Abstract :
We demonstrate a ldquotrading time for signalrdquo approach for the measurement of species-specific optical transmission, in ambients rich in particulates, using the example case of a turbulent fluidized bed reactor. The method is introduced on the basis of Monte Carlo simulations, as well as analysis of experimental data, of beam propagation for a range of path lengths, and particle concentrations. In a particular embodiment for relative propane-concentration measurements, data is acquired only during gated time intervals of partial beam occlusion detected in real time. The digitized data streams from the signal and background beams is processed by algorithms performing gating, digital balanced detection, and dual wavelength ratiometry. This combination, implemented on inexpensive programmable hardware, results in at least an order of magnitude improvement in sensitivity.
Keywords :
Monte Carlo methods; fluidised beds; image sensors; light absorption; light transmission; measurement by laser beam; reactors (electric); Monte Carlo simulations; beam propagation; digital balanced detection; dual wavelength ratiometry; gated ratiometric detection; optical absorption measurements; partial beam occlusion; particle-containing ambients; propane-concentration measurements; species-specific optical transmission; trading time for signal approach; turbulent fluidized bed reactors; Absorption; Data analysis; Fluidization; Inductors; Optical propagation; Optical sensors; Particle beams; Particle measurements; Time measurement; Wavelength measurement; Fluidized beds; gated measurements; optical absorption measurements; particulate media; ratiometric detection;
