Modelling of sulfur retention in circulating fluidized bed combustors

A mathematical model is developed to evaluate the performance of sulfur retention by limestone in circulating fluidized beds. The model considers particle movement and attrition, calcination and initial pore size distribution, pore plugging and cyclone performance. Percolation scaling theory is used

To optimise the circulating fluidized bed coal combustion (CFBC) with sorbent addition and make predictions about the eombustor behaviour in a broad range of operating conditions it is necessary to make a mathematical model of the process. This model was developed integrating hydrodynamic and sulpha

## Abstract A reactor model is presented to calculate the sulfur retention and SO~2~ emission of a fluidized‐bed coal combustor with absorption of SO~2~ by limestone or dolomite. It is based on the two‐phase theory of fluidization and a two parameter simplified rate expression for the sulfation rea

A mathematical model to describe a circulating fluidized-bed combustor is presented. A modified two-phase model which was used in the bubbling fluidized-bed combustor is considered to simulate the dense zone of the bottom section. For the upper section of the bed the momentum and energy-balance equa

The effects of operating conditions (coal particle size, temperature, excess air and linear gas velocity) on carbon combustion efficiency in a circulating fluidized bed combustor were studied. The operating conditions affected the combustion efficiency of each coal differently. To explain this, a ma