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Tytuł artykułu

Effect of incidence angle varying from 0 rad to Π/2 rad and intensity of radio waves on the performance of a silicon solar cell

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Języki publikacji
EN
Abstrakty
EN
In this work, a one dimensional approach is presented for modelling the effect of the incidence angle, varying from 0 rad to π/2 rad, and the intensity of radio waves on the performance of a polycrystalline silicon solar cell under constant multispectral illumination. By solving the continuity equation in steady state, we derived the expression of the density of excess minority carriers, the photocurrent density, the photovoltage, the electric power and their dependence on the incidence angle and the intensity of the electromagnetic field is analyzed. Using the electric power curves versus junction dynamic velocity we determined the electric power lost at the junction, the maximum electric power and we calculated the conversion efficiency for various incidence angle and intensity of the electromagnetic field. The leakage photocurrent density, deduced from the photocurrent density curves versus junction dynamic velocity, and the electric power lost at the junction allowed us to calculate the shunt resistance of the solar cell according to the incidence angle and the intensity of the electromagnetic field. The numerical data show the negative effect of radios waves on the performance of a silicon solar cell.
Twórcy
autor
  • Laboratory of Thermal and Renewable Energies, Department of Physics, Unit of Training and Research in Pure and Applied Sciences, University Ouaga I Prof. Joseph KI-ZERBO, Burkina Faso
autor
  • Laboratory of Thermal and Renewable Energies, Department of Physics, Unit of Training and Research in Pure and Applied Sciences, University Ouaga I Prof. Joseph KI-ZERBO, Burkina Faso
autor
  • Laboratory of Thermal and Renewable Energies, Department of Physics, Unit of Training and Research in Pure and Applied Sciences, University Ouaga I Prof. Joseph KI-ZERBO, Burkina Faso
autor
  • Laboratory of Thermal and Renewable Energies, Department of Physics, Unit of Training and Research in Pure and Applied Sciences, University Ouaga I Prof. Joseph KI-ZERBO, Burkina Faso
  • Laboratory of Thermal and Renewable Energies, Department of Physics, Unit of Training and Research in Pure and Applied Sciences, University Ouaga I Prof. Joseph KI-ZERBO, Burkina Faso
Bibliografia
  • 1.Dia F., Mbengue N., Diagne M., Niasse O. A., Ba B. and Séne C. Contribution to the study of the degradation of modules PV in the tropical latitudes: case of Senegal. Research Journal of Applied Sciences, Engineering and Technology, 12(4), 2016, 427–438.
  • 2.Drapalik M., Schmid J., Kancsar E., Schlosser V. and Klinger G. A study of the antenna effect of photovoltaic. International Conference on Renewable Energies and Power Quality (ICREPQ’10), Granada, Spain 2010.
  • 3.Freyer U. Nachrichten-Uebertragungstechnik, Carl Hanser, 1994.
  • 4.Koffi H. A., Kakane V. C. K., Kuditcher A., Hugues A. F., Adeleye M. B. and Amuzu J. K. A. Seasonal variations in the operating temperature of silicon solar panels in southern Ghana. African Journal of Science, Technology, Innovation and Development, 7(6), 2015, 485–490.
  • 5.Koffi H. A., Kuditcher A., Kakane V. C. K., Armah E. A., Yankson A. A. and Amuzu J. K. A. (2015) The Shockley five-parameter model of a silicon solar cell: A short note. African Journal of Science, Technology, Innovation and Development, 7(6), 491–494.
  • 6.Misiakos K., Wang C. H., Neugroschel A. and Lindholm F. A. Simultaneous Extraction of Minority-Carrier Parameters in Crystalline Semiconductors by Lateral Photocurrent. Journal of Applied Physics, 67(1), 1990, 321–333.
  • 7.Sane M., Sahin G., Barro F. I. and Maiga A. S. Incidence angle and spectral effects on vertical junction silicon solar cell capacitance. Turkish Journal of Physics, 38(2), 2014, 221–227.
  • 8.Sissoko G., Corréa A., Nanema E., Diarra M. N., Ndiaye A. L. and Adj A. Recombination parameters measurement in silicon double sided surface field solar cell. Proc. of World Renewable Energy Congress, Florence, Italy 1998, 1856–1859.
  • 9.Zerbo I., Zoungrana M., Ouedraogo A., Bruno K., Zouma B. and Bathiebo D. J. Influence of electromagnetic waves produced by an amplitude modulation radio antenna on the electric power delivered by a silicon solar cell. Global Journal of Pure and Applied Sciences, 20, 2014, 139–148.
  • 10.Zerbo I., Zoungrana M., Seré A. D., Ouedraogo F., Sam R., Zouma B. and Zougmoré F. Influence d’une onde électromagnétique sur une photopile au silicium sous éclairement multispectral en régime statique. Revue des Energies Renouvelables, 14(3), 2011, 517–532.
  • 11.Zerbo I., Zoungrna M., Seré A. D. and Zougmoré F. Silicon solar cell under electromagnetic wave in steady state: effect of the telecommunication source’s power of radiation. IOP Conference Series: Materials Science and Engineering, 29, 2012, 012019.
  • 12.Zerbo I., Zoungrana M., Sourabié I., Ouedraogo A., Zouma B. and Bathiebo D. J. External magnetic field effect on bifacial silicon solar cell’s electric power and conversion efficiency. Turkish Journal of Physics, 39(3), 2015, 288-294.
Uwagi
Opracowanie ze środków MNiSW w ramach umowy 812/P-DUN/2016 na działalność upowszechniającą naukę (zadania 2017)
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-4ad93714-1a36-40f0-bcc9-a8cdc5dd9690
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