CFD analysis of bed textural characteristics on TBR behaviour: Kinetics, scaling‐up, multiscale analysis, and wall effects

Uribe, Sebastián; Cordero, Mario E.; Zárate, Luis Gonzaga Alonso; López, J. Javier; Natividad, Reyna

doi:10.1002/cjce.23298

Cited by 3 publications

(2 citation statements)

References 49 publications

(102 reference statements)

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“…Over the past several decades, there have been vast contributions in the study of trickle bed reactors (TBR) hydrodynamics [ 2‐8 ] and mass transfer [ 9‐14 ] phenomena in the literature. In these contributions, it has been recognized that the hydrodynamics of TBR, and therefore the multiphase interactions, play a determining role in the mass and heat transfer phenomena, kinetics, and performance throughput of these systems.…”

Section: Introductionmentioning

confidence: 99%

Development of a hybrid pressure drop and liquid holdup phenomenological model for trickle bed reactors based on two‐phase volume averaged equations

Uribe

Farid

et al. 2020

Can J Chem Eng

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A model with a high predictive quality to estimate pressure drops and liquid holdups in trickle bed reactors (TBR) is yet necessary to assist in design, up scaling, and the implementation of new processes tasks. The currently available models to estimate pressure drops and liquid holdups on TBRs exhibit important deviations, which lead to uncertainties in their applicability. To overcome the limitations in prediction deviations in the currently available models, a new model is developed based on the volume averaged two‐phase transport equations in a porous media, as developed by Whitaker. In order to develop a model that could simultaneously predict pressure drops and liquid holdup with a high accuracy, the developed model was coupled with a modification of the extended slit model reported in the literature, leading to a new hybrid model with enhanced predictability. Experimentally determined pressure drops and liquid holdup in a column with a 0.14 m internal diameter and a height of 2 m, packed with different extrudate geometries, cylinders, trilobes, and quadlobes, were used to determine the model parameters and to verify the quality of the proposed hybrid model predictions. The developed model, when compared with the experimentally determined data of pressure drops showed mean squared errors (MSE) of 0.89%, 2.31%, and 1.22% for the cylinders, trilobes, and quadlobes particles, respectively, while the liquid holdups were predicted with MSEs of 0.03%, 0.16%, and 0.01% for the cylinders, trilobes, and quadlobes particles, respectively.

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Section: Introductionmentioning

confidence: 99%

Development of a hybrid pressure drop and liquid holdup phenomenological model for trickle bed reactors based on two‐phase volume averaged equations

Uribe

Farid

et al. 2020

Can J Chem Eng

Self Cite

View full text Add to dashboard Cite

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“…Multiphase flow was an important theme in this special section with applications for oil transport, liquid‐liquid dispersion, flashing spray jets, solid‐fluid systems in rotating drums, trickle bed, and fluidized bed reactors, and agglomeration in cyclone separators . Mixing phenomena were reported in variety of geometries and on diverse length scales: in an agitated tubular reactor, in T‐shaped micromixers, and in fluidic oscillators .…”

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confidence: 99%

CFD in Chemical Engineering: Process Design Symposium at the 10^th World Congress of Chemical Engineering (WCCE10)

Nunhez¹,

Derksen²,

Ranade³

2019

Can J Chem Eng

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Modelling and validation of TBR Hydrodynamics: Local comparison between CFD and experiments

Uribe

Al-Ani

Cordero

et al. 2020

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CFD analysis of bed textural characteristics on TBR behaviour: Kinetics, scaling‐up, multiscale analysis, and wall effects

Cited by 3 publications

References 49 publications

Development of a hybrid pressure drop and liquid holdup phenomenological model for trickle bed reactors based on two‐phase volume averaged equations

Development of a hybrid pressure drop and liquid holdup phenomenological model for trickle bed reactors based on two‐phase volume averaged equations

CFD in Chemical Engineering: Process Design Symposium at the 10^th World Congress of Chemical Engineering (WCCE10)

Modelling and validation of TBR Hydrodynamics: Local comparison between CFD and experiments

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CFD analysis of bed textural characteristics on TBR behaviour: Kinetics, scaling‐up, multiscale analysis, and wall effects

Cited by 3 publications

References 49 publications

Development of a hybrid pressure drop and liquid holdup phenomenological model for trickle bed reactors based on two‐phase volume averaged equations

Development of a hybrid pressure drop and liquid holdup phenomenological model for trickle bed reactors based on two‐phase volume averaged equations

CFD in Chemical Engineering: Process Design Symposium at the 10th World Congress of Chemical Engineering (WCCE10)

Modelling and validation of TBR Hydrodynamics: Local comparison between CFD and experiments

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Product

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CFD in Chemical Engineering: Process Design Symposium at the 10^th World Congress of Chemical Engineering (WCCE10)