Comparative numerical study of the energy performance of two different configurations of a hybrid photovoltaic/thermal air collector

https://doi.org/10.55214/25768484.v8i6.2846

Authors

  • Yao Kombate Regional Center of Excellence for Electricity Management (CERME), University of Lomé (UL), Lomé, Togo, and Solar Energy Laboratory, Department of Physics, Faculty of Sciences, University of Lomé (UL), Lomé, Togo
  • Kokou N’wuitcha Regional Center of Excellence for Electricity Management (CERME), University of Lomé (UL),
  • Komlan Déla Donald Aoukou Solar Energy Laboratory, Department of Physics, Faculty of Sciences, University of Lomé (UL), Lomé, Togo
  • Koffi Gagnon Apedanou Solar Energy Laboratory, Department of Physics, Faculty of Sciences, University of Lomé (UL), Lomé, Togo
  • Yendouban Kolani Solar Energy Laboratory, Department of Physics, Faculty of Sciences, University of Lomé (UL), Lomé, Togo
  • N’Gissa Attah Solar Energy Laboratory, Department of Physics, Faculty of Sciences, University of Lomé (UL), Lomé, Togo
  • Bernard Obese Department of Science Education, University of Cape Coast, Cape Coast, Ghana

Solar energy is a renewable alternative to fossil fuels. When solar energy is converted into electricity by photovoltaic (PV) solar modules, the heat generated increases the temperature of the PV solar cells and, as a result, reduces their electrical efficiency. Several techniques are used to cool PV solar cells in order to reduce their operating temperature. One technique is the use of hybrid photovoltaic/thermal (PVT) solar collectors, which simultaneously produce electricity and useful heat. In the airflow channel, the heat and mass transfer equations and those derived from the energy balance on the solid layers of the collector were discretized using the finite difference method with an implicit alternating directions (ADI) scheme. All the algebraic equations obtained after discretization were solved using the Thomas algorithm. The aim is to make a numerical comparison of the energy performance of the Verre-PV-Tedlar and Verre-PV-Verre flat-plate air PVT hybrid solar collectors in the climatic conditions of Lomé, Togo. Under the same operating conditions, the average electrical efficiencies of the Verre-PV-Verre and Verre-PV-Tedlar flat-plate air PVT hybrid collectors are 15.34% and 13.85% respectively. There is a 1.49% improvement in electrical efficiency for a Verre-PV-Verre air-source PVT hybrid collector compared with a Verre-PV-Tedlar PVT hybrid collector. The Verre-PV-Verre flat plate PVT air hybrid collector has an average daily electrical energy gain of 0.564 kWh and a thermal energy gain of 0.839 kWh, while the Verre-PV-Tedlar flat plate PVT air hybrid collector has an average daily electrical energy gain of 0.548 kWh and a thermal energy gain of 1.403 kWh.

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How to Cite

Kombate, Y. ., N’wuitcha, K. ., Aoukou, K. D. D. ., Apedanou, K. G. ., Kolani, Y. ., Attah, N. ., & Obese, B. . (2024). Comparative numerical study of the energy performance of two different configurations of a hybrid photovoltaic/thermal air collector. Edelweiss Applied Science and Technology, 8(6), 3902–3924. https://doi.org/10.55214/25768484.v8i6.2846
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Issue

Vol. 8 No. 6 (2024)

Section

Articles

Published

2024-11-05

Keywords

Cooling, Electrical energy, Glass-PV-Glass, Glass-PV-Tedlar, Modelling, energy performance, PVT hybrid solar collector.
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