Effect of cylinder geometry on the heat transfer enhancement of power-law fluid flow inside a channel

Sadeghi, Hosein; Izadpanah, Ehsan; Rabiee, Marzie Babaie; Hekmat, Mohamad Hamed

doi:10.1007/s40430-016-0695-3

Cited by 10 publications

(2 citation statements)

References 23 publications

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“…For complement, the fluid rheology property is also taken into account. Among the non-Newtonian fluid, the power-law fluid is a kind of typical fluid because its rheological property such as shear-shinning and shear-thickening has an effect on free convection [17], natural convection [18], and heat transfer enhancement [19]. Therefore, the purpose of this paper is to study the hydrodynamic coefficient, gap flow characteristics, and recirculation mode for the steady flow of power-law fluid with different power-law indices over a circular cylinder near a moving wall for different gap ratios and explain the formation mechanism by investigating the vortex characteristics in the wake behind the cylinder.…”

Section: Introductionmentioning

confidence: 99%

Flow of power-law fluid past a circular cylinder in the vicinity of a moving wall

Zhang

Lin

2019

J Braz. Soc. Mech. Sci. Eng.

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In this paper, the flow of power-law fluid over a circular cylinder near a moving wall is simulated numerically using a finite volume method for different Reynolds numbers (Re = 1, 10, 40), gap ratios (G/D = 0.2-1.0), and power-law indices (n = 0.5-1.5). The effects of fluid inertia, wall proximity, and rheological property on the drag and lift coefficient, gap flow characteristics, and recirculation modes are studied. Possible mechanisms for the variation of the drag and lift coefficient and the change in recirculation mode are addressed. The results show that the decrease in G/D or Re results in the increase in drag and lift coefficient, while the effect of n is dependent on Re and G/D. For the drag coefficient, shear-thickening fluid is more sensitive to the change of G/D. The variation of the lift coefficient can be explained by the movement of angular position of the front stagnation point. The redistribution of the flow around the cylinder results in different recirculation modes. Five distinct modes are found and the critical value of G/D for the mode change decreases with the decrease in n and increase in Re. Variation of the relative vortex intensity and the relative flow intensity nearby leads to the change of recirculation mode.

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Section: Introductionmentioning

confidence: 99%

Flow of power-law fluid past a circular cylinder in the vicinity of a moving wall

Zhang

Lin

2019

J Braz. Soc. Mech. Sci. Eng.

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“…A vast amount of numerical and experimental research in the last decade has been performed, with utilizing wavy walls or corrugations as a passive method to increase heat transfer in many engineering applications, particularly those employing compact heat exchangers. As a matter of fact, corrugated channels such as sinusoidal, triangular and trapezoidal prevent the development of flow by disturbing the flow field and boundary layer and improve the mixing of higher and lower temperature parts which enhance the heat transfer [1][2][3][4]. Many researchers studied the effect of sinusoidal wavy wall on heat transfer of conventional fluid, some of which will be described here.…”

Section: Introductionmentioning

confidence: 99%

Thermal performance optimization of a sinusoidal wavy channel with different phase shifts using artificial bee colony algorithm

Ramiar

Manavi

Yousefi-Lafouraki

et al. 2018

J Braz. Soc. Mech. Sci. Eng.

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In this article, heat transfer optimization of forced convection in a wavy channel with different phase shifts between the upper and lower wavy walls is represented. The flow is laminar in the range of (200 B Re B 800) and a uniform temperature of 350 K is considered in the wavy sections. The governing mass, momentum and energy equations are solved using the finite volume method. Different design parameters such as the channel height (h = 10, 15 and 20 mm), the amplitude of the wavy wall (A = 1.5, 2, 2.5 and 3 mm) and the phase shift of the upper wavy wall ð0 c 360 Þ are investigated. For optimization process, a recent method, named artificial bee colony (ABC) algorithm, is applied and compared with two other meta-heuristic algorithms, called particle swarm optimization (PSO) and differential evolution (DE). An ''in house'' code is developed which simultaneously uses the meta-heuristic algorithms and the computational fluid dynamics solver. The results indicate that ABC algorithm has higher accuracy and faster convergence rate than PSO and DE. The parameter considered for optimizing the average Nusselt number as the objective function was the phase shift. But, for optimizing the thermal performance factor, selected parameters were the wavy wall amplitude and the phase shift. The results showed that the maximum average Nusselt number is attained at c ¼ 250:2, A = 3 mm, h = 10 mm and Re = 800, in which the heat transfer rate has 96.6% enhancement rather than the parallel-plate channel. Also, it is found that c ¼ 283:3, A = 2.65 mm, h = 10 mm and Re = 800 are the optimized solutions to obtain the maximum thermal performance factor.

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Study of forced convection turbulent flow over a heated microprocessor chip

Sanga,

Oraon,

Datta

2023

J Anal

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Effect of cylinder geometry on the heat transfer enhancement of power-law fluid flow inside a channel

Cited by 10 publications

References 23 publications

Flow of power-law fluid past a circular cylinder in the vicinity of a moving wall

Flow of power-law fluid past a circular cylinder in the vicinity of a moving wall

Thermal performance optimization of a sinusoidal wavy channel with different phase shifts using artificial bee colony algorithm

Study of forced convection turbulent flow over a heated microprocessor chip

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