• 1. Mintz B, “Importance of Ar3 temperature in controlling ductility and width of hot ductility trough in steels, and its relationship to transverse cracking,” Mater Sci Tech-Lond, 12(2) (1996), 132-8.
  • 2. Brimacombe J, Sorimachi K. “Crack formation in the continuous casting of steel,” Metallurgical transactions B, 8(2) (1977), 489-505.
  • 3. Patrick B, Ludlow V. “Development of casting practices to minimise transverse cracking in microalloyed steels,” La Revue de Metallurgie-CIT Juilet-Aout, (1994), 1081-1089.
  • 4. WANG Wen-jun et al., “Development and Application of Mould with Chamfered Corners for Continuous Casting of Slabs,” Journal of Iron and Steel Research, 24(9) (2012), 21-26.
  • 5. CAO Jian-xin et al., “Application of Chamfered Mould on Slab Continuous Casting Production in Lianyuan Iron and Steel Company,” Iron and Steel, 48(11) (2013), 43-47.
  • 6. Ren Fei-fei et al., “Numerical Simulation of Actual Temperature Field for Chamfered Mould Copper,” Iron and Steel, 50(4) (2015), 27-33.
  • 7. Yang H et al., “Mathematical simulation on coupled flow, heat, and solute transport in slab continuous casting process,” Metallurgical and Materials Transactions B, 29(6) (1998), 1345-1356.
  • 8. Xie X et al., “Mathematical Modeling of Heat Transfer in Mold Copper Coupled with Cooling Water During the Slab Continuous Casting Process,” Metall Mater Trans B, 45(6) (2014):2442-2452.
  • 9. Chaudhary R et al., “Transient Mold Fluid Flow with Well- and Mountain-Bottom Nozzles in Continuous Casting of Steel,” Metall Mater Trans B, 39(6) (2008), 870-884.
  • 10. Najera-Bastida A et al., “Shell Thinning Phenomena Affected by Heat Transfer, Nozzle Design and Flux Chemistry in Billets Moulds,” Isij Int, 50(6) (2010), 830-838.
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