasing distance from the wall.

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More information

Accepted/In Press date: 8 April 2015
e-pub ahead of print date: 28 April 2015
Published date: August 2015
Keywords: ground-borne vibration, heavy masses, gabion wall, 2.5D modelling, coupled finite element–boundary element models
Organisations: Dynamics Group

Identifiers

Local EPrints ID: 381758
URI: http://eprints.soton.ac.uk/id/eprint/381758
DOI: doi:10.1016/j.soildyn.2015.04.003
ISSN: 0267-7261
PURE UUID: 42100bba-a952-4b74-8126-e09d52c76605
ORCID for M.G.R. Toward: ORCID iD orcid.org/0000-0001-7334-4355
ORCID for D.J. Thompson: ORCID iD orcid.org/0000-0002-7964-5906

Catalogue record

Date deposited: 13 Oct 2015 09:32
Last modified: 15 Mar 2024 03:07

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Contributors

Author: A. Dijckmans
Author: P. Coulier
Author: J. Jiang
Author: M.G.R. Toward ORCID iD
Author: D.J. Thompson ORCID iD
Author: G. Degrande
Author: G. Lombaert

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