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The effect of an asymmetric transition on wall shear stress is presented. It is shown that the Magnus force and moment can be substantially changed due to the shear stress contribution for the mixed boundary layer case on a spinning body. Comparison is made with the Magnus contributions due to pressure forces indicating the shear stress can account for as much as fifty percent or more of the total side force and moment. Some experimental data are analyzed to illustrate the trends predicted. (Author).
The effect of an asymmetric transition on wall shear stress is presented. It is shown that the Magnus force and moment can be substantially changed due to the shear stress contribution for the mixed boundary layer case on a spinning body. Comparison is made with the Magnus contributions due to pressure forces indicating the shear stress can account for as much as fifty percent or more of the total side force and moment. Some experimental data are analyzed to illustrate the trends predicted. (Author).
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An experimental investigation of the effects of spin induced distortion of the boundary-layer on a spinning cone and tangent-ogive-cylinder model for small angle of attack at Mach 2, 3 and 4 is reported. The profile of the location of boundary-layer transition has been determined completely about the surface of the models from spark shadowgraphs. These spark shadowgraphs were taken with the model mounted on an offset strut which was rolled incrementally in azimuth to reveal the entire surface of the model. Strain gage balance measurements of Magnus and normal force were made for three significantly different boundary-layer configurations--predominately laminar, predominately turbulent, tripped to turbulent--and confirm the pronounced sensitivity of Magnus to boundary-layer configuration. (Author).