ABSTRACT
In the first part of present study, an experimental setup with constant heat flux is used to investigate the thermal performance of the water inside a horizontal triangular pin fin channel. For the sake of validation of the computational fluid dynamics (CFD) study, a simulation is conducted according to the geometry and operating conditions of the experimental work. The numerical model consists of a study that has been established based on the geometrical parameters and operating conditions similar to the experimental work. The influence of four different cross sections of minifins (shaped as square, trapezoidal, triangular, and sinusoidal) and of number of triangular minifins (1, 3, 5, 7, and 9) and their positions (in the regions of entrance, central, and terminal) on the heat transfer rate and pressure drop in a minifin minichannel heat sink are numerically investigated by a two-dimensional CFD model. The coolant is Cu–water nanofluid at a volumetric concentration of 2%. The results demonstrated that the sinusoidal minifin minichannel heat sink has the highest convective heat transfer coefficient in comparison with other shapes, while the trapezoidal minifin minichannel showed the highest thermal resistance. The highest pressure drop was observed for the triangular minifin inside minichannel. By increasing the number of fins, thermal resistance considerably decreased. Likewise, at the central and entrance positions, respectively, the highest Nusselt number and friction factor inside the minichannel was observed. This study can provide useful guidelines for the design of the cooling devices.
Additional information
Notes on contributors
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Elham Hosseinirad
Elham Hosseinirad is a Ph.D. student in chemical engineering at Semnan University, Iran. Her areas of interest include the CFD simulation and experimental study of thermal-hydraulic performance, nanofluids, compact and mini heat exchangers, tortuous minichannels, fins, optimization, and heat transfer and friction factor correlations for different minichannel and minifin geometry. She teaches the heat transfer, fluid mechanics, and design of heat exchangers courses.
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Faramarz Hormozi
Faramarz Hormozi is an associate professor of chemical engineering at Semnan University, Iran. He has conducted many research studies, mainly in heat transfer, CFD, coiled areas, extended surface, microchannels, and nanofluids. He has also published several books about heat transfer and characteristics of microchannels. His research interests are nanofluids, heat transfer, and computational fluiddynamics.