Interaction between compressibility and particulate suspension on peristaltically driven flow in planar channel

Kamel, Mohamed Hassan; Vafai, Kambiz; Abdelsalam, Sara I.; Eldesoky, Islam M.; Abumandour, Ramzy M.

doi:10.1007/s10483-017-2156-6

Cited by 61 publications

(30 citation statements)

References 13 publications

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“…Choosing χ =0 and Kn = 0 in the analysis indicates a well-agreed physical situation as discussed by Srivastava and Srivastava [5]. Furthermore, the results of Eldesoky et al [38] can be reached by choosing Kn = 0 as shown in Figs. 2, 3.…”

Section: Validation Of the Problemsupporting

confidence: 63%

“…With regard to assessment, the mean-velocity perturbation function Ɉ Z (y) was determined by Fung and Yih [37], Srivastava and Srivastava [5], and Eldesoky et al [38] in the form from which the net time-axial velocity of the fluid phase can be obtained as…”

Section: Numerical Results and Discussionmentioning

confidence: 99%

“…The second system of equations is obtained by substituting (45) into Eqs. (36)(37)(38)(39)(40)(41) and (43), and the following set of equations is obtained as:…”

Section: Perturbation Technique Solutionmentioning

confidence: 99%

“…The study of non-Newtonian nanofluid with hall and ion slip effects on peristaltically induced motion in a nonuniform channel was discussed by Bhatti and Sara [36]. The previous applications of a 2D peristaltic movement of the solid-fluid structure were discussed by Srivastava and Srivastava [5], Fung and Yih [37], and Eldesoky et al [38].…”

Section: Introductionmentioning

confidence: 99%

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Effects of slip conditions and compressibility on the peristaltic flow of particulate suspension in a planar channel

2019

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This paper concerns with the peristaltic flow of a particle-fluid suspension (as blood model) through asymmetric twodimensional channel with slip conditions. The problem formulation is presented for a duct filled with a compressible viscous fluid mixed with rigid spherical particles. The resulting problems are solved by the perturbation expansion method. The effects of different physical parameters such as particles concentration, compressibility parameter, and slip parameter have a significant effect on velocity distributions and are presented and discussed graphically. It is found that the mean axial velocity increases as the slip parameter increases at a minimal compressibility parameter, and it decreases at a higher value of compressibility parameter with increasing slip parameter. This paper gives a scope for estimating the effects of the slip conditions of two-phase flow characteristics with compressible fluid problems and helps in understanding the role of the engineering applications of pumping solid-fluid mixture by peristaltically driven motion.

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Section: Validation Of the Problemsupporting

confidence: 63%

Section: Numerical Results and Discussionmentioning

confidence: 99%

“…The second system of equations is obtained by substituting (45) into Eqs. (36)(37)(38)(39)(40)(41) and (43), and the following set of equations is obtained as:…”

Section: Perturbation Technique Solutionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Effects of slip conditions and compressibility on the peristaltic flow of particulate suspension in a planar channel

2019

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“…Mekheimer and Abdel-Wahab [38] obtained expressions for mean axial velocity, net velocity at channel wall, and mean velocity perturbation function in terms of various flow and elastic wall parameters for the compressible fluid flow resulting from the surface acoustic wave in planar channel. Eldesoky et al [39] analyzed both influences of liquid compressibility and suspension concentration on the wavy compressible flow via rectangular channel; the results showed that the increase in particle concentration causes an increase in the mean flow velocity, whereas the velocity profile was insensitive to the liquid compressibility. Elshehawey et al [40] also analyzed the behaviour of aviscoelastic compressible liquid moving peristaltically via tapered pore.…”

Section: Introductionmentioning

confidence: 99%

The combined influences of heat transfer, compliant wall properties and slip conditions on the peristaltic flow through tube

et al. 2019

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In this research, the peristaltic flow with heat transfer through the two-dimensional horizontal tube of compliant wall properties with slip at boundaries is analyzed analytically. An approximated theoretical model is constructed of springbacked flexible compliant walls pipe, chosen to move as sinusoidal wave. Perturbation solution of the governing equations is obtained with small parameter ε, which means the amplitude ratio, and defined as the ratio of wave amplitude divided by tube radius. The influence of several parameters of slip conditions, wall properties and heat transfer on the dynamics of the liquid through the tube is mathematically studied, resulting in relations describing the fluid flow behavior and the induced net flow rate under the various values of flow parameters as "liquid compressibility, slip flow factor, and wave number", heat transfer parameter like Prandtl number, and elastic wall parameters such as "wall tension, wall damping coefficient, wall stiffness, and wall rigidity". Graphs for net flow rate under the effect of pervious parameters are plotted. Results disclose that the parameters of tube wall features, compressibility of liquid, Knudsen number for wall slip, and heat transfer in the presence of peristaltic pumping have a significant effect on net flow rate induced. This research has numerous related applications in different branches of science such as biological studies for blood flow motion in living creatures and also in industry including simulation of induced elastic waves for fluid flow through a tube.

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An entropy model for Carreau nanofluid ciliary flow with electroosmosis and thermal radiations: A numerical study

Alharbi,

Riaz,

Sikandar

2023

Electrophoresis

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In order to localize heat production and drug activation, it is possible for drug delivery to make use of nanofluids containing thermal radiation. By limiting the amount of medication that is administered to healthy tissues, this approach increases drug distribution. We explore the effect that thermal radiation has on the flow of a ternary‐hybrid nanofluid composed of titanium oxide (TiO2), silica (SiO2), and aluminum oxide (AI2O3). The base liquid that we use for our Carreau constitutive model is blood. Entropy and electroosmosis are both taken into account when the conduit is connected to the battery terminals outside. Following the step of translating the observation model into a wave frame, the physical restrictions of the lubrication theory are used in order to provide a more complete explanation for the wave occurrences. In this work, shooting is used to simulate boundary value issues that are solved with Mathematica NDSolve. The production of the least amount of entropy and a rise in thermodynamic efficiency are achieved by the motion of cilia and elastic electroosmotic pumping. It is also observed that heat transfer is proportional to the length of cilia. Nusselt number is increased by large cilia but skin friction got a reduction.

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Interaction between compressibility and particulate suspension on peristaltically driven flow in planar channel

Cited by 61 publications

References 13 publications

Effects of slip conditions and compressibility on the peristaltic flow of particulate suspension in a planar channel

Effects of slip conditions and compressibility on the peristaltic flow of particulate suspension in a planar channel

The combined influences of heat transfer, compliant wall properties and slip conditions on the peristaltic flow through tube

An entropy model for Carreau nanofluid ciliary flow with electroosmosis and thermal radiations: A numerical study

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