Design of novel geometries for minichannels to reduce junction temperature of heat sinks and enhance temperature uniformity

[Display omitted] •Numerical study is done to reduce temperature non-uniformity problem in heat sinks.•Novel combined minichannels are proposed and tested at a heat flux of 50 kW/m2.•Noticeable effects are detected on ΔTmax,b and Rt.•Maximum decrease of 11.5 K is found in ΔTmax,b with η = 1.53 at Re...

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Bibliographic Details
Published inApplied thermal engineering Vol. 192; p. 116926
Main Authors Khoshvaght-Aliabadi, M., Feizabadi, A., Nouri, M.
Format Journal Article
LanguageEnglish
Published Oxford Elsevier Ltd 25.06.2021
Elsevier BV
Subjects
Complex minichannels
Electronic systems
Fluid flow
Heat sink
Heat sinks
Heat transfer
Mathematical models
Nonuniformity
Numerical analysis
Performance indices
Plumbing fixtures
Reynolds number
Temperature
Temperature gradients
Temperature uniformity enhancement
Thermal resistance
Temperature uniformity enhancement
Numerical analysis
Heat sink
Complex minichannels
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Summary:[Display omitted] •Numerical study is done to reduce temperature non-uniformity problem in heat sinks.•Novel combined minichannels are proposed and tested at a heat flux of 50 kW/m2.•Noticeable effects are detected on ΔTmax,b and Rt.•Maximum decrease of 11.5 K is found in ΔTmax,b with η = 1.53 at Re = 900. Generally, various micro/minichannels are utilized to fabricate water-cooled heat sinks, but most of them have straight and simple geometries. To some extent, the heat sinks designed based on these geometries can dissipate the heat produced by electronic systems. However, there is still the temperature non-uniformity problem in heat sinks due to the limitation of pumping power (Pp). In this article, several novel minichannels are designed to reduce the junction temperature of heat sinks and enhance the temperature uniformity. In these models, both the upstream and the downstream represent wavy structure with the same wave-amplitude but variable wave-lengths. To this end, 3D numerical simulations are carried out along with an experimental validation study. The coolant is water at the entrance temperature of 293 K and Reynolds number (Re) range between 100 and 900. The results show that the proposed minichannels have appreciable positive impacts on the thermal performance of heat sink, such that the maximum base temperature difference (ΔTmax,b) experiences a maximum decrease of 11.5 K, which results in a 2.35 times reduction in the total thermal resistance (Rt). It is also found that despite a conflict between reducing Rt and lowering Pp, the novel minichannels show superior values of performance index (η) particularly at higher Re. Under the range of conditions studied, the maximum value of 1.53 is recorded for η at Re = 900.
ISSN:1359-4311
1873-5606
DOI:10.1016/j.applthermaleng.2021.116926