Physical Modelling of Tundish Slag Entrainment under Various Technological Conditions

Michalek, Karel; Gryc, Karel; Socha, Ladislav; Tkadlečková, Markéta; Saternus, M.; Pieprzyca, J.; Merder, T.; Pindor, Lukáš

doi:10.1515/amm-2017-0227

Cited by 11 publications

(17 citation statements)

References 13 publications

(27 reference statements)

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“…The residence time is the overall time of a steel particle "spends" in the tundish or, more technically, the time between entering the tundish via the ladle shroud and leaving it via one of the exit ports (submerged entry nozzles), C-curves are measured in steady state, i.e., with constant water level in the tundish (input flow rate = output flow rate). [8][9][10][11][12] During the measurements it was empirically found that the optimal quantity of tracer in terms of the working range of conductivity probes is 150 ml. In general, three measurements are performed for each set of tundish configurations and casting conditions.…”

Section: Physical Modelmentioning

confidence: 99%

Optimizing of steel flow in three-strand T-type tundish using mathematical and physical models

Buľko

Demeter

Dzurňák

et al. 2022

METAL 2022 Conference Proeedings

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The presented research was focused on optimizing the internal equipment of the tundish with respect to residence times between the middle (No. 2) and two lateral casting strands (No. 1 and 3). The different values of residence times of individual strands affect the cleanliness of steel and cause thermal and chemical inhomogeneities. The specific flow given by the shape of the three-strand symmetrical T-type tundish causes the middle casting strand to have a relatively short residence time compared to lateral strands. For this reason, the flow in the tundish was controlled by changing the angle of outlet holes in tundish baffle separating the inlet part of the tundish from its working volume. The research was carried out using computer simulations supported by the results from the SimConT physical model.

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Section: Physical Modelmentioning

confidence: 99%

Optimizing of steel flow in three-strand T-type tundish using mathematical and physical models

Buľko

Demeter

Dzurňák

et al. 2022

METAL 2022 Conference Proeedings

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“…The requirements imposed on the used refractory concrete are defined by the operating conditions on the continuous casting machine [1,2]. The operating temperature, usually in the range of 1540-1570 • C, and the exposure time in this environment, often reaching more than 30 hours, are considered essential [3][4][5]. During this time, several thousand tons of liquid metal are cast, which places high demands on the shape stability of the prefab placed in such a working environment Figure 1.…”

Section: Introductionmentioning

confidence: 99%

The Benefits of Using an Advanced Material for Production of Spherical Impact Pad for Tundish

Buľko,

Demeter,

Priesol

et al. 2024

International Scientific Conference Modern Metallurgy—Iron and Steelmaking 2023

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“…Some of the reports are concerned with the slag entrainment using physical modeling. Michalek et al developed a physical modeling methodology about the slag entrainment at a critical level of steel, which corresponds to an operational continuous casting machine. The steel level drop process in tundish is similar to that in the ladle to some extent.…”

Section: Introductionmentioning

confidence: 99%

“…Previous works showed that researchers used mathematical and physical simulation experiment to study the vortex formation and slag entrainment during ladle teeming, whereas recent works prefer to use water simulation to study the formation of vortex in tundish . The formation of vortex in tundish is inevitable, and it cannot be thoroughly studied only by using physical simulation.…”

Section: Introductionmentioning

confidence: 99%

Physical and Mathematical Simulation of Surface‐Free Vortex Formation and Vortex Prevention Design during the End of Casting in Tundish

Ruan

Yao

Shen

et al. 2020

steel research int.

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Herein, the formation of the vortex and slag entrainment in tundish is studied by using mathematical and physical simulation. This article aims at contributing to the understanding of the free surface vortex formation in continuous casting tundish at the end of casting. A 3D multiphase mathematical model using the renormalization group (RNG) k–ε turbulence model is developed to predict the vortex formation and slag layer behavior on the scale of the 1:4 water model of a two‐strand slab tundish. The Eulerian volume of fluid model is adopted to track the steel–slag–air free surface and vortex, and the effect of Coriolis force is considered in this simulation. An improved vortex prevention design is also proposed by changing the position of the diversion hole on the dam of the tundish, which is compared with the original scheme using numerical and physical simulation. The predicted results of the vortex structure and the critical height of the vortex formation agree well with the water modeling results. It is demonstrated that the critical height of the vortex formation is reduced significantly by regulating the position of the diversion hole on the dam near the outlet of the tundish.

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Physical Modelling of Tundish Slag Entrainment under Various Technological Conditions

Cited by 11 publications

References 13 publications

Optimizing of steel flow in three-strand T-type tundish using mathematical and physical models

Optimizing of steel flow in three-strand T-type tundish using mathematical and physical models

The Benefits of Using an Advanced Material for Production of Spherical Impact Pad for Tundish

Physical and Mathematical Simulation of Surface‐Free Vortex Formation and Vortex Prevention Design during the End of Casting in Tundish

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