Conjugate heat transfer analysis of floating photovoltaic panels with hybrid natural convection cooling loops and solar filter

Bayu Sutanto; Hector Iacovides; Adel Nasser; Andrea Cioncolini; Imran Afgan

Conjugate heat transfer analysis of floating photovoltaic panels with hybrid natural convection cooling loops and solar filter

Bayu Sutanto, Hector Iacovides, Adel Nasser, Andrea Cioncolini, Imran Afgan

Research output: Contribution to conference › Paper › peer-review

Abstract

Floating photovoltaic panels have several advantages such as using the open water surface instead of large land areas. Exploiting the water body as a heat sink to cool the panels offers an additional advantage, leading to increased efficiency. This study focuses on the development of a numerical model for a hybrid system that combines a natural convection cooling loop with a solar filter feature. This added feature decreases the temperature of photovoltaic cells and optimises the spectral distribution of the incoming solar radiation. A conjugate heat transfer analysis shows that the cooling system is highly effective in dissipating heat and maximising the electrical output of floating photovoltaic panels. The study also optimises the thickness of the cooling channel to assess the effectiveness of nanofluids.

Original language	English
Pages	33
Number of pages	3
Publication status	Published - 9 Sept 2024
Event	the 18th UK National Heat Transfer Conference - University of Birmingham, Birmingham, United Kingdom Duration: 9 Sept 2024 → 11 Sept 2024 Conference number: 18 https://more.bham.ac.uk/ukhtc-2024/

Conference

Conference	the 18th UK National Heat Transfer Conference
Abbreviated title	UKHT
Country/Territory	United Kingdom
City	Birmingham
Period	9/09/24 → 11/09/24
Internet address	https://more.bham.ac.uk/ukhtc-2024/

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This output contributes to the following UN Sustainable Development Goals (SDGs)

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https://www.researchgate.net/publication/390831680_Conjugate_heat_transfer_analysis_of_floating_photovoltaic_panels_with_hybrid_natural_convection_cooling_loops_and_solar_filter

Fluids Research Group
Iacovides, H. (Researcher), Beneitez Galan, M. (Researcher), Giustini, G. (Researcher), De Rosis, A. (Researcher), Harish, A. (Researcher), Mahmoudi Larimi, Y. (Researcher), Keshmiri, A. (Researcher), King, J. (Researcher), Laurence, D. (Researcher), Manchester, E. (Researcher), Mihajlovic, M. (Researcher), Nasser, A. (Researcher), Prosser, R. (Researcher), Revell, A. (Researcher), Rezaeiravesh, S. (Researcher), Skillen, A. (Researcher), Tang, T. (Researcher), Wilson, D. (Researcher) & Craft, T. (PI)
20/05/25 → …
Project: Research

Cite this

Sutanto, B., Iacovides, H., Nasser, A., Cioncolini, A., & Afgan, I. (2024). Conjugate heat transfer analysis of floating photovoltaic panels with hybrid natural convection cooling loops and solar filter. 33. Paper presented at the 18th UK National Heat Transfer Conference, Birmingham, United Kingdom. https://www.researchgate.net/publication/390831680_Conjugate_heat_transfer_analysis_of_floating_photovoltaic_panels_with_hybrid_natural_convection_cooling_loops_and_solar_filter

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title = "Conjugate heat transfer analysis of floating photovoltaic panels with hybrid natural convection cooling loops and solar filter",

abstract = "Floating photovoltaic panels have several advantages such as using the open water surface instead of large land areas. Exploiting the water body as a heat sink to cool the panels offers an additional advantage, leading to increased efficiency. This study focuses on the development of a numerical model for a hybrid system that combines a natural convection cooling loop with a solar filter feature. This added feature decreases the temperature of photovoltaic cells and optimises the spectral distribution of the incoming solar radiation. A conjugate heat transfer analysis shows that the cooling system is highly effective in dissipating heat and maximising the electrical output of floating photovoltaic panels. The study also optimises the thickness of the cooling channel to assess the effectiveness of nanofluids.",

author = "Bayu Sutanto and Hector Iacovides and Adel Nasser and Andrea Cioncolini and Imran Afgan",

year = "2024",

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language = "English",

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Sutanto, B , Iacovides, H , Nasser, A, Cioncolini, A & Afgan, I 2024, 'Conjugate heat transfer analysis of floating photovoltaic panels with hybrid natural convection cooling loops and solar filter', Paper presented at the 18th UK National Heat Transfer Conference, Birmingham, United Kingdom, 9/09/24 - 11/09/24 pp. 33. <https://www.researchgate.net/publication/390831680_Conjugate_heat_transfer_analysis_of_floating_photovoltaic_panels_with_hybrid_natural_convection_cooling_loops_and_solar_filter>

TY - CONF

T1 - Conjugate heat transfer analysis of floating photovoltaic panels with hybrid natural convection cooling loops and solar filter

AU - Sutanto, Bayu

AU - Iacovides, Hector

AU - Nasser, Adel

AU - Cioncolini, Andrea

AU - Afgan, Imran

N1 - Conference code: 18

PY - 2024/9/9

Y1 - 2024/9/9

N2 - Floating photovoltaic panels have several advantages such as using the open water surface instead of large land areas. Exploiting the water body as a heat sink to cool the panels offers an additional advantage, leading to increased efficiency. This study focuses on the development of a numerical model for a hybrid system that combines a natural convection cooling loop with a solar filter feature. This added feature decreases the temperature of photovoltaic cells and optimises the spectral distribution of the incoming solar radiation. A conjugate heat transfer analysis shows that the cooling system is highly effective in dissipating heat and maximising the electrical output of floating photovoltaic panels. The study also optimises the thickness of the cooling channel to assess the effectiveness of nanofluids.

AB - Floating photovoltaic panels have several advantages such as using the open water surface instead of large land areas. Exploiting the water body as a heat sink to cool the panels offers an additional advantage, leading to increased efficiency. This study focuses on the development of a numerical model for a hybrid system that combines a natural convection cooling loop with a solar filter feature. This added feature decreases the temperature of photovoltaic cells and optimises the spectral distribution of the incoming solar radiation. A conjugate heat transfer analysis shows that the cooling system is highly effective in dissipating heat and maximising the electrical output of floating photovoltaic panels. The study also optimises the thickness of the cooling channel to assess the effectiveness of nanofluids.

M3 - Paper

SP - 33

T2 - the 18th UK National Heat Transfer Conference

Y2 - 9 September 2024 through 11 September 2024

ER -

Conjugate heat transfer analysis of floating photovoltaic panels with hybrid natural convection cooling loops and solar filter

Abstract

Conference

UN SDGs

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Fluids Research Group

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