Welding arc is a transient interact

Welding arc is a transient interaction of electric and magnetic fields A fundamental knowledge about ionization and plasma formation is required for proper modeling of welding arc which is basically an electrical arc. Figure 1 shows the multi physics interactions in a welding arc.Even though the plasma physics is a developed area, only limited number of group’s work for interconnecting the developments in the arc physics with welding science. During earlier developments,many author shave published both theoretical and experimental results on behavior of welding arc, effects of electrode coatings, electrode tip angle, inert gas flow rate, etc. on arc shape, arc pressure and velocity distribution. A detailed literature review about the developments in this area is presented by B is was [2]. The welding arc can be simulated by accounting the micro heat transfer mechanisms like thermionic emission, cathode jet, ionization, etc. during the formation of arc. Wu [3–5] applied the fundamentals of plasma physics to the welding arc and developed the temperature, pressure, current, and velocity distributions in the arc and over the weld surface.Later in 2002,Wu et al.[6]developed micro heat transfer relations for determination of anode heat flux distribution by separately calculating conductive, convective, and radiative flux over the anode. The welding arc, which is governed by a set of physical laws, can be modeled by simultaneously solving mass, momentum,energy,and charge conservation equations,inside the computational domain, i.e., the welding arc.Recently, Wu et al. applied the conservation equations developed for a normal GTA welding arc [7] to the double-sided arc welding arc [8]. Ramirez et al. [9] presented a comparative study between magnetic and potential approaches for welding arc representations.They concluded that the potential approach is
superior to predict the heat flux and current densities.Shinichi et al. [10] developed a numerical model for hollow cathode arc. Murphy et al. [11] studied the weld pool behavior with considering the arc plasma in the computational domain, which is an initiative to couple the weld pool behavior with the welding arc. Traidia et al. [12] studied the interaction between welding arc and weld pool for pulsed current gas tungsten arc welding.