Frequency and Voltage Control for an Autonomous Distributed Variable-Speed Wind Turbine Based on a PID-Type Fuzzy Controller with Battery Support


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Abstract


The frequency and voltage of a distributed variable-speed wind turbine (VSWT) that drives a permanent magnet synchronous generator (PMSG) is vigorously affected by wind speed fluctuations. In practice, a power imbalance between supply and demand often occurs when the VSWT-PMSG is connected to a weak micro grid (MG). If load demand fluctuations become high, a weak MG cannot stabilize the frequency and voltage. Hence, battery storage should be installed for the MG to adjust the energy supply and demand. To enable flexible control of the active and reactive power flow from/to the battery storage, grid-connected inverters are used. For a system that has highly nonlinear components, conventional linear proportional-integral-derivative (PID) controllers can cause MG system performance deterioration. Moreover, these controllers exhibit slow, oscillating responses, and complex equations are required to obtain the best responses in other controllers. To cope with these limitations, this paper proposes a PID-type fuzzy controller (PIDfc) design to control a grid-connected inverter of the battery. Several simulation tests are performed to examine the scheme’s effectiveness. The results show that the proposed PIDfc controller demonstrates improved performance and adequate responses
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Keywords


Battery; PID-Type Fuzzy Controller; Inverter; Permanent Magnet Synchronous Generator (PMSG); Variable Speed Wind Turbine (VSWT)

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References


S.M. Muyeen, R. Takahashi, T. Murata, J. Tamura. Integration of an Energy Capacitor System with a Variable-Speed Wind Generator. IEEE Transactions on Energy Conversion, Vol. 24(issue 3): 740-749, September 2009.

Kurian, S., Sindhu, T.K., Cheriyan, E.P., Review on developments in wind energy generation and its integration to utility grid, (2013) International Review on Modelling and Simulations (IREMOS), 6 (5), pp. 1523-1532.

S. Barsali, M. Ceraolo, P. Pelacchi, D. Poli. Control techniques of Dispersed Generators to improve the continuity of electricity supply, Power Engineering Society Winter Meeting, Vol. 2, pp. 789-794, New York, January 2002.

M.C. Chandorkar, D.M. Divan, R. Adapa. Control of parallel connected inverters in standalone AC supply systems. IEEE Transactions on Industry Applications, Vol. 29 (Issue 1): 136-143, February 1993.

T. Kawabata, S. Higashino. Parallel operation of voltage source inverters. IEEE Transactions on Industry Applications, Vol. 24 (Issue 2): 281-287, April 1988.

H. Matthias, S. Helmut. Control of a three phase inverter feeding an unbalanced load and operating in paralel with other power sources. EPE-PEMC, pp. 1 – 10, Dubrovnik & Cavtat, 2002.

A. Tuladhar, K. Jin, T. Unger, K. Mauch. Parallel operation of single phase inverter modules with no control interconnections. Applied Power Electronics Conference and Exposition, Vol. 1, pp. 94-100, Atlanta, Georgia, February 1997.

S.J. Chiang, C.Y. Yen, K.T. Chang. A multimodule parallelable series-connected PWM voltage regulator. IEEE Transactions on Industrial Electronics, Vol. 48(Issue 3): 506-516, June 2001.

A. Engler. Control of Parallel Operating Battery Inverters PV Hybrid Power System. (2000).

http://renknownet2.iwes.fraunhofer.de/pages/hybird_system/data/2000aix-en-provence_engler_pv-hybrid.pdf

J. M. Guerrero, L. Garcia de Vicuna, J. Matas, M. Castilla, J. Miret. A wireless controller to enhance dynamic performance of parallel inverters in distributed generation systems. IEEE Transactions on Power Electronics, Vol. 19(Issue 5): 1205-1213, September 2004.

