Stability Analysis Of Anti-islanding Protection Based On Positive Feedback Technique

Andrei Giordano Holanda Battistel; Igor Weide Jaskulski; Humberto Pinheiro

doi:10.18618/REP.20114.339347

Authors

Andrei Giordano Holanda Battistel Dept. of Electrical Eng./COPPE Federal University of Rio de Janeiro Rio de Janeiro, RJ – Brazil
Igor Weide Jaskulski Power Electronics and Control Research Group (GEPOC), Federal University of Santa Maria 97105-900 Santa Maria, RS – Brazil
Humberto Pinheiro Power Electronics and Control Research Group (GEPOC), Federal University of Santa Maria 97105-900 Santa Maria, RS – Brazil

DOI:

https://doi.org/10.18618/REP.20114.339347

Keywords:

Anti-islanding, Distributed Generation (DG), Loss of Mains, Stability Analysis

Abstract

This paper develops a stability analysis of a local Islanding Detection Algorithm (IDA) based on positive feedback technique that has no Non Detection Zone (NDZ). A complete dynamic model for the system is derived and the stability analysis with Nyquist stability criterion is carried out. It is demonstrated that the parameters of the IDA can be easily tuned at the key operating conditions to guarantee the under or over voltage relay tripping whenever islanding occurs. Finally, experimental results are presented to support the theoretical analysis developed.

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Author Biographies

Andrei Giordano Holanda Battistel , Dept. of Electrical Eng./COPPE Federal University of Rio de Janeiro Rio de Janeiro, RJ – Brazil

was born in 1987. He received his B.S. degree in Electrical Engineering from Federal University of Santa Maria in 2009 and his M.S. degree in Electrical Engineering from Federal University of Rio de Janeiro in 2011, where he is currently a PhD student. His research includes nonlinear systems, control theory applications and robotics.

Igor Weide Jaskulski , Power Electronics and Control Research Group (GEPOC), Federal University of Santa Maria 97105-900 Santa Maria, RS – Brazil

was born in 1980. He received his B.Sc. of Electrical Engineering and M.Sc. degree from Federal University of Santa Maria, Brazil, in 2004 and 2007 respectively. Since 2007 he has been working with the Wind Power Industry in Germany. His main interests are wind turbine grid integration, modeling and simulation of power systems and power electronics and control associated with frequency converters connected to the grid.

Humberto Pinheiro, Power Electronics and Control Research Group (GEPOC), Federal University of Santa Maria 97105-900 Santa Maria, RS – Brazil

received the B.S. degree Electrical Engineering from Federal University of Santa Maria in 1983, the M.S. degree in Electrical Engineering from Federal University of Santa Catarina in 1987, and the PhD in Electrical Engineering from Concordia University, Canada, in 1999. Currently, he is associate professor at Electric Power Processing Department in Federal University of Santa Maria. His research interests include wind power systems and uninterruptible power supply systems.

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