Luminescent barometry in wind tunnels

Abstract

A flexible and relatively inexpensive method and apparatus are described for continuous pressure mapping of aerodynamic surfaces using photoluminescence and imaging techniques. Platinum octaethylporphyrin (PtOEP) has a phosphorescence known to be quenched by oxygen. When dissolved in a silicone matrix, PtOEP may be distributed over a surface as a thin, uniform film. When the film is irradiated with ultraviolet light, the luminescence intensity provides a readily detectable, qualitative surface flow visualization. Moreover, since the luminescence intensity is found to be inversely proportional to the partial pressure of oxygen, a quantitative measure of pressure change may be obtained using a silicon target vidicon or a charge‐coupled device video sensor to measure intensity. Luminescent images are captured by a commercial frame buffer board. Images taken in wind tunnels during airflow are ratioed to images taken under ambient ‘‘wind‐off’’ conditions. The resulting intensity ratio information is converted to pressure using calibration curves of I₀/I vs p/p₀, where I₀ is the intensity at ambient pressure p₀ and I is the intensity at any other pressure p. The result is a two‐dimensional static pressure plot for the surface of interest. It is shown that the pressure plots predicted by luminescence intensity compare favorably with pressure plots made by conventional pressure measuring devices.