Design and Modelling of PV system and Different MPPT algorithms
International Journal of Engineering Trends and Technology (IJETT) | |
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© 2013 by IJETT Journal | ||
Volume-4 Issue-9 |
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Year of Publication : 2013 | ||
Authors : Ch.Kiran Kumar , T.Dinesh , S.Ganesh Babu |
Citation
Ch.Kiran Kumar , T.Dinesh , S.Ganesh Babu. "Design and Modelling of PV system and Different MPPT algorithms". International Journal of Engineering Trends and Technology (IJETT). V4(9):4104-4112 Sep 2013. ISSN:2231-5381. www.ijettjournal.org. published by seventh sense research group.
Abstract
Photovoltaic (PV) is a technical name in which radiant (photon) energy from the sun is converted to direct current (dc) Electrical Energy. PV power output is still low, continuous efforts are taken to develop the PV converter and controller for maximum pow er extracting efficiency and reduced cost factor. Maximum power point trackers (MPPTs) play an important role in photovoltaic (PV) power systems because they maximize the power output from a PV system for a given set of conditions, and therefore maximize t he array efficiency. Thus, an MPPT can minimize the overall system cost. MPPTs find and maintain operation at the maximum power point, using an MPPT algorithm. Many such algorithms have been proposed. The mostly used MPPT are P&O and Incremental Conductance Method and Constant voltage and current , Pilot cell etc , Fuzzy. In this paper the designing and Modelling of different algorithms have been implemented using Matlab and comparison of two algorithms is done .
References
1. Katan RE, Agelidis VG, Nayar CV. Performance analysis of a solar water pumping system. Proceed ings of the 1996 IEEE International Conference on Power Electronics, Drives, and Energy Systems for Industrial Growth (PEDES), 1996; 81 – 87.
2. Taha MS, Suresh K. Maximum power point tracking inverter for photovoltaic source pumping applications. Proceeding s of the 1996 IEEE International Conference on Power Electronics, Drives, and Energy Systems for Industrial Growth (PEDES), 1996; 883 – 886.
3. Kourtoulis E, Kalaitzakis K, Voulgaris NC. Development of a microcontroller - based, photovoltaic maximum power poin t tracking control system. IEEE Transactions on Power Electronics 2001; 16(1): 46 – 54.
4. Won C - Y, Kim D - H, Kim S - C, Kim W - S, Kim H - S. A new maximum power point tracker of photovoltaic arrays using fuzzy controller. Proceedings of the 24th IEEE Power Electr onics Specialists Conference (PESC), 1994; 396 – 403.
5. Hua C, Shen C. Comparative study of peak power tracking techniques for solar storage systems. IEEE Applied Power Electronics Conference and Exposition — APEC, Proceedings of the 1998 13th Annual Applied Power Electronics Conference and Exposition 1998; 2: 697 – 685.
6. Hussein KH, Zhao G. Maximum photovoltaic power tracking: an algorithm for rapidly changing atmospheric conditions. IEE Proceedings of Generation, Transmission, Distribution 1995; 142(1): 59 – 6 4.
[7] Vikrant.A.Chaudhari, "Automatic Peak Power Traker for Solar PV Modules Using dSpacer Software.," in Maulana Azad National Institute Of Technologyvol. Degree of Master of Technology In Energy. Bhopal: Deemed University, 2005, pp. 98.
[8] T. P. Nguyen, "Solar Panel Maximum Power Point Tracker," in Department of Computer Science & Electrical Engineering: University of Queensland, 2001, pp. 64.
[9] B. S, Thansoe, N. A, R. G, K. A.S., and L. C. J., "The Study and Evaluation of Maximum Power Point Tr acking Systems," International Conference on Energy and Environment 2006 (ICEE 2006), pp. 17 - 22, 2006.
10. Andersen M, Alvsten B. 200W low cost module integrated utility interface for modular photovoltaic energy systems. IECON: Proceedings of the 1995 IEEE 21st International Conference on Industrial Electronics, Control and Instrumentation 1995; 1(1): 572 – 577.
11. van der Merwe L, van der Merwe G. Maximum power point tracking — implementation strategies. Proceedings of the IEEE International Symposium on Indu strial Electronics 1998; 1(1): 214 – 217.
12. Abou El Ela M, Roger J. Optimization of the function of a photovoltaic array using a feedback control system. Solar Cells: Their Science, Technology, Applications and Economics 1984; 13(2): 185 – 195.
13. Salameh Z , Dagher F, LynchW. Step - down maximum power point tracker for photovoltaic systems. Solar Energy 1991; 46(5): 279 – 282.
14. Brambilla A, et al. New approach to photovoltaic arrays maximum power point tracking. Proceedings of the 30th IEEE Power Electronics Conference, 1998; 632 – 637.
15. Hovel HJ. Semiconductors and Semimetals: Solar Cells. Academic Press: New York, 1975; 64ff. 16. Fraas LM, Avery JE, Gruenbaum PE, Sundaram VS. Fundamental characterization studies of GaSb solar cells. Proceedings of the IEEE Photovoltaic Specialists Conference, 1991; 80 – 84.
17. Hua C, Lin J, Shen C. Implementation of a DSP - controlled photovoltaic system with peak power tracking. IEEE Transaction on Industrial Electronics 1998; 45(1): 99 – 107.
18. Won C - Y, Kim D - H, Kim S - C, Kim W - S, Kim H - S. New maximum power point tracker of photovoltaic arrays using fuzzy controller. Proceedings of the 1994 25th Annual IEEE Power Electronics Specialists Conference 1994; 2: 396 – 403.
Keywords
Solar cells, MPPT, P& O , Fuzzy