Study of CO 2 desublimation during cryogenic carbon capture using the lattice Boltzmann method

Cryogenic carbon capture (CCC) can preferentially desublimate CO 2 out of the flue gas. A widespread application of CCC requires a comprehensive understanding of CO 2 desublimation properties. This is, however, highly challenging due to the multiphysics behind it. This study proposes a lattice Boltzmann (LB) model to study CO 2 desublimation on a cooled cylinder surface during CCC. In two-dimensional (2-D) simulations, various CO 2 desublimation and capture behaviours are produced in response to different operation conditions, namely, gas velocity (Péclet number Pe ) and cylinder temperature (subcooling degree (cid:2) T sub ). As Pe increases or (cid:2) T sub decreases, the desublimation rate gradually becomes insufficient compared with the CO 2 supply via convection/diffusion. Correspondingly, the desublimated solid CO 2 layer (SCL) transforms from a loose (i.e. cluster-like, dendritic or incomplete) structure to a dense one. Four desublimation regimes are thus classified as diffusion-controlled, joint-controlled, convection-controlled and desublimation-controlled regimes. The joint-controlled regime shows quantitatively a desirable CO 2 capture performance: fast desublimation rate, high capture capacity, and full cylinder utilization. Regime distributions are summarized on a Pe – (cid:2) T sub space to determine operation parameters for the joint-controlled regime. Moreover, three-dimensional simulations demonstrate four similar

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