Plasma Welding of Aluminum in an Oxygen-Free Argon Atmosphere

IF 1.5 Q4 MATERIALS SCIENCE, MULTIDISCIPLINARY Advances in Materials Science Pub Date : 2023-03-01 DOI:10.2478/adms-2023-0001
J. Klett, B. Bongartz, T. Wolf, Chentong Hao, H. Maier, T. Hassel
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引用次数: 1

Abstract

Abstract Plasma welding is characterized by a high concentration of energy, which allows for high welding speed and leads to less distortion and residual stresses compared to conventional welding processes. Due to the local and controlled heat input, the process is suitable for sheet metal from ≈ 0.1 mm (micro plasma) up to ≈ 10 mm. In the case of aluminum and its alloys, the natural aluminum oxide layer on the metal surface limits the productivity of the plasma welding process. The electrically isolating and thermally insulating Al2O3 layer has a significantly higher melting point compared to the aluminum (Tm(Al2O3) = 2072 °C vs. Tm(Al) = 660 °C). The oxide layer hinders the formation of a stable arc and can even impede the joining formation. In order to remove the oxide layer and to produce quality welds with a DC process, it is necessary to weld with reverse polarity to use the principle of cathodic surface cleaning. However, this leads to increased electrode wear and increased penetration depth, which is not always desirable. In the study presented, the use of silane to reduce the oxygen content in the welding atmosphere as well as to remove the natural aluminum oxide layer on the metal surface was investigated. As previous studies have shown that the use of silane-doped plasma-gases is suitable for removing the superficial oxide layer on aluminum components, high-quality welded joints were expected. Quality welds with sufficient dilution were achieved using a transferred arc silane-doped helium plasma. In contrast, welding with an argon-silane mixture led to excessive pores formation. Additionally challenges to stabilize the arc process were identified and ramifications with respect to process optimization are discussed.
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铝在无氧氩气环境中的等离子焊接
与传统焊接工艺相比,等离子焊接具有能量高度集中、焊接速度快、变形小、残余应力小的特点。由于局部和可控的热输入,该工艺适用于≈0.1 mm(微等离子体)至≈10 mm的金属板材。就铝及其合金而言,金属表面的天然氧化铝层限制了等离子焊接工艺的生产率。与铝相比,电隔离和隔热的Al2O3层具有明显更高的熔点(Tm(Al2O3) = 2072°C vs Tm(Al) = 660°C)。氧化层阻碍了稳定电弧的形成,甚至阻碍了连接的形成。为了去除氧化层,用直流工艺生产出高质量的焊缝,有必要利用阴极表面清洗原理进行反极性焊接。然而,这会导致电极磨损增加和穿透深度增加,这并不总是理想的。在本研究中,研究了利用硅烷降低焊接气氛中的氧含量以及去除金属表面天然氧化铝层的方法。以往的研究表明,使用掺杂硅烷的等离子体气体去除铝部件表面的氧化层是合适的,高质量的焊接接头有望实现。利用转移电弧掺杂硅烷的氦等离子体获得了充分稀释的高质量焊缝。相反,用氩气-硅烷混合物焊接会导致形成过多的气孔。此外,确定了稳定电弧过程的挑战,并讨论了与工艺优化有关的后果。
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Advances in Materials Science
Advances in Materials Science MATERIALS SCIENCE, MULTIDISCIPLINARY-
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