Parallel LES-DEM simulation of dense flows in fluidized beds

Simulations of gas-solid fluidized beds have been carried out using a hybrid simulation method, which couples the discrete element method (DEM) for particle dynamics with the ensemble-averaged two-fluid (TF) equations for the fluid phase. The coupling between the two phases is modeled using an interphase momentum transfer term. The results of the hybrid TF-DEM simulations are compared to experimental data and two-fluid model simulations. It is found that the TF-DEM simulation is capable of predicting general fluidized bed dynamics, i.e., pressure drop across the bed and bed expansion, which are in agreement with experimental measurements and two-fluid model predictions. In addition, the TF-DEM model demonstrates the capability to capture more heterogeneous structural information of the fluidized beds than the two-fluid model alone. The microstructures in fluidized beds are analyzed and the implications to kinetic theory for granular flows are discussed. However, the TF-DEM simulations depend on the form of the interphase momentum transfer model, which can be computed in terms of averaged or instantaneous particle quantities. Various forms of the interphase momentum transfer model are examined, and their suitability to the hybrid TF-DEM simulation approach is evaluated.

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Effect of Pressure Drop of Distributor on Flow Pattern in 2-D Fluidized Bed: DEM Simulation and Experiment

Volume 1: Fora, Parts A, B, C, and D ◽

10.1115/fedsm2003-45729 ◽

2003 ◽

Author(s):

Toshihiro Kawaguchi ◽

Yunosuke Mizushima ◽

Toshitsugu Tanaka ◽

Yutaka Tsuji

Keyword(s):

Pressure Drop ◽

Discrete Element Method ◽

Flow Pattern ◽

Fluidized Bed ◽

Particle Motion ◽

Fluidized Beds ◽

Gas Flows ◽

Dem Simulation ◽

Effect Of Pressure ◽

Simulation And Experiment

In the present study, effects of pressure drop across a distributor on particle motion in fluidized beds are studied numerically and empirically. The discrete element method (DEM) is employed to calculate the motion of individual particle. The predicted pressure drop across the distributor required to achieve uniform gas flows agreed well with previous empirical findings.

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APPLICATION OF THE LINEAR SPRING-DASHPOT MODEL IN THE CFD-DEM SIMULATION OF ALUMINA FLUIDIZATION

Revista de Engenharia Térmica ◽

10.5380/reterm.v14i2.62141 ◽

2015 ◽

Vol 14 (2) ◽

pp. 95

Author(s):

A. M. C. Branco Jr ◽

A. L. A. Mesquita ◽

J. R. P. Vaz

Keyword(s):

Experimental Data ◽

Fluidized Beds ◽

Limiting Factors ◽

Uniform Size ◽

Ansys Fluent ◽

Dem Simulation ◽

Linear Spring ◽

Computational Fluid Dynamics Cfd ◽

Drag Models ◽

Particle Approach

The coupling of the Computational Fluid Dynamics (CFD) to the Discrete Element Method (DEM) to simulate fluidization is computationally demanding. Although the Linear Spring-Dahspot (LSD) model can help to reduce the CFD-DEM simulation runtime due to its simplicity, its applicability is not reasonable for all sorts of problems. The objective of the present work is to show the application of the LSD model to the CFD-DEM simulation of alumina fluidization. The simulations were carried out with the software ANSYS FLUENT 14.5 and divided into two parts: (1) the reproduction with ANSYS FLUENT of simulations from the literature in which the LSD model and a representative particle approach were used. (2) the simulation of alumina fluidization and validation with experimental data. The results of three main sets of parameters were analysed to include different DEM and CFD time steps, drag models, the representation of particles with both uniform size and particle size distribution, etc. The main conclusion of this work is that the LSD model and the CFD-DEM approach can be used to model the actual behaviour of alumina fluidized beds, but the high simulation runtime and the correct setting of the strategies used to control it are still limiting factors which deserve special attention.

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