Nonlinear Thermal Analysis for Qing-Tibet Railway Embankments in Cold Regions
Publication: Journal of Cold Regions Engineering
Volume 17, Issue 4
Abstract
Heat convection in ballast mass in railway embankments is a problem of heat convection in porous media. In order to calculate the temperature distribution of the Qing-Tibet railway embankment from the governing equations used to study forced convection for incompressible fluids porous media, detailed finite-element formulas for heat convection in porous media are derived using Galerkin’s method. The temperature distributions on central lines of the traditional railway embankment, the ripped-rock embankment, and the ripped-rock revetment embankment that were constructed on July 15, 2002 have been analyzed and compared on July 15, October 15 in the 24th year after construction, and January 15 in the 25th year after construction under the climatic and geological conditions on the Qing-Tibet Railway. The calculated results indicate that the traditional railway embankment will raise the permafrost temperature under the embankment base and make the permafrost embankment thermally unstable. The ripped-rock embankment and the ripped-rock revetment embankment will reduce the permafrost temperature under the embankment base in cold regions, therefore maintaining the thermal stability of permafrost. However, the ripped-rock embankment needs more rock mass while the ripped-rock revetment embankment need less rock mass, and its construction cost is lower than that of the former. Therefore, it is highly recommended that the ripped-rock revetment embankment be used for the Qing-Tibet railway embankment structure in high temperature permafrost regions so that the permafrost embankment can be protected as much as possible.
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Information & Authors
Information
Published In
Journal of Cold Regions Engineering
Volume 17 • Issue 4 • December 2003
Pages: 171 - 184
Copyright
Copyright © 2003 American Society of Civil Engineers.
History
Received: Mar 27, 2002
Accepted: Aug 29, 2003
Published online: Nov 14, 2003
Published in print: Dec 2003
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