Entropy Generation and Optimization of Laminar Forced Convection Air Cooling in a Horizontal Channel Containing Heated Sources

A forced convection air-cooling of two identical heat sources mounted in a horizontal channel is numerically studied. Four effects of Reynolds number, separation distance, height and width of the components on the flow structure and heat transfer inside the channel have been examined. The entropy ge...

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Bibliographic Details
Published in:Journal of Applied Fluid Mechanics 2017-05, Vol.10 (3), p.819-831
Main Authors: Bensouici, M., Bensouici, F. Z.
Format: Article
Language:English
Subjects:
Aerodynamics
Air cooling
Algorithms
Computational fluid dynamics
Convection
Convection cooling
Cooling
Energy
Energy equation
Entropy
Finite volume method
Fluid flow
Forced convection
Heat sources
Heat transfer
Numerical simulation
Forced convection
Electronic component cooling
Entropy generation analysis
Optimization procedure
Nusselt number
Optimization
Parameters
Reynolds number
Separation
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Summary:A forced convection air-cooling of two identical heat sources mounted in a horizontal channel is numerically studied. Four effects of Reynolds number, separation distance, height and width of the components on the flow structure and heat transfer inside the channel have been examined. The entropy generation minimization method (EGM) is employed to optimize the heat transfer and fluid flow in the channel. The flow field is governed by the Navier–Stokes equation and the thermal field by the energy equation. The finite volume method and the SIMPLER algorithm are used to solve the continuity, momentum, energy and entropy generation equations. Results show that the mean Nusselt number increases with increase of the following parameters: Reynolds number, separation distance, height and width of the components. However, these parameters increase the total entropy generation, and thus provokes the degradation of the fan energy. The optimal values of separation distance, height and width heat source are: [(Sopt= 1 with W=0.25, C=0.25, Re=50, η=1.134), (Copt=0.3 with W=0.25, S=0.25, Re=100, η=0.895) and (Wopt= 0.1 S=0.25, C=0.25, Re=200, η=1.004)], respectively, where η is the optimization factor (=Num/S_T^*) and is defined as the ratio of Nusselt number to the total entropy generation. Finally, the optimal and the best configuration for maximum heat transfer and minimum entropy generation is observed at Re=50, S=1, C=0.25 and W=0.25.
ISSN:1735-3572
1735-3645
DOI:10.18869/acadpub.jafm.73.240.26847