Flow and heat transfer of non-miscible micropolar and Newtonian fluid in porous channel sandwiched between parallel plates

An analytical approach has been considered to inspect the flow and heat transfer of immiscible Newtonian and micropolar fluid in a porous medium. This study aims to elucidate the Darcy effect on the model in which isotropic porous regions with different permeability are used. The model of the curren...

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Bibliographic Details
Published in:Chinese journal of physics (Taipei) 2024-12, Vol.92, p.33-50
Main Authors: Srivastava, Alpana, Kumar, Ajit, Pandey, Akhilesh Chandra
Format: Article
Language:English
Subjects:
Flow rate
Heat transfer
Heat transfer rate
Linear differential equation
Micropolar fluid
Porous region
Prandtl number
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Summary:An analytical approach has been considered to inspect the flow and heat transfer of immiscible Newtonian and micropolar fluid in a porous medium. This study aims to elucidate the Darcy effect on the model in which isotropic porous regions with different permeability are used. The model of the current problem explains that the flow region is divided into two regions: Newtonian fluid flows in the upper layer, and micropolar fluid flows in the lower layer. Different constant temperatures imposed at boundary walls, heat transfer does not affect the pressure gradient. The governing equations are solved analytically by applying a linear differential equation (LDE). The effect of associated physical parameters such as material parameter, Darcy number, Eckert number, Prandtl number, and viscosity ratio on velocity, micro-rotation, heat transfer, flow rate, heat transfer rate, wall shear stress, and Nusselt number have been inspected. The most significant finding of this research work is that increasing the Darcy number signifies enhanced permeability, resulting in a higher flow rate. The heat transfer rate at the top occurs maximum when the material parameter’s range is minimum while raising the viscosity ratio leads to an increasing heat transfer rate at the bottom. Enhancement in material parameter influences Nusselt number and decreases in nature. The findings of our study are verified with the previously established results. The present work has a setup that is useful in petroleum extraction, transport problems in reservoir rock of an oil field, improving nutrient transport and thermal regulation in tissue engineering, and designing more efficient drug delivery systems and biomedical devices. [Display omitted] •Developed a model for immiscible fluid flow and heat transfer in the porous region.•MATHEMATICA software has been used to solve the system of equations.•Different Darcy numbers used to control the flow variable are discussed.•Explained the comparison of the flow rate of immiscible fluid with the particular case.
ISSN:0577-9073
DOI:10.1016/j.cjph.2024.08.041