Numerical simulation of the deformation risk in thin slab continuous casting process with liquid core reduction

Zhida Zhang , Jize Chen , Cheng Ji , Yutang Ma , Miaoyong Zhu , Wenxue Wang

International Journal of Minerals, Metallurgy, and Materials ›› 2025, Vol. 32 ›› Issue (5) : 1114 -1127.

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International Journal of Minerals, Metallurgy, and Materials ›› 2025, Vol. 32 ›› Issue (5) : 1114 -1127. DOI: 10.1007/s12613-024-3009-2
Research Article

Numerical simulation of the deformation risk in thin slab continuous casting process with liquid core reduction

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Abstract

The application of liquid core reduction (LCR) technology in thin slab continuous casting can refine the internal microstructures of slabs and improve their production efficiency. To avoid crack risks caused by large deformation during the LCR process and to minimize the thickness of the slab in bending segments, the maximum theoretical reduction amount and the corresponding reduction scheme for the LCR process must be determined. With SPA-H weathering steel as a specific research steel grade, the distributions of temperature and deformation fields of a slab with the LCR process were analyzed using a three-dimensional thermal-mechanical finite element model. High-temperature tensile tests were designed to determine the critical strain of corner crack propagation and intermediate crack initiation with various strain rates and temperatures, and a prediction model of the critical strain for two typical cracks, combining the effects of strain rate and temperature, was proposed by incorporating the Zener–Hollomon parameter. The crack risks with different LCR schemes were calculated using the crack risk prediction model, and the maximum theoretical reduction amount for the SPA-H slab with a transverse section of 145 mm × 1600 mm was 41.8 mm, with corresponding reduction amounts for Segment 0 to Segment 4 of 15.8, 7.3, 6.5, 6.4, and 5.8 mm, respectively.

Keywords

thin slab continuous casting / liquid core reduction / three-dimensional thermal-mechanical / critical strain / crack risk / maximum theoretical reduction amount

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Zhida Zhang, Jize Chen, Cheng Ji, Yutang Ma, Miaoyong Zhu, Wenxue Wang. Numerical simulation of the deformation risk in thin slab continuous casting process with liquid core reduction. International Journal of Minerals, Metallurgy, and Materials, 2025, 32(5): 1114-1127 DOI:10.1007/s12613-024-3009-2

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References

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

PanQK, ChenQD, MengT, WangB, GaoL. A mathematical model and two-stage heuristic for hot rolling scheduling in compact strip production. Appl. Math. Model., 2017, 48: 516

[2]

BayoumiLS, MegahedGM. Determination of rolling load in liquid core reduction of continuously cast thin steel slab. Ironmaking Steelmaking, 2003, 30(5): 348

[3]

LiJ, SunYH, AnHH, NiPY. Shape of slab solidification end under non-uniform cooling and its influence on the central segregation with mechanical soft reduction. Int. J. Miner. Metall. Mater., 2021, 28(11): 1788

[4]

SantosRG, AndradeSR, PeraltaJL. Influence of liquid core reduction in the microstructure of steel thin slabs. Mater. Sci. Forum, 2003, 426–432: 1499

[5]

DengAJ, ShuaiY, GongHG, CaoRH, WangHC, PengSH. Optimal control of surface crack in microalloyed steel with big stroke liquid core reduction process. Trans. Indian Inst. Met., 2022, 75(5): 1269

[6]

AnJZ, CaiZZ, ZhuMY. Effect of titanium content on the refinement of coarse columnar austenite grains during the solidification of peritectic steel. Int. J. Miner. Metall. Mater., 2022, 29(12): 2172

[7]

WangSZ, GaoZJ, WuGL, MaoXP. Titanium microalloying of steel: A review of its effects on processing, microstructure and mechanical properties. Int. J. Miner. Metall. Mater., 2022, 29(4): 645

[8]

CaiDW, ZhangL, WangWL, ZhangL, SohnI. Dissolution of TiO2 and TiN inclusions in CaO–SiO2–B2O3-based fluorine-free mold flux. Int. J. Miner. Metall. Mater., 2023, 30(9): 1740

[9]

WuCH, JiC, ZhuMY. Influence of differential roll rotation speed on evolution of internal porosity in continuous casting bloom during heavy reduction. J. Mater. Process. Technol., 2019, 271: 651

[10]

WuCH, JiC, ZhuMY. Closure of internal porosity in continuous casting bloom during heavy reduction process. Metall. Mater. Trans. B, 2019, 50(6): 2867

[11]

TsaiHT, YinH, LowryM, MoralesS. Analysis of transverse corner cracks om slabs and countermeasures. Iron Steel Technol, 2006, 3(7): 23
[12]

