MODELING AND SIMULATION OF SOLAR MODULE PHOTOVOLTAIC WAAREE WSM 330 USED BY THE CENTRAL SOLAR 7MW OF MALBAZA (NIGER)

Assarid Issaka Abdoulkarim; Adamou Mamane; Noma Talibi Soumaïla; Madougou Saidou; Boureima Seibou

doi:10.29121/granthaalayah.v11.i12.2023.5379

Authors

Assarid Issaka Abdoulkarim Kandadji Dam Agency, Niamey, Niger
Adamou Mamane Faculty of Science and Technology/André Salifou University (UAS), Zinder, Niger
Noma Talibi Soumaïla Laboratory of Energetic, Electronics, Electrotechnics, Automatics and Industrial Computing, Abdou Moumouni University (UAM), Niamey, Niger
Madougou Saidou Laboratory of Energetic, Electronics, Electrotechnics, Automatics and Industrial Computing, Abdou Moumouni University (UAM), Niamey, Niger
Boureima Seibou Electrical Engineering Department, Mines, Industry and Geology School (EMIG), Niger

DOI:

https://doi.org/10.29121/granthaalayah.v11.i12.2023.5379

Keywords:

Electricity Spot Market, Energy, Photovoltaic, PV 7 MW, Modeling, Simulation, Matlab, Malbaza

Abstract [English]

In order to study the behavior of the solar photovoltaic 7MW Malbaza depending on the irradiation and temperature, modeling of the various components of the system is essential. It is in this context that we have done modeling of a PV module comprising the solar field of the said plant. In this article, we initially presented the basic mathematical model of the photovoltaic cell, reported the equations models with two diodes and a diode, and later considered the case of the model with a diode to perform modeling PV of the central module. Secondly, we implemented the model developed in MATLAB Simulink to study the current-voltage characteristics for different irradiations considering the constant temperature and then for different temperature keeping constant light. The results are similar to the current-voltage characteristics provided by the manufacturer. This allowed us to conclude that the model developed is reliable. Finally, we will study the influence of radiation and temperature on the production of the module.

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