Optical detection system and method for determining particle size distribution in an oscillating flow field

Abstract

An optical detection system and method is disclosed comprising a first light guide for conveying light energy from a light source to a first light guide face end that is immersed in a dispersant medium. A first portion of the light energy exits the face end to irradiate particles contained in the dispersant medium and a second portion of the light energy is reflected by the face end back into the first light guide. A frequency transducer mounted to the first light guide receives at least one specific frequency from a range of frequencies generated by a frequency oscillator and oscillates the first light guide face end at the applied specific frequency. The transducer oscillations are further coupled into the dispersant medium, causing the dispersant medium and the particles contained therein to oscillate at the oscillation frequency of the first light guide face end. The light energy scattered by the oscillating particles is captured by the first light guide face end and is mixed within the first light guide with the reflected light energy, producing an optical Doppler beat signal for the applied specific frequency. A second light guide, optically connected to the first light guide, conveys the optical Doppler beat signal to a light detection device that produces an output signal representative of the optical Doppler beat signal. A mixer circuit receives the specific frequency signal from the frequency oscillator and the output signal from the detection device and produces a plurality of derived harmonics for the input specific frequency signal. The mixer circuit further generates frequency components for the input Doppler beat signal producing a total power value signal for each derived harmonic of the frequency. The total power value signals are applied to a signal processing system that calculates a particle motion amplitude signal for each applied specific frequency. The particle motion amplitude signal is used to determine the percentage of the total particles which are following the oscillations of the dispersant fluid at the applied specific frequency.