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Investigation of transient wheel-rail interaction and interface contact behaviour in movable-point crossing panel

Chaojiang Hao, Ping Wang, Jingmang Xu, Yibin Liu, Jiayin Chen, Boyang An, Qiang Yi, Shuguo Wang

2023Vehicle System Dynamics12 citationsDOI

Abstract

The high-speed turnout is a key part of railway track infrastructure. A process of wheel-load transition and single-wheel/multi-track contact take place in the turnout area, causing significant wheel-rail interaction. Most high-speed turnouts include movable-point crossings. To investigate the wheel-rail transient rolling contact behaviour in movable-point crossings, a 3D finite element (FE) model of a wheelset rolling over a crossing was introduced. The actual geometrical profile of the wheel and the rails in turnouts, the nonlinear materials, the actual relative motion between the point/wing rail, and the moving postures of the wheelset were considered. The simulated mode shape was compared with the experimental mode shape to verify the wheel-rail coupling model. Precise frictional rolling contact solutions and dynamic response, including wheel-rail force, contact stress, equivalent stress, equivalent plastic strain, and stick-slip distribution of the contact patches, were all studied. After this, the parametric analysis of dynamic wheel-rail contact behaviour was carried out. The simulated results indicate that the proposed explicit finite element method can characterise wheel-rail coupled dynamic interaction and mesoscopic rolling contact behaviour well, and improve the understanding of wheel-rail contact behaviour in the movable-point crossing panel of the high-speed turnouts.

Topics & Concepts

BallastFinite element methodEngineeringStructural engineeringContact mechanicsTrack (disk drive)Contact patchSlip (aerodynamics)Contact forceFastenerPoint (geometry)Parametric statisticsSlippageMechanical engineeringMaterials sciencePhysicsElectrical engineeringTreadGeometryAerospace engineeringComposite materialMathematicsStatisticsNatural rubberQuantum mechanicsRailway Engineering and DynamicsMechanical stress and fatigue analysisAdhesion, Friction, and Surface Interactions