Araştırma Makalesi
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Yıl 2018, , 76 - 81, 20.10.2018
https://doi.org/10.31593/ijeat.441431

Öz

Kaynakça

  • [1] Farrokhfal, Y. G., Kazhamiaka, F., Rosenberg, C., Keshav, S., 2015, “Optimal Design of Solar PV Farms with Storage”, IEEE Transactions on Sustainable Energy, 6 (4), 1586-1593.
  • [2] Devassy, S., Singh, B., 2018, “Design and Performance Analysis of Three-Phase Solar PV Integrated UPQC”, IEEE Transactions on Industry Applications, 54 (1), 73-81.
  • [3] Hishikawa, Y., et.al, 2018, “Voltage-Dependent Temperature Coefficient of the I–V Curves of Crystalline Silicon Photovoltaic Modules”, IEEE Journal of Photovoltaics, 8 (1), 48-53.
  • [4] Yu, Y., et.al, 2017, “Delta-Connected Cascaded H-Bridge Multilevel Converters for Large-Scale Photovoltaic Grid Integration”, IEEE Transactions on Industrial Electronics, 64 (11), 8877-8886.
  • [5] Dong, D., et.al, 2018, “PV Residential Microinverter with Grid-Support Function: Design, Implementation, and Field Testing”, IEEE Transactions on Industry Applications, 54 (1), 469-481.
  • [6] Kumar, S., Singh, B., 2018, “A Multipurpose PV System Integrated to a Three-Phase Distribution System Using an LWDF-Based Approach”, IEEE Transactions on Power Electronics, 33 (1), 739-748.
  • [7] Kim, J.S., Kwon, J. M. Kwon, B.H., 2018, “High-Efficiency Two-Stage Three-Level Grid-Connected Photovoltaic Inverter,” IEEE Transactions on Industrial Electronics, 65 (3), 2368-2377.
  • [8] Chandel, S.S., Naik, M.N., Chandel, R., 2015, “Review of solar photovoltaic water pumping system technology for irrigation and community drinking water supplies”, Renewable and Sustainable Energy Reviews, 49, 1084-1099.
  • [9] Gumus, B., Yakut Y. B., 2015, “Analysis of Induction Motor-pump System Supplied by a Photovoltaic Generator for Agricultural Irrigation in Southeastern Anatolian Region of Turkey”, J Electr Eng Technol, 10 (3), 777-785.
  • [10] Zahab, E.E.A., Zaki, A.M., El-sotouhy, M.M., 2017, “Design and control of a standalone PV water pumping system”, Journal of Electrical Systems and Information Technology, 4, 322-337.
  • [11] Yadav, K., et.al, 2015, “Performance comparison of controllers for solar PV water pumping applications”, Solar Energy, 119, 195-202.
  • [12] Kumar, R., Singh, B., 2017, “Single Stage Solar PV Fed Brushless DC Motor Driven Water Pump”, IEEE Journal of Emerging and Selected Topics in Power Electronics, 5 (3), 1377-1385.
  • [13] Boutelhig, A., Bakelli, Y., Hadj Mahammed, I., Hadj Arab, A., 2012, “Performances study of different PV powered DC pump configurations for an optimum energy rating at different heads under the outdoor conditions of a desert area”, Energy, 39, 33-39.
  • [14] Mozaffari Niapour, S.A.KH., Danyali, S., Sharifian, M.B.B., Feyzi, M.R., 2011, “Brushless DC motor drives supplied by PV power system based on Z-source inverter and FL-IC MPPT controller”, Energy Conversion and Management, 52, 3043-3059.
  • [15] Ozdemir, S., Altin, N., Sefa, I., Bal, G., 2014, “PV Supplied Single Stage MPPT Inverter for Induction Motor Actuated Ventilation Systems”, ELEKTRONIKA IR ELEKTROTECHNIKA, 20 (5), 116-122.
  • [16] Hussein, A., Hirasawa, K. Hu, J., 2004, “A robust control method for a PV-supplied DC motor using universal learning networks”, Solar Energy, 76, 771-780.
  • [17] Oshaba, A. S., Ali, E. S. Abd Elazim, S. M., 2017, “Speed control of SRM supplied by photovoltaic system via ant colony optimization algorithm”, Neural Comput & Applic, 28, 365-374.
  • [18] Oshaba, A. S., Ali, E. S. Abd Elazim, S. M., 2015, “MPPT Control Design of PV System Supplied SRM Using BAT Search Algorithm”, Sustainable Energy, Grids and Networks, 2, 51-60.
  • [19] Kocaman, B., Akdağ, M., Efe, S.B., Akdeniz, M., 2017, “Implementation and Performance Analysis of a Hybrid PV-Wind Energy System”, International Journal of Engineering and Advanced Technology, 7 (1), 100-104.
  • [20] Efe, S.B., Cebeci M., 2015, “Artificial Neural Network Based Power Flow Analysis for Micro Grids”, Bitlis Eren University Journal of Science and Technology, 5 (1), 42-47.
  • [21] Efe, S. B., Cebeci, M., Erdoğan, H., Öztürkmen, G., 2015, “A Novel Approach to Power Flow Analysis for Grid Connected Micro Grid”, 13th ICEMES, 11-12 June, 29-32, Oradea, Romania.
  • [22] Ch, S., Srikanth, M.V., 2014, “Modeling and Analysis of 6/4 Switched Reluctance Motor with Torque Ripple Reduction”, International Conference on Advances in Engineering & Technology, 37.
  • [23] Wong, K. F., Cheng, K. W. E., Ho, S. L., 2007, “Simulation of Switched Reluctance Motor Based on a Combination of Circuit-oriented and Signal-oriented Approaches Using Matlab/ SimPowerSystems”, Electric Power Components and Systems, 35(2), 205-219.
  • [24] Jambulingam, V., 2016, “Mathematical Modeling and Simulation of Switched Reluctance Motor”, International Journal for Research in Applied Science & Engineering Technology, 4 (4), 441-446.
  • [25] DiRenzo, M. T., 2000, “Switched Reluctance Motor Control – Basic Operation and Example Using the TMS320F240”, Texas Instruments Application Report.
  • [26] Demir, D., Efe, S. B., 2018, “Analysis of PV Supplied SRM for Different Operating Conditions”, 7th International Conference on Advanced Technologies, 28 April-1 May, 269-272, Antalya, Turkey.

