Research Article
ANAHTARLAMA FREKANSI İLE THDI ARASINDAKİ ANALİTİK İFADENİN SOLAR SİSTEMDE SPSS İSTATİSTİK PROGRAMI YÖNTEMİ İLE BULUNMASI
Abstract
Bu çalışma, şebekeden bağımsız fotovoltaik (PV) güç sisteminde anahtarlama frekansına bağlı olarak, inverter çıkış akımı toplam harmonik bozunumunun (THDI) ölçülmesi, modellemesi, analizi ve simülasyonu ile ilgilidir. Önerilen güneş enerjisi sistemi, DC-DC dönüştürücü, DC-AC solar inverter üç fazlı kontrolsüz doğrultucu ile R-L endüktif yükten oluşmaktadır. Bu makalede, anahtarlama frekansı ile THDI arasındaki ilişki SPSS istatistik programı yöntemi kullanılarak incelenmiştir. Darbe genlik modülasyonu (PWM) anahtarlama frekansının değeri arttıkça THDI değerinin azaldığı gözlenmektedir. Bu topolojinin tasarımı, modellenmesi ve simülasyonu, 500 ila 50 KHz anahtarlama frekansı için Matlab/Simulink programı kullanılarak gerçekleştirilmiştir. Anahtarlama frekansı ile THDI arasındaki analitik ifade SPSS istatistik yazılım programı kullanılarak elde edilmiştir.
Keywords
doğrusal olmayan yük harmonik bileşen toplam harmonik bozunumu şebekeden bağımsız fotovoltaik sistem anahtarlama frekansı
References
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- Ozdemir, A., & Ferikoglu, A. (2004). IEE Proceedings-Science Measurement And Technology. Low cost mixed-signal microcontroller based power measurement technique, - 151(4), 253-258.
- Pandiarajan, N., & Muthu, R. (2011). ICEES International Conference on Electrical Energy Systems. Mathematical modelling of photovoltaic module with Simulink, pp. 314-319.
- Sabir, R., Emrullah, O., Nuri, M.A, & Serhat, E.B. (2015). Bitlis Eren Univ J Sci & Technol. Reducing the effects of harmonics on the electrical power systems with passive filters, 5 (1), 1-10.
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Year 2020,
Volume: 23 Issue: 1, 1 - 8, 29.03.2020
Abstract
References
- Adak, S., & Cangi, H. (2016). Bitlis Eren Univ J Sci & Technol. Analysis and Simulation Total Harmonic Distortion of Output Voltage Three Level Diode Clamped Inverter in Photovoltaic System, 5(2), 242-253.
- Arifoğlu, U. (2016). Matlab 9.1-Simulink ve Mühendislik Uygulamaları, Alfa Yayıncılık, İstanbul.
- Badawy, M.O., Yilmaz, A.S., Sozer, Y., & Husein, I. (2014). IEEE T Ind Appl. Parallel power processing topology for solar PV applications, 50, 1245-1255.
- Bandaraa, K., Sweetb, T., & Ekanayake, J. (2012). Science Direct. Photovoltaic applications for off-grid electrification using novel multi-level inverter technology with energy storage, 37(1), 82-88.
- Cangi, H. (2019). Natural and Applied Sciences, University of Kahramanmaras Sutcu Imam. Analysis and Elimination of Harmonics at Low Irradiation Level in PV Systems, Ph.D. Thesis.
- İzgi, E., Öztopal, A., Durna, B., Kaymak, M.K., & Şahin, A.D. (2012). Solar Energy. Short–mid-term solar power prediction by using artificial, 86, 725-733.
- Jiang, Y.J.A., Qahouq, A., & Batarseh, I. (2010). Proc. IEEE Int. Symp. Circuits Syst. Improved solar PV cell MATLAB simulation model and comparison, pp. 2770–2773.
- Kashif, I., & Zainal, S. (2011). Sol Energy. An improved modelling method to determine the model parameters of photovoltaic (PV) modules using differential evolution (DE), 85, 2349-2359.
- Kılıc, B. (2011). International Journal Of Renewable Energy Research. Evaluating of Renewable Energy Potential in Turkey, 1(4), pp.259-264.
- Kocatepe, C., Uzunoglu, M., Yumurtacı, R., Karakaş, A., & Arıkan, O. (2003). Harmonics in Electrical Plants. Birsen Publication, İstanbul.
- Krismadinataa, N., Pinga, R.H.W., & Selvaraja. J. (2013). Pro-cedia Environmental Sciences. Photovoltaic module modelling using Simulink/MATLAB, 17, 537- 546.
- Kulaksi, A.A. (2013). Turk J ElecEng & Comp. ANFIS-based estimation of PV module equivalent parameters: application to a stand-alone PV system with MPPT controller, 21, 2127-2140.
- Malla, S.G., & Bhende, C.N. (2014). EEPS: International Journal of Emerging Electric Power Systems. Study of Stand-Alone Microgrid under Condition of Faults on Distribution Line, 15(5), pp. 501-512.
- Ozdemir, A., & Ferikoglu, A. (2004). IEE Proceedings-Science Measurement And Technology. Low cost mixed-signal microcontroller based power measurement technique, - 151(4), 253-258.
- Pandiarajan, N., & Muthu, R. (2011). ICEES International Conference on Electrical Energy Systems. Mathematical modelling of photovoltaic module with Simulink, pp. 314-319.
- Sabir, R., Emrullah, O., Nuri, M.A, & Serhat, E.B. (2015). Bitlis Eren Univ J Sci & Technol. Reducing the effects of harmonics on the electrical power systems with passive filters, 5 (1), 1-10.
- Sekkeli, M., Acıkgoz, H., Gani, A,. & Kececioglu, O.F. (2015). International Refereed Journal of Engineering and Sciences. Modeling and Analysis of Three Phase Space Vector Pulse Width Modulation Based Rectifiers Using Fuzzy PI Controller, 2(3), 75–75.
- Uysal, U. (2004). Mathematical and engineering applications with Matlab, Beta Basım A.Ş., İstanbul.
- Villalva, M.G., Gazoli J.R., & Ernesto, R.F. (2009). IEEE T Power Electr. Comprehensive approach to modelling and simulation of photovoltaic arrays, 24, 1198-1208.
There are 19 citations in total.
Details
| Primary Language | Turkish |
|---|---|
| Subjects | Electrical Engineering |
| Journal Section | Electrical and Electronics Engineering |
| Authors | |
| Publication Date | March 29, 2020 |
| Submission Date | July 24, 2019 |
| Published in Issue | Year 2020Volume: 23 Issue: 1 |
