Investigation of solar Photovoltaic cell utilizing hybrid nanofluid confined jet and helical fins for improving electrical efficiency in existence of thermoelectric module

Sheikholeslami, M.; Khalili, Z.

doi:10.1016/j.applthermaleng.2023.121329

Cited by 34 publications

(1 citation statement)

References 36 publications

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“…The results show that the spectral splitting CPV/T system based on ethylene glycol-ZnO nanofluid has the best performance. [45] Conducting an in-depth study, Sheikholeslami et al [49][50][51][52] investigated the impact of nanofluid flow under various geometries on the system performance to lower the temperature of silicon cells in a solar PV device. Initially, the study investigated two cooling system geometries, one without and the other with heat sinks.…”

Section: Nanofluid Coolingmentioning

confidence: 99%

Research Progress of Photovoltaic Cooling Systems Based on Phase Change Materials: An Overview

Liu,

Zhang,

Hua

et al. 2024

Energy Tech

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Photovoltaic technology plays a crucial role in harnessing renewable energy. While photovoltaic panels directly convert solar energy into electricity, more than 50% of solar radiation is lost as waste heat, diminishing the overall efficiency of the panels. This study reviews various cooling technologies for photovoltaic systems, focusing on the use of phase change materials for cooling in photovoltaic systems. Phase change materials, known for their high latent heat capacity, are extensively used in thermal energy storage applications. Incorporating phase change materials in photovoltaic systems can increase thermal storage potential by 30–50% compared to conventional systems, leading to a 70% extension in heat storage duration and various levels of enhanced power output. The main purpose of the article is to review the advantages and disadvantages of various technologies, determine the research direction of phase change materials for cooling systems in photovoltaics, and ensure the reliability of this technology.

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Section: Nanofluid Coolingmentioning

confidence: 99%

Research Progress of Photovoltaic Cooling Systems Based on Phase Change Materials: An Overview

Liu,

Zhang,

Hua

et al. 2024

Energy Tech

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Paradigm on Levenberg–Marquardt neural algorithm analysis of heat conduction optimization for ternary hybrid nanofluid with entropy generation

Qureshi,

Shah,

Raja

et al. 2024

Z Angew Math Mech

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The significance of the present article is to enhance the thermal management and energy efficiency of complex engineering infrastructures such as energy storage systems, modern electric vehicles, thermal insulations, heavy‐duty machinery, and production units. This research aims to understand the intricate relationship between the thermal conductivity performance of ternary () hybrid nanomaterial and entropy generation to optimize material design and efficacy. A synergetic combination of three distinct nanomaterials silicon dioxide, ferric oxide, and titanium oxide with ethylene glycol and water in the ratio 3:2 as a base solvent is comprised of contributing unique thermophysical properties. To elucidate the impact of this hybrid composition on thermal conductivity, various factors are analyzed. The advanced computational technique of Artificial intelligent feed‐forward neural network (AIFFNN) is utilized. The problem governed the system of PDEs, which is transformed into ODEs by dimensionless similarity. Adams method provided the dataset which is filtered and embedded into Marquardt–Levenberg Algorithm (LMA). The study examines the role of nanomaterial constituents, morphology, and boundary conditions on thermal performance and entropy generation. Graphical analysis of velocity, temperature, and entropy is provided with respect to varying parameters, including surface absorption (λ), magnetic strength (Tesla M), radiation parameter (Rd), Brownian motion (Br), and Eckert number (Ec). The findings have practical significance for optimizing material design in engineering and industrial applications.

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Significance of coupled effects of resistive heating and perpendicular magnetic field on heat transfer process of mixed convective flow of ternary nanofluid

Adnan,

Abbas,

Said

et al. 2023

J Therm Anal Calorim

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Investigation of solar Photovoltaic cell utilizing hybrid nanofluid confined jet and helical fins for improving electrical efficiency in existence of thermoelectric module

Cited by 34 publications

References 36 publications

Research Progress of Photovoltaic Cooling Systems Based on Phase Change Materials: An Overview

Research Progress of Photovoltaic Cooling Systems Based on Phase Change Materials: An Overview

Paradigm on Levenberg–Marquardt neural algorithm analysis of heat conduction optimization for ternary hybrid nanofluid with entropy generation

Significance of coupled effects of resistive heating and perpendicular magnetic field on heat transfer process of mixed convective flow of ternary nanofluid

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