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轮轨接触条件对铁路车轮微观结构和硬度的影响。

The influence of wheel/rail contact conditions on the microstructure and hardness of railway wheels.

作者信息

Molyneux-Berry Paul, Davis Claire, Bevan Adam

机构信息

Institute of Railway Research, School of Computing and Engineering, University of Huddersfield, Queensgate, Huddersfield HD1 3DH, UK.

School of Metallurgy and Materials, University of Birmingham, Edgbaston, Birmingham B15 2TT, UK.

出版信息

ScientificWorldJournal. 2014 Jan 16;2014:209752. doi: 10.1155/2014/209752. eCollection 2014.

DOI:10.1155/2014/209752
PMID:24526883
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3914578/
Abstract

The susceptibility of railway wheels to wear and rolling contact fatigue damage is influenced by the properties of the wheel material. These are influenced by the steel composition, wheel manufacturing process, and thermal and mechanical loading during operation. The in-service properties therefore vary with depth below the surface and with position across the wheel tread. This paper discusses the stress history at the wheel/rail contact (derived from dynamic simulations) and observed variations in hardness and microstructure. It is shown that the hardness of an "in-service" wheel rim varies significantly, with three distinct effects. The underlying hardness trend with depth can be related to microstructural changes during manufacturing (proeutectoid ferrite fraction and pearlite lamellae spacing). The near-surface layer exhibits plastic flow and microstructural shear, especially in regions which experience high tangential forces when curving, with consequentially higher hardness values. Between 1 mm and 7 mm depth, the wheel/rail contacts cause stresses exceeding the material yield stress, leading to work hardening, without a macroscopic change in microstructure. These changes in material properties through the depth of the wheel rim would tend to increase the likelihood of crack initiation on wheels toward the end of their life. This correlates with observations from several train fleets.

摘要

铁路车轮对磨损和滚动接触疲劳损伤的敏感性受车轮材料性能的影响。而这些性能又受钢的成分、车轮制造工艺以及运行期间的热负荷和机械负荷的影响。因此,服役期间的性能会随着距表面深度以及车轮踏面不同位置而变化。本文讨论了车轮/钢轨接触处的应力历史(由动态模拟得出)以及观察到的硬度和微观结构变化。结果表明,“服役”车轮轮辋的硬度变化显著,有三种不同的影响因素。随着深度变化的基本硬度趋势可能与制造过程中的微观结构变化有关(先共析铁素体分数和珠光体片层间距)。近表面层呈现塑性流动和微观结构剪切,尤其是在弯道处承受高切向力的区域,因此硬度值更高。在深度1毫米至7毫米之间,车轮/钢轨接触产生的应力超过材料屈服应力,导致加工硬化,而微观结构没有宏观变化。轮辋深度方向上材料性能的这些变化往往会增加车轮在使用寿命末期出现裂纹萌生的可能性。这与多个列车车组的观察结果相关。

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