High temperature CO2 capture in lithium orthosilicate packed fluidized bed: Gamma ray densitometry based numerical model and its experimental validation.

• Application of pure Li 4 SiO 4 packed fluidized bed for high temperature CO 2 capture. • Gamma ray densitometry to obtain real-time dynamics of packed fluidized particles. • Numerical model based on experimental results of Gamma ray densitometry experiments. • Effective thermal conductivity doubles after operating in packed fluidization mode. • Total solid weight gain in packed fluidized bed 120% that of unary packed bed. Lithium orthosilicate (Li 4 SiO 4) is steadily emerging as the default solid sorbent for high temperature CO 2 capture in industrial settings. Li 4 SiO 4 is also one the few materials qualified to serve as both catalyst and sorbent in sorption enhanced steam reforming process for high purity carbon neutral H 2 production. Application of packed fluidization technique to enhance CO 2 uptake in packed bed of pure Li 4 SiO 4 particles has not been reported until now. Gamma ray densitometry (GRD) technique is employed to non-intrusively obtain average voidage of Li 4 SiO 4 packed fluidized bed as a function of operating time and axial bed coordinate. Based on the experimental results of GRD technique, a numerical model is developed to obtain the transient cross-sectional profiles of internal bed temperature and gas phase CO 2 concentration as high temperature carbonation of Li 4 SiO 4 progresses in packed fluidized bed. The numerical model is validated using experimentally obtained internal bed temperature and breakthrough curves. Temporal variation of bed effective thermal conductivity has been evaluated from model temperature profiles. It was observed that the time averaged effective thermal conductivity and net solid weight gain of packed fluidized bed is around 1.7–2.3 and 1.1–1.3 times that of unary packed bed respectively at specified process parameters for high temperature CO 2 capture. Comparative plot for net solid weight gain and time averaged effective thermal conductivity (ETC) in lithium orthosilicate packed fluidized bed and unary packed bed [Display omitted] [ABSTRACT FROM AUTHOR]