Thermal imaging of railways to identify rack sections prone to buckling

Lee Chapman; John Thornes; SP White

Thermal imaging of railways to identify rack sections prone to buckling

Lee Chapman, John Thornes, SP White

Research output: Contribution to journal › Article

Abstract

A technique is described to measure the spatial variation of rail temperatures with a view to highlighting sections of railway track prone to buckling in extreme temperatures. Thermal maps of a section of test track were produced by equipping a personnel carrier with a thermal imager and global positioning system (GPS). Temperature readings were taken using the rusted web (side) of the rail so that emissivity could be assumed constant. The results indicate that much of the spatial variation in daytime rail temperature can be explained by shading effects, with exposed sections of track on embankments being consistently the warmest and, therefore, the most prone to buckling. It is envisaged that the technique could be used to forecast the problem areas and will ultimately provide useful verification data for spatial modelling studies.

Original language	English
Pages (from-to)	317-327
Number of pages	11
Journal	Proceedings of the Institution of Mechanical Engineers Part F: Journal of Rail and Rapid Transport
Volume	220
Publication status	Published - 1 Jan 2006

Keywords

thermal imaging
rail buckling
rail microclimate

Cite this

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title = "Thermal imaging of railways to identify rack sections prone to buckling",

abstract = "A technique is described to measure the spatial variation of rail temperatures with a view to highlighting sections of railway track prone to buckling in extreme temperatures. Thermal maps of a section of test track were produced by equipping a personnel carrier with a thermal imager and global positioning system (GPS). Temperature readings were taken using the rusted web (side) of the rail so that emissivity could be assumed constant. The results indicate that much of the spatial variation in daytime rail temperature can be explained by shading effects, with exposed sections of track on embankments being consistently the warmest and, therefore, the most prone to buckling. It is envisaged that the technique could be used to forecast the problem areas and will ultimately provide useful verification data for spatial modelling studies.",

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author = "Lee Chapman and John Thornes and SP White",

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journal = "Proceedings of the Institution of Mechanical Engineers Part F: Journal of Rail and Rapid Transport",

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T1 - Thermal imaging of railways to identify rack sections prone to buckling

AU - Chapman, Lee

AU - Thornes, John

AU - White, SP

PY - 2006/1/1

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N2 - A technique is described to measure the spatial variation of rail temperatures with a view to highlighting sections of railway track prone to buckling in extreme temperatures. Thermal maps of a section of test track were produced by equipping a personnel carrier with a thermal imager and global positioning system (GPS). Temperature readings were taken using the rusted web (side) of the rail so that emissivity could be assumed constant. The results indicate that much of the spatial variation in daytime rail temperature can be explained by shading effects, with exposed sections of track on embankments being consistently the warmest and, therefore, the most prone to buckling. It is envisaged that the technique could be used to forecast the problem areas and will ultimately provide useful verification data for spatial modelling studies.

AB - A technique is described to measure the spatial variation of rail temperatures with a view to highlighting sections of railway track prone to buckling in extreme temperatures. Thermal maps of a section of test track were produced by equipping a personnel carrier with a thermal imager and global positioning system (GPS). Temperature readings were taken using the rusted web (side) of the rail so that emissivity could be assumed constant. The results indicate that much of the spatial variation in daytime rail temperature can be explained by shading effects, with exposed sections of track on embankments being consistently the warmest and, therefore, the most prone to buckling. It is envisaged that the technique could be used to forecast the problem areas and will ultimately provide useful verification data for spatial modelling studies.

KW - thermal imaging

KW - rail buckling

KW - rail microclimate

M3 - Article

SN - 2041-3017

VL - 220

SP - 317

EP - 327

JO - Proceedings of the Institution of Mechanical Engineers Part F: Journal of Rail and Rapid Transport

JF - Proceedings of the Institution of Mechanical Engineers Part F: Journal of Rail and Rapid Transport

ER -

Thermal imaging of railways to identify rack sections prone to buckling

Abstract

Keywords

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