Perturbation analysis of 2-dimensional boundary layer flow of an inelastic fluid using williamson model

Nirmal Sacheti; Tayfour El-Bashir; Pallath Chandran

Perturbation analysis of 2-dimensional boundary layer flow of an inelastic fluid using williamson model

Nirmal Sacheti, Tayfour El-Bashir, Pallath Chandran

Mathematics & Statistics

Research output: Contribution to journal › Article › peer-review

10 Citations (Scopus)

Abstract

In this paper, we have discussed steady boundary layer flow of an inelastic fluid encountered in a number of engineering and biomedical applications, using the constitutive equation of the Williamson fluid. The flow is assumed to take place near a stagnation point on an infinite rigid flat surface. Using similarity transformations, the governing partial differential equations have been reduced to a nonlinear boundary value problem. The emphasis of our work in this study is to analyze the conventional perturbation solution vis-à-vis higher order effects. It is established that the higher order terms in the perturbation expansion, usually not considered in perturbation analyses, do influence the flow in the boundary layer region of the inelastic fluid. A quantity of engineering interest, namely, wall shear stress, has also been computed and analyzed.

Original language	English
Pages (from-to)	12728-12734
Number of pages	7
Journal	International Journal of Applied Engineering Research
Volume	12
Issue number	22
Publication status	Published - 2017

Keywords

Boundary layer flow
Inelastic fluid
Perturbation analysis
Stagnation point
Wall shear stress
Williamson model

ASJC Scopus subject areas

Engineering(all)

Cite this

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abstract = "In this paper, we have discussed steady boundary layer flow of an inelastic fluid encountered in a number of engineering and biomedical applications, using the constitutive equation of the Williamson fluid. The flow is assumed to take place near a stagnation point on an infinite rigid flat surface. Using similarity transformations, the governing partial differential equations have been reduced to a nonlinear boundary value problem. The emphasis of our work in this study is to analyze the conventional perturbation solution vis-{\`a}-vis higher order effects. It is established that the higher order terms in the perturbation expansion, usually not considered in perturbation analyses, do influence the flow in the boundary layer region of the inelastic fluid. A quantity of engineering interest, namely, wall shear stress, has also been computed and analyzed.",

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AU - Sacheti, Nirmal

AU - El-Bashir, Tayfour

AU - Chandran, Pallath

PY - 2017

Y1 - 2017

N2 - In this paper, we have discussed steady boundary layer flow of an inelastic fluid encountered in a number of engineering and biomedical applications, using the constitutive equation of the Williamson fluid. The flow is assumed to take place near a stagnation point on an infinite rigid flat surface. Using similarity transformations, the governing partial differential equations have been reduced to a nonlinear boundary value problem. The emphasis of our work in this study is to analyze the conventional perturbation solution vis-à-vis higher order effects. It is established that the higher order terms in the perturbation expansion, usually not considered in perturbation analyses, do influence the flow in the boundary layer region of the inelastic fluid. A quantity of engineering interest, namely, wall shear stress, has also been computed and analyzed.

AB - In this paper, we have discussed steady boundary layer flow of an inelastic fluid encountered in a number of engineering and biomedical applications, using the constitutive equation of the Williamson fluid. The flow is assumed to take place near a stagnation point on an infinite rigid flat surface. Using similarity transformations, the governing partial differential equations have been reduced to a nonlinear boundary value problem. The emphasis of our work in this study is to analyze the conventional perturbation solution vis-à-vis higher order effects. It is established that the higher order terms in the perturbation expansion, usually not considered in perturbation analyses, do influence the flow in the boundary layer region of the inelastic fluid. A quantity of engineering interest, namely, wall shear stress, has also been computed and analyzed.

KW - Boundary layer flow

KW - Inelastic fluid

KW - Perturbation analysis

KW - Stagnation point

KW - Wall shear stress

KW - Williamson model

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IS - 22

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Perturbation analysis of 2-dimensional boundary layer flow of an inelastic fluid using williamson model

Abstract

Keywords

ASJC Scopus subject areas

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