Heat Transfer Analysis on Peristaltic Transport of Sisko Fluid in an Inclined Uniform Channel

Sanil, Prathiksha; Manjunatha, G.; Rajashekhar, C.; Vaidya, Hanumesh; Prasad, K. V.

doi:10.37934/arfmts.103.2.157179

Cited by 5 publications

(3 citation statements)

References 29 publications

(34 reference statements)

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“…Where width of the Nonuniform channel is given by 𝑙(𝑋), time by 𝑡, and wave amplitude by 𝑏. The formulas governing the flow are as given below [21][22][23][24][25][26][27][28][29][30][31] " The elastic wall motion expression is represented as…”

Section: Problem Formulationmentioning

confidence: 99%

See 1 more Smart Citation

Peristaltic Transport of Bingham Fluid through Nonuniform Channel with Convective Conditions and Lorentz Forces

Gonchigara¹,

Gnanaprasunamba²

2023

ARFMTS

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In this study, the impacts of changing the liquid characteristics of the Bingham fluid are highlighted under MHD peristaltic transport. Conditions for convective and porous boundary conditions are taken into consideration. By using proper similarity transformations, the governing equations become dimensionless. For temperature, velocity, and streamlines, the series solution is found. The MATLAB 2019b programming offers a graphical depiction of relevant metrics on physiological flow parameters. The findings demonstrate that lowering the velocity and temperature profiles occurs when the magnetic parameter is increased. Furthermore, the effect of changing viscosity increases the trapped bolus size by a small amount. Once again, the results of the present investigation have significance for our knowledge of the complex rheological mechanisms governing blood flow via small arteries.

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Section: Problem Formulationmentioning

confidence: 99%

“…Recently, Tanveer et al, [20] analysed how electro osmosis affected the peristaltic nanofluid flow using the Bingham liquid. Several researchers has calculated to the peristaltic transport medium with nonNewtonian fluids and nanofluids via different geometry [21][22][23][24][25][26][27][28][29][30][31][32][33][34][35][36][37][38][39].…”

Section: Introductionmentioning

confidence: 99%

Peristaltic Transport of Bingham Fluid through Nonuniform Channel with Convective Conditions and Lorentz Forces

Gonchigara¹,

Gnanaprasunamba²

2023

ARFMTS

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“…Their research focused on analyzing the Reynolds and wave numbers under lower conditions based on second-order assumptions. The researchers considered various parameters such as tapered length, velocity of the wave, and radius to investigate their effects on the peristalsis flow [29,30]. The study involved examining pipes with radii ranging from 0.01cm to 4 cm over a distance of 20 cm.…”

Section: Introductionmentioning

confidence: 99%

Analyzing Single Peristaltic Wave Behavior in Ureter with Variable Diameters: A Ureterdynamic Study

Laxmikant G Keni,

Satish Shenoy B,

Chethan K N

et al. 2024

CFDL

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Ureters are muscular tubes that transport urine from the kidney to the bladder. The peristalsis wave is responsible for carrying urine to the bladder. With the regular appearance of peristalsis, areas with anatomic narrowing junctions are crucial for ureteral diseases. A three-dimensional flow analysis is performed for different time steps to understand the effect of the urine bolus formation and the reflux phenomenon on variable diameter ureters. For the constant and variable diameter ureter, the pressure is obtained behind and in front of the propagating bolus respectively. The peristalsis wave creates the high-velocity of a jet in the neck region of the ureter. The contraction produces the trapping of the bolus leading to adverse flow in the contraction region. By virtue tapering, the high-pressure gradient builds up, leading to high wall shear in the ureter. The main goal is to determine the pressure, velocity, gradient pressure, and shear force on the ureter wall during peristaltic motion. These parameters are very important for clinicians to understand its effect in the unobstructed variable diameter ureter. This article may help to build a medical device for engineers. The physical significance of this information lies in its profound insights into the biomechanics and functionality of the ureters, which are essential components of the human urinary system.

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EHD peristaltic flow of Sisko fluid under the effects of convection and endoscope

Hafez

2024

Ain Shams Engineering Journal

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Heat Transfer Analysis on Peristaltic Transport of Sisko Fluid in an Inclined Uniform Channel

Cited by 5 publications

References 29 publications

Peristaltic Transport of Bingham Fluid through Nonuniform Channel with Convective Conditions and Lorentz Forces

Peristaltic Transport of Bingham Fluid through Nonuniform Channel with Convective Conditions and Lorentz Forces

Analyzing Single Peristaltic Wave Behavior in Ureter with Variable Diameters: A Ureterdynamic Study

EHD peristaltic flow of Sisko fluid under the effects of convection and endoscope

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