Design and analysis of PV fed SRM system

Yıl 2018, , 76 - 81, 20.10.2018
https://doi.org/10.31593/ijeat.441431

Öz

Renewable
energy sources supplied motor applications are being studied widely by
researchers. As it is especially focused on design and control of such systems,
studies on performance analysis approach is limited. It is vital to determine
the operating behaviour of motor loads when they are supplied by limited energy
sources like photovoltaic (PV) systems. According to this necessity, in this
study, a switched reluctance motor (SRM) which is supplied by a PV system is analysed
in terms of speed, current and torque data. Because of its advantages as it can
be controlled over a wide range, its reliability and stability, SRM was used
for analysis. Such data are observed in two cases, PV system irradiance change
and fault conditions. System is designed as direct-fed, which is not include
any storage unit. Therefore, any changes at supply system directly affect motor
parameters. These effects and results are discussed by using the graphs that
obtained from various points of system for both cases.

Kaynakça

  • [1] Farrokhfal, Y. G., Kazhamiaka, F., Rosenberg, C., Keshav, S., 2015, “Optimal Design of Solar PV Farms with Storage”, IEEE Transactions on Sustainable Energy, 6 (4), 1586-1593.
  • [2] Devassy, S., Singh, B., 2018, “Design and Performance Analysis of Three-Phase Solar PV Integrated UPQC”, IEEE Transactions on Industry Applications, 54 (1), 73-81.
  • [3] Hishikawa, Y., et.al, 2018, “Voltage-Dependent Temperature Coefficient of the I–V Curves of Crystalline Silicon Photovoltaic Modules”, IEEE Journal of Photovoltaics, 8 (1), 48-53.
  • [4] Yu, Y., et.al, 2017, “Delta-Connected Cascaded H-Bridge Multilevel Converters for Large-Scale Photovoltaic Grid Integration”, IEEE Transactions on Industrial Electronics, 64 (11), 8877-8886.
  • [5] Dong, D., et.al, 2018, “PV Residential Microinverter with Grid-Support Function: Design, Implementation, and Field Testing”, IEEE Transactions on Industry Applications, 54 (1), 469-481.
  • [6] Kumar, S., Singh, B., 2018, “A Multipurpose PV System Integrated to a Three-Phase Distribution System Using an LWDF-Based Approach”, IEEE Transactions on Power Electronics, 33 (1), 739-748.
  • [7] Kim, J.S., Kwon, J. M. Kwon, B.H., 2018, “High-Efficiency Two-Stage Three-Level Grid-Connected Photovoltaic Inverter,” IEEE Transactions on Industrial Electronics, 65 (3), 2368-2377.
  • [8] Chandel, S.S., Naik, M.N., Chandel, R., 2015, “Review of solar photovoltaic water pumping system technology for irrigation and community drinking water supplies”, Renewable and Sustainable Energy Reviews, 49, 1084-1099.
  • [9] Gumus, B., Yakut Y. B., 2015, “Analysis of Induction Motor-pump System Supplied by a Photovoltaic Generator for Agricultural Irrigation in Southeastern Anatolian Region of Turkey”, J Electr Eng Technol, 10 (3), 777-785.
  • [10] Zahab, E.E.A., Zaki, A.M., El-sotouhy, M.M., 2017, “Design and control of a standalone PV water pumping system”, Journal of Electrical Systems and Information Technology, 4, 322-337.
