Title :
Dynamic modeling of DC arc discharge on ice surfaces
Author :
Farzaneh, M. ; Fofana, I. ; Tavakoli, C. ; Chen, X.
Author_Institution :
UQAC on Atmos. Icing of Power Network Equip. (CIGELE), Hydro-Quebec, Chicoutimi, Que., Canada
fDate :
6/1/2003 12:00:00 AM
Abstract :
A dynamic model for predicting DC arc behavior and critical flashover voltage of ice-covered insulating surfaces is presented. The model takes into consideration insulating geometry, pre-contamination level, and characteristics of ice layers. Assuming arc behavior as a time dependant impedance, it is possible to determine various arc characteristics such as time histories of leakage currents, potential gradient, channel radius, trajectory, propagation velocity and the energy injected into the zones free of ice (also called air gaps). The simulated results provided by the model are in agreement with those obtained experimentally using a simplified ice-covered cylinder as well as a short string of five IEEE standard porcelain suspension units covered with artificial ice.
Keywords :
flashover; ice; insulators; leakage currents; DC arc discharge; IEEE standard porcelain suspension units; air gaps; arc behaviour; arc characteristics; artificial ice; channel radius; critical flashover voltage; dynamic modeling; ice layers; ice surfaces; ice-covered cylinder; ice-covered insulating surfaces; insulating geometry; leakage current; potential gradient; pre-contamination level; propagation velocity; time dependant impedance; trajectory; Arc discharges; Flashover; Geometry; Ice surface; Insulation; Predictive models; Solid modeling; Surface discharges; Surface impedance; Voltage;
Journal_Title :
Dielectrics and Electrical Insulation, IEEE Transactions on
DOI :
10.1109/TDEI.2003.1207474
