Numerical investigation of heat transfer enhancement in microchannel heat sink with fan cavities using secondary channels and ribs

Subrahmanyam, K Bala; Das, Pritam

doi:10.1177/09544089221127132

Proceedings of the Institution of Mechanical Engineers, Part E:

2022

DOI: 10.1177/09544089221127132

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Numerical investigation of heat transfer enhancement in microchannel heat sink with fan cavities using secondary channels and ribs

K Bala Subrahmanyam

Pritam Das

Abstract: A computational three-dimensional modeling of microchannel heat sink (MCHS) with fan cavity and four different rib configurations along with secondary channels (SCs) has been performed in detail to identify the influence of geometrical parameters on characteristics of heat transfer and provide insight into optimum configuration. The adverse effect of high processing speed and heat flux demands lower operational temperature at the expense of high pumping power in order to increase the lifespan of electronic equ… Show more

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2024

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Cited by 3 publications

References 30 publications

(43 reference statements)

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Effect of cylindrical ribs location in a fan-shaped cavity on thermo-hydraulic performance of a microchannel heatsink

Khan,

Ali,

Alam

2024

J Therm Anal Calorim

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Effect of cylindrical ribs location in a fan-shaped cavity on thermo-hydraulic performance of a microchannel heatsink

Khan,

Ali,

Alam

2024

J Therm Anal Calorim

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Effect of cylindrical ribs arrangement in the cavity region of the microchannel heatsink with a fan-shaped cavity

Ali,

Alam,

Khan

2024

Proceedings of the Institution of Mechanical Engineers, Part E:

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Fan-shaped cavity microchannel heatsink with the combination of ribs is an effective configuration to dissipate large amounts of heat at the expense of lower pressure drop. However, the most effective location of circular ribs within a fan-shaped cavity which enhances the performance of a microchannel heat sink is still unknown. In this work, seven different structural units based on the ribs location in the cavity region such as ribs at the front of the cavities (RFC), at the back (RBC), at the centre (RCC), at the front and back (RFBC), at the left (RLC), at the right (RRC) and at the left and right (RLRC) are analysed for the range of Reynolds number from 100 to 500 and the results are compared with the microchannel with fan-shaped cavity only (MHFC) and plain rectangular microchannel heat sink on the basis of Nusselt number, interface temperature, pressure drop and performance factor. A notable finding of this study is identifying a rib as a disruption leading to the splitting of flow into two streams towards the arcuate region of the cavity and results in the enhanced mixing of the mainstream flow and the trapped fluid in the arcuate region. The maximum Nusselt number is exhibited by the RFBC with an increment of about 19% relative to the conventional centre location of the ribs in the cavity (RCC). At a lower Reynolds number, the Nusselt number of RLRC is lower than RCC and RBC however at Re > 300, the Nusselt number of RLRC is nearly equal to RCC whereas the minimum Nusselt number is associated with RRC and RLC among the microchannels having cavities and ribs. Along with the highest Nusselt number the largest value of pressure drop is also associated with RFBC whereas minimum pressure drop is accompanied by RRC and RLC.

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State of art on the role of using a nanofluid in enhancing heat transfer in microchannels with different geometries

Elfatah,

Abd-Ellatif,

Attia

et al. 2024

J. Eng. Appl. Sci.

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Nanofluids in microchannels present a promising solution for enhancing heat dissipation across various engineering applications. This study provide an in-depth analysis of nanofluid role in improving heat transfer efficiency, focusing on critical factors such as nanoparticle concentration, type, and size. The influence of microchannel geometry—such as sinusoidal, square, and circular designs—and the addition of rib structures were also examined. A noticeable increase in the pressure drop was observed across the spectrum of microchannel investigations beyond a concentration threshold of 1 vol. %. Diverging-converging channels demonstrated potential for enhancing heat transfer with minimal pressure drop and pumping power. Most of the reviewed papers have used water and water-ethylene glycol mixtures (65% and 16%, respectively), along with the prevalent use of Al2O3 nanoparticles (37%), underscoring the need to explore alternative base fluids and nanoparticle combinations to achieve optimal performance. The focus on numerical simulations with 61% and 75% single-phase flow in numerical studies highlights the potential to expand research into multiphase flow phenomena. Furthermore, the limited exploration of nanoparticle shape effects and the reliance on simplistic thermal conductivity models point toward avenues for future investigation and model refinement.

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Numerical investigation of heat transfer enhancement in microchannel heat sink with fan cavities using secondary channels and ribs

Cited by 3 publications

References 30 publications

Effect of cylindrical ribs location in a fan-shaped cavity on thermo-hydraulic performance of a microchannel heatsink

Effect of cylindrical ribs location in a fan-shaped cavity on thermo-hydraulic performance of a microchannel heatsink

Effect of cylindrical ribs arrangement in the cavity region of the microchannel heatsink with a fan-shaped cavity

State of art on the role of using a nanofluid in enhancing heat transfer in microchannels with different geometries

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