Thermal transport of two-phase physiological flow of non-Newtonian fluid through an inclined channel with flexible walls

Nazeer, Mubbashar; Al-Zubaidi, A.; Hussain, Farooq; Duraihem, Faisal Z.; Anila, Sadaf; Saleem, S.

doi:10.1016/j.csite.2022.102146

Cited by 29 publications

(5 citation statements)

References 27 publications

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“…The flow of the Jeffrey fluid is related to the study of two fluids in a tube of tiny size by Nallapu and Radhakrishnamacharya 24 . Nazeer et al 25 studied the thermal transport of two‐phase physiological flow of non‐Newtonian fluid through an inclined channel with flexible walls. They observed that the momentum of the Jeffrey fluid gradually increases due to the Darcy number.…”

Section: Introductionmentioning

confidence: 99%

The flow of non‐Newtonian fluid in an inclined channel through variable permeability

Bandi

Mallela²,

Sreenadh

et al. 2023

Heat Trans

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A non‐Newtonian fluid's Poiseuille flow in a porous medium with variable inclination and permeability is investigated. Let us assume for the sake of simplification that permeability varies as a quadratic parabolic function form. The porous medium is used by the Brinkman methodology to control the flow. The equations for velocity distribution and mass flow that result from this are evaluated using different input values. This problem describes the effect of inclination, Jeffrey parameter, and variable permeability on the classical Poiseuille flow between parallel plates. This problem can also be treated as an extension of the work of Hamdan and Kamel for non‐Newtonian fluid flow in an inclined channel. Also, the effects of these variables on the variation of mass flux with Jeffrey parameter λ1 is analyzed through graphs, and the skin friction coefficient is analyzed through table values. It is observed that the maximum permeability of the porous medium affects both the mass flow rate and the velocity, which increase with rising λ1 and decrease with rising Ha, respectively.

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Section: Introductionmentioning

confidence: 99%

The flow of non‐Newtonian fluid in an inclined channel through variable permeability

Bandi

Mallela²,

Sreenadh

et al. 2023

Heat Trans

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“…He noticed that there is a sizable variation between the flow’s velocities at later times when the Reynolds number is small and large. Nazeer et al 33 discussed Magnetohydrodynamics (MHD) of a non-Newtonian fluid with heat transfer through a porous medium and observed that Newtonian multiphase fluid is less common than Jeffrey multiphase suspension.…”

Section: Introductionmentioning

confidence: 99%

Heat transport in inclined flow towards a rotating disk under MHD

Mahmud

Duraihem

Mehmood

et al. 2023

Sci Rep

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Flow towards a rotating disk is of highly practical significance in numerous engineering applications such as Turbine disks, rotary type machine systems and many more. In light of this, the current work is an attempt to explore MHD oblique flow towards a rotating disk. Hydromagnetic effects in addition to heat transfer is taken into consideration. The flow governing Partial Differential Equations are altered to a system to coupled non-linear Ordinary Differential Equations through scaling group of transformations which afterwards are tackled using Shooting Algorithm. The impact of obliqueness parameter γ, rotation ratio parameter $$\alpha$$ α and magnetic field parameter M on 2-dimensional and 3-dimensional stream contours are presented. Location of the shear center varies with magnetic field parameter. Heat flow at the disk surface boosts with magnet field parameter M and rotation ratio parameter $$\alpha$$ α .

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“…While the magnetic field and rotation parameter exhibit the opposite pattern, the axial velocity increases with increasing particle volume percentage. Using Jeffrey fluid as a model, Nazeer et al (2022) investigated the MHD of a non-Newtonian fluid with heat transport in a porous media. The effects of lubrication on the channel's two bendable walls were taken into account.…”

Section: Introductionmentioning

confidence: 99%

Machine learning analysis of heat transfer and electroosmotic effects on multiphase wavy flow: a numerical approach

Aslam,

Riaz,

Shaukat

et al. 2023

HFF

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Purpose This study aims to present a unique hybrid metaheuristic approach to solving the nonlinear analysis of hall currents and electric double layer (EDL) effects in multiphase wavy flow by merging the firefly algorithm (FA) and the water cycle algorithm (WCA). Design/methodology/approach Nonlinear Hall currents and EDL effects in multiphase wavy flow are originally described by partial differential equations, which are then translated into an ordinary differential equation model. The hybrid FA-WCA technique is used to take on the optimization challenge and find the best possible design weights for artificial neural networks. The fitness function is efficiently optimized by this hybrid approach, allowing the optimal design weights to be determined. Findings The proposed strategy is shown to be effective by taking into account multiple variables to arrive at a single answer. The numerical results obtained from the proposed method exhibit good agreement with the reference solution within finite intervals, showcasing the accuracy of the approach used in this study. Furthermore, a comparison is made between the presented results and the reference numerical solutions of the Hall Currents and electroosmotic effects in multiphase wavy flow problem. Originality/value This comparative analysis includes various performance indices, providing a statistical assessment of the precision, efficiency and reliability of the proposed approach. Moreover, to the best of the authors’ knowledge, this is a new work which has not been explored in existing literature and will add new directions to the field of fluid flows to predict most accurate results.

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Thermal transport of two-phase physiological flow of non-Newtonian fluid through an inclined channel with flexible walls

Cited by 29 publications

References 27 publications

The flow of non‐Newtonian fluid in an inclined channel through variable permeability

The flow of non‐Newtonian fluid in an inclined channel through variable permeability

Heat transport in inclined flow towards a rotating disk under MHD

Machine learning analysis of heat transfer and electroosmotic effects on multiphase wavy flow: a numerical approach

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