Identyfikatory
Warianty tytułu
Języki publikacji
Abstrakty
Field conditions decrease the energy output of photovoltaic (PV) systems, mainly due to excessive temperatures. However, in regions with moderate ambient temperatures, as in Poland, solar energy is commonly delivered with highly fluctuating irradiance. This introduces yet another source of energy losses due to the non-ideal tracking of actual position of Maximum Power Point (MPP). Majority of PV-systems are equipped with DC/AC and grid-connected inverter. Since the solar energy flux is variable, an adequate MPP-tracking algorithm is required to handle a wide range of load levels and face rapid changes of input power. Along with the essential DC/AC conversion, the quality of MPP-tracking must also be taken into account in evaluation of inverter efficiency. The tracking in dynamic conditions has been addressed only recently. Several algorithms has been studied theoretically, experimentally or in laboratory conditions by applying artificial input test-patterns. This work takes the opposite approach by applying the recorded real-life solar irradiance and simulating the tracking behavior to study the problem for true field conditions in Poland. The simulation uses the unique high-quality irradiance data collected with 200 ms time resolution. The calculation of both static and dynamic MPP-tracking efficiency has been performed for representative variable-cloudy day, applying commonly used Perturb&Observe tracking algorithm.
Rocznik
Tom
Strony
713--721
Opis fizyczny
Bibliogr. 22, wykr., rys.
Twórcy
autor
- Department of Microelectronics and Computer Science, Lodz University of Technology, 221/223 Wólczańska St., 90-924 Łódź, Poland
autor
- Department of Microelectronics and Computer Science, Lodz University of Technology, 221/223 Wólczańska St., 90-924 Łódź, Poland
Bibliografia
- [1] M.S. Imamura, P. Helm, and W. Palz, Photovoltaic System Technology. A European Handbook, H S Stephens & Associates, London, 1992.
- [2] T. Kozak, G. De Mey, A. De Vos, W. Marańda, and A. Napieralski, “Influence of ambient temperature on the amount of electric energy produced by solar modules”, Electronics, Technologies, Applications, SIGMA-NOT 12, 46-48 (2009).
- [3] European Photovoltaic Industry Association, Global Market Outlook For Photovoltaics 2013-2017, EPIA Report (2013).
- [4] J. Kiciński, “Do we have a chance for small-scale energy generation? The examples of technologies and devices for distributed energy systems in micro & small scale in Poland”, Bull. Pol. Ac.: Tech. 61 (4), 749--756 (2013).
- [5] W. Marańda, G. Jabłoński, and D. Makowski, “1 kWp PV System at Technical University of Lodz in Poland”, Proc. 19th Eur. PV Solar Energy Conf. 3, 2915-2917 (2004).
- [6] M.G. Villalva, J.R. Gazoli, and E.R. Filho, “Comprehensive approach to modeling and simulation of photovoltaic arrays”, IEEE Trans. Power Electronics 24 (5), 1198-1208 (2009).
- [7] W. Marańda and M. Piotrowicz, “Extraction of thermal model parameters for field-installed photovoltaic module”, Proc. 27th Int. Conf. on Microelectronics (MIEL) 1 CD-ROM (2010).
- [8] International Standard IEC 61683, “Photovoltaic systems, Power conditioners, Procedure for measuring efficiency”, 1999-11.
- [9] R. Hotopp, Private Photovoltaik-Stromerzeugungsanlagen im Netzparallelbetrieb, RWE Energie AG, Essen, 1990.
- [10] V. Salas, E. Olias, M. Alonso-Abella, and F. Chenlo, “Analysis between energy efficiency and european efficiency”, Proceedings of ISES Solar World Congress 1, CD-ROM (2007).
- [11] H. Haeberlin, L. Borgna, M. Kaempfer, and U. Zwahlen, “Total efficiency _TOT - a new quantity for better characterisation of grid-connected PV inverters”, Proc. 20th Eur. PV Solar Energy Conf. 1, CD-ROM (2005).
- [12] H. Haeberlin and Ph. Schaerf, “New procedure for measuring dynamic MPP-tracking efficiency at grid-connected PV inverters”, 24th Eur. PV Solar Energy Conf. 1, CD-ROM (2009).
- [13] V. Salas, M. Alonso-Abella, F. Chenlo, and E. Olias, “Analysis of the maximum power point tracking in the photovoltaic grid inverters of 5 kW”, Renewable Energy 34, 2366-2372 (2009).
- [14] M. Piotrowicz and W. Marańda, “Report on efficiency of fieldinstalled PV-Inverter with focus on radiation variability”, Proceedings of Mixed Design of Integrated Circuits and Systems (MIXDES) 1, CD-ROM (2013).
- [15] D.P. Hohmand and M.E. Ropp, “Comparative study of maximum power point tracking algorithms”, Progress in Photovoltaics: Research and Applications 11 (1), 47-62 (2003).
- [16] N. Onat, “Recent developments in maximum power point tracking technologies for photovoltaic systems”, Int. J. Photoenergy 2010 (245316), CD-ROM (2010).
- [17] V. Salas, E. Olias, A. Barrado, and A. Lazaro, “Review of the maximum power point tracking algorithms for stand-alone photovoltaic systems”, Solar Energy Materials & Solar Cells 90, 1555-1578 (2006).
- [18] S. Pirog, R. Stala, and L. Stawiarski, “Power electronic converter for photovoltaic systems with the use of FPGA-based real-time modeling of single phase grid-connected systems”, Bull. Pol. Ac.: Tech. 57 (4), 345-354 (2009).
- [19] N. Femia, G. Petrone, G. Spagnuolo, and M. Vitelli, “A technique for improving P&O MPPT performances of double-stage grid-connected photovoltaic systems”, IEEE Trans. on Industrial Electronics 56, 11, 4473--4482 (2009).
- [20] C. Wang, M. Wu, S. Ou, K. Lin, and C. Lin, “Analysis and research on maximum power point tracking of photovoltaic array with fuzzy logic control and three-point weight comparison method”, Science China Technological Sciences 53 (8), 2183--2189 (2010).
- [21] W. Marańda, “Numerical modeling of photovoltaic devices with python scripting language”, Proc. 17th Int. Conf. on Information Technology Systems 1, CD-ROM (2010).
- [22] G. De Mey, J. Wyrzutowicz, A. De Vos, W. Marańda, and A. Napieralski, “Influence of lateral heat diffusion on the thermal impedance measurement of photovoltaic panels”, Solar Energy Materials and Solar Cells 112, 1-5 (2013).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-554c9849-cca9-4ecf-8c9f-f68d298f7fa4