Abstract
One of the most important aspects in railway operation is the interaction between rail and wheel. Railway wheels are commonly made from medium carbon steels (∼ 0.55 wt.% C), heat treated to a near pearlitic microstructure with some 5–10% pro-eutectoid ferrite. During the operation of freight trains, where block brakes are used, high thermal loads are evolved because of recurring braking and occasional slippage. Thus the combination of mechanical and thermal loads leads to changes in the mechanical properties of the material. The focus of the current investigation is to evaluate the mechanical behaviour of wheel material (UIC ER7T) subjected to non-proportional biaxial fatigue loading, as this simulates the actual working conditions in a better way than uniaxial loading. Axial-torsional low cycle fatigue tests were performed at room temperature and elevated temperatures using thin walled specimens to study the cyclic stress-strain properties of this material. The results showed large influence of temperature on the ratcheting behaviour of the material. Biaxial non-proportional loading gave much higher strain hardening as compared to uniaxial loading. Hardening due to dynamic strain ageing can be seen in the biaxial tests at temperatures around 300°C.
Highlights
One of the common engineering applications for steel these days lies within the railway industry, for the manufacturing of rails and wheels
There is little further hardening after the initial cycles
The main goal of the investigation in this paper was to compare the biaxial loading behaviour of this material with uniaxial fatigue tests performed in a previous work by the authors
Summary
One of the common engineering applications for steel these days lies within the railway industry, for the manufacturing of rails and wheels. These steels have a predominantly pearlitic microstructure and for wheel material, they consist of carbon steels with around 0.55 wt.% carbon. The forging and subsequent heat treatment that these wheels undergo, produces a fine pearlitic microstructure with some 5% proeutectoid ferrite. Steels with this microstructure exhibit a very good combination of wear and strength properties, which are very suitable for railway applications. Biaxial experiments with non-proportional loading at elevated temperature simulates the actual working conditions in a better way than uniaxial loading
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