Three-dimensional numerical modelling of a magnetically deflected dc transferred arc in argon

The aim of this work is to develop a numerical model for the deflection of do transferred arcs using an external magnetic field as a first step into the modelling of industrial arc furnaces. The arc is deflected by the use of a conductor aligned parallel to the arc axis through which flows an electric current. The model is validated by comparing the results of axisymmetric calculations to modelling results from the scientific literature. The present model is found to be a good representation of the electric do arc as differences with the literature are easily explained by model parameters such as the critical boundary conditions at the electrodes. Transferred arc cases exhibit the expected behaviour as the temperature T, the velocity (v) over right arrow and the electrical potential drop Deltaphi all increase with the arc current I and the argon flow rate Q. Three-dimensional geometry is implemented, enabling one to numerically deflect the arc. For the deflected arc cases, the deflection increases with the arc current I and conductor current I-conductor and decreases with the flow rate Q and x(0), the arc-conductor distance. These deflection behaviours are explained using physical arguments.