General expressions for heat distribution, pressure, and current density in argon welding arcs

Abstract In welding and wire-arc additive manufacturing (WAAM), a mobile arc is the heat source that enables the deposition of metals and the resulting properties of the final product. Because the arc involves temperatures of 20 000 K, and gas velocities of the order of 300 m/s, there are only a few...

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Published inIOP conference series. Materials Science and Engineering Vol. 1281; no. 1; pp. 12007 - 12016
Main Authors Villarreal-Medina, R., Delgado-Álvarez, A., Murphy, A. B., Méndez, P. F., Ramirez-Árgaez, M. A.
Format Journal Article
LanguageEnglish
Published Bristol IOP Publishing 01.05.2023
Subjects
Arc deposition
Argon
Conduction heating
Consumable electrode welding
Electric arcs
Energy consumption
Gas tungsten arc welding
Heat distribution
Metamodels
Numerical models
Ohmic dissipation
Optimization
Resistance heating
Weld metal pool
Wire
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Summary:Abstract In welding and wire-arc additive manufacturing (WAAM), a mobile arc is the heat source that enables the deposition of metals and the resulting properties of the final product. Because the arc involves temperatures of 20 000 K, and gas velocities of the order of 300 m/s, there are only a few experiments and models available to determine optimal, or at least acceptable, parameters for the operation such as current, voltage, and arc length. On the other hand, there is a lack of engineering guidance to optimize the processes resulting in costly and time-consuming trial-and-error optimization methods, which also involve wasteful use of energy and scrap parts. In this work, a numerical model of the gas-tungsten arc welding (GTAW) arc was created and validated against experiments. The model considers the arc interactions between a non-consumable electrode and the weld pool and accounts for multiple coupled heat transfer mechanisms: Joule heating, conduction, advection, radiation, and Thomson effect. The conditions considered cover the vast majority of GTAW welding operations. The results are generalized in the form of engineering expressions suitable to be embedded in metamodels, in which the heat source is just a part. Applications include penetration and width of welds and deposition rate in external-wire WAAM.
ISSN:1757-8981
1757-899X
DOI:10.1088/1757-899X/1281/1/012007