Goodarz Ahmadi - Department of Mechanical and Aeronautical Engineering Clarkson University Potsdam, NY ۱۳۶۹۹-۵۷۲۵, USA
Xinyu Zhang - Department of Mechanical and Aeronautical Engineering Clarkson University Potsdam, NY ۱۳۶۹۹-۵۷۲۵, USA
wei Chen - Department of Mechanical and Aeronautical Engineering Clarkson University Potsdam, NY ۱۳۶۹۹-۵۷۲۵, USA

An Eulerian-Lagrangian computational model for simulations of gas-liquid-solid flows in three–phase slurry reactors is developed. In this approach, the liquid flow is modeled using a volume-averaged system of governing equations, whereas motions of bubbles and particles are evaluated by Lagrangian trajectory analysis procedure. The two-way interactions between bubble-liquid and particle-liquid are included in the analysis. The discrete phase equations include drag, lift, buoyancy, and virtual mass forces. Particle-particle interactions and bubble-bubble interactions are accounted for by the hard particle model approach. The bubble coalescence is also included in the model. The predicted results are compared with the experimental data, and good agreement is obtained. The transient flow characteristics of the three-phase flow are studied and the effects of bubble size on variation of flow characteristics are discussed. The simulations show that the transient characteristics of the three-phase flow in a column are dominated by time-dependent staggered vortices. The bubble plumes move along the S-shape path and exhibit an oscillatory behavior. While particles are mainly located outside the vortices, some bubbles and particles are retained in the vortices. The bubble size significantly affects the characteristics of the three-phase flows and flows with larger bubbles appear to evolve faster.

Bubble Column – Three-Phase Flow – Computational Model – Trajectory Analysis