Velocity Profiling of a Gas–Solid Fluidized Bed Using Electrical Capacitance Volume Tomography

Abstract

In this work, a method of producing velocity profile maps from electrical capacitance volume tomography (ECVT) measurements by reconstructing displacement from measured changes in capacitance is developed and applied to fluidized bed systems. The mapping of the reconstruction leverages the gradient of the sensitivity distribution of the ECVT sensor to circumvent the need for image cross-correlation techniques. Experimental data of both bubbling and slugging fluidized beds are collected in a cold flow model. Adaptation of the technique is discussed in detail and velocity profiles are obtained for a range of gas flow rates. The produced velocity maps are compared against the established methods of cross-correlation and against empirical correlations from literature and are found to agree well in tracking slug and bubble velocity. The exception is when the tracked object is large relative to the ECVT sensor dimensions, a scenario that can be avoided through proper sensor design. The quantities of average velocity, momentum, and solids and gas volume fraction are derived from the image and velocity profiles. The results demonstrate and extend the power of ECVT as a measurement tool for the study and monitoring of gas-solid fluidized beds by providing a computationally cheaper alternative to 3-D cross-correlation for deriving velocity profiles.