A Study about the Influence of Carbon Content in the Steel on the Casting Behavior

Xia, Guangmin; Bernhard, Christian; Ilie, Sergiu; Fuerst, C. D.

doi:10.1002/srin.201000196

Cited by 15 publications

(8 citation statements)

References 12 publications

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“…Mold cooling is a self‐limiting process essentially. As the shell grows thicker, its thermal resistance increases, causing the total thermal resistance to increase and the rate of heat removal decrease . When the shell formation in the mold reaches a limiting thickness that is dependent on the total heat removal in the mold, it would influence the further growth of the shell.…”

Section: Molten Steel Solidification Versus Heat Transfermentioning

confidence: 99%

Initial Solidification and Its Related Heat Transfer Phenomena in the Continuous Casting Mold

Wang

Zhu

Zhou

2017

steel research int.

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The initial solidification of molten steel in the mold is very important, as it is the origin of the final slab, which associates with the surface defects and determines the final quality of casting slab. In this article, six main topics, including the initial solidification study method, molten steel solidification, mold flux structure, fluid flow, oscillation marks formation, and breakout are reviewed with the purpose to explore the intrinsic mechanism of the complex initial solidification process and its related multi-phase heat transfer phenomena. The results summarized here can provide a foundational understanding of the initial solidification and heat transfer phenomena occurring in the continuous casting mold.

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Section: Molten Steel Solidification Versus Heat Transfermentioning

confidence: 99%

Initial Solidification and Its Related Heat Transfer Phenomena in the Continuous Casting Mold

Wang

Zhu

Zhou

2017

steel research int.

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“…It is well known that during continuous casting, and especially high‐speed casting, surface longitudinal cracks form more easily in slabs of peritectic steel than in other steels . The occurrence of cracks is related to the initial ferrite shell undergoing a peritectic phase transition: liquid ( L ) + ferrite ( δ ) → austenite ( γ ).…”

Section: Introductionmentioning

confidence: 99%

“…A volume contraction of about 6% accompanies the progression of the incoherent δ / γ interface during peritectic transformation ( δ → γ ) due to the diverse crystal structure, and there is a 4% mismatch between the thermal contraction coefficient of δ and γ . These changes lead to a distinctly wrinkled shell, and the mismatch in the contraction coefficients and the uneven shell lead to the accumulation of stress and longitudinal cracking . For the continuous casting process, it is very important to distinguish between the cracking tendencies of specific steels because longitudinal cracking can be reduced by selecting a lower casting speed and special mold powders for a steel that is susceptible to cracking …”

Section: Introductionmentioning

confidence: 99%

Analysis of Crack Susceptibility of Peritectic Steels Based on Surface Roughness

Guo

Wen

Tang

et al. 2019

steel research int.

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Surface longitudinal cracking during solidification is a serious defect in the continuous casting of peritectic steels, which is dictated by the alloy composition and the cooling rate. Herein, to analyze the crack susceptibility of steels, surface roughness (R a ), which is determined by the peritectic transformation contraction, is proposed to evaluate the cracking tendency of steels. First, the solidified surface roughness of some steels is obtained by a high-temperature laser scanning confocal experiment under different cooling rates, and then the calculation formula and the criteria for surface roughness are obtained by data analysis. The results show that the peritectic transformation contraction and crack susceptibility reflected by surface roughness vary significantly with alloy compositions and cooling rates. In comparison with other methods, this method successfully contains the effect of alloy compositions and cooling rates on crack susceptibility. Good agreement between the predicted results and the experimental observations indicates that the crack susceptibility of steels can be evaluated reliably using their surface roughness.

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“…It is well known that hypo-peritectic steels are more sensitive to deep oscillations, surface shape variations, cracks, and even breakouts than low or high-carbon counterparts during continuous casting, especially at high casting speeds [ 1 , 2 , 3 , 4 , 5 ]. The surface quality problems are strongly related to the complicated peritectic transition process, which leads to nonuniform volume contraction of hypo-peritectic steels during the initial solidifying stage in the mold [ 4 , 5 , 6 , 7 , 8 ]. However, because peritectic steels have excellent mechanical properties, such as Advanced High Strength Steel and High Strength Low Alloy [ 9 , 10 ], and low manufacturing costs, they are still produced preferentially, even though surface defects are often encountered.…”

Section: Introductionmentioning

confidence: 99%

“…The subsequent growth of γ into the δ and L phases, respectively, is classed as the peritectic transformations. Generally, severe volume shrinkage and defect susceptibility occur when casting steels with carbon content between 0.10%C and 0.18%C, because the peritectic transformation of δ to γ coincides with the final solidification and ends in the solid during the early solidification stage, which can enhance the thermal contraction [ 7 , 8 , 9 , 13 ]. Therefore, the degree of contraction and defect susceptibility of steels are always evaluated according to the relationship between the carbon content and the position of the peritectic point.…”

Section: Introductionmentioning

confidence: 99%

A Novel Approach for Evaluating the Contraction of Hypo-Peritectic Steels during Initial Solidification by Surface Roughness

Guo

Wen

et al. 2018

Materials

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The contraction of peritectic steels in the initial solidification has an important influence on the formation of surface defects of continuously cast slabs. In order to understand the contraction behavior of the initial solidification of steels in the mold, the solidification process and surface roughness in a commercial hypo-peritectic and several non-peritectic steels were investigated using Confocal Scanning Laser Microscope (CSLM). The massive transformation of delta-Fe (δ) to austenite (γ) was documented in the hypo-peritectic steel, which caused surface wrinkles and greatly increases the surface roughness of samples in the experiments. Surface roughness (Ra(δ→γ)) was calculated to evaluate the contraction level of the hypo-peritectic steel due to δ–γ transformation. The result shows that the surface roughness method can facilitate the estimation of the contraction level of peritectic transformation over a wide range of cooling rates.

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A Study about the Influence of Carbon Content in the Steel on the Casting Behavior

Cited by 15 publications

References 12 publications

Initial Solidification and Its Related Heat Transfer Phenomena in the Continuous Casting Mold

Initial Solidification and Its Related Heat Transfer Phenomena in the Continuous Casting Mold

Analysis of Crack Susceptibility of Peritectic Steels Based on Surface Roughness

A Novel Approach for Evaluating the Contraction of Hypo-Peritectic Steels during Initial Solidification by Surface Roughness

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