Journal article Open Access

A Study on the Power Control of Wind Energy Conversion System

Mehdi Nafar; Mohammad Reza Mansouri

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        <rdf:type rdf:resource=""/>
        <foaf:name>Mehdi Nafar</foaf:name>
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        <foaf:name>Mohammad Reza Mansouri</foaf:name>
    <dct:title>A Study on the Power Control of Wind Energy Conversion System</dct:title>
    <dct:issued rdf:datatype="">2017</dct:issued>
    <dcat:keyword>power quality improvement</dcat:keyword>
    <dcat:keyword>wind energy conversion system</dcat:keyword>
    <dcat:keyword>fuzzy logic</dcat:keyword>
    <dct:issued rdf:datatype="">2017-04-05</dct:issued>
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    <dct:description>The present research presents a direct active and reactive power control (DPC) of a wind energy conversion system (WECS) for the maximum power point tracking (MPPT) based on a doubly fed induction generator (DFIG) connected to electric power grid. The control strategy of the Rotor Side Converter (RSC) is targeted in extracting a maximum of power under fluctuating wind speed. A fuzzy logic speed controller (FLC) has been used to ensure the MPPT. The Grid Side Converter is directed in a way to ensure sinusoidal current in the grid side and a smooth DC voltage. To reduce fluctuations, rotor torque and voltage use of multilevel inverters is a good way to remove the rotor harmony.</dct:description>
    <dct:description xml:lang="">{"references": ["Brahim Nait-kaci, Mamadou L. Doumbia, \"Active and Reactive power control of a doubly fed induction generator for wind applications\", IEEE 2009.", "Arantxa Tapia, Gerardo Tapia, J. Xabier Ostolaza, \"Modeling and Control of a Wind Turbine Driven doubly fed Induction Generator\", IEEE 2003.", "J. Ben Alaya, A Khedher and M. F. Mimouni, \"DTC, DPC and Nonlinear Vector Control Strategies Applied to the DFIG operated at Variable Speed\", Journal of Electrical Engineering (IEEE), vol.6, no II, pp. 744-753, 2011.", "A. Nassani, A. Ghazal, and A L. Elshafei, \"Speed sensorless control of DFIG based MRAS observer\", 14th International Middle East Conference, pp. 476-481. 2010.", "A Luna, F. K. A Lima, P. Rodriguez, E. H. Watanabe and R. Teodorescu, \"Comparison of Power Control Strategies for DFIG Wind Turbines\", IEEE Trans on Energy Conversion, pp. 2131-2136, 2008.", "M. Singh, V. Khadkikar, A. Chandra. Grid synchronization with harmonics and reactive power compensation capability of a permanent magnet synchronous generator-based variable speed wind energy conversion system. IET Power Electronics 2011; 41:122e30.", "Z. Chen, Compensation schemes for a SCR converter in variable speed wind power systems. IEEE Transactions on Power Delivery 2004; 192:813e21.", "S. Engelhardt, I. Erlich, C. Feltes, J. Kretschmann, F. Shewarega. Reactive power capability of wind turbines based on doubly fed induction generators. IEEE Transactions on Energy Conversion 2011; 261:364e72.", "Kayik\u00e7i. M, J. Milanovic. Reactive power control strategies for DFIG-based plants. IEEE Transactions on Energy Conversion 2007; 222:389e96.\n[10]\tM. Machmoum, A. Hatoum, T. Bouaouiche. Flicker mitigation of a doubly-fed induction generator for wind energy conversion system. Mathematics and Computers in Simulation 2010; 812:433e45.\n[11]\tM. Shahbazi, P. Poore, S. Saadate, M.R Zalghadri. Five-leg converter topology for wind energy conversion system with doubly fed induction generator. Renewable Energy 2011; 3611:3187e94.\n[12]\tO. Soares, H. Gon\u00e7alves, A. Martins, A. Carvalho. Nonlinear control of the doubly fed induction generator in wind power systems. Renewable Energy 2010; 358:1662e70.\n[13]\tF. Poitiers, T. Bouaouiche, M. Machmoum. Advanced control of a doubly-fed induction generator for wind energy conversion. Electric Power Systems Research 2009; 797:1085e96. \n[14]\tT.K.A. Brekken, N. Mohan. Control of a doubly fed induction wind generator under unbalanced grid voltage conditions. IEEE Transaction on Energy Conversion 22 (March (1)) (2007) 129\u2013135. \n[15]\tZ. S., Changliang Xia, T. Shi. Assessing transient response of DFIG based wind turbines during voltage dips regarding main flux saturation and rotor deep-bar effect. Applied Energy 87 (2010) 3283\u20133293. \n[16]\tA. Gaillard, P. Poure, S. Saadate, M. Machmoum. Variable Speed DFIG Wind Energy System for Power Generation and Harmonic Current Mitigation. Renewable Energy 34, 2009 pp 1545-1553. \n[17]\tB. Robyns, B. Francois, P. Degobert, J. P. Hautier, Vector control of induction machines, Springer-Verlag London 2012. \n[18]\tP.C. Krause Analysis of electric machinery. New York: McGraw-Hill; 1986. \n[19]\tH. M. Jabr and N. C. Kar, \"Neuro-fuzzy vector control for doubly-fed wind driven induction generator,\" in Proc. of the IEEE Electrical Power Conference, pp. 236 - 241, 2007.\n[20]\tH. M. Jabr and N. C. Kar, \"Leakage flux saturation effects on the transient performance of wound-rotor induction motor,\" Journal of Electric Power Systems Research, Vol.78, No.7, pp.1280-1289, 2008."]}</dct:description>
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