Numerical Simulation and Experimental Study of the Gas–Solid Flow Behavior Inside a Full-Loop Circulating Fluidized Bed: Evaluation of Different Drag Models

Xu, Yupeng; Musser, Jordan; Li, Tingwen; Gopalan, Balaji; Panday, Rupen; Tucker, Jonathan; Breault, Greggory; Clarke, Mary Ann; Rogers, William A.

doi:10.1021/acs.iecr.7b03817

Cited by 60 publications

(23 citation statements)

References 66 publications

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“…With the development of the model and computing capacity, more and more investigators conducted full-loop simulation of the CFB system [14][15][16][17][18][19][20][21][22], which treats the CFB as a whole dynamic system. Chu et al [14] conducted a 3D full-loop simulation for CFB by means of the combined continuum and discrete method.…”

Section: Introductionmentioning

confidence: 99%

Comparison of Riser-Simplified, Riser-Only, and Full-Loop Simulations for a Circulating Fluidized Bed

Wang

Shi

et al. 2019

Processes

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With the development of computing power, the simulation of circulating fluidized bed (CFB) has developed from riser-simplified simulation to riser-only simulation, then to full-loop simulation. This paper compared these three methods based on pilot-scale CFB experiment data to find the scope of application of each method. All these simulations, using the Eulerian–Eulerian two-fluid model with the kinetic theory of granular theory, were conducted to simulate a pilot-scale CFB. The hydrodynamics, such as pressure balance, solids holdup distribution, solids velocity distribution, and instantaneous mass flow rates in the riser or CFB system, were investigated in different simulations. By comparing the results from different methods, it was found that riser-simplified simulation is not sufficient to obtain accurate hydrodynamics, especially in higher solids circulating rates. The riser-only simulation is able to make a reasonable prediction of time-averaged behaviors of gas–solids in most parts of riser but the entrance region. Further, the full-loop simulation can not only predict precise results, but also obtain comprehensive details and instantaneous information in the CFB system.

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Section: Introductionmentioning

confidence: 99%

Comparison of Riser-Simplified, Riser-Only, and Full-Loop Simulations for a Circulating Fluidized Bed

Wang

Shi

et al. 2019

Processes

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“…The Eulerian–Lagrangian framework in MFiX suite of solver has been used to model the fluidization of sand and biomass in this work. The gas phase is described by volume averaged Navier–Stokes equations and solved by semi‐implicit method for pressure linked equations method.…”

Section: Numerical Models and Simulation Parametersmentioning

confidence: 99%

“…Due to the complexity of directly investigating biomass mixing with bed material under reacting conditions, mixing experiments under ambient room conditions are carried out. The gas pressure profiles are widely used to estimate the macroscale distributions of solids in fluidized beds . The electrical capacitance tomography sensors can provide an estimate of the mixing of biomass and sands based on the different permittivity of sand particles and biomass.…”

Section: Introductionmentioning

confidence: 99%

Experimental and numerical investigation of sands and Geldart A biomass co‐fluidization

Gao

et al. 2020

AIChE Journal

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This article investigated the fluidization of sands and small Geldart A biomass mixtures. The mixture fluidized like Geldart A type particles with a uniform bed expansion regime before bubbling. The video recorded color distance between pure sands and sands-biomass mixtures was used to estimate the sands-biomass mixing. The coarse-grained computational fluid dynamics-discrete element method with a hybrid drag model which couples the Syamlal-O'Brien drag and a filtered drag can capture the mixing while the simulation with Gidaspow drag predicted a segregated bed. The simulations were further validated with experimental measured pressure drops. The time averaged pressure drop equals the weight of the bed material, however, its fluctuation is about three times of the bed material fluctuation. K E Y W O R D S biomass, coarse-grained CFD-DEM, drag model, filtered model, fluidized bed

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“…Fluid-particle interaction forces are calculated using the fluid drag model, meaning that the motion of fluids and particles depends strongly on the drag model used. 8,9) The Ergun 10) and Di Felice 11) equations are often used to model drag forces in conventional CFD-DEM coupling simulations. The Ergun equation cannot be used in the high porosity range; hence, a combination of the Ergun and Wen-Yu 12) equations, the latter being a drag model for high porosity flows, has been used in the past studies.…”

Section: Introductionmentioning

confidence: 99%

Elementary-Volume-Scale Simulations of Inertial Flow in Sphere Pack: Improvement of Di Felice Drag Model in High Porosity

2020

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In this study, we studied the elementary volume (EV) size in pore scale simulations of flow in sphere packs and evaluated existing drag models in wide porosity range. The sphere packs in different porosities were modeled with the discrete-element method. Through a parametric study, we confirmed that as the EV size grows large, the simulated values of porosity, permeability and hydraulic tortuosity nearly converge to their respective constants. This trend agrees well with previously reported experimental and numerical results. Using the EV size determined by the parametric study, we simulated the inertial flow in sphere packs of porosity range between 0.3 and 0.95. We found that the simulated drag force disagreed drastically with the existing drag models for high porosity range. Accordingly, we improved the Di Felice equation suitable in high porosity range.

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Numerical Simulation and Experimental Study of the Gas–Solid Flow Behavior Inside a Full-Loop Circulating Fluidized Bed: Evaluation of Different Drag Models

Cited by 60 publications

References 66 publications

Comparison of Riser-Simplified, Riser-Only, and Full-Loop Simulations for a Circulating Fluidized Bed

Comparison of Riser-Simplified, Riser-Only, and Full-Loop Simulations for a Circulating Fluidized Bed

Experimental and numerical investigation of sands and Geldart A biomass co‐fluidization

Elementary-Volume-Scale Simulations of Inertial Flow in Sphere Pack: Improvement of Di Felice Drag Model in High Porosity

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