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Numerical investigation of railway subgrade stiffening : Critical speed and free-field vibrations

Malmborg, J. LU ; Persson, P. LU and Persson, K. LU (2022) In Transportation Geotechnics 34.
Abstract

For a train speed close to the speed of elastic waves in the soil, often referred to as “critical speed”, largely elevated vibration responses occur. This can be a practical problem for soft soil sites, where the phenomenon may cause excessive vibrations in the track and also at distances far from the track. To ensure the running safety of the train, the long-term quality of the track and to reduce the vibrations in the surroundings, such effects must be avoided. An effective counter-measure is to increase the stiffness of the soil underneath the track, thereby increasing the critical velocity. In this paper, a 2.5D finite element model is used for studying the critical velocity phenomenon and its mitigation through soil stiffening, for... (More)

For a train speed close to the speed of elastic waves in the soil, often referred to as “critical speed”, largely elevated vibration responses occur. This can be a practical problem for soft soil sites, where the phenomenon may cause excessive vibrations in the track and also at distances far from the track. To ensure the running safety of the train, the long-term quality of the track and to reduce the vibrations in the surroundings, such effects must be avoided. An effective counter-measure is to increase the stiffness of the soil underneath the track, thereby increasing the critical velocity. In this paper, a 2.5D finite element model is used for studying the critical velocity phenomenon and its mitigation through soil stiffening, for a ballasted track on a layered half-space with very soft soil. Soil improvement under the track, in the shape of a solid block or as various number of panels, with varying depth and stiffness is considered. The effect of the soil improvement is evaluated both in terms of the maximum rail and free-field displacements. It is shown that a shallow soil stiffening increases the critical velocity and reduces the rail and free-field response for load speeds near the shear wave velocity of the soft top soil layer. It is also demonstrated that a deep soil stiffening, by use of panels along the track direction, increases the critical velocity further, and may also be efficient in reducing the response for load speeds near the shear wave speed of the underlying half-space.

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author
; and
organization
publishing date
type
Contribution to journal
publication status
published
subject
keywords
2.5D finite elements, Lime–cement columns, Perfectly matched layers, Soil stabilization, Train-induced ground vibration
in
Transportation Geotechnics
volume
34
article number
100748
publisher
Elsevier
external identifiers
  • scopus:85126784009
ISSN
2214-3912
DOI
10.1016/j.trgeo.2022.100748
language
English
LU publication?
yes
id
8217fc4c-ce73-4a58-b1f9-d50d1d00cfef
date added to LUP
2022-04-19 12:54:26
date last changed
2022-04-21 08:05:56
@article{8217fc4c-ce73-4a58-b1f9-d50d1d00cfef,
  abstract     = {{<p>For a train speed close to the speed of elastic waves in the soil, often referred to as “critical speed”, largely elevated vibration responses occur. This can be a practical problem for soft soil sites, where the phenomenon may cause excessive vibrations in the track and also at distances far from the track. To ensure the running safety of the train, the long-term quality of the track and to reduce the vibrations in the surroundings, such effects must be avoided. An effective counter-measure is to increase the stiffness of the soil underneath the track, thereby increasing the critical velocity. In this paper, a 2.5D finite element model is used for studying the critical velocity phenomenon and its mitigation through soil stiffening, for a ballasted track on a layered half-space with very soft soil. Soil improvement under the track, in the shape of a solid block or as various number of panels, with varying depth and stiffness is considered. The effect of the soil improvement is evaluated both in terms of the maximum rail and free-field displacements. It is shown that a shallow soil stiffening increases the critical velocity and reduces the rail and free-field response for load speeds near the shear wave velocity of the soft top soil layer. It is also demonstrated that a deep soil stiffening, by use of panels along the track direction, increases the critical velocity further, and may also be efficient in reducing the response for load speeds near the shear wave speed of the underlying half-space.</p>}},
  author       = {{Malmborg, J. and Persson, P. and Persson, K.}},
  issn         = {{2214-3912}},
  keywords     = {{2.5D finite elements; Lime–cement columns; Perfectly matched layers; Soil stabilization; Train-induced ground vibration}},
  language     = {{eng}},
  publisher    = {{Elsevier}},
  series       = {{Transportation Geotechnics}},
  title        = {{Numerical investigation of railway subgrade stiffening : Critical speed and free-field vibrations}},
  url          = {{http://dx.doi.org/10.1016/j.trgeo.2022.100748}},
  doi          = {{10.1016/j.trgeo.2022.100748}},
  volume       = {{34}},
  year         = {{2022}},
}