Title :
A DC Arc Model for Series Faults in Low Voltage Microgrids
Author :
Uriarte, Fabian M. ; Gattozzi, Angelo L. ; Herbst, John D. ; Estes, Hunter B. ; Hotz, Thomas J. ; Kwasinski, Alexis ; Hebner, Robert E.
Author_Institution :
Center for Electromech., Univ. of Texas, Austin, TX, USA
Abstract :
This paper presents a dc arc model to simplify the study of a critical issue in dc microgrids: series faults. The model is derived from a hyperbolic approximation of observed arc voltage and current patterns, which permit analyzing the arc in terms of its resistance, power, energy, and quenching condition. Recent faults staged by the authors on a dc microgrid yielded enough data to develop an arc model for three fault types: constant-gap speed, fixed-gap distance, and accelerated gap. The results in this paper compare experimental and simulation results for the three fault types. It is concluded that because the instantaneous voltage, current, power, and energy waveforms produced by the model agree well with experimental results, the model is suitable for transient simulations.
Keywords :
arcs (electric); distributed power generation; power system faults; power system transients; DC arc model; DC microgrids; accelerated gap; arc voltage; constant-gap speed; current patterns; fixed-gap distance; hyperbolic approximation; low voltage microgrids; series faults; transient simulations; Approximation methods; Circuit faults; Electrodes; Integrated circuit modeling; Mathematical model; Resistance; Arc; computer; dc; energy; fault; flash; hazard; microgrid; model; power; series; simulation; transient;
Journal_Title :
Smart Grid, IEEE Transactions on
DOI :
10.1109/TSG.2012.2201757
