Incident energy determination of three-phase arc flash using magnetohydrodynamics simulations: A case study for horizontal electrodes in open-air configurations

Abstract

Arc flashes pose significant hazards to personnel working with energised power lines due to their high thermal risk, quantified by incident energy (IE) in joules or calories per area. Accurate estimation of IE is crucial for ensuring safety. The most widely employed method for estimating IE from an arc flash is outlined in IEEE Std 1584-2018, which applies exclusively to three-phase AC arc flashes. However, limited research has explored alternative methods due to the complexities, costs, and preparation involved. Numerical simulations offer a viable alternative for studying arc flashes. This paper introduces a multiphysics simulation approach for determining IE by modelling three-phase AC arc flashes using the magnetohydrodynamics (MHD) theory. This study exclusively investigates horizontal electrodes in open-air (HOA) configuration due to the specific characteristics of the local power system configuration, which predominantly features overhead power lines, and the available test setup in the laboratory. The IE derived from simulations is compared with measurements from an arc flash laboratory based on IEEE Std 1584-2018 and with the IE calculated by the standard itself. The results indicate a significant alignment between this innovative approach and other methods for estimating IE for three-phase arc flashes.