Large Eddy Simulation on the Two‐Phase Flow in a Water Model of Continuous Casting Strand with Gas Injection

Chen, Wei; Ren, Ying; Zhang, Lifeng

doi:10.1002/srin.201800287

Cited by 22 publications

(16 citation statements)

References 39 publications

(53 reference statements)

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“…The vortex moved toward the meniscus in the upper circulation zone with the increasing of the argon flow rate. [58] Figure 19 shows the flow velocity and the average diameter of argon bubbles on the meniscus of the mold at different argon flow rates. The speed near the SEN increased with the increasing of the argon flow rate since the buoyancy of bubbles on the molten steel was enhanced.…”

Section: Effect Of Argon Flow Rate On the Bubble Size Distributionmentioning

confidence: 99%

See 1 more Smart Citation

Study on the Spatial Distribution of Argon Bubbles in a Steel Slab Continuous Casting Strand

Liu

Zhang

Zhou

et al. 2021

steel research int.

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Section: Effect Of Argon Flow Rate On the Bubble Size Distributionmentioning

confidence: 99%

“…The vortex moved toward the meniscus in the upper circulation zone with the increasing of the argon flow rate. [ 58 ]…”

Section: Effect Of Argon Flow Rate On the Bubble Size Distributionmentioning

confidence: 99%

Study on the Spatial Distribution of Argon Bubbles in a Steel Slab Continuous Casting Strand

Liu

Zhang

Zhou

et al. 2021

steel research int.

Self Cite

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show abstract

“…where p is pressure,

\overset{g}{true}

is gravitational acceleration, and

\overset{F}{true}

is external force. The physical properties, including the density ρ and viscosity μ are determined by volume‐weighted averages.…”

Section: Experimental and Simulation Methodsmentioning

confidence: 99%

“…Smirnov et al used LES method in high‐Reynolds number bubbly ship‐wake flows simulations, and bubble distributions for mixing layers and wakes were obtained only consuming reasonable computing resources. Chen et al used LES combined with VOF and discrete phase model to study the flow pattern and bubble distribution of air injection into water tank, where the influence of drag force and lift force on bubble motion was analyzed. Asiagbe et al simulated microbubbles in a vertical turbulent channel flow of water using LES, fluid structures affecting bubble behavior, and the influence of bubble on the continuous flow are obtained.…”

Section: Introductionmentioning

confidence: 99%

Single bubble breakup in the flow field induced by a horizontal jet—The numerical simulation

Cao

Huang

et al. 2019

Asia-Pacific J Chem Eng

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Bubble breakup is a common in the multiphase flow, and the breakup result will influence the performance of the gas-liquid reactor, in which liquid jetting is a typical way in breaking the bubble. In present work, based on the comparison with the experimental results, large eddy simulation and volume of fluid method are coupled to simulate processes of the deformation and breakup of a single bubble in the liquid jet flow. The trajectory of mother bubble, number of daughter bubbles, variation of bubble surface area, and the forces acting on the bubble surface were analyzed. It was found that the shear force at the bubble neck was significantly larger compared with that in the stage of undeformed, and the critical condition for bubble breakup was when the total turbulent pressure on bubble surface was greater than the surface force of bubble. Based on the velocity difference on the upstream and downstream of the bubble, a modified critical Weber number was proposed for a better description of the breakup condition of the single bubble in the liquid jet flow.

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“…In many simulations, even very recent ones, the standard k-ε turbulence model is used for the turbulence modeling of the liquid phase or of the mixture of liquid and gas. [7,9,21,22] Recently some groups have been using large eddy simulations for multiphase mold flow simulations, [8,23,[25][26][27] while hybrid turbulence models such as the scale adaptive simulation (SAS) model are very rare. [23] For the results presented in this publication, two turbulence models are used: the realizable k-ε [28,29] (RKE) and the SAS model.…”

Section: Turbulence Modelingmentioning

confidence: 99%

Bubbly Mold Flow in Continuous Casting: Comparison of Numerical Flow Simulations with Water Model Measurements

Javurek

Wincor

2020

steel research int.

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The impact on the mold flow of inert gas bubbles originating from a gas injection at the top of the submerged entry nozzle is investigated. Results from a physical model using water and air are compared with corresponding numerical flow simulation results. In numerical models, the bubble velocities are determined by calculating the force equilibrium between buoyancy, drag force, and other forces acting on the bubbles. For the observed bubble size in the physical model, the so‐determined rising velocity of the bubbles is significantly too high in comparison to the water model experiment. Various effects can influence the rising velocity of bubbles. One of them is that the presence of turbulence obviously reduces the rising velocity. The influence of turbulence models and of a turbulence‐induced bubble drag modification is analyzed in numerical flow simulations and compared to water model results.

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Large Eddy Simulation on the Two‐Phase Flow in a Water Model of Continuous Casting Strand with Gas Injection

Cited by 22 publications

References 39 publications

Study on the Spatial Distribution of Argon Bubbles in a Steel Slab Continuous Casting Strand

Study on the Spatial Distribution of Argon Bubbles in a Steel Slab Continuous Casting Strand

Single bubble breakup in the flow field induced by a horizontal jet—The numerical simulation

Bubbly Mold Flow in Continuous Casting: Comparison of Numerical Flow Simulations with Water Model Measurements

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