The transition to aeration in turbulent two-phase mixing in stirred vessels

Kahouadji, Lyes; Liang, Fuyue; Valdés, Juan Pablo; Shin, Seungwon; Chergui, Jalel; Jurić, Damir; Matar, Omar

doi:10.1017/flo.2022.24

Cited by 5 publications

(2 citation statements)

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“…The water flow is characterised by a high level of turbulence involving the development of a multitude of vortices of varying scales. Similar behaviour in the water phase was demonstrated by Kahouadji et al. (2022) who carried out simulations of air–water mixing in stirred vessels.…”

Section: Resultssupporting

confidence: 78%

“…Mass is conserved to within in all of our simulations. Our numerical procedure (Shin et al., 2018) has also been employed to simulate aeration in gas–liquid mixing (Kahouadji et al., 2022), vortex-interface dynamics and dispersion formation in turbulent water jets injected into an oil medium (Constante-Amores, 2021; Constante-Amores et al., 2021b, 2020b), the breakup of ligaments (Constante-Amores et al., 2020a), the coalescence of drops with interfaces (Constante-Amores et al., 2021a), the bursting of bubbles through interfaces (Constante-Amores et al., 2021c) and the dynamics of falling films (Batchvarov et al., 2020). We have also carried out a validation study against the experimental work of Hančil and Rod (1988); the results are in the Supplementary Information.…”

Section: Simulation Configuration and Methodsmentioning

confidence: 99%

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Numerical study of oil–water emulsion formation in stirred vessels: effect of impeller speed

Liang

Kahouadji

Valdés

et al. 2022

Flow

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The mixing of immiscible oil and water by a pitched blade turbine in a cylindrical vessel is studied numerically. Three-dimensional simulations combined with a hybrid front-tracking/level-set method are employed to capture the complex flow and interfacial dynamics. A large eddy simulation approach, with a Lilly–Smagorinsky model, is employed to simulate the turbulent two-phase dynamics at large Reynolds numbers $Re=1802{-}18\ 026$ . The numerical predictions are validated against previous experimental work involving single-drop breakup in a stirred vessel. For small $Re$ , the interface is deformed but does not reach the impeller hub, assuming instead the shape of a Newton's Bucket. As the rotating speed increases, the deforming interface attaches to the impeller hub which leads to the formation of long ligaments that subsequently break up into small droplets. For the largest $Re$ studied, the system dynamics becomes extremely complex wherein the creation of ligaments, their breakup and the coalescence of drops occur simultaneously. The simulation outcomes are presented in terms of spatio-temporal evolution of the interface shape and vortical structures. The results of a drop size analysis in terms of the evolution of the number of drops, and their size distribution, is also presented as a parametric function of $Re$ .

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Section: Resultssupporting

confidence: 78%