Particle migration in nanofluids considering thermophoresis and its effect on convective heat transfer

•Particle migration effect was assessed considering thermophoresis.•Non-uniform concentration was applied in the dispersion model.•An experimental study was conducted to examine the numerical solution accuracy.•Considering thermophoresis yields the greater convective heat transfer coefficient.•At gr...

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Veröffentlicht in:	Thermochimica acta 2013-12, Vol.574, p.47-54
Hauptverfasser:	Bahiraei, Mehdi, Hosseinalipour, Seyed Mostafa
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Sprache:	eng
Schlagworte:	Coefficients Convective heat transfer Dispersion model Experimental study Fluid flow Heat transfer heat transfer coefficient Migration Nanofluid Nanofluids Nanomaterials Nanostructure Particle distribution particle size Reynolds number Thermophoresis viscosity
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creator	Bahiraei, Mehdi Hosseinalipour, Seyed Mostafa
description	•Particle migration effect was assessed considering thermophoresis.•Non-uniform concentration was applied in the dispersion model.•An experimental study was conducted to examine the numerical solution accuracy.•Considering thermophoresis yields the greater convective heat transfer coefficient.•At greater concentrations, the effect of thermophoresis is more significant. The effects of particle migration on concentration distribution and convective heat transfer coefficient of the water-TiO2 nanofluid were investigated inside a circular tube. The concentration distribution was obtained considering thermophoresis, non-uniform shear rate, Brownian diffusion and viscosity gradient. Using the scale analysis, it was demonstrated that thermophoresis can have a significant effect on the particle migration. Dispersion approach was used for simulation, while a non-uniform concentration was applied. An experimental study was conducted to examine the numerical solution accuracy and there was a good agreement between the experimental and numerical results. Non-uniformity of the concentration is intensified by increasing the Reynolds number and the particle size. Thermophoresis makes the concentration more non-uniform and the velocity profile flatter as well. At greater mean concentrations, the effect of thermophoresis on particle distribution and convective heat transfer coefficient is highlighted. Meanwhile, considering thermophoresis yields greater convective heat transfer coefficient in all Reynolds numbers.
doi_str_mv	10.1016/j.tca.2013.09.010
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The effects of particle migration on concentration distribution and convective heat transfer coefficient of the water-TiO2 nanofluid were investigated inside a circular tube. The concentration distribution was obtained considering thermophoresis, non-uniform shear rate, Brownian diffusion and viscosity gradient. Using the scale analysis, it was demonstrated that thermophoresis can have a significant effect on the particle migration. Dispersion approach was used for simulation, while a non-uniform concentration was applied. An experimental study was conducted to examine the numerical solution accuracy and there was a good agreement between the experimental and numerical results. Non-uniformity of the concentration is intensified by increasing the Reynolds number and the particle size. Thermophoresis makes the concentration more non-uniform and the velocity profile flatter as well. At greater mean concentrations, the effect of thermophoresis on particle distribution and convective heat transfer coefficient is highlighted. 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The effects of particle migration on concentration distribution and convective heat transfer coefficient of the water-TiO2 nanofluid were investigated inside a circular tube. The concentration distribution was obtained considering thermophoresis, non-uniform shear rate, Brownian diffusion and viscosity gradient. Using the scale analysis, it was demonstrated that thermophoresis can have a significant effect on the particle migration. Dispersion approach was used for simulation, while a non-uniform concentration was applied. An experimental study was conducted to examine the numerical solution accuracy and there was a good agreement between the experimental and numerical results. Non-uniformity of the concentration is intensified by increasing the Reynolds number and the particle size. Thermophoresis makes the concentration more non-uniform and the velocity profile flatter as well. At greater mean concentrations, the effect of thermophoresis on particle distribution and convective heat transfer coefficient is highlighted. 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The effects of particle migration on concentration distribution and convective heat transfer coefficient of the water-TiO2 nanofluid were investigated inside a circular tube. The concentration distribution was obtained considering thermophoresis, non-uniform shear rate, Brownian diffusion and viscosity gradient. Using the scale analysis, it was demonstrated that thermophoresis can have a significant effect on the particle migration. Dispersion approach was used for simulation, while a non-uniform concentration was applied. An experimental study was conducted to examine the numerical solution accuracy and there was a good agreement between the experimental and numerical results. Non-uniformity of the concentration is intensified by increasing the Reynolds number and the particle size. Thermophoresis makes the concentration more non-uniform and the velocity profile flatter as well. At greater mean concentrations, the effect of thermophoresis on particle distribution and convective heat transfer coefficient is highlighted. Meanwhile, considering thermophoresis yields greater convective heat transfer coefficient in all Reynolds numbers.</abstract><pub>Elsevier B.V</pub><doi>10.1016/j.tca.2013.09.010</doi><tpages>8</tpages></addata></record>
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subjects	Coefficients Convective heat transfer Dispersion model Experimental study Fluid flow Heat transfer heat transfer coefficient Migration Nanofluid Nanofluids Nanomaterials Nanostructure Particle distribution particle size Reynolds number Thermophoresis viscosity
title	Particle migration in nanofluids considering thermophoresis and its effect on convective heat transfer
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