Gas Dispersion and Bubble-to-Emulsion Phase Mass Exchange in a Gas-Solid Bubbling Fluidized Bed: A Computational and Experimental Study

Knowledge of gas dispersion and mass exchange between the bubble and the emulsion phases is essential for a correct prediction of the performance of fluidized beds, particularly when catalytic reactions take place. Test cases of single rising bubble and a bubbling fluidized bed operated with a jet without a chemical reaction were studied in order to obtain fundamental insights in the prevailing mass transfer phenomena. Numerical simulations were carried out to predict the dispersion of tracer gas using a two-fluid model based on Kinetic Theory of Granular Flow (KTGF). The simulations of a single-bubble rising through an incipiently fluidized bed revealed that the assumptions often made in phenomenological models in the derivation of correlations for the mass transfer coefficient, mainly that the bubble diameter remains constant and that the tracer concentration is uniform in the bubble, are not valid. The predicted bubble-to-emulsion phase mass transfer coefficient showed good agreement with the estimated values from the literature correlations assuming additive convection-diffusion transport for different bubble sizes and different particle sizes, indicating the importance of the convective distribution even for relatively small particles. Experiments were carried out to measure the steady state concentration profiles of a tracer gas in a pseudo two-dimensional bubbling fluidized bed operated with a jet. The simulated steady state concentration profiles of the tracer gas agreed well the experimental measurements. The radial convection of the gas is significantly influenced by the bubble ‘throughflow’ and therefore depends upon the particle and bubble size. The experimental comparison of theoretical results was extended to study the influence of the jet velocity and the particle diameter on the radial dispersion of the tracer gas in the bed.

[1]  Reghan J. Hill,et al.  INERTIAL EFFECTS IN SUSPENSION AND POROUS-MEDIA FLOWS , 2001 .

[2]  S. Ergun Fluid flow through packed columns , 1952 .

[3]  Anuj Srivastava,et al.  Analysis of a frictional-kinetic model for gas-particle flow , 2003 .

[4]  M. Puncochár,et al.  The tortuosity concept in fixed and fluidized bed , 1993 .

[5]  C. Wen Mechanics of Fluidization , 1966 .

[6]  R. King 3 – Interaction between fluids and particles , 2002 .

[7]  D. Gidaspow Multiphase Flow and Fluidization: Continuum and Kinetic Theory Descriptions , 1994 .

[8]  R. Jackson,et al.  Gas‐particle flow in a vertical pipe with particle‐particle interactions , 1989 .

[9]  D. Gidaspow,et al.  A bubbling fluidization model using kinetic theory of granular flow , 1990 .

[10]  T. Chiba,et al.  Gas exchange between the bubble and emulsion phases in gas-solid fluidized beds , 1970 .

[11]  R. H. Fowler The Mathematical Theory of Non-Uniform Gases , 1939, Nature.

[12]  J. Jenkins,et al.  A theory for the rapid flow of identical, smooth, nearly elastic, spherical particles , 1983, Journal of Fluid Mechanics.

[13]  T. G. Cowling,et al.  The mathematical theory of non-uniform gases , 1939 .

[14]  J. Grace,et al.  Interphase mass transfer in an aggregative fluidized bed , 1978 .

[15]  C. Chavarie,et al.  Interphase mass transfer in a gas fluidized bed , 1976 .

[16]  M. Syamlal,et al.  A numerical model of silane pyrolysis in a gas-solids fluidized bed , 1998 .

[17]  S. Savage,et al.  Analyses of slow high-concentration flows of granular materials , 1998, Journal of Fluid Mechanics.

[18]  D. J. Gunn,et al.  Axial and radial dispersion in fixed beds , 1987 .

[19]  P. L. Bransby,et al.  THE MECHANICS OF SOILS, AN INTRODUCTION TO CRITICAL STATE SOIL MECHANICS , 1987 .

[20]  R. Jackson,et al.  Frictional–collisional constitutive relations for granular materials, with application to plane shearing , 1987, Journal of Fluid Mechanics.

[21]  Goodarz Ahmadi,et al.  An equation of state for dense rigid sphere gases , 1986 .