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Tanaka, Keigo
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Publications (5/5 displayed)
- 2021Effect of alkaline elements on the metal transfer behavior in metal cored arc weldingcitations
- 2020Numerical study of the metal vapour transport in tungsten inert-gas welding in argon for stainless steelcitations
- 2020Numerical study of the effects and transport mechanisms of iron vapour in tungsten inert-gas welding in argoncitations
- 2018A computational model of gas tungsten arc welding of stainless steel: the importance of treating the different metal vapours simultaneouslycitations
- 2017Mixing of multiple metal vapours into an arc plasma in gas tungsten arc welding of stainless steelcitations
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article
Effect of alkaline elements on the metal transfer behavior in metal cored arc welding
Abstract
The aim of this study was to clarify the effects of adding a small amount of an alkaline element to the wire in metal cored arc welding (MCAW) on the metal transfer process. Sodium was selected as the alkaline element, and a standard wire without sodium (wire 1) and three wires with 0.028, 0.056, and 0.084 mass% sodium (wire 2, 3, and 4) were prototyped. They were observed using a high-speed video camera equipped with laser illumination, which clarified that the droplet transfer frequency tended to increaseproportionally with the amount of sodium added. Subsequently, the line spectra of the iron atom (particularly the Fe I 537.1 nm line) and sodium atom (particularly the Na I 589.0 nm line) were primarily observed using a bandpass filter. Iron vapor evaporated from the droplet bottom, while sodium vapor mainly evaporated from the molten wire tip or the neck between the wire and the droplet because of its low boiling point. Because the sodium atom has a low ionization energy, we considered that a new current path of sodium plasma was directly formed from the tip or neck of the molten wire through the arc plasma to the molten pool, bypassing the inside of the droplet. The formation of this new current path was considered to reduce the current of the iron plasma flowing from the droplet bottom reducing the arc pressure and further enhance the electromagnetic force acting on the neck to promote droplet detachment, thereby increasing the metal transfer frequency.