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contributor authorXin He
contributor authorWanming Zhai
contributor authorYunlong Guo
date accessioned2026-02-16T21:45:11Z
date available2026-02-16T21:45:11Z
date copyright2025/02/01
date issued2025
identifier otherIJGNAI.GMENG-10307.pdf
identifier urihttp://yetl.yabesh.ir/yetl1/handle/yetl/4309677
description abstractHanging sleepers, which result from the differential settlement of the ballast layer, are a prevalent issue that leads to the rapid degradation of track components that include the ballast, sleeper, fastener, and rail. A novel type of sleeper, the wedge-shaped self-leveling sleeper (WSS), was proposed as a solution to the hanging sleeper problem. The WSS leverages the train’s dynamic loading and the gravity of the ballast to naturally allow the ballast particles to fill the gap between the ballast and the sleeper. This paper focuses on the dynamic performance of the WSS from different aspects, which include wedge angles (30°, 45°, and 60°), sleeper materials (concrete and plastic), and the number of WSS to replace regular sleepers in the transition zone. A series of numerical modeling [which coupled multibody simulation (MBS) and discrete-element methods (DEM)] were conducted to design, optimize, and test the WSS. The results reveal that a concrete WSS is well-suited to address the problem of hanging sleepers in transition zones. The WSS with a 45° angle demonstrated superior performance compared with other types of WSS. Importantly, the WSS could reduce vibrations in the vehicle and track, even when dealing with hanging sleepers. Due to the self-leveling function, the WSS shows significant promise for applications in transition zones, which could reduce the frequent need for track geometry maintenance.
publisherAmerican Society of Civil Engineers
titleDynamic Performance of Wedge-Shaped Self-Leveling Sleepers in Railway Transition Zones
typeJournal Article
journal volume25
journal issue2
journal titleInternational Journal of Geomechanics
identifier doi10.1061/IJGNAI.GMENG-10307
journal fristpage04024344-1
journal lastpage04024344-17
page17
treeInternational Journal of Geomechanics:;2025:;Volume ( 025 ):;issue: 002
contenttypeFulltext


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