The aim of this work is to investigate by means of a 3D time-dependent numerical model the plasma flow and heat transfer inside a DC non-transferred arc plasma torch operating at atmospheric pressure [1-6], using a customized version of the CFD commercial code FLUENT©. Unsteady flow and heat transfer equations are solved with coupled electromagnetic ones, for an Ar optically thin plasma under conditions of LTE. Cathode and anode regions are taken into account in a simplified way, neglecting the non equilibrium effects of the sheath region. The attachment and detachment of the discharge on the anode wall as a result of the drag of the flow field is predicted imposing an uniform zero potential condition on the wall. Turbulence effects are taken into account by means of a Large Eddy Simulation (L.E.S.) approach, solving the dynamic behavior of the larger scale eddies outside the torch nozzle. Prediction of particle trajectories and thermal history is performed in order to predict the effect of the cold gas entrained eddies on particle behavior. ©2007 IEEE.
Time dependent 3D large eddy simulation of a DC nontransferred ARC plasma spraying torch with particle injections / Colombo V.; Concetti A.; Ghedini E.. - ELETTRONICO. - 2:(2007), pp. 4652486.1565-4652486.1568. (Intervento presentato al convegno PPPS-2007: Pulsed Power and Plasma Science 2007, The 16th IEEE International Pulsed Power Conference and The 34th IEEE International Conference on Plasma Science tenutosi a Albuquerque, NM, usa nel 2007) [10.1109/PPPS.2007.4652486].
Time dependent 3D large eddy simulation of a DC nontransferred ARC plasma spraying torch with particle injections
Colombo V.;Concetti A.;Ghedini E.
2007
Abstract
The aim of this work is to investigate by means of a 3D time-dependent numerical model the plasma flow and heat transfer inside a DC non-transferred arc plasma torch operating at atmospheric pressure [1-6], using a customized version of the CFD commercial code FLUENT©. Unsteady flow and heat transfer equations are solved with coupled electromagnetic ones, for an Ar optically thin plasma under conditions of LTE. Cathode and anode regions are taken into account in a simplified way, neglecting the non equilibrium effects of the sheath region. The attachment and detachment of the discharge on the anode wall as a result of the drag of the flow field is predicted imposing an uniform zero potential condition on the wall. Turbulence effects are taken into account by means of a Large Eddy Simulation (L.E.S.) approach, solving the dynamic behavior of the larger scale eddies outside the torch nozzle. Prediction of particle trajectories and thermal history is performed in order to predict the effect of the cold gas entrained eddies on particle behavior. ©2007 IEEE.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
