Sustainable Energy Progress via Integration of Thermal Energy Storage and Other Performance Enhancement Strategies in FPCs: A Synergistic Review

Flat plate collectors (FPCs) are the leading solar thermal technology for low-medium range temperature applications. However, their expansion in developing countries is still lacking because of their poor thermal performance. Improving the thermal performance of flat plate collectors (FPCs) is a cru...

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Veröffentlicht in:	Sustainability 2023-09, Vol.15 (18), p.13749
Hauptverfasser:	Pathak, Sudhir Kumar, Tazmeen, Tagamud, Chopra, K, Tyagi, V. V, Anand, Sanjeev, Abdulateef, Ammar M, Pandey, A. K
Format:	Artikel
Sprache:	eng
Schlagworte:	Alternative energy sources Drinking water Efficiency Energy industry Energy storage Fossil fuels Friction Green technology Heat conductivity Heat storage Heat transfer Heaters Payback periods Renewable resources Research methodology Solar energy Sustainability Thermal energy Water heaters
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creator	Pathak, Sudhir Kumar Tazmeen, Tagamud Chopra, K Tyagi, V. V Anand, Sanjeev Abdulateef, Ammar M Pandey, A. K
description	Flat plate collectors (FPCs) are the leading solar thermal technology for low-medium range temperature applications. However, their expansion in developing countries is still lacking because of their poor thermal performance. Improving the thermal performance of flat plate collectors (FPCs) is a crucial concern addressed in this review This study comprehensively discussed the performance improvement methods of FPCs, such as design modification, reflectors, working fluid, and energy storage materials, by covering current issues and future recommendations. Design factors such as coating and glass cover thickness, thickness of absorber plate and material, air gap between the glass cover and absorber plate, and riser spacing, along with insulation materials, are examined for their impact on FPC performance. Absorber design changes with selective coatings for improving the heat transmission rate between the working fluid and absorber are critical for enhancing collectors’ thermal output. The nanofluids utilization improved FPC’s thermal performance in terms of energetic and exergetic outcomes in the 20–30% range. Moreover, adding a heat storage unit extends the operating hours and thermal output fluctuations of FPCs. Research suggests that employing turbulators and nanofluids as heat transfer fluids are particularly effective for enhancing heat transfer in FPCs. This comprehensive review serves as a critical tool for evaluating and comparing various heat transfer augmentation techniques, aiding in the selection of the most suitable option.
doi_str_mv	10.3390/su151813749
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subjects	Alternative energy sources Drinking water Efficiency Energy industry Energy storage Fossil fuels Friction Green technology Heat conductivity Heat storage Heat transfer Heaters Payback periods Renewable resources Research methodology Solar energy Sustainability Thermal energy Water heaters
title	Sustainable Energy Progress via Integration of Thermal Energy Storage and Other Performance Enhancement Strategies in FPCs: A Synergistic Review
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