The Momentum Integral Approximation for Compressible Magnetogasdynamic Boundary-Layer Flow

J. J. Kauzlarich; A. B. Cambel

Source: Journal of Applied Mechanics:;1963:;volume( 030 ):;issue: 002::page 269

Author:

J. J. Kauzlarich

A. B. Cambel

DOI: 10.1115/1.3636523

Publisher: The American Society of Mechanical Engineers (ASME)

Abstract: The drag of an adiabatic flat plate in an ionized gas for a constant magnetic field applied to the boundary layer on the plate is found by a momentum integral approximation of von Karman. Laminar, two-dimensional flow, zero pressure gradient, small magnetic Reynolds number, and negligible electrical conductivity outside the boundary layer are assumed. The solution is valid in particular to a continuous, perfect-gas plasma, of unitary Prandtl number, and for conditions when the interaction parameter is very small. The solution shows the following effects: The adiabatic wall temperature is independent of the magnetic field; there is an increase in the boundary-layer thickness as the magnetic-field strength is increased; and the viscous drag coefficient decreases whereas the coefficient of total drag increases.

keyword(s): Flow (Dynamics) , Boundary layers , Approximation , Momentum , Magnetic fields , Drag (Fluid dynamics) , Reynolds number , Plasmas (Ionized gases) , Flat plates , Prandtl number , Pressure gradient , Thickness , Wall temperature AND Electrical conductivity ,

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The Momentum Integral Approximation for Compressible Magnetogasdynamic Boundary-Layer Flow

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contributor author	J. J. Kauzlarich
contributor author	A. B. Cambel
date accessioned	2017-05-08T23:08:59Z
date available	2017-05-08T23:08:59Z
date copyright	June, 1963
date issued	1963
identifier issn	0021-8936
identifier other	JAMCAV-25708#269_1.pdf
identifier uri	http://yetl.yabesh.ir/yetl/handle/yetl/93434
description abstract	The drag of an adiabatic flat plate in an ionized gas for a constant magnetic field applied to the boundary layer on the plate is found by a momentum integral approximation of von Karman. Laminar, two-dimensional flow, zero pressure gradient, small magnetic Reynolds number, and negligible electrical conductivity outside the boundary layer are assumed. The solution is valid in particular to a continuous, perfect-gas plasma, of unitary Prandtl number, and for conditions when the interaction parameter is very small. The solution shows the following effects: The adiabatic wall temperature is independent of the magnetic field; there is an increase in the boundary-layer thickness as the magnetic-field strength is increased; and the viscous drag coefficient decreases whereas the coefficient of total drag increases.
publisher	The American Society of Mechanical Engineers (ASME)
title	The Momentum Integral Approximation for Compressible Magnetogasdynamic Boundary-Layer Flow
type	Journal Paper
journal volume	30
journal issue	2
journal title	Journal of Applied Mechanics
identifier doi	10.1115/1.3636523
journal fristpage	269
journal lastpage	274
identifier eissn	1528-9036
keywords	Flow (Dynamics)
keywords	Boundary layers
keywords	Approximation
keywords	Momentum
keywords	Magnetic fields
keywords	Drag (Fluid dynamics)
keywords	Reynolds number
keywords	Plasmas (Ionized gases)
keywords	Flat plates
keywords	Prandtl number
keywords	Pressure gradient
keywords	Thickness
keywords	Wall temperature AND Electrical conductivity
tree	Journal of Applied Mechanics:;1963:;volume( 030 ):;issue: 002
contenttype	Fulltext

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