Narzędzia help

Preferencje help
Widoczny [Schowaj] Abstrakt
Liczba wyników
first previous next last
cannonical link button


Przegląd Elektrotechniczny

Tytuł artykułu

Soft-switching AC module inverter with flyback transformer for photovoltaic power system

Autorzy Tan, G.  Tang, Y.  Gao, B.  Fu, X.  Ji, Y. 
Treść / Zawartość
Warianty tytułu
PL Modułowy przekształtnik AC z transformatorem typy flyback w systemie fotowoltaicznym
Języki publikacji EN
EN This paper presents an AC module inverter for photovoltaic (PV) power system. The PV inverter employs a Buck-Boost converter on the DC side and a flyback inverter on the AC side. Based on capacitive idling (CI) techniques and peak current control method, the proposed inverter shows low current distortion, high power factor, small power decoupling capacitor and soft-switching operation. Analysis and experimental results are provided to demonstrate these excellent features.
PL W artykule zaprezentowano modułowy przekształtnik AC zastosowany w systemach fotowoltaicznych. Przekształtnik wykorzystuje konwerter Buck-Boost po stronie DC i konwerter typu flyback po stronie AC. Układ bazuje na jałowym biegu pojemnościowym i kontroli wartości szczytowej prądu. (Modułowy przekształtnik AC z transformatorem typy flyback w systemie fotowoltaicznym)
Słowa kluczowe
PL przekształtnik flyback   systemy fotowoltaiczne  
EN flyback inverter   soft-switching   capacitive idling (CI)   photovoltaic (PV)  
Wydawca Wydawnictwo SIGMA-NOT
Czasopismo Przegląd Elektrotechniczny
Rocznik 2012
Tom R. 88, nr 10a
Strony 180--184
Opis fizyczny Bibliogr. 17 poz., rys.
autor Tan, G.
autor Tang, Y.
autor Gao, B.
autor Fu, X.
autor Ji, Y.
[1] Blaabjerg, F., Chen, Z., and Kjaer, S. B., Power electronics as efficient interface in dispersed power generation systems, IEEE Trans. Power Electron., 19(2004), No. 5, 1184-1194
[2] Pan, C. T., Lai, C. M., and Cheng, M. C., A novel integrated single-phase inverter with auxiliary step-up circuit for low voltage alternative energy source applications, IEEE Trans.Power Electron., 25(2010), No. 9, 2234-2241
[3] Hanif, M., Basu, M., and Gaughan, K., Understanding the operation of a Z-source inverter for photovoltaic application with a design example, IET Power Electron., 4(2011), No. 3, 278-287
[4] Wills, R. H., Hall, F. E., Strong, S. J., and Wohlgemuth, J. H., The AC photovoltaic module, in Proc. IEEE Photovoltaic Specialists Conference 1996, 1231-1234
[5] Yatsuki, S., Wada, K., Shimizu, T., Takagi, H., and Ito, M., A novel AC photovoltaic module system based on the impedance-admittance conversion theory, in Proc. IEEE PESC 2001, 2191-2196
[6] Papanikolaou, N. P., Tatakis, E. C., Critsis, A., and Klimis, D., Simplified high frequency converter in decentralized gridconnected PV systems: a novel low-cost solution, in European Conference of Power Electronics and Applications 2003, CDROM
[7] Kasa, N., Iida, T., and Chen, L., Flyback inverter controlled by sensorless current MPPT for photovoltaic power system, IEEE Trans. Ind. Electron., 52(2005), No. 4, 1145-1152
[8] Chandhaket, S., Ogura, K., Nakaoka, M., and Konishi, Y., High-frequency flyback transformer linked utility-connected sinewave soft-switching power conditioner using a switched capacitor snubber, in Proc. IEEE IPEMC 2004, 1242-1247
[9] Kasa, N., Iida, T., and Bhat, A. K. S., Zero-voltage transition flyback inverter for small scale photovoltaic power system, in Proc. IEEE PESC 2005, 2098-2103
[10] Chandhaket, S., Konishi, Y., Ogura, K., and Nakaoka, M., Utility AC interfaced soft-switching sinewave PWM power conditioner with two-switch flyback high-frequency transformer, IET Electr. Power Appl., 151(2004), No. 5, 526-533
[11] Shimizu, T., Wada, K., and Nakamura, N., A flyback-type single phase utility interactive inverter with low-frequency ripple current reduction on the DC input for an AC photovoltaic module system, in Proc. IEEE PESC 2002, 1483-1488
[12] Shimizu, T., Wada, K., and Nakamura, N., Flyback-type singlephase utility interactive inverter with power pulsation decoupling on the DC input for an AC photovoltaic module system, IEEE Trans. Power Electron., 21(2006), No. 5, 1264-1272
[13] Kjaer, S. B., and Blaabjerg, F., Design optimization of a single phase inverter for photovoltaic applications, in Proc. IEEE PESC 2003, 1183-1190
[14] Stevanovic, L.D., and Cuk, S., Capacitive idling converters with decoupled input voltage and load regulation loops, in Proc. IEEE PESC 1993, 681-688
[15] Knight, J., Shirsavar, S., and Holderbaum, W., Capacitive idling techniques improve inverter performance, in Proc. IEE PEMD 2004, 638-643
[16] Vendrusculo, E.A., and Pomilio, J.A., Soft commutation in capacitive idling converters, IEEE Trans. Ind. Electron., 45(1998), No. 3, 521-522
[17] Nafeh, A., Fahmy, F., Mahgoub, O., and El-Zahab, E., Microprocessor control system for maximum power operation of PV arrays, International Journal of Numerical Modelling, 12(1999), No. 3, 187-195
Kolekcja BazTech
Identyfikator YADDA bwmeta1.element.baztech-article-BPS3-0025-0056