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S. Hawksbee¹, I. Grossoni¹, Y. Bezin¹, B. Lee², G. Watson³, D. Milne³, L. Le Pen^3,4, T. Abadi³ and P. Jorge¹

¹Institute of Railway Research, University of Huddersfield, United Kingdom
²Network Rail, United Kingdom
³University of Southampton, United Kingdom
⁴Ramboll, United Kingdom

doi:10.4203/ccc.1.5.6

S. Hawksbee, I. Grossoni, Y. Bezin, B. Lee, G. Watson, D. Milne, L. Le Pen, T. Abadi, P. Jorge, "Modelling the improved behaviour of a switch installed on ballast-asphalt track", in J. Pombo, (Editor), "Proceedings of the Fifth International Conference on Railway Technology: Research, Development and Maintenance", Civil-Comp Press, Edinburgh, UK, Online volume: CCC 1, Paper 5.6, 2022, doi:10.4203/ccc.1.5.6

Keywords: asphalt track, switches and crossings, vehicle-track interaction, finite element method.

Abstract

Switches and crossings are a critical part of railway infrastructure and have a complex superstructure, creating variable support and bending stiffness along the track length. These variable structural and loading effects lead to faster rates of track geometry deterioration compared with plain line. Multibody vehicle-track interaction and finite element models combined with empirical predictions have been used to assess the likely benefits and improvements of using an asphalt layer combined with reduced ballast depth under S&C, in terms of long-term ballast differential settlement as well as in terms of reducing stress levels within the ballast and the subgrade layers. The assessment is primarily comparative against a baseline scenario site without asphalt layer. The introduction of asphalt track configurations reduced the variation in trackbed stiffness and increased stiffness throughout the switch panel. Using stresses calculated from finite element modelling, the ballast settlement was calculated using a semi-empirical equation to account for higher load cycles. The introduction of the asphalt layer reduced both maximum and differential settlements, originating from the ballast layer, in the switch panel with respect to the baseline scenario. Furthermore, the maximum stresses transmitted to the subgrade are generally reduced for both asphalt thicknesses with respect to the baseline.

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Front Page Browse CCC CCP CSETS CTR IJRT Other Authors Search Purchase Guide FAQ Contact us	Civil-Comp Conferences ISSN 2753-3239 CCC: 1 PROCEEDINGS OF THE FIFTH INTERNATIONAL CONFERENCE ON RAILWAY TECHNOLOGY: RESEARCH, DEVELOPMENT AND MAINTENANCE Edited by: J. Pombo Paper 5.6 Modelling the improved behaviour of a switch installed on ballast-asphalt track S. Hawksbee¹, I. Grossoni¹, Y. Bezin¹, B. Lee², G. Watson³, D. Milne³, L. Le Pen^3,4, T. Abadi³ and P. Jorge¹ ¹Institute of Railway Research, University of Huddersfield, United Kingdom ²Network Rail, United Kingdom ³University of Southampton, United Kingdom ⁴Ramboll, United Kingdom doi:10.4203/ccc.1.5.6 Full Bibliographic Reference for this paper S. Hawksbee, I. Grossoni, Y. Bezin, B. Lee, G. Watson, D. Milne, L. Le Pen, T. Abadi, P. Jorge, "Modelling the improved behaviour of a switch installed on ballast-asphalt track", in J. Pombo, (Editor), "Proceedings of the Fifth International Conference on Railway Technology: Research, Development and Maintenance", Civil-Comp Press, Edinburgh, UK, Online volume: CCC 1, Paper 5.6, 2022, doi:10.4203/ccc.1.5.6 Keywords: asphalt track, switches and crossings, vehicle-track interaction, finite element method. Abstract Switches and crossings are a critical part of railway infrastructure and have a complex superstructure, creating variable support and bending stiffness along the track length. These variable structural and loading effects lead to faster rates of track geometry deterioration compared with plain line. Multibody vehicle-track interaction and finite element models combined with empirical predictions have been used to assess the likely benefits and improvements of using an asphalt layer combined with reduced ballast depth under S&C, in terms of long-term ballast differential settlement as well as in terms of reducing stress levels within the ballast and the subgrade layers. The assessment is primarily comparative against a baseline scenario site without asphalt layer. The introduction of asphalt track configurations reduced the variation in trackbed stiffness and increased stiffness throughout the switch panel. Using stresses calculated from finite element modelling, the ballast settlement was calculated using a semi-empirical equation to account for higher load cycles. The introduction of the asphalt layer reduced both maximum and differential settlements, originating from the ballast layer, in the switch panel with respect to the baseline scenario. Furthermore, the maximum stresses transmitted to the subgrade are generally reduced for both asphalt thicknesses with respect to the baseline. download the full-text of this paper (PDF, 8 pages, 707 Kb) go to the previous paper go to the next paper return to the table of contents return to the volume description
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