The role of several heat transfer mechanisms on the enhancement of thermal conductivity in nanofluids

Machrafi, Hatim; Lebon, Georgy

doi:10.1007/s00161-015-0488-4

Cited by 31 publications

(17 citation statements)

References 71 publications

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“…Here for simplicity , we limit our developments to the use of P and P (3) as flux state variables but there will be no difficulty to include higher order tensors as P (4) , … P (N) as done previously in the problem of non-local heat conduction wherein an infinite number of extra fluxes have been introduced [30][31][32]. From the kinetic theory point of view, P (2) and P (3) represent the second and third order moments of the velocity distribution.…”

Section: Extended Irreversible Thermodynamicsmentioning

confidence: 99%

A thermodynamic model of nanofluid viscosity based on a generalized Maxwell-type constitutive equation

Lebon

Machrafi

2018

Journal of Non-Newtonian Fluid Mechanics

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An original study of nanofluid viscosity is proposed. The carrier fluid is assumed Newtonian but the two-phase nanofluid displays properties typical of a generalized Maxwell constitutive law. Our approach is based on an extension of Einstein's model describing suspensions of solid particles in fluids by the introduction of the following elements: presence of a layer around the nanoparticles and a thermodynamic description of the role of size effects. The theoretical formalism is applied to liquid argon with lithium nanoparticles and to alumina nanoparticles in water. Good agreement with experimental data and molecular dynamics simulation is observed.

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Section: Extended Irreversible Thermodynamicsmentioning

confidence: 99%

A thermodynamic model of nanofluid viscosity based on a generalized Maxwell-type constitutive equation

Lebon

Machrafi

2018

Journal of Non-Newtonian Fluid Mechanics

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“…Lately, Hamilton and Crosser [4], came up with a modified version of Maxwell's model, which demonstrated the influence of particle shape and volume fraction, on the thermal efficiency of the fluid containing nanometer sized structures. Further studies have exposed a diverse class of models, which incorporates different features of nanomaterials, like Brownian motion [5], nanoparticles size [6,7], shapes [8], liquid layering [9], and particles agglomeration [10,11], in order to examine the variations in thermo-physical characteristics of nanofluid.…”

Section: Introductionmentioning

confidence: 99%

Heat Transfer Enhancement by Coupling of Carbon Nanotubes and SiO2 Nanofluids: A Numerical Approach

et al. 2019

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This article comprises the study of three-dimensional squeezing flow of (CNT-SiO2/H2O) hybrid nanofluid. The flow is confined inside a rotating channel whose lower wall is stretchable as well as permeable. Heat transfer with viscous dissipation is a main subject of interest. We have analyzed mathematically the benefits of hybridizing SiO 2 -based nanofluid with carbon nanotubes ( CNTs ) nanoparticles. To describe the effective thermal conductivity of the CNTs -based nanofluid, a renovated Hamilton–Crosser model (RHCM) has been employed. This model is an extension of Hamilton and Crosser’s model because it also incorporates the effect of the interfacial layer. For the present flow scenario, the governing equations (after the implementation of similarity transformations) results in a set of ordinary differential equations (ODEs). We have solved that system of ODEs, coupled with suitable boundary conditions (BCs), by implementing a newly proposed modified Hermite wavelet method (MHWM). The credibility of the proposed algorithm has been ensured by comparing the procured results with the result obtained by the Runge-Kutta-Fehlberg solution. Moreover, graphical assistance has also been provided to inspect the significance of various embedded parameters on the temperature and velocity profile. The expression for the local Nusselt number and the skin friction coefficient were also derived, and their influential behavior has been briefly discussed.

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“…More studies in this area introduce a variety of models which examined the effects of nanoparticles type [6][7][8], particle shapes [9] and particles size [10,11] etc. Moreover, various heat transfer mechanisms including Brownian movement of particles [12], particles agglomeration [13,14] and liquid layering [15] would also gain the attention of many scientists.…”

Section: Introductionmentioning

confidence: 99%

Thermophysical Analysis of Water Based (Cu–Al2O3) Hybrid Nanofluid in an Asymmetric Channel with Dilating/Squeezing Walls Considering Different Shapes of Nanoparticles

et al. 2018

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An innovative concept of water-based Cu–Al2O3 hybrid nanofluid has been employed to investigate the behavior of flow and heat transfer inside a rectangular channel whose permeable walls experiences dilation or contraction in height. The transformed set of ordinary differential equations is then solved by a well-known Runge–Kutta–Fehlberg algorithm. The analysis also includes three different shapes of copper nanocomposites, namely, platelet, cylinder and brick- shaped. The impact of various embedded parameters on the flow and heat transfer distributions have been demonstrated through the graphs. All the flow properties, temperature profile and rate of heat transfer at the walls are greatly influenced by the presence of copper nanoparticles. Furthermore, it was observed that the platelet shaped nanocomposites provide a better heat transfer ability as compared to the other shapes of nanoparticles.

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The role of several heat transfer mechanisms on the enhancement of thermal conductivity in nanofluids

Cited by 31 publications

References 71 publications

A thermodynamic model of nanofluid viscosity based on a generalized Maxwell-type constitutive equation

A thermodynamic model of nanofluid viscosity based on a generalized Maxwell-type constitutive equation

Heat Transfer Enhancement by Coupling of Carbon Nanotubes and SiO2 Nanofluids: A Numerical Approach

Thermophysical Analysis of Water Based (Cu–Al2O3) Hybrid Nanofluid in an Asymmetric Channel with Dilating/Squeezing Walls Considering Different Shapes of Nanoparticles

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