Myeong-Hun Kang scite author profile

In order to elucidate possible mechanism causing nozzle clogging during continuous casting of Ti added Ultra Low C (Ti-ULC) steel, thermodynamic analysis and experimental validation were carried out with an emphasis on the chemical reaction between the liquid steel and nozzle refractory. It was pointed out that the reaction occurs between CO gas from the nozzle refractory and the liquid steel, at the interface between them. A series of thermodynamic calculations were carried out in order to predict related phase equilibria. It was found that Ti in the steel induces the formation of a liquid oxide composed of Fe t O-Al 2 O 3-TiO x along with solid alumina. This was different to a case of Ti-free ULC where only solid alumina was stable. In order to verify the thermodynamic predictions, a series of experiments were conducted. A number of Fe-Al-Ti alloys were reacted with CO gas at 1 560°C in order to simulate the interfacial reaction. Surface and cross section of the alloy samples were analyzed using Scanning Electron Microscopy (SEM) with Energy Dispersive Spectrometry (EDS). The experimental results were in good agreement with the thermodynamic predictions. This finding provides an idea why nozzle clogging is deteriorated by addition of Ti in ULC steel. It is proposed that Ti is oxidized together with Fe and Al by CO gas from a nozzle, and forms a liquid oxide composed of Fe t O-Al 2 O 3-TiO x , which shows good wettability both to liquid steel and to refractory. This would be a precursor of clog material inside the nozzle. KEY WORDS: Ti added ultra-low carbon steel; nozzle clogging; interfacial reaction; thermodynamics; Fe t O-Al 2 O 3-TiO x liquid oxide.

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Influence of vanadium, boron and titanium on hot ductility of high Al, TWIP steels

Kang

Mintz

2021

Materials Science and Technology

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High Al, twinning induced plasticity (TWIP) steels have high tensile strengths and excellent ductility but low yield strengths compared to other advanced high strength steels and this has limited their application. A.Vanadium addition is a possible answer but cracking on casting is a worry. Hot tensile tests were therefore performed on 1.5% Al, TWIP steels with vanadium levels approximately 0.05–0.7% (all wt-%). Only the 0.05% vanadium steel gave acceptable hot ductility but the room temperature yield strength was too low. In contrast, the Ti–B high 0.5% V steel which was as well as able to give a high yield strength due to precipitation hardening by vanadium carbide gave better ductility by boron segregating to the boundaries and strengthening them.

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Influence of Al/Ti Ratio in Ti-ULC Steel and Refractory Components of Submerged Entry Nozzle on Formation of Clogging Deposits

et al. 2019

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Nozzle clogging during continuous casting of Ti-ULC (Ultra Low C) steel was investigated by inspections of plant-used SENs and laboratory scale experiments using a rotating finger method. Various Al/Ti ratios in the steel and different kinds of nozzles (with or without CaO) were employed. Clog deposits found in the used SENs were composed of complicated oxide (CaO-Al 2 O 3-TiO x-…), Fe drops and chunks. Increasing Ti concentration increased amount of the deposit the metallic deposits. In the laboratory scale experiments, increasing Al/Ti ratios was effective to suppress the formation of the deposit and the oxidation loss of Ti in the steel. When a refractory without CaO was used, increasing Al/Ti ratio decreased the portion of Ti oxide in the deposit. Almost no Fe drops were observed, except for a thin layer of Fe on surface of the oxide deposit. When CaO-lined refractory was used, many numbers of Fe drops were found inside the deposit. Increasing Al/Ti ratio lowered Ti peak in the oxide deposit. The present results lend a strong support that Ti-ULC steel is oxidized by CO gas from nozzle refractory, forming Fe t O-containing liquid oxide and solid alumina. The liquid oxide is reduced to leave Fe drops and Al 2 O 3-TiO x layer. If CaO presents in the nozzle, then a complicated oxide of CaO-Al 2 O 3-TiO x forms, as was found in the SEN from the practical operation. KEY WORDS: Ti-ULC steel casting; nozzle clogging; Al/Ti ratio; Fe t O-Al 2 O 3-TiO x ; nozzle refractory.

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Interfacial Reaction Between Ultra Low C Steel and Gas Generated from Refractory Material Used for Submerged Entry Nozzle for Continuous Casting

Lee

Kim

Kang

et al. 2017

Berg Huettenmaenn Monatsh

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AlN-assisted internal oxidation behavior in Al-containing high Mn steels

Lee

Heo

Lee

et al. 2022

Materials Characterization

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Myeong-Hun Kang

Oxidation of Ti Added ULC Steel by CO Gas Simulating Interfacial Reaction between the Steel and SEN during Continuous Casting

Influence of vanadium, boron and titanium on hot ductility of high Al, TWIP steels

Influence of Al/Ti Ratio in Ti-ULC Steel and Refractory Components of Submerged Entry Nozzle on Formation of Clogging Deposits

Interfacial Reaction Between Ultra Low C Steel and Gas Generated from Refractory Material Used for Submerged Entry Nozzle for Continuous Casting

AlN-assisted internal oxidation behavior in Al-containing high Mn steels

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