APPLICATION OF OPTICAL TECHNIQUES TO THE STUDY OF PLUMES IN STRATIFIED FLUIDS

Digital techniques for the correction of signal distortions that arise in planar laser-induced fluorescence (PLIF) measurements (by PC-based video digitizing systems) of jets and plumes and the production of fl ow statistics in both time and space are reviewed. The entire concentr ation field is repeatedly imaged in 1/30 s intervals over hundreds of thousands of points in a plane. By the recognition of signal distortio n sources and the employment of corrections, a clearer picture of trac er concentrations may be realized. Fluorescence studies are made with a planar sheet of laser light 430 mm tall and 1.5 mm thick. The fluore scence excitation produced from trace concentrations of Rhodamine 6G i s used to visualize and measure the propagation of a jet or plume in a density stratified laboratory tank. The emitted light is collected by a CCD camera in a 512 x 480 pixel format over a 940 x 715 mm field of view. The captured images are corrected for transverse laser sheet in tensity distribution; laser beam attenuation; refraction; lens vignett e; time varying and spatial noise; digitization aspect ratio; camera r esponse. The measurement and methods of correction are discussed in de tail. The resulting image data can then be used to collect tracer conc entration statistics for jets and plumes. Instantaneous (i.e. over 1/3 0th of a second intervals), average, maximum, minimum, standard deviat ion, and coefficient of variation are given as introductory examples o f image statistics realizable for a buoyant jet.