Single-particle behaviour in circulating fluidized beds

This paper describes an experimental investigation of single-particle behaviour in a cold pilot-scale model of a circulating fluidized bed combustor (CFBC). In the system, sand is recirculated by means of air. Pressure measurements along the riser are used to determine the suspension density. A radioactive tracking facility, which detects single radioactive particles, is developed and applied to determine the dynamic picture of the particle trajectories in the simulated boiler. The tracer particles are observed to move between the zone above and below the secondary air inlet with a mean frequency of about 1 Hz under the present operating conditions. This relatively high frequency is due to the fact that most of the particle trajectories take place just around the secondary air inlet. It is found that the upward particle velocity in the upper dilute transport zone decreases with the particle size or density, which results in a decreased number of particle observations for the larger particles with the riser height. The experiments show that the mean particle residence times in the zones above and below the secondary air inlet are almost independent of the particle characteristics. The overall mean particle residence time in the riser is proportional to the magnitude of the internal particle recirculation, which increases with the particle size.

[1]  Jan Erik Johnsson,et al.  Formation and reduction of nitrogen oxides in fluidized-bed combustion☆ , 1994 .

[2]  M. J. Rhodes,et al.  Modelling the flow structure of upward-flowing gas-solids suspensions , 1990 .

[3]  P. Hansen,et al.  High-temperature reaction between sulphur dioxide and limestone. V: The effect of periodically changing oxidizing and reducing conditions , 1993 .

[4]  P. A. Ambler,et al.  Residence time distribution of solids in a circulating fluidized bed: Experimental and modelling studies , 1990 .

[5]  C.M.H. Brereton,et al.  Modelling of circulating fluidised-bed solids flow and distribution , 1992 .

[6]  Derek Geldart,et al.  Interaction of fine and coarse particles in the freeboard of a fluidized bed , 1983 .

[7]  B. Leckner,et al.  Influence of SO2 on the NON2O chemistry in fluidized bed combustion: 2. Interpretation of full-scale observations based on laboratory experiments , 1993 .

[8]  Nicolas Kalogerakis,et al.  Modelling the internal flow structure of circulating fluidized beds , 1989 .

[9]  B. Leckner,et al.  Influence of SO2 on the NO/ N2O chemistry in fluidized bed combustion 1. Full-scale experiments , 1993 .

[10]  Filip Johnsson,et al.  Boundary layers---first measurements in the 12 MW CFB research plant at Chalmers University , 1991 .

[11]  Anders Lyngfelt,et al.  Sulphur capture in fluidized bed boilers: the effect of reductive decomposition of CaSO4 , 1989 .

[12]  Lone Aslaug Hansen,et al.  Alkali metals in a coal- and biomass-fired CFBC -- Measurements and thermodynamic modeling , 1995 .

[13]  Mooson Kwauk,et al.  The Dynamics of Fast Fluidization , 1980 .

[14]  K. Dam-Johansen,et al.  High-temperature reaction between sulphur dioxide and limestone—I. Comparison of limestones in two laboratory reactors and a pilot plant , 1991 .

[15]  Masayuki Horio,et al.  The Clustering Annular Flow Model of Circulating Fluidized Beds , 1989 .

[16]  O. Levenspiel,et al.  Drag coefficient and terminal velocity of spherical and nonspherical particles , 1989 .

[17]  Octave Levenspiel,et al.  Entrainment of solids from fluidized beds I. Hold-up of solids in the freeboard II. Operation of fast fluidized beds , 1990 .

[18]  H. Arastoopour,et al.  Particle—particle interaction force in a dilute gas—solid system , 1982 .