Distribution of macro-inclusions in low carbon aluminium-killed steel slabs

Deng, Xiaoxuan; Ji, Chenxi; Dong, Wenliang; Li, Linping; Yin, Xiaochun; Yang, Yindong; McLean, Alex

doi:10.1080/03019233.2017.1305676

Cited by 17 publications

(9 citation statements)

References 36 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Figure 11 also shows that with increasing casting speed, the inclusion particle entrapment probability decreased. The aforementioned conclusions were consistent with the statistical conclusions concerning slab cleanliness presented in References [27][28][29]. When the shell moved downwards, the molten steel at the meniscus overflowed out of the shell, leading to particles gathering near the meniscus being deposited above the nascent hook.…”

Section: Inclusions Entrapped By Hookssupporting

confidence: 89%

“…Shorter and thinner hooks were formed after the continuous casting process was optimized by using a higher casting speed or pouring temperature or higher crystalline tendency of the mold flux (mech-I of OM formation) to suppress the solidification of the meniscus or by using a mold flux with low viscosity and solidification temperature (mech-II and mech-III) to enhance the lubrication for infiltration of the mold flux and reduce the slag rim size [26]. Previous studies have confirmed that the entrapment of inclusions by hooks results in more macro-inclusions being present at the subsurface than in the slab interior [27][28][29]. To the best of our knowledge, however, a study on the specific process of hook inclusion entrapment has not yet been published.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Hook evolution and inclusion entrapment during initial solidification process of continuous casting slab

Ping

Zhu

et al. 2018

Metall. Res. Technol.

View full text Add to dashboard Cite

A two-dimensional numerical model was established to describe the mechanism of hook formation and evolution during the initial solidification process of continuous casting slab. Melting, coarsening, growing, and burying stages were observed to follow hook formation at the meniscus. The coordinates at which the hook was finally buried into the shell were determined for different casting speeds and pouring temperatures. The final hook depth was predicted to be approximately 1.8-2.9 mm, which was confirmed by metallographic experiments. A physical model was established based on the calculated shell shape, and the process by which the inclusions were entrapped by the hook structure was investigated. The results indicated that the floating inclusions were most likely entrapped under the nascent hook, and the inclusions gathering near the meniscus were easily captured by the upper part of the nascent hook when overflow of the molten steel occurred. The hooklike structure increased the area of the shell inner face, which resulted in swirling flow of the molten steel near the shell and increased the probability of the inclusions being captured.

show abstract

Section: Inclusions Entrapped By Hookssupporting

confidence: 89%

Section: Introductionmentioning

confidence: 99%

Hook evolution and inclusion entrapment during initial solidification process of continuous casting slab

Ping

Zhu

et al. 2018

Metall. Res. Technol.

View full text Add to dashboard Cite

show abstract

“…Over 50% of the total oxygen is removed between the tundish and the cast slabs although the total oxygen at different width locations in the slabs is essentially the same. Deng et al 18 found variations in the number of largesized inclusions at different width locations, perhaps because the total oxygen content generally represents the amount of small inclusions distributed throughout the steel and only occasionally includes some large inclusions.…”

Section: Total Oxygen and Nitrogen Contentsmentioning

confidence: 99%

“…However, in the present work, a substantial difference in inclusion size and number density was found between the samples taken from the tundish and the final slabs. In the current study, the evolution of macro inclusions during continuous casting was elucidated by means of total oxygen measurements, large-area inclusion characterisation using ASPEX [18][19][20] and analysis of nozzle blockage deposits. Based on the findings from this investigation, formation mechanisms for the different macro inclusions found in the slabs are proposed.…”

Section: Introductionmentioning

confidence: 99%

Formation and evolution of macro inclusions in IF steels during continuous casting

Deng

Chen

et al. 2017

Ironmaking & Steelmaking

View full text Add to dashboard Cite

The evolution of macro inclusions during continuous casting was investigated by large-area inclusion characterization using ASPEX and analysis of nozzle blockage deposits. Six kinds of inclusions over 5 μm were observed in samples taken from the tundish and the slabs: single alumina particles, alumina dendrites, refractory-related alumina, alumina associated with bubbles, alumina clusters and Al-Ti complex oxides. By examining the morphology of the nozzle blockage deposit, it was concluded that the refractory-related alumina in the slabs came from the decarburization layer washed away by the steel stream. Some of the alumina clusters that came from the nozzle blockage deposit dislodged by the steel flow, were formed by the agglomeration and sintering of 5-20 μm inclusions that were carried over from the tundish. Two kinds of Al-Ti oxides were found in the tundish, and their evolution mechanisms during the casting process were proposed.

show abstract

“…The solubility of magnesium in molten steel is relatively high. Magnesium has a strong affinity with oxygen and sulfur, which can effectively reduce the content of O and S in steel, and improve the quantity and morphology of inclusions in steel; moreover, it has an obvious modification effect on oxide inclusions and plays a role in purifying molten steel [9][10][11][12][13][14].…”

Section: Introductionmentioning

confidence: 99%

Kinetics Study on the Modification Process of Al2O3 Inclusions in High-Carbon Hard Wire Steel by Magnesium Treatment

Xiong

et al. 2021

Metals

View full text Add to dashboard Cite

The aim of the experiment in this work is to modify the Al2O3 inclusions in high-carbon hard wire steel by magnesium treatment. The general evolution process of inclusions in steel is: Al2O3 → MgO·Al2O3(MA) → MgO. The unreacted core model was used to study the modification process of inclusions. The results show that the complete modification time (tf) of inclusions is significantly shortened by the increase of magnesium content in molten steel. For Al2O3 inclusions with radius of 1 μm and Mg content in the range of 0.0005–0.0055%, the modification time of Al2O3 inclusions to MA decreased from 755 s to 25 s, which was reduced by 730 s. For Al2O3 inclusions with a radius of 1.5 μm and Mg content in the range of 0.001–0.0035%, the Al2O3 inclusions were completely modified to MgO inclusions from 592 s to 55 s. The Mg content in the molten steel increased 3.4-fold, and the time for complete modification of inclusions was shortened by about 10-fold. With the increase of Al and O content in molten steel, the complete modification time increased slightly, but the change was small. At the same time, the larger the radius of the unmodified inclusion is, the longer the complete modification time is. The tf of Al2O3 inclusions with a radius of 1 μm when modified to MA is 191 s, and the tf of Al2O3 inclusions with a radius of 2 μm when modified to MA is 765 s. According to the boundary conditions and the parameters of the unreacted core model, the MgO content in inclusions with different radius is calculated. The experimental results are essentially consistent with the kinetic calculation results.

show abstract

Distribution of macro-inclusions in low carbon aluminium-killed steel slabs

Cited by 17 publications

References 36 publications

Hook evolution and inclusion entrapment during initial solidification process of continuous casting slab

Hook evolution and inclusion entrapment during initial solidification process of continuous casting slab

Formation and evolution of macro inclusions in IF steels during continuous casting

Kinetics Study on the Modification Process of Al2O3 Inclusions in High-Carbon Hard Wire Steel by Magnesium Treatment

Contact Info

Product

Resources

About