  • [11] Yadav, K., et.al, 2015, “Performance comparison of controllers for solar PV water pumping applications”, Solar Energy, 119, 195-202.
  • [12] Kumar, R., Singh, B., 2017, “Single Stage Solar PV Fed Brushless DC Motor Driven Water Pump”, IEEE Journal of Emerging and Selected Topics in Power Electronics, 5 (3), 1377-1385.
  • [13] Boutelhig, A., Bakelli, Y., Hadj Mahammed, I., Hadj Arab, A., 2012, “Performances study of different PV powered DC pump configurations for an optimum energy rating at different heads under the outdoor conditions of a desert area”, Energy, 39, 33-39.
  • [14] Mozaffari Niapour, S.A.KH., Danyali, S., Sharifian, M.B.B., Feyzi, M.R., 2011, “Brushless DC motor drives supplied by PV power system based on Z-source inverter and FL-IC MPPT controller”, Energy Conversion and Management, 52, 3043-3059.
  • [15] Ozdemir, S., Altin, N., Sefa, I., Bal, G., 2014, “PV Supplied Single Stage MPPT Inverter for Induction Motor Actuated Ventilation Systems”, ELEKTRONIKA IR ELEKTROTECHNIKA, 20 (5), 116-122.
  • [16] Hussein, A., Hirasawa, K. Hu, J., 2004, “A robust control method for a PV-supplied DC motor using universal learning networks”, Solar Energy, 76, 771-780.
  • [17] Oshaba, A. S., Ali, E. S. Abd Elazim, S. M., 2017, “Speed control of SRM supplied by photovoltaic system via ant colony optimization algorithm”, Neural Comput & Applic, 28, 365-374.
  • [18] Oshaba, A. S., Ali, E. S. Abd Elazim, S. M., 2015, “MPPT Control Design of PV System Supplied SRM Using BAT Search Algorithm”, Sustainable Energy, Grids and Networks, 2, 51-60.
  • [19] Kocaman, B., Akdağ, M., Efe, S.B., Akdeniz, M., 2017, “Implementation and Performance Analysis of a Hybrid PV-Wind Energy System”, International Journal of Engineering and Advanced Technology, 7 (1), 100-104.
  • [20] Efe, S.B., Cebeci M., 2015, “Artificial Neural Network Based Power Flow Analysis for Micro Grids”, Bitlis Eren University Journal of Science and Technology, 5 (1), 42-47.
  • [21] Efe, S. B., Cebeci, M., Erdoğan, H., Öztürkmen, G., 2015, “A Novel Approach to Power Flow Analysis for Grid Connected Micro Grid”, 13th ICEMES, 11-12 June, 29-32, Oradea, Romania.
  • [22] Ch, S., Srikanth, M.V., 2014, “Modeling and Analysis of 6/4 Switched Reluctance Motor with Torque Ripple Reduction”, International Conference on Advances in Engineering & Technology, 37.
  • [23] Wong, K. F., Cheng, K. W. E., Ho, S. L., 2007, “Simulation of Switched Reluctance Motor Based on a Combination of Circuit-oriented and Signal-oriented Approaches Using Matlab/ SimPowerSystems”, Electric Power Components and Systems, 35(2), 205-219.
  • [24] Jambulingam, V., 2016, “Mathematical Modeling and Simulation of Switched Reluctance Motor”, International Journal for Research in Applied Science & Engineering Technology, 4 (4), 441-446.
  • [25] DiRenzo, M. T., 2000, “Switched Reluctance Motor Control – Basic Operation and Example Using the TMS320F240”, Texas Instruments Application Report.
  • [26] Demir, D., Efe, S. B., 2018, “Analysis of PV Supplied SRM for Different Operating Conditions”, 7th International Conference on Advanced Technologies, 28 April-1 May, 269-272, Antalya, Turkey.
Toplam 26 adet kaynakça vardır.

