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Thermal performance enhancement of a novel receiver for parabolic trough solar collector

The parabolic trough solar collector stands out as the most advanced method for harnessing concentrating solar power. However, its efficiency is significantly affected by the circumferential temperature gradient brought on by uneven heat flux distribution around the receiver. This leads to thermal s...

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Published in:	Hyperfine interactions 2024-12, Vol.246 (1)
Main Authors:	Byiringiro, Justin, Chaanaoui, Meriem, Hammouti, Belkheir
Format:	Article
Language:	English
Subjects:	Atomic Computational fluid dynamics Condensed Matter Physics Configuration management Fins Fluid flow Hadrons Heat flux Heat transfer Heavy Ions Mirrors Molecular Nuclear Physics Optical and Plasma Physics Performance enhancement Performance evaluation Physics Physics and Astronomy Solar collectors Surfaces and Interfaces System effectiveness Thermal stress Thin Films
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container_title	Hyperfine interactions
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creator	Byiringiro, Justin Chaanaoui, Meriem Hammouti, Belkheir
description	The parabolic trough solar collector stands out as the most advanced method for harnessing concentrating solar power. However, its efficiency is significantly affected by the circumferential temperature gradient brought on by uneven heat flux distribution around the receiver. This leads to thermal stress and potential deformation of the receiver. To address this issue, this study presents an innovative parabolic trough solar receiver design featuring fins and a rod insert to enhance the system’s thermal performance. Computational fluid dynamics simulations were performed in ANSYS Fluent to evaluate different inlet velocities, with Therminol VP-1 as the heat transfer fluid. The model’s accuracy was confirmed through validation against experimental data and established theoretical correlations from the literature. The results indicated that the proposed configuration substantially enhances heat transfer performance compared to the conventional receiver. The Nusselt number increased by 49.7%, while the circumferential temperature gradient was reduced by 41.2%. These improvements demonstrate the effectiveness of the novel receiver in enhancing fluid mixing and heat transfer, which significantly lowers temperature gradients and mitigates thermal stresses, ultimately improving the durability and performance of parabolic trough solar collector systems.
doi_str_mv	10.1007/s10751-024-02230-3
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However, its efficiency is significantly affected by the circumferential temperature gradient brought on by uneven heat flux distribution around the receiver. This leads to thermal stress and potential deformation of the receiver. To address this issue, this study presents an innovative parabolic trough solar receiver design featuring fins and a rod insert to enhance the system’s thermal performance. Computational fluid dynamics simulations were performed in ANSYS Fluent to evaluate different inlet velocities, with Therminol VP-1 as the heat transfer fluid. The model’s accuracy was confirmed through validation against experimental data and established theoretical correlations from the literature. The results indicated that the proposed configuration substantially enhances heat transfer performance compared to the conventional receiver. The Nusselt number increased by 49.7%, while the circumferential temperature gradient was reduced by 41.2%. 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subjects	Atomic Computational fluid dynamics Condensed Matter Physics Configuration management Fins Fluid flow Hadrons Heat flux Heat transfer Heavy Ions Mirrors Molecular Nuclear Physics Optical and Plasma Physics Performance enhancement Performance evaluation Physics Physics and Astronomy Solar collectors Surfaces and Interfaces System effectiveness Thermal stress Thin Films
title	Thermal performance enhancement of a novel receiver for parabolic trough solar collector
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