EMMS-based Eulerian simulation on the hydrodynamics of a bubbling fluidized bed with FCC particles

Although great progress has been made in modeling the bubbling fluidization of Geldart B and D particles using standard Eulerian approach, recent studies have shown that suitable sub-grid scale models should be introduced to improve the simulation on the hydrodynamics of Geldart A particles. In this study, the flow structures inside a bubbling fluidized bed of FCC particles are simulated in an Eulerian approach employing the energy minimization multi-scale (EMMS) model (Chemical Engineering Science, 2008, 63: 1553–1571) as the sub-grid scale model for effective inter-phase drag force, using an implicit cluster diameter expression. It was shown that the experimentally found axial and radial solid concentration profiles and radial particle velocity profiles can be well reproduced.

Graphical abstractEulerian simulations are performed to study the flow structures inside a bubbling fluidized bed of FCC particles, where the energy minimization multi-scale (EMMS) model is used as the sub-grid scale model for effective inter-phase drag force. It is shown that the experimentally found axial and radial solid concentration profiles and radial particle velocity profiles can be well reproduced.Figure optionsDownload full-size imageDownload as PowerPoint slide