Performance investigation of radial heat sink with pin fins placed normally on circular base edge

This paper presents the effects of heat dissipation performance of pin fins with different heat sink structures. The heat dissipation performance of two types of pin fin arrays heat sink are compared through measuring their heat resistance and the average Nusselt number in different cooling water flow. The temperature of cpu chip is monitored to determine the temperature is in the normal range of working temperature. The cooling water flow is in the range of 0.02L/s to 0.15L/s. It’s found that the increase of pin fins in the corner region effectively reduce the temperature of heat sink and cpu chip. The new type of pin fin arrays increase convection heat transfer coefficient and reduce heat resistance of heat sink.

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Improved Design of Heat Sink Including Porous Pin Fins with Different Arrangements: A Numerical Turbulent Flow and Heat Transfer Study

Applied Thermal Engineering ◽

10.1016/j.applthermaleng.2021.117519 ◽

2021 ◽

pp. 117519

Author(s):

Ali Mohammad Ranjbar ◽

Zeinab Pouransari ◽

Majid Siavashi

Keyword(s):

Heat Transfer ◽

Turbulent Flow ◽

Heat Sink ◽

Flow And Heat Transfer ◽

Pin Fins ◽

Improved Design ◽

Transfer Study

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Hydoroil-Based Micro Pin Fin Heat Sink

Microelectromechanical Systems ◽

10.1115/imece2006-13257 ◽

2006 ◽

Cited By ~ 8

Author(s):

Ali Kosar ◽

Chih-Jung Kuo ◽

Yoav Peles

Keyword(s):

Heat Sink ◽

Hydraulic Performance ◽

Heat Fluxes ◽

Heat Sinks ◽

Transfer Coefficients ◽

Pin Fin ◽

Nusselt Numbers ◽

Friction Factors ◽

Pin Fins ◽

Micro Pin Fins

An experimental study on thermal-hydraulic performance of de-ionized water over a bank of shrouded NACA 66-021 hydrofoil micro pin fins with wetted perimeter of 1030-μm and chord thickness of 100 μm has been performed. Average heat transfer coefficients have been obtained over effective heat fluxes ranging from 4.0 to 308 W/cm2 and mass velocities from 134 to 6600 kg/m2s. The experimental data is reduced to the Nusselt numbers, Reynolds numbers, total thermal resistances, and friction factors in order to determine the thermal-hydraulic performance of the heat sink. It has been found that prodigious hydrodynamic improvement can be obtained with the hydrofoil-based micro pin fin heat sink compared to the circular pin fin device. Fluid flow over pin fin heat sinks comprised from hydrofoils yielded radically lower thermal resistances than circular pin fins for a similar pressure drop.

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Experimental and numerical investigation of traveling wave tube radial heat sink connector thermal stress and deformation with a focus on energy cost management

International Communications in Heat and Mass Transfer ◽

10.1016/j.icheatmasstransfer.2021.105770 ◽

2022 ◽

Vol 131 ◽

pp. 105770

Author(s):

Alireza Moradikazerouni

Keyword(s):

Thermal Stress ◽

Numerical Investigation ◽

Traveling Wave ◽

Heat Sink ◽

Energy Cost ◽

Cost Management ◽

Traveling Wave Tube ◽

Wave Tube ◽

Radial Heat ◽

Stress And Deformation

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Optimum Fin Parameters of Radial Heat Sinks Subjected to Natural Convection

Journal of Thermal Science and Engineering Applications ◽

10.1115/1.4043091 ◽

2019 ◽

Vol 11 (5) ◽

Cited By ~ 2

Author(s):

S. Manna ◽

S. K. Ghosh ◽

S. C. Haldar

Keyword(s):

Heat Transfer ◽

Heat Sink ◽

Heat Sinks ◽

Computational Domain ◽

Active Length ◽

Vorticity Vector ◽

Radial Heat ◽

In The Beginning ◽

Opposing Effects ◽

Fin Thickness

Free convection from an upward facing radial heat sink with fins at an equal angular gap attached to an isothermal base has been investigated numerically. The governing equations in primitive variables were changed to vorticity-vector potential formulation, and an in-house code was developed using finite difference technique. To close the computational domain, two pseudo boundaries were considered. Length, height, and number of fins strongly influence the rate of heat transfer while the fin thickness has a marginal role. As the fin length increases, the rate of heat transfer first increases and then remains almost unaffected. However, the active length of the fins depends on the strength of buoyancy. Heat transfer continuously increases with fin height but with diminishing effect. Adding more number of fins has two opposing effects. It provides more surface area for convection, but at the same time, the induced air is unable to reach the interior of the heat sink making the inner portion of the fins inoperative. As a result of these two opposing influences, heat transfer increases in the beginning and then decreases as more fins are added. This article suggests various fin parameters to achieve maximum cooling. In addition, one can estimate the rate of cooling to be achieved by any radial heat sink.

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