Thermal cooling system with Ag/Fe3O4 nanofluids mixture as coolant for electronic devices cooling

Siricharoenpanich, A.; Wiriyasart, Songkran; Srichat, Aphichat; Naphon, Paisarn

doi:10.1016/j.csite.2020.100641

Cited by 42 publications

(10 citation statements)

References 39 publications

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“…With accordance to the literature, there exist two published papers on using antibacterial silver-based NFs in the SSs, up to now [26,36]. In addition, it was proved that the thermal behavior of a silvermagnetite hybrid nanofluid (HNF) is better than that of a sole silverbased NF [37]. The novelty of this work is simultaneous employment of magnetic and antibacterial properties for an HNF (Ag@Fe 3 O 4 / deionized water HNF) at different volume fractions (0.04 and 0.08 VF) as well as integrating a concentrating evacuated tube collector (CETC) using a compound parabolic concentrator with a TCCSS to provide hot basin fluid to enhance the solar system productivity.…”

Section: A Cmentioning

confidence: 64%

Retrofitting a thermoelectric-based solar still integrated with an evacuated tube collector utilizing an antibacterial-magnetic hybrid nanofluid

Sadeghi

Nazari

2021

Desalination

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Section: A Cmentioning

confidence: 64%

Retrofitting a thermoelectric-based solar still integrated with an evacuated tube collector utilizing an antibacterial-magnetic hybrid nanofluid

Sadeghi

Nazari

2021

Desalination

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“…Additionally, magnetic nanoingredients have attracted significant attention for their biomedical importance; among them, ferrous (Fe O ) 3 4 nanoparticles are frequently used as contrast agents in magnetic resonance imaging, drug delivery agents, gene carriers in gene microtechnology, hyperthermia cancer treatments, tissue repair, extraction of heavy metals, nuclear reactors, electronic device cooling, and so on. [64][65][66][67] Hence, this investigation discloses the hydrothermal pattern of radiative natural convective magnetized water-based ferrofluid fluid flow confined in a square chamber. The left-sided vertical wall and one bottom surface of the compartment are nonuniformly and uniformly heated, whereas the remaining right-sided vertical boundary is isothermally cooled at a fixed temperature and the topmost wall is made insulated.…”

Section: Introductionmentioning

confidence: 77%

Finite element analysis on the hydrothermal pattern of radiative natural convective nanofluid flow inside a square enclosure having nonuniform heated walls

Acharya¹

2021

Heat Trans

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The present article enlightens us on the hydrothermal pattern of a steady incompressible laminar natural convective nanofluid flow inside a heated square chamber.The square enclosure is filled with water-based sphericalshaped ferrous (Fe 3 O 4 ) nanoparticles. Magnetic effect and thermal radiation are presumed within the flow. The leftsided vertical wall and one bottom wall of the chamber are nonuniformly and uniformly heated, while the remaining right-sided vertical wall is isothermally cooled at a constant temperature and the upper wall is insulated. A detailed analysis is conducted to exhibit that how nonuniform and uniform heated walls influence flow within the square chamber. The leading dimensional equations are made into a dimensionless form using apposite similarity variables and the Galerkin finite element technique is executed to solve those equations. The grid independence test and a parallel comparison with existing literature are presented to verify the validity of the outcomes. The streamlines, isotherms, temperature, velocities, and average Nusselt number are depicted through several graphs for several parametric values of Rayleigh number, Hartmann number, thermal radiation, and nanoparticle volume fraction. The outcomes showed that increasing nanoparticle concentration and Rayleigh number lead to

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“…The experimental findings showed that the new air heater worked well in Bagdad's climate. For cooling, Siricharoenpanicha et al [38] utilized a combination of Ag and Fe 3 O 4 nanofluids. It was taken into account how the flow rate, shape, and MCHS design would affect thermal dissipation.…”

Section: Introductionmentioning

confidence: 99%

Experimental Investigation of Al2O3 Nanofluid for Thermal Energy Management of Microchannel Heat Sink

Aglawe

Yadav²,

Thool

2022

tjes

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Energy is one of the primary foundations supporting evolutionary changes. Heat transfer is improved by increasing the surface area density and/or changing the base fluid characteristics. Because of its small size and improved heat transfer properties, nanofluid cooled microchannel heat sinks (MCHS) have lately become a popular choice for electronics and thermal applications. The influence of employing nanofluids for cooling a chip was investigated experimentally in this work to evaluate the heat transfer characteristics. The investigations were carried out in order to confirm the influence of nanofluid concentration and wall temperature upon thermal-hydraulic properties of the microchannel heat sink. In present study, Al2O3 water nanofluid was employed, with 0.1, 0.2, 0.3, 0.4, and 0.5% nanoparticle volume fractions, mass flow rate (MFL) 2, 5, and 8 m/s at 25, 30 and 35oC inlet tempreture. The resulting experimental findings was verified from results obtained by other researchers, which showed important correlation. The heat transfer efficacy of electronics cooling systems has been enhanced by the nanofluid technology and the configuration of the rectangular heat sink.

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Thermal cooling system with Ag/Fe3O4 nanofluids mixture as coolant for electronic devices cooling

Cited by 42 publications

References 39 publications

Retrofitting a thermoelectric-based solar still integrated with an evacuated tube collector utilizing an antibacterial-magnetic hybrid nanofluid

Retrofitting a thermoelectric-based solar still integrated with an evacuated tube collector utilizing an antibacterial-magnetic hybrid nanofluid

Finite element analysis on the hydrothermal pattern of radiative natural convective nanofluid flow inside a square enclosure having nonuniform heated walls

Experimental Investigation of Al2O3 Nanofluid for Thermal Energy Management of Microchannel Heat Sink

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