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References (21)
-
O. Barambones (2012)
Robust vector control strategy for variable speed wind turbinesInternational Journal of Power Electronics, 4
-
V. Utkin (1993)
Sliding mode control design principles and applications to electric drivesIEEE Trans. Ind. Electron., 40
-
M. Mansour, M. Mansouri, M. Mmimouni (2011)
Study and Control of a Variable-Speed Wind-Energy System Connected to the GridInternational Journal of Renewable Energy Research, 1
-
F. Bianchi, R. Mantz, H. Battista (2006)
Wind Turbine Control Systems: Principles, Modelling and Gain Scheduling Design -
F. Bianchi, H. Battista, R. Mantz (2006)
Wind turbine control systems -
B. Beltran, T. Ahmed-Ali, M. Benbouzid (2009)
High-Order Sliding-Mode Control of Variable-Speed Wind TurbinesIEEE Transactions on Industrial Electronics, 56
-
V. Utkin (1992)
Sliding Modes in Control and Optimization -
(2006)
Les strate´gies de commande pour 1 'optimisation et la re´gulation de puissance des e´oliennes a`vitesse variable. The`se De Doctorat En Sciences -
(2016)
Energy management and control system for laboratory scale microgrid -
O. Dahhani, A. El-jouni, I. Boumhidi (2018)
Assessment and control of wind turbine by support vector machinesSustainable Energy Technologies and Assessments, 27
-
(2005)
Etude comparative de chaınes de conversion d'e´nergie de´die´es a`une e´olienne de petite puissance. The`se De Doctorat -
K. Chandramohan, S. Padmanaban, Rajambal Kalyanasundaram, M. Bhaskar, L. Mihet-Popa (2017)
Grid Synchronization of a Seven-Phase Wind Electric Generator Using d-q PLLEnergies, 10
-
A. Merabet, Khandker Ahmed, H. Ibrahim, R. Beguenane, A. Ghias (2017)
Energy Management and Control System for Laboratory Scale Microgrid Based Wind-PV-BatteryIEEE Transactions on Sustainable Energy, 8
-
M. Bouhrik, S. Belkacem (2015)
Study and Control of a Variable-Speed Wind Energy System Connected to the Grid -
T. Roy, Md. Mahmud, A. Oo, R. Bansal, M. Haque (2017)
Nonlinear Adaptive Backstepping Controller Design for Three-Phase Grid-Connected Solar Photovoltaic SystemsElectric Power Components and Systems, 45
-
Anirban Ghoshal, V. John (2007)
A Method to Improve PLL Performance Under Abnormal Grid Conditions -
I. Munteanu, S. Bacha, A. Bratcu, J. Guiraud, D. Roye (2008)
Energy-Reliability Optimization of Wind Energy Conversion Systems by Sliding Mode ControlIEEE Transactions on Energy Conversion, 23
-
Y. Vidal, L. Acho, N. Luo, M. Zapateiro, F. Pozo (2012)
Power control design for variable-speed wind turbinesEnergies, 5
-
B. Boukhezzar, L. Lupu, H. Siguerdidjane, M. Hand (2007)
Multivariable control strategy for variable speed, variable pitch wind turbinesRenewable Energy, 32
-
K. Arulkumar, D. Vijayakumar, K. Palanisamy (2016)
Investigation of PLL performance for utility connected systems under abnormal grid conditions2016 IEEE International Conference on Power and Energy (PECon)
-
A. Hemeida, W. Farag, O. Mahgoub (2011)
Modeling and Control of Direct Driven PMSG for Ultra Large Wind TurbinesWorld Academy of Science, Engineering and Technology, International Journal of Computer, Electrical, Automation, Control and Information Engineering, 5
- Publisher
- SAGE
- Copyright
- © The Author(s) 2019
- ISSN
- 0309-524X
- eISSN
- 2048-402X
- DOI
- 10.1177/0309524X19889365
- Publisher site
- See Article on Publisher Site
Abstract
In this article, we process the modeling and control of a global chain of the wind energy conversion system based on a permanent magnet synchronous generator, and the injection of the produced energy into electrical grid. The proposed control technique of the wind energy system is based on a sliding mode control which is designed for a variable speed wind turbine. Sliding mode control is assessed on a wind turbine to supply three phases grid. The aim in this work is to operate over all the wind conversion system at its maximum power point. Initially, three controls have been designed by sliding mode control: the first is for electromagnetic torque of the used permanent magnet synchronous generator, the second is for the machine side converter, and the last is for the grid side converter. Thereafter, another proportional integral controller has been designed for the phase looked loop. Finally, the permanent magnet synchronous generator–based wind turbine and the grid are modeled, and proposed controls are applied, various simulations results by MATLAB/SIMULINK environment are presented and discussed.
Journal
Wind Engineering – SAGE
Published: Jan 1, 2019