Numerical modeling negative corona under the influence of applied voltage variation

In high-voltage gaseous insulation systems, the corona discharge is important because it can lead to drop of the insulating qualities of the gas in addition to the production of harm by-products. The influence of the applied voltage variation on the negative corona characteristics in a coaxial electrode geometry has been investigated based on one-dimensional dynamic model of corona discharge includes one-dimensional continuity equations and Poisson equation. The one-dimensional fluid model of corona discharge is solved by finite difference flux correction method (FD-FCT). The calculations were performed on oxygen gas under the atmospheric pressure using COMSOL multiphysics software. The corona discharge parameters are simulated under different voltage values 4KV, 6KV, 7KV, 8KV and 10KV, respectively. The effect of the applied voltage on the spatial distribution of main charged species and electron as well as the ozone was considered. The results show that as the negative applied voltage on the cathode increased the total current density also increase while the electron density decrease. The ozone density do not much affected by the increasing the applied voltage.