3-DIMENSIONAL MODELING OF UNSTEADY HIGH-PRESSURE ARCS IN ARGON

Three-dimensional, unsteady behaviour of high-pressure electric arcs in argon is studied by means of numerical simulations. Attention is paid to argon arcs whose steady structure is fairly well understood. Results are reported for the case of a one centimetre long are, burning in argon and driven by a total current of 200 A and 300 A. The influence of the boundary conditions for the electrical potential on the macroscopic structure of the are is studied and it is found that the distribution of the current density near the cathode is one of the critical parameters which can significantly modify both the distribution of mean quantities and the stability of the are. All mean quantities found from three-dimensional calculations are compared with two-dimensional axi-symmetric fields obtained by a previously used code for are simulations. The results indicate good agreement between the results from three-dimensional calculations, hive-dimensional axi-symmetric simulations and results from physical experiments documented in literature.