Interferometric Rayleigh Scattering and PIV Measurements in the Near Field of Underexpanded Sonic Jets

Abstract

∗ Assistant Professor, Member AIAA † Professor, Senior Member AIAA ‡ Vice President, Associate Fellow AIAA ABSTRACT Velocity measurements were made in the near field of underexpanded sonic air jets using particle image velocimetry (PIV), interferometric Rayleigh scattering and total pressure tubes. The two main objectives were to study the effect of underexpansion ratio on the flow structure and to determine the suitability of the PIV technique in high-speed flows with shock waves. The jets were produced by a convergent nozzle connected to a settling chamber. Different underexpansion conditions were obtained by changing the chamber (jet total) pressure against the atmospheric ambient. Jet exit-toambient pressure ratios, u = pe/pa, ranged between 1 and 20.32 corresponding to fully-expanded jet Mach numbers between Mj = 1 and 3.03. The PIV measurements of the streamwise and transverse velocities in the near field up to x/D = 10 (where D is the nozzle diameter) were made. From these data, distributions of mean velocities, turbulence intensities and turbulent shear stress were obtained. In order to check the accuracy of the PIV measurements (particularly, the particle lag effects) an interferometric Rayleigh scattering technique was also used to obtain the streamwise velocity for certain jet conditions. Additionally, some pressure measurements were made using a total pressure tube to provide a comparison with the two optical techniques. In general, the PIV method provided good velocity data in the jet near field and allowed the identification of flow structures and their respective locations such as shock waves, expansion regions, slip lines and shear layers. However, when compared to the Rayleigh scattering data, the effect of particle inertia was evident in certain locations in the jets. This effect was most dramatic just downstream of the Mach disk (barrel shock) in the case of highly underexpanded jets.