Optimal hydrothermal design of microchannel heat sink using trapezoidal cavities and solid/slotted oval pins

•MCHS having trapezoidal cavities is numerically investigated.•An oval pin with and without slot is inserted for enhancing the thermal design.•The pin position, pin AR, and pin slot thickness are analyzed and optimized.•The optimal hydrothermal design is obtained by varying the above parameters.•The...

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Bibliographic Details
Published inApplied thermal engineering Vol. 158; p. 113765
Main Authors Alfellag, Mohanad A., Ahmed, Hamdi E., Fadhil, Obaid T., Sh. Kherbeet, Akeel
Format Journal Article
LanguageEnglish
Published Oxford Elsevier Ltd 25.07.2019
Elsevier BV
Subjects
Algorithms
Aspect ratio
Computational fluid dynamics
Finite volume method
Flow characteristics
Fluid flow
Friction factor
Heat transfer
Holes
Hydrothermal design enhancement
Microchannel heat sink
Microchannels
Oval pin
Parameter estimation
Plate-fin heat exchangers
Reynolds number
Slot
Thickness
Trapezoidal cavity
Slot
Oval pin
Microchannel heat sink
Hydrothermal design enhancement
Trapezoidal cavity
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Summary:•MCHS having trapezoidal cavities is numerically investigated.•An oval pin with and without slot is inserted for enhancing the thermal design.•The pin position, pin AR, and pin slot thickness are analyzed and optimized.•The optimal hydrothermal design is obtained by varying the above parameters.•The max JF recorded is 1.3 at a specified pin position, AR, and slot thickness. A new design of plate-fin microchannel heat sink (MCHS) with trapezoidal cavities and oval pins with and without slots is proposed. Heat transfer and fluid flow characteristics are numerically studied and analyzed for Reynolds number ranging from 100 to 1200. Three geometric parameters have been considered in this study including; the aspect ratio of the oval pins, pin position from cavity center toward the inlet, and lastly thickness of the two inclined slots of the pins. The finite volume method (FVM) is adopted for solving the governing equations, and the SIMPLE algorithm is utilized for the computations. The overall performance of the present design is evaluated based on friction factor, Nusselt number and hydrothermal performance factor (PEC). The results indicate that the optimal design of the proposed design is at a pin aspect ratio of (AR = 1.25), pin distance from cavity center of (x = 0.03 mm) and slot thickness of (t = 0.008 mm) which gives a maximum PEC of 1.37.
ISSN:1359-4311
1873-5606
DOI:10.1016/j.applthermaleng.2019.113765