The Measurement of Turbulent Skin Friction with the Preston Tube
Author : Ingo Rechenberg
Publisher :
Page : 21 pages
File Size : 28,39 MB
Release : 1964
Category :
ISBN :
Author : Ingo Rechenberg
Publisher :
Page : 21 pages
File Size : 28,39 MB
Release : 1964
Category :
ISBN :
Author : Earl R. Keener
Publisher :
Page : 28 pages
File Size : 31,37 MB
Release : 1969
Category : Aerodynamics, Supersonic
ISBN :
Use of Preston tubes for measuring hypersonic turbulent skin friction.
Author : Jerry M. Allen
Publisher :
Page : 36 pages
File Size : 24,70 MB
Release : 1970
Category : Aerodynamics, Supersonic
ISBN :
Author : Amir Nassirharand
Publisher : LAP Lambert Academic Publishing
Page : 128 pages
File Size : 39,81 MB
Release : 2010-04
Category :
ISBN : 9783838339054
This publication develops the first correlation equation between the theoretical turbulent skin friction with Preston-tube measurements on a subsonic cone. Lecturers, scientists, and practicing engineers in the field of fluid dynamics should be interested in this development. The goals of this NASA sponsored research are in two fold: (1) to develop a new procedure which could be used to develop a correlation equation for correlating Preston-tube pressure measurements within turbulent boundary layers with the corresponding theoretical values of skin friction coefficient, and (2) to apply the procedure to a ten-degree cone in order to obtain the said correlation equation. The boundary layer conservation of mass, momentum, and energy equations are numerically solved. The inviscid pressure distribution is also numerically determined in order to specify the boundary conditions along the outer edge of the boundary layer. Finally, the Preston- tube pressure measurements are correlated to the corresponding theoretical skin friction coefficient values by means of a least-squares technique.
Author : Amir Nassirharand
Publisher :
Page : 248 pages
File Size : 16,14 MB
Release : 1981
Category :
ISBN :
Author : J. C. Westkaemper
Publisher :
Page : 13 pages
File Size : 27,34 MB
Release : 1964
Category : Skin friction (Aerodynamics)
ISBN :
This report summarizes work done on the use of the surface impact probe, or Preston tube, method of measuring skin friction in turbulent, compressible boundary layers. The theory for incompressible flow was extended to the case of adiabatic, compressible flow, and the extended theory was experimentally shown to be valid. It has also been demonstrated that the extension is applicable to adiabatic flow with moderate adverse pressure gradients. Experimental and theoretical efforts to apply the impact probe method to compressible flows with moderate, aerodynamic heating were only partially successful. (Author).
Author : Earl R. Keener
Publisher :
Page : 20 pages
File Size : 49,40 MB
Release : 1969
Category : Aerodynamics, Supersonic
ISBN :
Use of Preston tubes for measuring hypersonic turbulent skin friction.
Author : Donald W. Smith
Publisher :
Page : 44 pages
File Size : 25,38 MB
Release : 1959
Category : Compressibility
ISBN :
Experiment have been conducted to measure the local surface-shear stress and the average skin-friction coefficient in incompressible flow for a turbulent boundary layer on a smooth flat plate having zero pressure gradient. Data were obtained for a range of Reynolds numbers from 1 million to 45 million. The local surface-shear stress was measured by a floating-element skin-friction balance and also by a calibrated total head tube located on the surface of the test wall. The average skin-friction coefficient was obtained from boundary-layer velocity profiles.
Author : T. N. Stevenson
Publisher :
Page : 8 pages
File Size : 31,52 MB
Release : 1964
Category : Boundary layer
ISBN :
Author : Güttler, Andreas
Publisher : KIT Scientific Publishing
Page : 238 pages
File Size : 12,26 MB
Release : 2017-04-13
Category : Technology (General)
ISBN : 3731505029
The present work delivers a versatile, accurate and reliable wind tunnel facility that is particularly developed to test different flow control techniques for drag reduction in precisely adjustable test conditions. Skin friction changes of 0.4% are resolved, which is comparable to the most accurate reported studies in liquids. this high accuracy is verified through a comprehensive uncertainty analysis. Subsequently, various passive and active flow control strategies are investigated.