A review of recent NASA Langley Research Center experimental aerothermodynamic contributions to slender and winged hypersonic flight programs is presented. Significant findings and lessons learned are highlighted and discussed for a range of high profile national flight programs. In many cases, the experimental results are shown to be crucial to the success of these programs. To assure success with future hypersonic flight programs, experimental aerothermodynamic facilities will be required to provide invaluable support both pre--and post--flight.
The effects of fin leading-edge radius and sweep angle on peak heating rates due to shock-shock interactions were investigated in the NASA Langley Research Center 20-Inch Mach 6 Air Tunnel. The cylindrical leading-edge fin models, with radii varied from 0.25 to 0.75 inches, represent wings or struts on hypersonic vehicles. A 9° wedge generated a planar oblique shock at 16.7° to the flow that intersected the fin bow shock, producing a shockshock interaction that impinged on the fin leading edge. The fin sweep angle was varied from 0° (normal to the free-stream) to 15° and 25° swept forward. These cases were chosen to explore three characterized shock-shock interaction types. Global temperature data were obtained from the surface of the fused silica fins using phosphor thermography. Metal oil flow models with the same geometries as the fused silica models were used to visualize the streamline patterns for each angle of attack. High-speed zoom-schlieren videos were recorded to show the features and any temporal unsteadiness of the shock-shock interactions. The temperature data were analyzed using a one-dimensional semi-infinite method, as well as one-and two-dimensional finite-volume methods. These results were compared to determine the proper heat transfer analysis approach to minimize errors from lateral heat conduction due to the presence of strong surface temperature gradients induced by the shock interactions. The general trends in the leading-edge heat transfer behavior were similar for each explored shock-shock interaction type regardless of the leading-edge radius. However, the dimensional peak heat transfer coefficient augmentation increased with decreasing leading-edge radius. The dimensional peak heat transfer output from the two-dimensional code was about 20% higher than the value from a standard, semi-infinite one-dimensional method.
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