T. Goya, E. Omine, Y. Kinjyo, T. Senjyu, A. Yona, N. Urasaki, et al. Frequency control in isolated island by using parallel operated battery systems applying H-inf; control theory based on droop characteristics, IET Renewable Power Generation, Vol. 5(Issue 2): 160-166, August 2011.

S. Patra, S. Sen, G. Ray. Design of Robust Load Frequency Controller: H ∞ Loop Shaping Approach. Electric Power Components and Systems, Vol. 35(Issue 7): 769-783, April 2007.

V.P. Singh, S.R. Mohanty, N. Kishor, P.K. Ray. Robust H-infinity load frequency control in hybrid distributed generation system. International Journal of Electrical Power & Energy Systems, Vol. 46(Issue 0): 294-305, March 2013.

Routray, S.K., Nayak, N., Rout, P.K., A robust H-infinity controller based STATCOM for damping power system oscillations, (2013) International Review of Electrical Engineering (IREE), 8 (3), pp. 1043-1056.

X.C.M. Cubillos, L.C.G.d. Souza. Using H-infinity Control Method in Attitude Control System of Rigid-Flexible Satellite. Mathematical Problems in Engineering, Vol. 2009: 1-9, November 2009.

Z. Qing-Chang. Robust Droop Controller for Accurate Proportional Load Sharing Among Inverters Operated in Parallel, IEEE Transactions on Industrial Electronics, Vol. 60(Issue 4): 1281-1290, April 2013.

H. B. Verbruggen, P. M. Bruijn. Fuzzy control and conventional control: What is (and can be) the real contribution of Fuzzy Systems? Fuzzy Sets and Systems, Vol. 90(Issue 2): 151-60, September 1997.

S. K. Pandey, S. R. Mohanty, N. Kishor. A literature survey on load–frequency control for conventional and distribution generation power systems, Renewable and Sustainable Energy Reviews, Vol. 25 (Issue 0): 318-334, September 2013.

E. Yeşil, M. Güzelkaya, İ. Eksin. Self-tuning fuzzy PID type load and frequency controller. Energy Conversion and Management, Vol. 45(Issue 0): 377-390, February 2004.

F.W. Energy. Alize Wind Turbine. http://www.fortiswindenergy.com/products/wind-turbines/alize.

J.G. Slootweg, S.W.H. De Haan, H. Polinder, W.L. Kling. General model for representing variable speed wind turbines in power system dynamics simulations. IEEE Transactions on Power Systems, Vol. 18(Issue 1): 144-51, February 2003.

Matlab/SimPowerSystems. Permanent magnet Synchronous Generator. http://www.mathworks.com/help/physmod/powersys/ref/permanentmagnetsynchronousmachine.html2013.

Matlab/SimPowerSystems. Battery - Implement generic battery model. http://www.mathworks.com/help/physmod/powersys/ref/battery.html2013.

O. Tremblay, L. A. Dessaint. Experimental Validation of a Battery Dynamic Model for EV Application. World Electric Vehicle Journal. Vol. 3: 1-10, 2009.

K. De Brabandere, B. Bolsens, J. Van den Keybus, A. Woyte, J. Driesen, R. Belmans. A Voltage and Frequency Droop Control Method for Parallel Inverters. IEEE Transactions on Power Electronics, Vol. 22(Issue 4): 1107-1115, July 2007.

Z. Chen, E. Spooner. Grid interface options for variable-speed, permanent-magnet generators, IEE Proceedings Electric Power Applications, Vol. 145(Issue 4): 273-283, July 1998.

Q. Wu Zhi, M. Mizumoto. PID type fuzzy controller and parameters adaptive method, Fuzzy Sets and Systems, Vol. 78(Issue 1): 23-35, February 1996.

F. Ronilaya, H. Miyauchi. Modeling and assessment of a small embedded PMSG wind power equipped with battery energy storage. The IEEJ of electric power technology research handouts, Vol. PE-13, pp. 7-12, Kitakyushu, Japan, September 2013.


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