Modeling hydrodynamics of gas–liquid airlift reactor

Talvy, Samuel Lucien; Cockx, Arnaud; Liné, Alain

doi:10.1002/aic.11078

Cited by 55 publications

(45 citation statements)

References 23 publications

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“…This post-processing can lead to significant loss of information. Talvy et al (2007) proposed an alternative method based on the expression of the different contributions to axial dispersion as function of the velocity and the concentration fields (i.e. molecular diffusion, temporal dispersion and spatial dispersion) (Talvy et al, 2007;Le Moullec et al, 2008).…”

Section: Methodsmentioning

confidence: 99%

“…Talvy et al (2007) proposed an alternative method based on the expression of the different contributions to axial dispersion as function of the velocity and the concentration fields (i.e. molecular diffusion, temporal dispersion and spatial dispersion) (Talvy et al, 2007;Le Moullec et al, 2008). Therefore, axial dispersion coefficient can be estimated from simulations solving the continuity equation, Navier-Stokes equations and the transport equation of a tracer.…”

Section: Methodsmentioning

confidence: 99%

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A new numerical method for axial dispersion characterization in microreactors

Moreau¹,

Raimondi²,

Sauze³

et al. 2017

Chemical Engineering Science

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new numerical method for axial dispersion characterization in microreactors.(2017) Chemical Engineering Science, vol. 168. pp. 178-188. ISSN 0009-2509 Open Archive TOULOUSE Archive Ouverte (OATAO) OATAO is an open access repository that collects the work of Toulouse researchers and makes it freely available over the web where possible. h i g h l i g h t sAn innovative numerical method for axial dispersion characterization is proposed. The method is validated thanks to a RTD experiment in a microchannel. The method is applied to rectangular millimetric wavy channels. The impact of the channel geometry on the axial dispersion coefficient is studied. Keywords:Axial dispersion Numerical method CFD simulations Microreactor Wavy channel a s t r a c t Axial dispersion is a key phenomenon in reactor engineering that can affect yield and selectivity when reactions are carried out. Therefore its characterization is necessary for an adequate modelling of the reactor. The development of compact reactors to fit with process intensification expectations requires the use of characterization methods adapted to small-scale devices. An original method not-frequently used up to now for the estimation of axial dispersion coefficients is presented and applied to millimetric wavy channels. It is based on CFD simulations to calculate velocity and concentration fields from which axial dispersion coefficient can be estimated. This method is used to predict the impact of the wavy channel geometry and of the fluid velocity on axial dispersion in laminar flow regime. The investigated geometrical parameters are the hydraulic diameter (2-4 mm), the cross-sectional aspect ratio defined as the ratio between the channel width and its depth (0.25-1) and the internal curvature radius of the bends (2-3.4 mm). The range of Reynolds number considered is Re = 70-1 600. Axial dispersion coefficient increases with velocity, values range from 2.8 Á 10 À4 to 3.2 Á 10 À3 m 2 Ás À1. It appears that axial dispersion varies slightly in function of the channel hydraulic diameter. Square wavy channels generate less axial dispersion than rectangular wavy ones. Finally, axial dispersion coefficient increases with the internal curvature radius which shows the positive impact of sharp bends to reduce axial dispersion effect.

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Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

A new numerical method for axial dispersion characterization in microreactors

Moreau¹,

Raimondi²,

Sauze³

et al. 2017

Chemical Engineering Science

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show abstract

“…As of current, no universal set of closure models have been concluded for bubbly flow in an airlift reactor although a diverse set of closure models have been proposed across literature [19][20][21][22]. These closure models which composed of interfacial momentum forces can be divided down further as drag and non-drag forces.…”

Section: Introductionmentioning

confidence: 99%

“…Hence, comparison studies have been conducted over the decade to evaluate the sensitivity of these drag models on local hydrodynamics. A study carried out in an internal-loop airlift reactor have shown superior performance through the drag model Karamanev and Nikolov (1992) as a function of Reynolds number when compared with other models governed by Eötvös number [19]. Another study showed that the combination of both Reynolds and Eötvös number (i.e.…”

Section: Introductionmentioning

confidence: 99%

Experimental measurement and CFD simulation on the hydrodynamics of an internal-loop airlift reactor

2017

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Abstract. This paper concerns with the experimental measurement and computational fluid dynamics simulation on local hydrodynamics of a gas-liquid internal-loop airlift reactor. The aim of this work is to study the sensitivity of the drag models and the significance of considering the lift force on the predictive accuracy of the simulation. The experimental analysis was carried out using laser Doppler anemometry at three different heights (i.e. Y = 0.20 m, 0.30 m and 0.38 m) across the riser and downcomer at volumetric flow rate of 0.30 m 3 /h to provide validation for the simulation results. A transient three-dimensional gasliquid internal-loop airlift reactor was carried out using FLUENT 16.2 by implementing the two-fluid model approach. The Eulerian-Eulerian multiphase and standard k-İ dispersed turbulence model were employed in this study. Results suggest that the spherical drag model performed poorly and that the drag model governed by Rayleigh-Taylor shows promising accuracy in the prediction of overall mean axial liquid velocity. On the other hand, the consideration of lift model shows slightly improvement in accuracy. These findings may serve as a guidance for future scale-up and design of airlift reactor studies

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“…For bubble sizes above 3×10 -3 m they have reported correction factors above 1.1. Talvy et al (2007b) have shown that the ellipsoidal shape of the bubbles seems to be significant in estimation of the drag coefficient. When these correlations are improved and become applicable at various temperatures, then the dimensionless temperature ratio in Eq.…”

mentioning

confidence: 99%