2017
DOI: 10.1061/(asce)gt.1943-5606.0001669
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Use of Rubber Mats to Improve the Deformation and Degradation Behavior of Rail Ballast under Cyclic Loading

Abstract: The deterioration of a rail track due to large dynamic wheel loads is inevitable over the years, and one that leads to frequent and high maintenance costs. This problem is more critical in isolated rail track locations such as bridges and tunnels where the substructure is much stiffer than the surface track assembly. One measure used to minimize track deterioration is to place geosynthetic inclusions such as rubber mats under the layer of ballast. In this study, cyclic loads from fast and heavy haul trains wer… Show more

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Cited by 96 publications
(48 citation statements)
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References 46 publications
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“…In previous studies [33,46,49], almost all of the cycle load number, used to study permanent deformation characteristics or cumulative plastic strain of soil medium, are lower than one million times. In this manuscript, in order to present the residual deformation in more rigorous cases than previous studies, we assume 10 million times of cycle loads to predict the cumulative plastic strain of MSC used as subgrade material.…”
Section: Logarithmic Prediction Modelmentioning
confidence: 99%
“…In previous studies [33,46,49], almost all of the cycle load number, used to study permanent deformation characteristics or cumulative plastic strain of soil medium, are lower than one million times. In this manuscript, in order to present the residual deformation in more rigorous cases than previous studies, we assume 10 million times of cycle loads to predict the cumulative plastic strain of MSC used as subgrade material.…”
Section: Logarithmic Prediction Modelmentioning
confidence: 99%
“…These impact forces can likewise be generated at transition zones involving abrupt variations of vertical track stiffness, such as at the approaches to tunnels, bridge or viaduct and level crossings, or where there is a sudden change from conventional ballast to slab track intensifying ballast breakage and adversely affecting track stability [11][12][13][14][15]. One potential method of enhancing the substructure capacity to withstand the large cyclic and impact loads induced by fast-moving heavy-haul trains is to improve the performance of the ballast layer using plastic (e.g., geogrids) and rubber inclusions (e.g., rubber mat, tire cell, and rubber crumbs) [2,[11][12][13][14][15][16][17][18][19][20][21][22][23][24][25][26][27][28][29][30].…”
Section: Introductionmentioning
confidence: 99%
“…placed at the interfaces between rails and sleepers); (ii) under sleeper pads (i.e. placed at the sleeper/ballast interfaces); (iii) rubber mats installed beneath the ballast (shock mats); and (iv) ballast mixed with rubber crumbs or shreds [17,41,60]. The inclusion of rubber shock mats decreases the hard interface between the ballast aggregates and other track components, such as the sleepers or underlying formations, and allows the particles bedding into softer pads, thus enhancing the area of contact of the aggregates and minimising the inter-particle contact forces [42,47,51].…”
Section: Introductionmentioning
confidence: 99%