Simulation of nonuniform heating induced by alternating-current rail flash butt welding at the end face

IF 2.4 4区 材料科学 Q2 METALLURGY & METALLURGICAL ENGINEERING Welding in the World Pub Date : 2024-08-10 DOI:10.1007/s40194-024-01821-6
Xiao Wang, Hui Chen, Zongtao Zhu, Meiqi Hao, Hongtao Tan, Yuhu Pei, Qibing Lv
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Abstract

Nonuniform temperature field upsetting is prone to oxide inclusions, and the temperature field of rail flash butt welding (FBW) is primarily formed because of the Joule heat generated by the end-face current. The current distribution at the end face largely determines the heat distribution; thus, the current distribution and heat production at the end face of an alternating-current (AC) FBW must be investigated. This study combined finite element simulation and experimental validation to establish an AC rail FBW electric–magnetic–thermal coupling model to explore the influence of current parameters, end-face temperature, and feed mode on the distribution of the end-face current. The results show that a reduction in the welding current, current frequency, and time in low- and medium-temperature stages can improve the uniformity of the temperature field. The electrode clamping method determines the shape of the temperature field, whereas the proposed hybrid clamping method is the most conducive to uniform heat generation at the end face. Moreover, electrode clamping at 210 mm near the end face yielded uniform temperature fields. The experimental validation results were consistent with the calculated results, indicating that the proposed model is reasonable and reliable. In practical welding operations, it is advisable to optimize current and frequency to achieve an end face temperature > 1000 °C swiftly. This study provides a direction for enhancing the uniformity of the temperature field and improving the expulsion capability of impurities during the upsetting process, thereby optimizing the flash butt welding process for rails.

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模拟交变电流钢轨端面闪光对接焊引起的不均匀加热
不均匀的温度场镦粗容易产生氧化物夹杂,而轨道闪光对焊(FBW)的温度场主要是由端面电流产生的焦耳热形成的。端面的电流分布在很大程度上决定了热量分布;因此,必须研究交流 (AC) FBW 端面的电流分布和发热情况。本研究结合有限元仿真和实验验证,建立了交流轨道 FBW 电-磁-热耦合模型,以探讨电流参数、端面温度和进给模式对端面电流分布的影响。结果表明,降低低温和中温阶段的焊接电流、电流频率和时间可以改善温度场的均匀性。电极夹紧方法决定了温度场的形状,而所提出的混合夹紧方法最有利于端面均匀发热。此外,在端面附近 210 毫米处夹紧电极可产生均匀的温度场。实验验证结果与计算结果一致,表明所提出的模型合理可靠。在实际焊接操作中,最好优化电流和频率,以迅速达到端面温度 > 1000 °C。这项研究为提高镦粗过程中温度场的均匀性和杂质的排出能力提供了一个方向,从而优化了钢轨闪光对焊工艺。
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来源期刊
Welding in the World
Welding in the World METALLURGY & METALLURGICAL ENGINEERING-
CiteScore
4.20
自引率
14.30%
发文量
181
审稿时长
6-12 weeks
期刊介绍: The journal Welding in the World publishes authoritative papers on every aspect of materials joining, including welding, brazing, soldering, cutting, thermal spraying and allied joining and fabrication techniques.
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