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Fluid Flow over a Sharp and Blunt V-shaped R

Gihan. E. H. Ali / Ismail I. A.

In this paper we study a viscous fluid flow over a V-shaped body for a range of Reynold's number from Re = 5 up to Re = 500. We solved the unsteady Naveir-stokes equations in the stream function - vorticity formulation. The irregular physical domain is transformed into a rectangular shape using the elliptic grid generation. We applied the Finite diference discretization technique for governing the partial diferential equations, in this technique, the computational domain is covered by a pattern, network or mesh points called grid points. The governing equations are then reformulated at each interior point by replacing all partial derivatives with appropriate Finite diferences, thus converted to a set of discrete algebraic equations.

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Fluid Flow over a Sharp and Blunt V-shaped R

Gihan. E. H. Ali / Ismail I. A.

In this paper we study a viscous fluid flow over a V-shaped body for a range of Reynold's number from Re = 5 up to Re = 500. We solved the unsteady Naveir-stokes equations in the stream function - vorticity formulation. The irregular physical domain is transformed into a rectangular shape using the elliptic grid generation. We applied the Finite diference discretization technique for governing the partial diferential equations, in this technique, the computational domain is covered by a pattern, network or mesh points called grid points. The governing equations are then reformulated at each interior point by replacing all partial derivatives with appropriate Finite diferences, thus converted to a set of discrete algebraic equations.

Fluid Flow over a Sharp and Blunt V-shaped R

Gihan. E. H. Ali / Ismail I. A.

In this paper we study a viscous fluid flow over a V-shaped body for a range of Reynold's number from Re = 5 up to Re = 500. We solved the unsteady Naveir-stokes equations in the stream function - vorticity formulation. The irregular physical domain is transformed into a rectangular shape using the elliptic grid generation. We applied the Finite diference discretization technique for governing the partial diferential equations, in this technique, the computational domain is covered by a pattern, network or mesh points called grid points. The governing equations are then reformulated at each interior point by replacing all partial derivatives with appropriate Finite diferences, thus converted to a set of discrete algebraic equations.

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Title:

Fluid Flow over a Sharp and Blunt V-shaped R

Contributors:

Gihan. E. H. Ali (author) / Ismail I. A. (author)

Published in:

Acta Montanistica Slovaca, Vol 10, Iss 3, Pp 280-289 (2005)

Publication date:

2005

ISSN:

Type of media:

Article (Journal)

Type of material:

Electronic Resource

Language:

Unknown

Keywords:

successive-over relaxation iteration method , Naveir-Stokes equations , Stream function-Vorticity formulation , Grid Generation , Mining engineering. Metallurgy , TN1-997 , Geology , QE1-996.5

Metadata by DOAJ is licensed under CC BY-SA 1.0

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