Three‐Dimensional Simulation of Hydrodynamics in a Rotating Disc Contactor using Computational Fluid Dynamics

Ghaniyari-Benis, S.; Hedayat, N.; Ziyari, A.; Kazemzadeh, M.; Shafiee, Mohammad Hossein

doi:10.1002/ceat.200800391

Cited by 17 publications

(10 citation statements)

References 17 publications

(23 reference statements)

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“…[39][40][41] This concept consists of solving of the continuity equation and momentum balance equation for each phase. In this formulation, the continuity equation of each phase has form…”

Section: Model Formulation Hydrodynamic Modelmentioning

confidence: 99%

Characterization of liquid‐liquid dispersions with variable viscosity by coupled computational fluid dynamics and population balances

Vonka

Šoóš

2015

AIChE Journal

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in Wiley Online Library (wileyonlinelibrary.com) Sustaining stable liquid-liquid dispersion with the desired drop size still relies on experimental correlations, which do not reflect our understanding of the underlying physics and have a limited prediction capability. The complex behavior of liquid-liquid dispersions inside a stirred tank, which is equipped with a Rushton turbine, was characterized by a combination of computational fluid dynamics and population balance equations (PBE). PBE took into account both the drop coalescence and breakup. With the increasing drop viscosity, the resistance to drop breakage also increases, which was introduced by the local criteria for drop breakup in the form of the local critical Webber number (We c ). The dependency of We c on the drop viscosity was derived from the experimental data available in the literature. Predictions of Sauter mean diameter agree well with the experimentally measured values allowing prediction of mean drop size as a function of variable viscosity, interfacial tension, and stirring speed.

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“…[39][40][41] This concept consists of solving of the continuity equation and momentum balance equation for each phase. In this formulation, the continuity equation of each phase has form…”

Section: Model Formulation Hydrodynamic Modelmentioning

confidence: 99%

Characterization of liquid‐liquid dispersions with variable viscosity by coupled computational fluid dynamics and population balances

Vonka

Šoóš

2015

AIChE Journal

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“…In literature, some good progress has been made in determining stirred column design parameters using CFD simulations both in single‐phase4–8 and two‐phase mode 9–13. Recent work has also dealt with liquid–liquid problems in pulsed extraction columns 14, 15.…”

Section: Introductionmentioning

confidence: 99%

“…Over the last years, the Euler–Euler approach emerged as the standard approach to model multiphase problems at higher hold‐up and was successfully applied to model stirred RDC extractors of various geometries 5, 10–12. The Euler–Lagrange approach, also known as the discrete phase model, is best used for flow regimes where the difference between the volume fractions of the two phases is large.…”

Section: Introductionmentioning

confidence: 99%

CFD simulations and particle image velocimetry measurements in an industrial scale rotating disc contactor

2010

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in Wiley Online Library (wileyonlinelibrary.com).Fluid dynamics of the single-phase and two-phase flow in a segment of a rotating disc contactor (RDC) liquid-liquid extraction column with 450 mm inner diameter were studied by performing computational fluid dynamics (CFD) simulations and particle image velocimetry (PIV) measurements. The fluid dynamics were investigated to test the predictivity of CFD at industrial scale. Different turbulence models in conjunction with the Eulerian approach were applied in the single-phase and two-phase simulations. The turbulent flow characteristics were analyzed by PIV measurements to validate the CFD simulations. An iso-optical system composed of CaCl 2 /water-butylacetate allows for the two-phase PIV measurements. Local turbulent energy dissipation was derived from velocity gradients in PIV data. In this connection, the influence of the PIV spatial resolution on the measured energy dissipation was also analyzed, and different fit functions were tested to scale the measured energy dissipation. Simulated velocity fields as well as the energy dissipation were compared with the experimental PIV data. The results from the simulations and experiments are in good agreement. The work shows that CFD can predict hydrodynamic characteristics even at bigger scales but is still subject to some minor restrictions.

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“…While significant research efforts have been made to understand the liquid–liquid separation in different equipment with supporting phenomenological models as well as empirical correlations, 2,4,5,13‐18 experimentally‐verified CFD models that are capable of simulating liquid–liquid separation are still being developed. Several researchers performed two‐fluid and multi‐fluid CFD simulations of dispersed liquid–liquid flow in various equipment such as stirred vessels, 23‐26 RDCs 27‐29 and pulsed‐sieve plate extraction columns 30 . In most of these simulations, they predicted the spatial distribution of dispersed phase volume fraction, average DSD, and velocity distributions inside these equipment.…”

Section: Introductionmentioning

confidence: 99%

Separation of liquid–liquid dispersion in a batch settler: CFD‐PBM simulations incorporating interfacial coalescence

Thaker

Buwa

2020

AIChE Journal

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Several commercially important chemical processes involve liquid-liquid phase separation. In the present work, we have developed a multi-fluid Eulerian CFD model using OpenFOAM that incorporates binary and interfacial coalescence processes. We simulated separation of kerosene dispersed in water in a batch settler and validated the predictions using the measurements of time-evolution of coalescing and settling interfaces, local dispersed-phase volume fraction (α O) and drop size distribution (DSD). Simulations are performed to understand the contributions of binary and interfacial coalescence processes to the phase separation process. While the timeevolution of coalescing and settling fronts can be predicted reasonably well using the two-fluid model with empirically-corrected drag models, local α O and DSD could not be predicted. We have shown that the comprehensive multi-fluid Eulerian model, which incorporates binary and interfacial coalescence, predicts the time-evolution of the coalescing and settling fronts, local α O and the DSD in an excellent agreement with the measurements.

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Three‐Dimensional Simulation of Hydrodynamics in a Rotating Disc Contactor using Computational Fluid Dynamics

Cited by 17 publications

References 17 publications

Characterization of liquid‐liquid dispersions with variable viscosity by coupled computational fluid dynamics and population balances

Characterization of liquid‐liquid dispersions with variable viscosity by coupled computational fluid dynamics and population balances

CFD simulations and particle image velocimetry measurements in an industrial scale rotating disc contactor

Separation of liquid–liquid dispersion in a batch settler: CFD‐PBM simulations incorporating interfacial coalescence

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