Performance of Ballast Influenced by Deformation and Degradation: Laboratory Testing and Numerical Modeling
Publication: International Journal of Geomechanics
Volume 20, Issue 1
Abstract
This paper presents a study on the deformation and degradation responses of railway ballast using large-scale laboratory testing and computational modeling approaches. A series of large-scale triaxial tests were carried out to investigate the ballast breakage responses under cyclic train loading subjected to varying frequencies, . The role of recycled rubber energy-absorbing mats (REAMs) on reducing ballast breakage was also examined. Laboratory test results show that the ballast experiences significant degradation (breakage) and deformation, while the inclusion of REAMs can reduce the ballast breakage up to about 35%. Numerical modeling using the coupled discrete-continuum approach [coupled discrete-element method–finite-difference method (DEM-FDM)] is introduced to provide insightful understanding on the deformation and breaking of ballast under cyclic loading. Discrete ballast grains were simulated by bonding of many circular elements together at appropriate sizes and locations. Selected cylinders located at corners, surfaces, and sharp edges of the simulated particles were connected by parallel bonds; and when those bonds were broken, they were considered to represent ballast breakage. The subgrade and rubber mat were simulated as a continuum media using FDM. The predicted axial strain and volumetric strain obtained from the coupled DEM-FDM model are in good agreement with those measured in the laboratory. The model was then used to explore micromechanical aspects of ballast aggregates including the evolution of particle breakage, contact force distributions, and orientation of contacts during cyclic loading. These findings are imperative for a more insightful understanding of the breakage behavior of ballast from the perspective of microstructure characteristics of discrete particle assemblies.
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Acknowledgments
This research was conducted by the Australian Research Council Industrial Transformation Training Centre for Advanced Technologies in Rail Track Infrastructure (IC170100006) and funded by the Government of Australia. Collaboration with Tim Neville [Australian Rail Track Corporation (ARTC)] for encouraging the use of recycled REAMs in real-life tracks is also appreciated, with subsequent support from organizations including the Australasian Centre for Rail Innovation (ACRI) and Rail Manufacturing Cooperative Research Centre (RM CRC) (Project No. R2.5.1). The authors are also grateful to Alan Grant, Cameron Neilson, and Duncan Best for their assistance during the laboratory work. The authors also thank Robert Clayton (English editor) for proofreading and professionally editing the manuscript.
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©2019 American Society of Civil Engineers.
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Received: Jan 7, 2019
Accepted: Apr 23, 2019
Published online: Oct 23, 2019
Published in print: Jan 1, 2020
Discussion open until: Mar 23, 2020
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