Selection of Welding Conditions for Achieving Both a High Efficiency and Low Heat Input for Hot-Wire Gas Metal Arc Welding

IF 3.3 Q2 ENGINEERING, MANUFACTURING

Journal of Manufacturing and Materials Processing Pub Date : 2024-04-18 DOI:10.3390/jmmp8020082

Keita Marumoto, A. Fujinaga, Takeshi Takahashi, Hikaru Yamamoto, Motomichi Yamamoto

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Abstract

This study presents a new gas metal arc welding (GMAW) technique that achieves both high efficiency and low heat input using a hybridization of the hot-wire method. The optimal combination of welding speed and welding current conditions was investigated using a fixed hot-wire feeding speed of 10 m/min on a butt joint with a V-shaped groove using 19 mm thick steel plates. Molten pool stability and defect formation were observed using high-speed imaging and cross-sectional observations. The power consumption and heat input were predicted prior to welding and measured in the experiments. The results indicate that a combination of a welding current of 350–500 A and welding speed of 0.3–0.7 m/min is optimal to avoid defect formation and molten metal precedence using three or four passes. The higher efficiency and lower heat input achieved by hot-wire GMAW results in a weld metal of adequate hardness, narrower heat-affected zone, smaller grain size at the fusion boundary, and lower power consumption than those obtained using tandem GMAW and high-current GMAW. Based on the experimental results, a single bevel groove, which is widely used in construction machinery welding joints, was welded using hot-wire GMAW, and we confirmed that the welding part could be welded in six passes, whereas eight passes were required with GMAW only.

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为热丝气体金属弧焊选择既高效又低热输入的焊接条件

本研究介绍了一种新型气体金属弧焊（GMAW）技术，该技术采用热丝混合法实现了高效率和低热量输入。在使用 19 毫米厚钢板焊接带 V 形槽的对接接头时，采用 10 米/分钟的固定热丝送丝速度，研究了焊接速度和焊接电流条件的最佳组合。通过高速成像和横截面观察，观察了熔池的稳定性和缺陷的形成。焊接前对功率消耗和热输入进行了预测，并在实验中进行了测量。结果表明，焊接电流为 350-500 A，焊接速度为 0.3-0.7 m/min，这样的组合是避免缺陷形成和熔融金属先于三道或四道焊接的最佳选择。与串联 GMAW 和大电流 GMAW 相比，热丝 GMAW 具有更高的效率和更低的热输入，因此焊接金属具有足够的硬度、更窄的热影响区、更小的熔合边界晶粒度和更低的功率消耗。根据实验结果，我们使用热丝 GMAW 焊接了工程机械焊接接头中广泛使用的单坡口槽，并确认焊接部件可在六道次内完成焊接，而仅使用 GMAW 则需要八道次。

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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