LiQP, WenGH, ChenFH, TangP, HouZB, MoXY. Irregular initial solidification by mold thermal monitoring in the continuous casting of steels: A review. Int. J. Miner. Metall. Mater., 2024, 31(5): 1003

[13]

KonishiJ, MilitzerM, SamarasekeraIV, BrimacombeJK. Modeling the formation of longitudinal facial cracks during continuous casting of hypoperitectic steel. Metall. Mater. Trans. B, 2002, 33(3): 413

[14]

WonYM, YeoTJ, SeolDJ, OhKH. A new criterion for internal crack formation in continuously cast steels. Metall. Mater. Trans. B, 2000, 31(4): 779

[15]

LeeJE, YeoTJ, OhKH, YoonJK, YoonUS. Prediction of cracks in continuously cast steel beam blank through fully coupled analysis of fluid flow, heat transfer, and deformation behavior of a solidifying shell. Metall. Mater. Trans. A, 2000, 31(1): 225

[16]

BelletM, CerriO, BobadillaM, ChastelY. Modeling hot tearing during solidification of steels: Assessment and improvement of macroscopic criteria through the analysis of two experimental tests. Metall. Mater. Trans. A, 2009, 40(11): 2705

[17]

LiGL, JiC, ZhuMY. Prediction of internal crack initiation in continuously cast blooms. Metall. Mater. Trans. B, 2021, 52(2): 1164

[18]

SenguptaJ, OjedaC, ThomasBG. Thermal-mechanical behaviour during initial solidification in continuous casting: Steel grade effects. Int. J. Cast Met. Res., 2009, 22(1–4): 8

[19]

EnosDG, ScullyJR. A critical-strain criterion for hydrogen embrittlement of cold-drawn, ultrafine pearlitic steel. Metall. Mater. Trans. A, 2002, 33(4): 1151

[20]

MatsumiyaT, ItoM, KajiokaH, YamaguchiS, NakamuraY. An evaluation of critical strain for internal crack formation in continuously cast slabs. Trans. Iron Steel Inst. Jpn., 1986, 26(6): 540

[21]

HuWG, JiC, ZhuMY. Numerical simulation of continuous casting round blooms with different solidification end reduction strategies. Metall. Mater. Trans. B, 2021, 52(6): 4130

[22]

ChenHY, JiC, ZhuMY. H-shaped process of continuous casting bloom with double-sided convex roll reduction for H-beam blank effective production. Metall. Mater. Trans. B, 2023, 54(5): 2530

[23]

R.M. Pineda Huitron, P.E. Ramirez Lopez, E. Vuorinen, R. Jentner, and M.E. Kärkkäinen, Converging criteria to characterize crack susceptibility in a micro-alloyed steel during continuous casting, Mater. Sci. Eng. A, 772(2020), art. No. 138691.
[24]

JiC, WuCH, ZhuMY. Thermo-mechanical behavior of the continuous casting bloom in the heavy reduction process. JOM, 2016, 68(12): 3107

[25]

LiQH, LanP, WangHJ, AiHZ, ChenDL, WangHD. Formation and control of the surface defect in hypo-peritectic steel during continuous casting: A review. Int. J. Miner. Metall. Mater., 2023, 30(12): 2281

[26]

X.G. Yang, L.F. Zhang, C.B. Lai, S.S. Li, M. Li, and Z.H. Deng, A method to control the transverse corner cracks on a continuous casting slab by combining microstructure analysis with numerical simulation of the slab temperature field, Steel Res. Int., 89(2018), No. 5, art. No. 1700480.
[27]

JiC, WangZL, WuCH, ZhuMY. Constitutive modeling of the flow stress of GCr15 continuous casting bloom in the heavy reduction process. Metall. Mater. Trans. B, 2018, 49(2): 767

[28]

JiC, LuoS, ZhuMY, SahaiY. Uneven solidification during wide-thick slab continuous casting process and its influence on soft reduction zone. ISIJ Int., 2014, 54(1): 103

[29]

ChenY, JiC, ZhuMY. Design of process and equipment for wide-thick slab CSC-roll reduction and study of the resulting surface crack risk. Metall. Mater. Trans. B, 2022, 53(5): 2925

[30]

ChenTC, HuX, ZhaoT, JiC, ZhuMY. Microstructure evolution and its influence on thermoplasticity of wide and thick continuous casting slab with heavy reduction. J. Iron Steel Res. Int., 2024, 31(9): 2196

[31]

ClyneTW, WolfM, KurzW. The effect of melt composition on solidification cracking of steel, with particular reference to continuous casting. Metall. Trans. B, 1982, 13(2): 259

[32]

YamanakaA, KumakuraS, OkamuraK, et al.. Thin slab casting with liquid core reduction. Ironmaking Steelmaking, 1999, 26(6): 457

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