An Integrated Reactive Power Control Strategy for Improving Low Voltage Ride-through Capability

doi:10.23919/CJEE.2019.000022

中国电气工程学报（英文） ›› 2019, Vol. 5 ›› Issue (4): 1-14.doi: 10.23919/CJEE.2019.000022

• • 下一篇

出版日期:2019-12-25 发布日期:2020-03-12

An Integrated Reactive Power Control Strategy for Improving Low Voltage Ride-through Capability

Ehsan Gatavi^*, Ali Hellany, Mahmood Nagrial, Jamal Rizk

School of Computing, Engineering, and Mathematics, Western Sydney University, NSW 2751, Australia

Online:2019-12-25 Published:2020-03-12
Contact: * Email: e.gatavi@westernsydney.edu.au
About author:Ehsan Gatavi received the B.E. in electrical and electronic engineering from Islamic Azad University, Iran, in 2007, and M.E. in mechatronics and automatic control engineering from University Technology Malaysia, in 2011. From 2012 to 2014, he was a research assistant with University of Technology Sydney, Australia. He is currently working toward the Ph.D. degree in electrical engineering with Western Sydney University, Australia. His research interests include but not limited to renewable energy, large-scale control system, reactive power compensation, voltage regulation and decentralized control to achieve a highest level of flexibility. He is an active reviewer for IEEE Transaction on Industrial Electronics.
Ali Hellany holds a B.E. in Telecommunication, M.E. (Hons) in Electrical Engineering and a Ph.D. in Electrical Engineering, from Western Sydney University, Australia. He is a member of IEEE, Executive member of IEEE NSW Section and chairing the student activities. He is a member of the Power and Education societies. He is a senior lecturer in Electrical Engineering, Western Sydney University since 2002. Dr. Hellany has published numerous papers in the field of Renewable Energy, Power Quality, AC Interference, and Learning Styles in journals and presented his research in many international conferences. Dr. Hellany is a member of the “Renewable Energy” research group.
Mahmood Nagrial obtained his Ph.D. from University of Leeds, UK. He has extensive experience in Power Electronics and Drive Systems, Renewable Energy Systems. He is Coordinator for Research Group “Power Conversion & Intelligent Motion Control”. He has conducted many short courses and contributed refereed papers to many International conferences. Dr. Nagrial has been a leading researcher in the area of permanent magnet & variable reluctance machines & drive systems. He has supervised Ph.D. and M. Eng. (Hons) Research Theses and postdoctoral fellows in this general area. Dr. Nagrial has also worked as Principal Research Scientist at CSIRO, where he has been responsible for developing new devices using rare-earth magnets.
Jamal Rizk is a member of the Research Group: Power Conversion and Intelligent Motion Control (PCIMC). He has a doctorate from Kharkov Polytechnic, Ukraine and a Ph.D. from University of Western Sydney, Australia. He is a Senior Lecturer in the School of Engineering, Western Sydney University. Since 1997 he has attended and presented results of his research at different Australian and International Conferences. He has developed special expertise in the analysis of magnetic analysis of different types of permanent magnet machines. He has been involved in design, fabrication and testing of electrical drives.

摘要/Abstract

Abstract: Among all renewable energies, wind power is rapidly growing, whereby it has the most participation to supply power. Doubly fed induction generator (DFIG) is the most popular wind turbine, as it can play a very significant role to enhance low voltage ride through (LVRT) capability. Ancillary services such as voltage control and reactive power capability are the main topics in wind power control systems that should be handled profoundly and carefully. The lack of reactive power during fault period can result in instability in generators and/or disconnection of the wind turbine from the power system. The main aims of this study are to illustrate the most effective approaches subject to improve the efficiency, stability, and reliability of wind power plant associated with LVRT capability enhancement. This effectiveness and efficiency are demonstrated by, firstly, comparison between all types of wind turbines, focusing on the ancillary services, after the existing advanced control strategies. According to the literature, there is a consensus that modifying converter-based control topology is the most effective approach to enhance LVRT capability in DFIG-based wind turbine (WT). Therefore, an advanced integrated control strategy is designed by considering the effect of the rotor side converter (RSC) and the grid side converter (GSC). A model of the wind power plant is presented based on the control objectives. MATLAB/Simulink is also used to illustrate the effectiveness of the designed algorithm.

Key words: Doubly fed induction generator, low voltage ride-through, series dynamic braking resistor, reactive power

. [J]. 中国电气工程学报（英文）, 2019, 5(4): 1-14.

Ehsan Gatavi, Ali Hellany, Mahmood Nagrial, Jamal Rizk. An Integrated Reactive Power Control Strategy for Improving Low Voltage Ride-through Capability[J]. Chinese Journal of Electrical Engineering, 2019, 5(4): 1-14.

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