Optimization of coupling phase-change materials and thermal screens in façade-integrated hybrid photovoltaic collectors for optimal energy production and thermal comfort in buildings

https://doi.org/10.55214/25768484.v8i6.2558

Authors

  • Kokou Aménuvéla Toka Laboratoire Sur l’Energie Solaire /Groupe Phénomènes de Transfert et Energétique, Université de Lomé, 01 Lomé BP 1515, Togo
  • Yawovi Nougbléga Laboratoire Sur l’Energie Solaire /Groupe Phénomènes de Transfert et Energétique, Université de Lomé, 01 Lomé BP 1515, Togo, and Regional Centre of Excellence on Electricity Management (CERME), University of Lomé, Togo
  • Yemboate Doubik Laré Laboratoire Sur l’Energie Solaire /Groupe Phénomènes de Transfert et Energétique, Université de Lomé, 01 Lomé BP 1515, Togo
  • Kodjo Kpodé Laboratoire de Matériaux, Energie Renouvelable et Environnement de l’Université de Kara, Togo

The operation of building-integrated photovoltaic (BIPV) systems gives rise to a significant proportion of the solar radiation absorbed by the cells being unable to be converted into electricity. This phenomenon consequently increases the temperature. This temperature increase impacts the cells' electrical efficiency, leading to a reduction in their performance and accelerating their degradation. The combination of phase-change materials with insulating fluid blades, situated behind photovoltaic cells, represents a passive cooling solution that optimizes the performance of hybrid photovoltaic systems when incorporated into facades. The present study assesses a system that incorporates paraffin as a PCM and an argon layer in a PV-PCM-argon layer physical model (PVT/ArPCM), in comparison with a PV-PCM system (PVT/PCM), to enhance the thermoelectric performance of photovoltaic systems mounted on façades while ensuring optimal thermal comfort within buildings. The discrete heat transfer equations were solved using the Thomas algorithm and the iterative Gauss-Seidel method in conjunction with the implicit finite difference method. The findings illustrate that the electrical efficiency experienced only a slight increase, estimated at 0.01%, while there was a notable enhancement in the indoor thermal comfort experienced by occupants, with a 65% improvement observed due to the incorporation of an argon-filled thermal screen. The incorporation of an argon layer led to a minor reduction in temperature of 0.01°C in the photovoltaic cells, resulting in a minimal improvement of 0.014% in electrical power production. The phase-changing material incorporated into PVT/ArPCM demonstrated superior thermal management capabilities in comparison to the same material employed in PVT/PCM.

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How to Cite

Toka, K. A. ., Nougbléga, Y. ., Laré, Y. D. ., & Kpodé, K. . (2024). Optimization of coupling phase-change materials and thermal screens in façade-integrated hybrid photovoltaic collectors for optimal energy production and thermal comfort in buildings. Edelweiss Applied Science and Technology, 8(6), 2789–2808. https://doi.org/10.55214/25768484.v8i6.2558
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Issue

Vol. 8 No. 6 (2024)

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Articles

Published

2024-10-25

Keywords

Argon layer, Heat transfer, Numerical study, Phase change materials, Photovoltaic coating.
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