A generalized CFD model for evaluating catalytic separation process in structured porous materials

doi:10.1016/j.cjche.2021.12.004

Abstract

Abstract: A hybrid multiphase model is developed to simulate the simultaneous momentum, heat and mass transfer and heterogeneous catalyzed reaction in structured catalytic porous materials. The approach relies on the combination of the volume of fluid (VOF) and Eulerian–Eulerian models, and several plug-in field functions. The VOF method is used to capture the gas–liquid interface motion, and the Eulerian–Eulerian framework solves the temperature and chemical species concentration equations for each phase. The self-defined field functions utilize a single-domain approach to overcome convergence difficulty when applying the hybrid multiphase for a multi-domain problem. The method is then applied to investigate selective removal of specific species in multicomponent reactive evaporation process. The results show that the coupling of catalytic reaction and interface species mass transfer at the phase interface is conditional, and the coupling of catalytic reaction and momentum transfer across fluid–porous interface significantly affects the conversion rate of reactants. Based on the numerical results, a strategy is proposed for matching solid catalyst with operating condition in catalytic distillation application.

Key words: CFD (computational fluid dynamics), Hybrid multiphase model, SiC foam, Mass transfer, Catalytic distillation

摘要： A hybrid multiphase model is developed to simulate the simultaneous momentum, heat and mass transfer and heterogeneous catalyzed reaction in structured catalytic porous materials. The approach relies on the combination of the volume of fluid (VOF) and Eulerian–Eulerian models, and several plug-in field functions. The VOF method is used to capture the gas–liquid interface motion, and the Eulerian–Eulerian framework solves the temperature and chemical species concentration equations for each phase. The self-defined field functions utilize a single-domain approach to overcome convergence difficulty when applying the hybrid multiphase for a multi-domain problem. The method is then applied to investigate selective removal of specific species in multicomponent reactive evaporation process. The results show that the coupling of catalytic reaction and interface species mass transfer at the phase interface is conditional, and the coupling of catalytic reaction and momentum transfer across fluid–porous interface significantly affects the conversion rate of reactants. Based on the numerical results, a strategy is proposed for matching solid catalyst with operating condition in catalytic distillation application.

关键词: CFD (computational fluid dynamics), Hybrid multiphase model, SiC foam, Mass transfer, Catalytic distillation

Anshi Hong, Zisheng Zhang, Xingang Li, Xin Gao. A generalized CFD model for evaluating catalytic separation process in structured porous materials[J]. Chinese Journal of Chemical Engineering, 2022, 51(11): 168-177.

Anshi Hong, Zisheng Zhang, Xingang Li, Xin Gao. A generalized CFD model for evaluating catalytic separation process in structured porous materials[J]. 中国化学工程学报, 2022, 51(11): 168-177.

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