Effects of Filler Wire Intervention on Gas Tungsten Arc: Part II - Dynamic Behaviors of Liquid Droplets

IF 2.2 3区材料科学 Q2 METALLURGY & METALLURGICAL ENGINEERING

Welding Journal Pub Date : 2020-10-01 DOI:10.29391/2020.99.025

S. Zou, Zhijiang Wang, Sheng-Sun Hu, G. Zhao, Wandong Wang, You-Quan Chen

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引用次数: 4

Abstract

In gas tungsten arc welding (GTAW), the filler wire increases the deposition efficiency and influences the welding stability. Its interactions with the gas tungsten arc (GTA) are significant to better understand the welding process and to monitor and control weld quality. In view of this, the first part of the work, Effects of Filler Wire Intervention on Gas Tungsten Arc: Part I — Mechanism, explained the interaction mechanisms between the filler wire and the gas tungsten arc based on the proposed arc-sensing method of detecting probe voltage (i.e., the voltage signal between the filler wire and the tungsten electrode/workpiece). In this second part of the work, experiments were designed to make the filler wire melt in different areas of the arc to study the dynamic behaviors of the droplet and its effect on the arc. Typical metal transfer modes are discussed, and droplet oscillation is geometrically characterized through image processing and then analyzed in the time domain and time-frequency domain. The results show that the liquid droplet affects the arc through its transfer to the weld pool, its oscillation, and occupying the arc space. Information about these dynamic behaviors can be easily reflected in the probe voltage, which would be a valuable signal to monitor the process stability in GTAW with filler wire. This work shows the potential of the proposed sensing method for monitoring and controlling weld quality in all welding positions, GTA-based additive manufacturing, etc.

查看原文本刊更多论文

填充丝介入对气体钨电弧的影响:第二部分-液滴的动态行为

在钨极气体保护焊（GTAW）中，填充焊丝提高了沉积效率并影响了焊接稳定性。它与钨极气体保护焊（GTA）的相互作用对于更好地了解焊接过程以及监测和控制焊接质量具有重要意义。有鉴于此，本工作的第一部分《填充线干预对钨极气体电弧的影响：第一部分——机理》基于所提出的探测探针电压（即填充线与钨极/工件之间的电压信号）的电弧传感方法，解释了填充线与气相钨极之间的相互作用机制。在这项工作的第二部分中，设计了使填充焊丝在电弧的不同区域熔化的实验，以研究液滴的动态行为及其对电弧的影响。讨论了典型的金属转移模式，并通过图像处理对液滴振荡进行了几何表征，然后在时域和时频域进行了分析。结果表明，液滴通过转移到熔池、振荡和占据电弧空间来影响电弧。关于这些动态行为的信息可以很容易地反映在探针电压中，这将是监测填充焊丝GTAW工艺稳定性的有价值的信号。这项工作显示了所提出的传感方法在监测和控制所有焊接位置的焊接质量、基于GTA的增材制造等方面的潜力。

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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来源期刊

Welding Journal 工程技术-冶金工程

CiteScore

3.00

自引率

0.00%

发文量

审稿时长

3 months

期刊介绍： The Welding Journal has been published continually since 1922 — an unmatched link to all issues and advancements concerning metal fabrication and construction. Each month the Welding Journal delivers news of the welding and metal fabricating industry. Stay informed on the latest products, trends, technology and events via in-depth articles, full-color photos and illustrations, and timely, cost-saving advice. Also featured are articles and supplements on related activities, such as testing and inspection, maintenance and repair, design, training, personal safety, and brazing and soldering.