Turbulent Flow Phenomena and Ce2O3 Behavior during a Steel Teeming Process

Ni, Peiyuan; Jonsson, Lage; Ersson, Mikael; Jönsson, Pär G.

doi:10.2355/isijinternational.53.792

Cited by 12 publications

(5 citation statements)

References 44 publications

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“…Based on the previous discussion, the distribution and percentages of the inclusions touching the nozzle wall have support through the analysis of the flow velocity and turbulent kinetic energy, underlining that the touching inclusion percentage should not be taken as the attachment inclusion percentage, as reported in several works [3,50,51]. Experimental results [26][27][28][29] indicate that the proportion of the largest inclusions yield low attachment rates while the numerical results reported here yield no influence of the particle size.…”

Section: Analysis Of the Nozzle Geometry Effects On The Fluid Dynamicsupporting

confidence: 61%

Decrease of Nozzle Clogging through Fluid Flow Control

Gutiérrez

Barreto

Garcia-Hernandez

et al. 2020

Metals

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Decreasing the clogging deposition rate of alumina inclusions in continuous casting nozzles is possible through three simultaneous measures: Flow modification, use of raw materials with low impurities contents, and smoothed internal surfaces. The control of the internal flow consists on avoiding dead regions and developing symmetric patterns. A mathematical model performed tests of the feasibility of these measures. The adherence of inclusions to the nozzle wall, using this model, employs a boundary condition based on the thickness of the sublaminar boundary instead of the conventional “trap” boundary condition. The use of the general boundary condition yields deposition rates that are unaffected by the inclusion size. The proposed boundary condition discriminates against the clogging deposition rate through the particle sizes. Plant trials complemented with water modeling, using these nozzles, proved that the present approach could considerably decrease the clogging occurrence.

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Section: Analysis Of the Nozzle Geometry Effects On The Fluid Dynamicsupporting

confidence: 61%

Decrease of Nozzle Clogging through Fluid Flow Control

Gutiérrez

Barreto

Garcia-Hernandez

et al. 2020

Metals

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“…The previous pilot plant experiments show that the REM alloyed steel has a very serious nozzle clogging problem during teeming . Figure shows the pictures of a clogged nozzle from a pilot plant experiment . It can be seen that regions 3 and 4 have a serious clogging problem.…”

Section: Resultsmentioning

confidence: 90%

“…The molten steel flow is normally very complex and it is very difficult to get the real observation or measurement on some phenomena in steel flows at such high temperature around 1773 K. The interface phenomena are even more complex compared to an air flow since some other forces may exist like the interfacial tension gradient force, which is related to the content of some surface active elements in molten steel . Therefore, a “stick” boundary is commonly assumed when investigating inclusion depositions in steel flows …”

Section: Introductionmentioning

confidence: 99%

“…Zhang et al tracked the trajectories and entrapment locations of inclusions in a slide‐gate nozzle, based on the flow field solved by k ‐ ϵ turbulence model. Ni et al investigated different sizes and densities of inclusions touching the nozzle wall in the flow field solved by realizable k ‐ ϵ turbulence model and compared predictions to pilot plant experiment data. In addition, the inclusions deposition in a swirling flow SEN was investigated …”

Section: Introductionmentioning

confidence: 99%

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Transport and Deposition of Non‐Metallic Inclusions in Steel Flows‐ A Comparison of Different Model Predictions to Pilot Plant Experiment Data

Jonsson

Ersson

et al. 2017

steel research int.

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Inclusion behavior during a ladle teeming process is investigated. A Lagrangian method is used to track different-size inclusions and to compare their behaviors in steel flows, solved by the realizable k-e model with SWF (Standard Wall Function), realizable k-e model with EWT (Enhanced Wall Treatment), and RSM (Reynolds Stress Model). The results show that inclusion tracking based on the realizable k-e model with SWF to predict the steel flow does not agree with the data from plant experiments. The predicted number of inclusions touching the wall shows almost no dependence on inclusion size. This is due to that the boundary layer is not resolved. The inclusion deposition predicted using the realizable k-e model with EWT and the RSM model to predict the steel flow generally agrees with the experimental observations. However, the large size inclusion deposition is over-predicted when using the realizable k-e model with EWT. More specifically, the prediction for 20 mm inclusions is three times larger than that with the RSM. This is due to that this model cannot calculate the anisotropic turbulence fluctuations. In summary, the turbulence properties in the near-wall boundary layer are found to be very important for a good prediction on inclusion deposition.

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“…[4][5][6][7][8][9][10][11] Although much effort has been invested, clogging is still a common problem in steel production. A large number of mathematical simulations, summarized by Ni et al, [12] have been carried out aiming to get a good understanding of the inclusion transport. However, none of the previous simulations can even give an effective prediction on the deposition rate of inclusions, which is very important to help in judging the clogging situation.…”

Section: Introductionmentioning

confidence: 99%

The Use of an Enhanced Eulerian Deposition Model to Investigate Nozzle Clogging During Continuous Casting of Steel

Jonsson

Ersson

et al. 2014

Metall Mater Trans B

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Nozzle clogging caused by the build-up of non-metallic inclusions on ceramic walls is a serious industrial problem during continuous casting of steel. The current theoretical study uses the extended Eulerian model to predict the inclusion deposition rate in a submerged entry nozzle (SEN). The model considers Brownian and turbulent diffusion, turbophoresis, and thermophoresis as transportation mechanisms. First, the steel flow in a tundish was simulated using a three-dimensional CFD model. The obtained flow parameter in a SEN was then put into the Eulerian deposition model to predict the deposition rate of non-metallic inclusions. Thereafter, the deposition rates of different-size inclusions in the SEN were predicted and compared. The result shows that the steel flow is non-uniform in the SEN of the tundish. This leads to an uneven distribution of the inclusion deposition rates at different locations of the inner wall of the SEN. In addition, large size inclusions among the size of inclusions considered show a large deposition rate, due to the strong effect of turbophoresis.

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Turbulent Flow Phenomena and Ce2O3 Behavior during a Steel Teeming Process

Cited by 12 publications

References 44 publications

Decrease of Nozzle Clogging through Fluid Flow Control

Decrease of Nozzle Clogging through Fluid Flow Control

Transport and Deposition of Non‐Metallic Inclusions in Steel Flows‐ A Comparison of Different Model Predictions to Pilot Plant Experiment Data

The Use of an Enhanced Eulerian Deposition Model to Investigate Nozzle Clogging During Continuous Casting of Steel

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