Ayrıntılar

Birincil Dil İngilizce
Konular Elektrik Mühendisliği
Bölüm Research Article
Yazarlar

Serhat Berat Efe 0000-0001-6076-4166

Dilan Demir Aktaş

Yayımlanma Tarihi 20 Ekim 2018
Gönderilme Tarihi 6 Temmuz 2018
Kabul Tarihi 1 Eylül 2018
Yayımlandığı Sayı Yıl 2018

Kaynak Göster

APA Efe, S. B., & Demir Aktaş, D. (2018). Design and analysis of PV fed SRM system. International Journal of Energy Applications and Technologies, 5(2), 76-81. https://doi.org/10.31593/ijeat.441431
AMA Efe SB, Demir Aktaş D. Design and analysis of PV fed SRM system. IJEAT. Ekim 2018;5(2):76-81. doi:10.31593/ijeat.441431
Chicago Efe, Serhat Berat, ve Dilan Demir Aktaş. “Design and Analysis of PV Fed SRM System”. International Journal of Energy Applications and Technologies 5, sy. 2 (Ekim 2018): 76-81. https://doi.org/10.31593/ijeat.441431.
EndNote Efe SB, Demir Aktaş D (01 Ekim 2018) Design and analysis of PV fed SRM system. International Journal of Energy Applications and Technologies 5 2 76–81.
IEEE S. B. Efe ve D. Demir Aktaş, “Design and analysis of PV fed SRM system”, IJEAT, c. 5, sy. 2, ss. 76–81, 2018, doi: 10.31593/ijeat.441431.
ISNAD Efe, Serhat Berat - Demir Aktaş, Dilan. “Design and Analysis of PV Fed SRM System”. International Journal of Energy Applications and Technologies 5/2 (Ekim 2018), 76-81. https://doi.org/10.31593/ijeat.441431.
JAMA Efe SB, Demir Aktaş D. Design and analysis of PV fed SRM system. IJEAT. 2018;5:76–81.
MLA Efe, Serhat Berat ve Dilan Demir Aktaş. “Design and Analysis of PV Fed SRM System”. International Journal of Energy Applications and Technologies, c. 5, sy. 2, 2018, ss. 76-81, doi:10.31593/ijeat.441431.
Vancouver Efe SB, Demir Aktaş D. Design and analysis of PV fed SRM system. IJEAT. 2018;5(2):76-81.