Abstract

To concentrate CO₂ in combustion processes by efficient and energy-saving ways is a first and very important step for its sequestration. Chemical looping combustion (CLC) could easily achieve this goal. A chemical-looping combustion system consists of a fuel reactor and an air reactor. Two reactors in the form of interconnected fluidized beds are used in the process: (1) a fuel reactor where the oxygen carrier is reduced by reaction with the fuel, and (2) an air reactor where the reduced oxygen carrier from the fuel reactor is oxidized with air. The outlet gas from the fuel reactor consists of CO₂ and H₂O, while the outlet gas stream from the air reactor contains only N₂ and some unused O₂. The water in combustion products can be easily removed by condensation and pure carbon dioxide is obtained without any loss of energy for separation.

Until now, there is little literature about mathematical modeling of chemical-looping combustion using the computational fluid dynamics (CFD) approach. In this work, the reaction kinetic model of the fuel reactor (CaSO₄+ H₂) is developed by means of the commercial code FLUENT and the effects of partial pressure of H₂ (concentration of H₂) on chemical looping combustion performance are also studied. The results show that the concentration of H₂ could enhance the CLC performance.

Recommended Citation

Jin, Baosheng; Xiao, Rui; Deng, Zhongyi; and Song, Qilei (2009) "Computational Fluid Dynamics Modeling of Chemical Looping Combustion Process with Calcium Sulphate Oxygen Carrier," International Journal of Chemical Reactor Engineering: Vol. 7: A19.
Available at: http://www.bepress.com/ijcre/vol7/A19