Title :
DC-Arc Models and Incident-Energy Calculations
Author :
Ammerman, Ravel F. ; Gammon, Tammy ; Sen, Pankaj K. ; Nelson, John P.
Author_Institution :
Colorado Sch. of Mines, Golden, CO, USA
Abstract :
There are many industrial applications of large-scale dc power systems, but only a limited amount of scientific literature addresses the modeling of dc arcs. Since the early dc-arc research focused on the arc as an illuminant, most of the early data was obtained from low-current dc systems. More recent publications provide a better understanding of the high-current dc arc. The dc-arc models reviewed in this paper cover a wide range of arcing situations and test conditions. Even with the test variations, a comparison of dc-arc resistance equations shows a fair degree of consistency in the formulations. A method for estimating incident energy for a dc arcing fault is developed based on a nonlinear arc resistance. Additional dc-arc testing is needed so that more accurate incident-energy models can be developed for dc arcs.
Keywords :
DC power transmission; arcs (electric); dc-arc models; incident energy calculations; industrial applications; large-scale dc power systems; scientific literature addresses; Circuit faults; Electrodes; Equations; Power system analysis computing; Power system dynamics; Power system faults; Power system measurements; Power system modeling; Testing; USA Councils; DC-arc modeling; dc incident-energy calculations; dc-arc resistance; dc-system hazard risk category evaluation; free-burning arcs in open air; volt–ampere ($V$– $I$) characteristics;
Journal_Title :
Industry Applications, IEEE Transactions on
DOI :
10.1109/TIA.2010.2057497
