Interface‐resolved simulations of normal collisions of spheres on a wet surface

Tang, Yali; Buck, Britta; Heinrich, Stefan; Deen, NG Niels; Kuipers, J.A.M.

doi:10.1002/aic.15847

Cited by 15 publications

(3 citation statements)

References 56 publications

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“…The results of CoR agree well with experiments, however the formation of the liquid bridge did not. Hence, Tang et al (2017) extended this VOF/IB model by further implementing a tensile force model and a contact model. This led to a much better agreement between model and experiments regarding the overall collision dynamics including liquid bridge shape and lifetime as well as the dependence of the CoR on several parameters (collision velocity, layer thickness, liquid viscosity, surface tension).…”

Section: Introductionmentioning

confidence: 99%

Numerical investigation of collision dynamics of wet particles via force balance

Buck

Lunewski

Tang

et al. 2018

Chemical Engineering Research and Design

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Section: Introductionmentioning

confidence: 99%

Numerical investigation of collision dynamics of wet particles via force balance

Buck

Lunewski

Tang

et al. 2018

Chemical Engineering Research and Design

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“…While the Coefficient of Restitution results correlated well with experiments, the model faced challenges in accurately representing the formation of the liquid bridge. Subsequently, Tang et al extended this VOF/IB model by incorporating a tensile force model and a contact model to address these limitations. Yuan et al employed the Euler–Euler two-fluid model (TFM) in conjunction with the Kinetic Theory of Granular Flow (KTGF) method, introducing a model for the dynamic recovery coefficient of wet particles that considers the impact of liquid film.…”

Section: Introductionmentioning

confidence: 99%

Insights into the Impact of Small Particle Liquid Film on the Spatiotemporal Distribution of Suspension in Stirred Reactors

Chen,

Ouyang,

et al. 2024

Ind. Eng. Chem. Res.

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The liquid film has a significant impact on solid− liquid interactions. There is limited research on the effect of liquid film on the distribution of suspended particles in stirred tanks. This study proposes a drag model incorporating particle liquid film and analyzes the effect of liquid film thickness on solid−liquid mixing. First, the formation mechanism of liquid film on the surface of particles, the influence of liquid film on particle dynamics, and interphase forces were introduced. Second, the accuracy of the modified drag model was validated by comparing predicted solid concentration distribution with experimental data and employed to analyze and study the interaction between fluids and solids. The results indicate that the simulation results obtained by the modified model are consistent with the experimental values, with an average relative error of only 9.82%. Furthermore, the results indicate that under low Reynolds number conditions, the influence of particle liquid film thickness is significant. Under high Reynolds number conditions, the influence of liquid film thickness on particle distribution can be ignored.

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“…Many emerging studies have emphasized the interfacial wettability effects on multiphase transport processes. Specifically, interfacial wettability effects have been investigated in terms of fluid dynamics (drag reduction and wet particle collision), hydrodynamics (membrane bubbling and sieve tray), heat transfer and anti‐icing, oil recovery, oil–water separation, micro‐reactor technology, and so forth.…”

Section: Introductionmentioning

confidence: 99%

Hydrodynamics and mechanism of hydrophobic foam column tray: Contact angle hysteresis effect

Yan

et al. 2019

AIChE Journal

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Interfacial wettability adjustment is a new method for intensifying vapor-liquid mass transfer process. Contact angle effect has been well investigated but not complete due to interfacial wettability consisting of both static behavior (contact angle) and dynamic behavior (contact angle hysteresis). Here, methods of adjusting contact angle hysteresis (CAH) were proposed, and then, the CAH effect on the hydrodynamics was investigated. A multiscale analysis of CAH effect, from interfacial force and wettability to single-bubble and gas-liquid two-phase flow inside the foam to bubble swarm hydrodynamics, was conducted, and thus, the hydrodynamic performance criteria were derived. The interfaces had similar contact angles, whereas a significant difference in the CAH was prepared by using the developed sol dip-coating and spray coating methods. Subsequent experiments revealed that lower CAH can decrease the pressure drop, homogenize the gas distribution, and increase the weeping rate, which are consistent with the derived criteria.

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Interface‐resolved simulations of normal collisions of spheres on a wet surface

Cited by 15 publications

References 56 publications

Numerical investigation of collision dynamics of wet particles via force balance

Numerical investigation of collision dynamics of wet particles via force balance

Insights into the Impact of Small Particle Liquid Film on the Spatiotemporal Distribution of Suspension in Stirred Reactors

Hydrodynamics and mechanism of hydrophobic foam column tray: Contact angle hysteresis effect

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