有限元法
材料科学
复合材料
结构工程
机械工程
工程类
汽车工程
作者
Chunyan He,Zhen Yang,Pan Zhang,Rolf Dollevoet,Zili Li
标识
DOI:10.1016/j.triboint.2025.110666
摘要
Frictional heat is generated at the wheel-rail interface during train operations, particularly under high slip ratios during acceleration and braking. Thermal effects can accelerate wear, induce plastic deformation, and contribute to thermal fatigue. Reliable modelling of wheel-rail contact that considers friction-induced thermal effects is desirable for the accurate prediction of wheel-rail interface deterioration. Several analytical and numerical models have been proposed to simulate thermal or thermomechanical wheel-rail loads but have rarely been validated, especially in high slip ratio scenarios where flash temperatures exceed 200 °C. This study develops and experimentally validates a three-dimensional thermomechanical finite element (FE) wheel-rail contact model for high slip ratio conditions, with contact temperatures reaching 360 °C. The model incorporates key mechanical parameters, including wheel loads, coefficients of friction, and slip ratios. Simulated rail surface temperatures across various slip ratios (5 %, 10 %, and 15 %) are compared with the flash temperatures measured with an onboard infrared thermal camera, showing good agreement with a maximum deviation of 9.9 %. This confirms the reliability of the model for simulating wheel-rail contact under thermal effects. • Proposed a thermomechanical FE model for wheel-rail frictional rolling contact. • Measured continuously wheel-rail contact temperature using a thermal camera. • Achieved good agreement between the modelling and measurement up to high slip ratios. • Provided for the first time validation of the FE thermal contact modeling up to 360°C. • Identified a linear relationship between wheel-rail slip ratio and contact temperature.
科研通智能强力驱动
Strongly Powered by AbleSci AI