Analytical Solution of Non-Newtonian Nanofluid Flows Within Circular Duct under Convective Boundary Condition

Tahiri, Antar; Mansouri, Kacem; Kouider, Rahmani; Amar, Kouadri; Embarek, Douroum

doi:10.18280/mmep.080504

MMEP

2021

DOI: 10.18280/mmep.080504

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Analytical Solution of Non-Newtonian Nanofluid Flows Within Circular Duct under Convective Boundary Condition

Antar Tahiri¹,

Kacem Mansouri²,

Rahmani Kouider³

et al.

Abstract: At the outset, this work aims to carried out an analytical investigation of forced convection by establishing a laminar flow into circular duct under convective boundary conditions of the third type for non-Newtonian nanofluid, the fluid containing TiO2 uniformly dispersed in aqueous solution with 0.5wt% of CMC solutions (Carboxymethyl Cellulose) is used as working fluid. The viscous dissipation effects are taken into account, the employed methodology is based on a combination of the Ritz variational approach … Show more

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2024

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Cited by 1 publication

References 28 publications

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Heat transfer and entropy generation in viscous-joule heating MHD microchannels flow under asymmetric heating

Tahiri,

Ragueb,

Moussaoui

et al. 2024

HFF

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Purpose This paper aims to present a numerical investigation into heat transfer and entropy generation resulting from magnetohydrodynamic laminar flow through a microchannel under asymmetric boundary conditions. Furthermore, the authors consider the effects of viscous dissipation and Joule heating. Design/methodology/approach The finite difference method is used to obtain the numerical solution. Simulations are conducted across a broad range of Hartmann (Ha = 0 ∼ 40) and Brinkman (Br = 0.01 ∼ 1) numbers, along with various asymmetric isothermal boundaries characterized by a heating ratio denoted as ϕ. Findings The findings indicate a significant increase in the Nusselt number with increasing Hartmann number, regardless of whether Br equals zero or not. In addition, it is demonstrated that temperature differences between the microchannel walls can lead to substantial distortions in fluid temperature distribution and heat transfer. The results reveal that the maximum entropy generation occurs at the highest values of Ha and η (a dimensionless parameter emerging from the formulation) obtained for ϕ = −1. Moreover, it is observed that local entropy generation rates are highest near the channel wall at the entrance region. Originality/value The study provides valuable insights into the complex interactions between magnetic fields, viscous dissipation and Joule heating in microchannel flows, particularly under asymmetric heating conditions. This contributes to a better understanding of heat transfer and entropy generation in advanced microfluidic systems, which is essential for optimizing their design and performance.

show abstract

Heat transfer and entropy generation in viscous-joule heating MHD microchannels flow under asymmetric heating

Tahiri,

Ragueb,

Moussaoui

et al. 2024

HFF

View full text Add to dashboard Cite

show abstract

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Analytical Solution of Non-Newtonian Nanofluid Flows Within Circular Duct under Convective Boundary Condition

Cited by 1 publication

References 28 publications

Heat transfer and entropy generation in viscous-joule heating MHD microchannels flow under asymmetric heating

Heat transfer and entropy generation in viscous-joule heating MHD microchannels flow under asymmetric heating

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