COMPUTER SIMULATION TO PREDICT THE SLIDING WEAR OF PEARLITIC RAILS IN CONTACT BETWEEN CAST AND FORGED RAILWAY WHEELS

J. V. SILVA E SILVA, Luiz F.V. Corrêa, R. Camporez, C. Scandian, G. D. dos Santos
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Abstract

This work aims to implement and evaluate the effectiveness of the semi-analytical computational method global incremental wear model (GIWM) in predicting the sliding wear of rails in contact with the flange of railway wheels during curves, which is a parameter of great importance for the efficiency of railway operation. The method validation was performed by comparing the wear depth calculated using the GIWM algorithm to the experimental results published in previous work. The data was obtained in dry (relative humidity: 55% ± 10%) pin-on-disc tests carried out on a universal PLINT TE67 tribometer under a normal load of 24.6 N, representing 1.5 GPa of contact pressure. The specimens, hemispherical pins, were extracted from a pearlitic steel rail and the discs were extracted from two different, forged and cast, Class C railway wheels. The tangential sliding speeds were 0.1 m/s and 0.9 m/s, the latter being the most representative according to the literature. The wear model was based on Archard’s law for sliding wear and the algorithm was implemented in Python. The results showed good agreement of the wear depth values between the computational and experimental methods for the cast wheel material under higher sliding speed, partial agreement for both wheel materials at lower speed and inconsistency for the forged wheel material under higher sliding speed. Furthermore, the algorithm is computationally efficient, presenting simulation time up to 180 times less than the finite element methods reported in the literature. Therefore, it was concluded that the GIWM method has potential for application in the freight railway sector, which uses cast wheels extensively, to guide technical areas regarding the wear behavior of rails under sliding contact during curves.
用计算机模拟预测铸锻轮毂接触时珠光体轨道的滑动磨损
本文旨在实现并评估半解析计算方法全局增量磨损模型(GIWM)在预测铁路轮缘弯道接触轨道滑动磨损方面的有效性,这是一个对铁路运行效率至关重要的参数。将采用GIWM算法计算的磨损深度与前人发表的实验结果进行对比,验证方法的有效性。数据是在干燥(相对湿度:55%±10%)的pin-on-disc测试中获得的,在通用PLINT TE67摩擦计上进行,正常负载为24.6 N,代表1.5 GPa的接触压力。样品,半球形销,从珠光体钢轨中提取,圆盘从两个不同的,锻造和铸造的,C级铁路车轮中提取。切向滑动速度分别为0.1 m/s和0.9 m/s,文献中以0.9 m/s最具代表性。磨损模型基于滑动磨损的Archard定律,算法在Python中实现。结果表明,高滑动速度下铸造车轮材料的磨损深度计算值与实验值吻合较好,低滑动速度下两种车轮材料的磨损深度计算值部分吻合,高滑动速度下锻造车轮材料的磨损深度计算值不一致。此外,该算法计算效率高,模拟时间比文献中报道的有限元方法少180倍。因此,该方法在广泛使用铸造车轮的货运铁路领域具有应用潜力,可用于指导弯道滑动接触下钢轨磨损行为的技术领域。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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