Investigation into the critical speed of ballastless track
Investigation into the critical speed of ballastless track
As train speeds are increased, the issue of the critical speed must be faced, especially when tracks run across soft ground. This is the phenomenon describes the amplification of the track deflections due to coincidence of the train speed with the wavespeeds of the underlying ground. Modern high-speed lines are often constructed on ballastless track which has different dynamic behaviour to conventional ballasted track. Therefore, further research is needed to investigate the critical speed of ballastless track. In this paper, a dynamic analysis model comprising track, embankment and ground is presented based on the two-and-half-dimensional (2.5D) finite element method to predict the vibrations generated by train moving loads. The rails and track slab are modeled as Euler-Bernoulli beams resting on the embankment. The concrete base, embankment and ground are modeled by the 2.5D finite elements. The results show that the critical speed of ballastless track is higher than the Rayleigh wave velocity of the underlying soil and quite close to the Rayleigh wave velocity of the subgrade. The existence of the subgrade can highly improve the critical speed of the ballastless track even with a shallow subgrade of 1.25 m depth. The underlying soil stiffness is the conclusive factor in determining the track vibration amplitude. It is also found that the embankment plays an essential role in reducing the inhomogeneity of the lateral stress distribution and the amplitude of vertical stress in ballastless track.
2.5D finite element method, Ballastless track, Critical speed, Dynamic stress, High-speed train
142-148
Hu, Jing
915d2ade-ccec-4366-a6d3-7deb0cb21682
Bian, Xuecheng
b0dbeeda-cee0-4870-ab0b-be795d7e045c
Xu, Weichang
ba270044-562d-43ef-a9af-52a8f5215168
Thompson, David
bca37fd3-d692-4779-b663-5916b01edae5
1 March 2019
Hu, Jing
915d2ade-ccec-4366-a6d3-7deb0cb21682
Bian, Xuecheng
b0dbeeda-cee0-4870-ab0b-be795d7e045c
Xu, Weichang
ba270044-562d-43ef-a9af-52a8f5215168
Thompson, David
bca37fd3-d692-4779-b663-5916b01edae5
Hu, Jing, Bian, Xuecheng, Xu, Weichang and Thompson, David
(2019)
Investigation into the critical speed of ballastless track.
Transportation Geotechnics, 18, .
(doi:10.1016/j.trgeo.2018.12.004).
Abstract
As train speeds are increased, the issue of the critical speed must be faced, especially when tracks run across soft ground. This is the phenomenon describes the amplification of the track deflections due to coincidence of the train speed with the wavespeeds of the underlying ground. Modern high-speed lines are often constructed on ballastless track which has different dynamic behaviour to conventional ballasted track. Therefore, further research is needed to investigate the critical speed of ballastless track. In this paper, a dynamic analysis model comprising track, embankment and ground is presented based on the two-and-half-dimensional (2.5D) finite element method to predict the vibrations generated by train moving loads. The rails and track slab are modeled as Euler-Bernoulli beams resting on the embankment. The concrete base, embankment and ground are modeled by the 2.5D finite elements. The results show that the critical speed of ballastless track is higher than the Rayleigh wave velocity of the underlying soil and quite close to the Rayleigh wave velocity of the subgrade. The existence of the subgrade can highly improve the critical speed of the ballastless track even with a shallow subgrade of 1.25 m depth. The underlying soil stiffness is the conclusive factor in determining the track vibration amplitude. It is also found that the embankment plays an essential role in reducing the inhomogeneity of the lateral stress distribution and the amplitude of vertical stress in ballastless track.
Text
INVESTIGATION INTO THE CRITICAL SPEED OF BALLASTLESS TRACK
- Accepted Manuscript
More information
Accepted/In Press date: 18 December 2018
e-pub ahead of print date: 19 December 2018
Published date: 1 March 2019
Keywords:
2.5D finite element method, Ballastless track, Critical speed, Dynamic stress, High-speed train
Identifiers
Local EPrints ID: 427102
URI: http://eprints.soton.ac.uk/id/eprint/427102
ISSN: 2214-3912
PURE UUID: cc597017-d176-4948-bcaa-9fe0a904d7e0
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Date deposited: 03 Jan 2019 10:27
Last modified: 18 Mar 2024 05:21
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Author:
Jing Hu
Author:
Xuecheng Bian
Author:
Weichang Xu
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