International Journal of Renewable Energy Research-IJRER

Wind energy is characterized by fluctuation because of a main intermittent source, which can damage the stability of the electrical network which leads to an imbalance between production and consumption. To resolve this difficulty, an integration of a micro-grid based on a wind farm interconnected to the electricity grid is proposed which presents the first objective of this paper. The two-level inverter is so much used in this domain, but the main limitations of this solutions are the fact that the voltage output presents high ripples and that this inverter is not a practical solution for applications with high power. Thus, the second aim of this paper consists in using a multicellular inverter. The main unit of this farm is based on a three permanent magnet synchronous generators which are entrained by three aero-generators. This unity is connected to a DC bus through three controlled rectifiers. The obtained power is injected to the electricity grid using a multicellular inverter as well as an inductor and resistor filter. The three generators and the proposed inverter are controlled through a vector control. A theoretical study of the suggested farm is parented and simulated using a Matlab/Simulink environment. The obtained simulation results confirm the approach robustness.

Wind farm; PMSG; Multicellular Converters; Micro-Grid (MG); Pitch angle.

Glasnovic Z, Margeta J. “Vision of total renewable electricity scenarioâ€, Renew Sust Energy Rev vol. 15, n°. 4, pp.1873–1884, 2011.

Chowdhury SP, Chowdhury S, Crossley PA. UK. “Scenario of islanded operation of Active distribution networks with renewable distributed generatorsâ€. International Journal of Electrical Power & Energy Systems, vol. 33, n°. 7, pp. 1251–1255, 2011.

Sanseverino ER, Di Silvestre ML, Ippolito MG, De Paola A, Re GL. “An execution, monitoring and replanting approach for optimal energy management in micro-gridsâ€. Energy, vol. 36, n°. 5, pp. 3429–3436, 2011.

N. Pogaku, M. Prodanovic, T. Green, “Modeling, Analysis and Testing of Autonomous Operation of an Inverter- Based Micro-grid,†IEEE Trans. Power Electron, vol. 22, pp. 613-625, 2007.

A.A. Bhuiyan, A.K.M.S. Islam, A.I. Alam, “Application of Wind Resource Assessment (WEA) tool: A case study in Kuakata, Bangladesh,†International Journal of Renewable Energy Research, vol. 1, pp. 83-90, 2011.

Wen J, Zheng Y, Donghan F, “A review on reliability assessment for wind powerâ€, Renew Sustain Energy Rev, vol. 13, n°. 9, pp. 2485–2494, 2009.

Hoogwijk M, De Vries B, Turkenburg W, “Assessment of the global and regional geographical, technical and economic potential of onshore wind energyâ€, Energy Econom, vol. 26, n°. 5, pp. 889–919, 2004.

Lund H, Clark WW, “Management of fluctuations in wind power and CHP comparing two possible Danish strategiesâ€, Energy, vol. 27, n°. 5, pp. 471-483, 2002.

Rabiee, A., Khorramdel, H., Aghaei, J, “A review of energy storage systems in micro-grids with wind turbinesâ€, Renewable and Sustainable Energy Reviews, vol. 18, pp. 316-326, 2013.

Abbey C, Joos G, “Super-capacitor energy storage for wind energy applicationsâ€, IEEE Trans Ind Appl, vol. 43, n°. 3, pp. 769-776, 2007.

McDowall J, “Integrating energy storage with wind power in weak electricity gridsâ€, J Power Sources, vol. 162, n°. 2, pp. 959-964, 2006.

Donald Grahame Holmes, Brendan P. McGrath, “Opportunities for Harmonic Cancellation with Carrier-Based PWM for Two-Level and Multilevel Cascaded Invertersâ€, IEEE TRANSACTIONS ON INDUSTRY APPLICATIONS, vol. 37, n°. 2, pp. 574-582, march/april 2001.

T.Meynard, H. Foch, P. Thomas, J. Courault, R. Jacob, andM. Nahrstaedt, “Multicell converters: Basic concepts and industry applications,†IEEE Trans. Ind. Electron., vol. 49, no. 5, pp. 955–964, Oct 2002.

D. Krug, M. Malinowski, and S. Bernet, “Design and comparison of medium voltage multi-level converters for industry applicationsâ€, 39th IEEE IAS Annual Meeting, in Conference Record. vol. 2, pp. 781–790, 2004.

T. Meynard, M. Fadel, and N. Aouda, “Modeling of multilevel converters,†IEEE Trans. Ind. Electron., vol. 44, n°. 3, pp. 356–364, Jun 1997.

Masmoudi A, Abdelkafi A, Krichen L. “Electric power generation based on variable speed wind turbine under load disturbanceâ€. Energy, vol. 36, n°. 8, pp. 5016–5026, 2011.

Minh Quan Duong, Francesco Grimaccia, Sonia Leva, Marco Mussetta, Emanuele Ogliari, “Pitch Angle Control Using Hybrid Controller for All Operating Regions of SCIG Wind Turbine Systemâ€, Renewable Energy, vol. 70, pp. 197- 203, 2014.

Muhando EB, Senjyua T, Urasakia N, Yonaa A, Kinjob H, Funabashi T, “Gain scheduling control of variable speed WTG under widely varying turbulence loadingâ€, Renew Energy, vol. 32, n°. 14, pp. 2407-2423, 2007.

Galdi V, Piccolo A, Siano P, “Exploiting maximum energy from variable speed wind power generation systems by using an adaptive Takagi-Sugeno-Kang fuzzy modelâ€, Energy Convers Manage, vol. 50, n°. 2, pp. 413-421, 2009.

R. Chedid, F. Mirad et M. Basma, “Intelligent control of a class of wind energy conversion systemsâ€, IEEE Transactions on Energy Conversion, vol. 14, n°. 4, pp.1597-1604, 1999.

J. L. Rodriguez – Amenedo, S. Arnalte et J. C. Burgos, “ Automatic generation control of wind farm with variable speed wind turbine â€, IEEE Transactions on Energy Conversion, vol. 17, n°. 2, pp. 279-284, 2002.

Mouna Rekik, Achraf Abdelkafi, Lotfi Krichen, “A novel control strategy of a distributed generator operating in seven modes for ancillary services under grid faultsâ€, International Journal of Electrical Power and Energy Systems, vol. 47, pp. 100-108, 2013.

François Defaÿ, Ana-Maria Llor, Maurice Fadel, “A Predictive Control With Flying Capacitor Balancing of a Multicell Active Power Filterâ€, IEEE transactions on industrial electronics, vol. 55, n°. 9, pp. 3212-3220, september 2008.

M.Mansour, M.N.Mansouri, M.F.Mmimouni, “Study and Control of a Variable-Speed Wind-Energy System Connected to the Gridâ€, vol. 1, no. 2, pp. 96-104 , 2011.