Experimental and numerical study on a bubbling fluidized bed with wet particles

Wang, Tianyu; He, Yurong; Tang, Tianqi; Wang, Peng

doi:10.1002/aic.15195

Cited by 45 publications

(26 citation statements)

References 55 publications

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“…These results show qualitatively how cohesion due to liquid bridging makes it more difficult for bubbles to rise freely through beds, as it becomes more difficult to move particles relative to one another due to viscous and capillary forces. The decrease in speed of particles is consistent with previous studies in pseudo‐2D beds, a study using particle tracking to find average particle speed on a temporally unresolved level and a computational study of a 3D bed . The Supporting Information Video shows a set of videos of fluidization behavior for these dry and wet cases with values of U/U mf,dry and U/U mf,wet of 1.1, 1.3, and 1.5 to provide a fuller comparison.…”

Section: Resultssupporting

confidence: 85%

“…We are unaware of prior experimental studies which have been able to investigate the effects of liquid bridging on bubble size or number of bubbles in 3D beds, pointing to the power of MRI. Previous studies have found discrepancies in the effect of adding liquid on the amplitude and frequency of pressure oscillations; this discrepancy can be attributed to different fluidization conditions, as well as the fact that pressure oscillations result from a variety of changes in hydrodynamics. We are unaware of any experimental studies which have investigated the validity of maintaining the same value of U/U mf between wet and dry conditions, but the prior computational study of Boyce et al produced insights consistent with those in this article.…”

Section: Discussionmentioning

confidence: 99%

“…On a larger scale, this leads to greater heterogeneity in gas and particle flow, affecting many aspects of fluidization hydrodynamics, which in turn alters heat and mass transport as well as chemical reactions. Previous studies have shown that the addition of small amounts of liquid alters the oscillations in pressure drop across the bed, slows the speed of particles, and increases the minimum fluidization velocity . Studies have also sought to map the behavior of wet fluidized beds into regimes based on the amount of liquid added as well as the surface tension and viscosity of the liquid; these regimes have included shifts in the Geldart grouping of the particles and the growth or breakup of agglomerates .…”

Section: Introductionmentioning

confidence: 99%

“…Difficulties in fully understanding the effects of liquid bridging on fluidization hydrodynamics stem in part from a lack of temporally and spatially resolved experimental data on gas and particle motion in wet fluidized beds. Previous studies have been limited to device‐scale measurements, such as pressure oscillations and fluidization curves, measurements on pseudo‐2D fluidized beds using optical imaging and tomographic measurements on 3D beds of tracer particles, which are unable to capture behavior across the entire device on a temporally resolved level. In recent years, magnetic resonance imaging (MRI) has been able to generate detailed maps of both particle and gas motion in fluidized beds.…”

Section: Introductionmentioning

confidence: 99%

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Magnetic resonance imaging of gas–solid fluidization with liquid bridging

et al. 2017

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Magnetic resonance imaging is used to generate snapshots of particle concentration and velocity fields in gas-solid fluidized beds into which small amounts of liquid are injected. Three regimes of bed behavior (stationary, channeling, and bubbling) are mapped based on superficial velocity and liquid loading. Images are analyzed to determine quantitatively the number of bubbles, the bubble diameter, bed height, and the distribution of particle speeds under different wetting conditions. The cohesion and dissipation provided by liquid bridges cause an increase in the minimum fluidization velocity and a decrease in the number of bubbles and fast particles in the bed. Changes in liquid loading alter hydrodynamics to a greater extent than changes in surface tension or viscosity. Keeping U/U mf at a constant value of 1.5 produced fairly similar hydrodynamics across different wetting conditions. The detailed results presented provide an important dataset for assessment of the validity of assumptions in computational models.

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Section: Resultssupporting

confidence: 85%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Magnetic resonance imaging of gas–solid fluidization with liquid bridging

et al. 2017

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“…Nevertheless, due to the limitation of measurement methods, most of these researches focused on global and visual phenomenon, i.e. minimum fluidization [4,5], defluidization pattern [6], bubble behaviors [7,8], particle mixing [9] etc. Recently, lots of researchers made efforts for more insight into the fluidization dynamics of cohesive particles with the aid of advanced measurement approaches.…”

Section: Introductionmentioning

confidence: 99%

Fluidization dynamics of cohesive Geldart B particles. Part II: Pressure fluctuation analysis

Ommen

Liu

et al. 2019

Chemical Engineering Journal

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Growth and breakup of a wet agglomerate in a dry gas–solid fluidized bed

et al. 2017

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SignificanceUsing CFD‐DEM simulations, a wet agglomerate of particles was placed in a void region of a dry vigorously fluidized bed to understand how wet agglomerates grow or breakup and how liquid spreads when agglomerates interact with dry fluidized particles. In the CFD‐DEM model, cohesive and viscous forces arising from liquid bridges between particles were modeled, as well as a finite rate of liquid bridge filling. The liquid properties were varied between different simulations to vary Bond number (surface tension forces/gravitational forces) and Capillary number (viscous forces/surface tension forces) in the system. Resulting agglomerate behavior was divided into regimes of (i) the agglomerate breaking up, (ii) the agglomerate retaining its initial form, but not growing, and (iii) the agglomerate retaining its initial form and growing. Regimes were mapped based on Bo and Ca. Implications of agglomerate behavior on spreading of liquid to initially dry particles were investigated. This article identifies a new way to map agglomerate growth and breakup behavior based on Bo and Ca. In modeling both liquid forces and a finite rate of liquid transfer, it identifies the complex influence viscosity has on agglomeration by strengthening liquid bridges while slowing their formation. Viewing Ca as the ratio of bridge formation time to particle collision and separation time capture why agglomerates with high Ca struggle to grow. © 2017 American Institute of Chemical Engineers AIChE J, 63: 2520–2527, 2017

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Experimental and numerical study on a bubbling fluidized bed with wet particles

Cited by 45 publications

References 55 publications

Magnetic resonance imaging of gas–solid fluidization with liquid bridging

Magnetic resonance imaging of gas–solid fluidization with liquid bridging

Fluidization dynamics of cohesive Geldart B particles. Part II: Pressure fluctuation analysis

Growth and breakup of a wet agglomerate in a dry gas–solid fluidized bed

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