Numerical Analysis of the Metal Transfer and Welding Arc Behaviors in Underwater Flux-cored Arc Welding

•A three-dimensional numerical model coupling both metal transfer and arc burning is firstly developed for underwater FCAW.•Due to the special gas composition in the bubbles, the welding arc concentrates below the droplet and constantly influences the droplet behaviors.•An intense electromagnetic sp...

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Bibliographic Details
Published in:International journal of heat and mass transfer 2020-06, Vol.153, p.119570, Article 119570
Main Authors: Xing, Changjian, Jia, Chuanbao, Han, Yanfei, Dong, Shengfa, Yang, Jie, Wu, Chuansong
Format: Article
Language:English
Subjects:
Arc spot welding
Computer simulation
Droplets
Electromagnetic forces
Flow resistance
Gas flow
High speed cameras
Mathematical models
Metal transfer
Modelling
Numerical analysis
Plasma arc welding
Three dimensional analysis
Three dimensional models
Underwater
Underwater welding
Welding arc
Welding current
Welding fluxes
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Summary:•A three-dimensional numerical model coupling both metal transfer and arc burning is firstly developed for underwater FCAW.•Due to the special gas composition in the bubbles, the welding arc concentrates below the droplet and constantly influences the droplet behaviors.•An intense electromagnetic spot force forms at the anode spot, which hinders the droplets transfer process. Based on the VOF method, a three-dimensional numerical analysis model coupling both droplets and arc behaviors is developed to simulate the metal transfer and arc plasma flow processes in underwater wet flux-cored arc welding. The relationships between several physical quantities such as droplet shape and temperature, electromagnetic force and current density of droplets and arc at different periods are analyzed. As it turns out, the special arc plasma component is the main reason why the arc concentrates on the bottom of the droplet, rather than being wrapped. As the volume of the droplet increases, the arc temperature decreases. The constriction of arc shape leads to the result that the welding current flow goes through from the droplet bottom–a small area to subjacent arc. Therefore, at the anode spot an intense electromagnetic spot force is formed. The droplets are also affected by the gas flow resistance inside the bubble. Under the combinative actions of the spot force and the gas flow resistance, the main mode of droplet transfer is large droplet repelled transfer. For verifying the reliability of the model, the real-time metal transfer process is captured by a high-speed camera, the experimental values and the simulated values are found to be in good agreement. [Display omitted]
ISSN:0017-9310
1879-2189
DOI:10.1016/j.ijheatmasstransfer.2020.119570