Analysis of cracking phenomena in continuous casting of 1Cr13 stainless steel billets with final electromagnetic stirring

Yu Xu , Rong-jun Xu , Zheng-jie Fan , Cheng-bin Li , An-yuan Deng , En-gang Wang

International Journal of Minerals, Metallurgy, and Materials ›› 2016, Vol. 23 ›› Issue (5) : 534 -541.

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International Journal of Minerals, Metallurgy, and Materials ›› 2016, Vol. 23 ›› Issue (5) : 534 -541. DOI: 10.1007/s12613-016-1264-6
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Analysis of cracking phenomena in continuous casting of 1Cr13 stainless steel billets with final electromagnetic stirring

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Abstract

Solidification cracking that occurs during continuous casting of 1Cr13 stainless steel was investigated with and without final electromagnetic stirring (F-EMS). The results show that cracks initiates and propagates along the grain boundaries where the elements of carbon and sulfur are enriched. The final stirrer should be appropriately placed at a location that is 7.5 m away from the meniscus, and the appropriate thickness of the liquid core in the stirring zone is 50 mm. As a stirring current of 250 A is imposed, it can promote columnar-equiaxed transition, decrease the secondary dendrite arm spacing, and reduce the segregation of both carbon and sulfur. F-EMS can effectively decrease the amount of cracks in 1Cr13 stainless steel.

Keywords

stainless steel / cracking / solidification / continuous casting / electromagnetic stirring

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Yu Xu, Rong-jun Xu, Zheng-jie Fan, Cheng-bin Li, An-yuan Deng, En-gang Wang. Analysis of cracking phenomena in continuous casting of 1Cr13 stainless steel billets with final electromagnetic stirring. International Journal of Minerals, Metallurgy, and Materials, 2016, 23(5): 534-541 DOI:10.1007/s12613-016-1264-6

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References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Wen P., Cai Z.P., Feng Z.H., Wang G. Microstructure and mechanical properties of hot wire laser clad layers for repairing precipitation hardening martensitic stainless steel. Opt. Laser Technol., 2015, 75, 2015.

[2]

Yang J.Q., Liu Y., Ye Z.Y., Yang D.Z., Ye S.H. Microstructure and tribological characteristics of nitrided layer on 2Cr13 steel in air and vacuum. Surf. Coat. Technol., 2009, 204(5): 705.

[3]

Scuracchio B.G., Schön C.G. Influence of alloying elements upon the solidification interval of CA6NM cast martensitic stainless steel. J. Phase Equilib. Diff., 2012, 33(2): 115.

[4]

Trejo M.H., Lopez E.A., Mondragon J.J.R., Roman M.J.C., Tovar H.S. Effect of solidification path and contraction on the cracking susceptibility of carbon peritectic steels. Met. Mater. Int., 2010, 16(5): 731.

[5]

Konishi J., Militzer M., Samarasekera I.V., Brimacombe J.K. Modeling the formation of longitudinal facial cracks during continuous casting of hypoperitectic steel. Metall. Mater. Trans. B, 2002, 33(3): 413.

[6]

Stefanescu D.M. Microstructure evolution during the solidification of steel. ISIJ Int., 2006, 46(6): 786.

[7]

Kou S. A criterion for cracking during solidification. Acta Mater., 2015, 88, 2015.

[8]

Zhu L.G., Kumar R.V. Shrinkage of carbon steel by thermal contraction and phase transformation during solidification. Ironmaking Steelmaking, 2007, 34(1): 71.

[9]

Kim K., Han H.N., Yeo T., Lee Y., Oh K.H., Lee D.N. Analysis of surface and internal cracks in continuously cast beam blank. Ironmaking Steelmaking, 1997, 24(3): 249.
[10]

Han Z.Q., Cai K., Liu B.C. Prediction and analysis on formation of internal cracks in continuously cast slabs by mathematical models. ISIJ Int., 2001, 41(12): 1473.

[11]

Deisinger M., Tacke K.H. Unbending of continuously cast slabs with liquid-core. Ironmaking Steelmaking, 1997, 24(4): 321.
[12]

Ridolfi M.R. Hot tearing modeling: a microstructural approach applied to steel solidification. Metall. Mater. Trans. B, 2014, 45(4): 1425.

[13]

Wu H.J., Wei N., Bao Y.P., Wang G.X., Xiao C.P., Liu J.J. Effect of M-EMS on the solidification structure of a steel billet. Int. J. Miner. Metall. Mater., 2011, 18(2): 159.

[14]

Bettlman L. Effect of mold EMS design on billet casting productivity and product quality. Can. Metall. Q., 1999, 38(5): 301.

[15]

Oh K.S., Chang Y.W. Macrosegregation behavior in continuously cast high carbon steel blooms and billets at the final stage of solidification in combination stirring. ISIJ Int., 1995, 35(7): 866.

[16]

Raj M., Pandey J.C. Optimisation of electromagnetic stirring in continuously cast steel billets using ultrasonic C-scan imaging technique. Ironmaking Steelmaking, 2008, 35(4): 28.

[17]

Xiao C., Zhang J.M., Luo Y.Z., Wei X.D., Wu L., Wang S.X. Control of macrosegregation behavior by applying final electromagnetic stirring for continuously cast high carbon steel billet. J. Iron steel Res. Int., 2013, 20(11): 1.

[18]

Yu Y.N. Principles of Metallography, 2000, Beijing, Metallurgy Industry Press, 248.
[19]

Cabrera-Marrero J.M., Carreño-Galindo V., Morales R.D., Chávez-Alcalá F. Macro-micro modeling of the dendritic microstructure of steel billets processed by continuous casting. ISIJ Int., 1998, 38(8): 812.

[20]

Jin W.Z., Li T.J., Yin G.M. Research on vacuum-electromagnetic casting of IN100 superalloy ingots. Sci. Technol. Adv. Mater., 2007, 8(1-2): 1.

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