REFERENCES
- Ma, Y.; Wang, X.D.; Zang, X.Z.; Yao, M.; Zhang, L.; Ye, S.H. Mold lubrication and friction behaviour with hydraulic oscillatios in slab continuous casting. Ironmaking and Steelmaking 2010, 37 (2), 112–118.
- Masahito, H.; Masayuki, K. Flux film in the mold of high speed continuous casting. Iron and Steel Institute of Japan International 2008, 48 (2), 180–185.
- Kulkarni, M.M.; Babu, A.S. Optimization of continuous casting using simulation. Materials and Manufacturing Process 2005, 20, 595–606.
- Suzuki, M.; Mizukami, H.; Kitagawa, T.; Kawakami, K.; Uchida, S.; Komatsu, Y. Development of a new mold oscillation mode for high-speed continuous casting of steel slabs. Iron and Steel Institute of Japan International 1991, 31 (3), 254–261.
- Chakraborti, N.; Kumar, R.; Jain, D. A study of the continous casting mold using a pareto-converging genetic algorithm. Applied Mathematical Modelling 2001, 25, 287–297.
- Chakraborti, N.; Mukherjee, A. Optimisation of continous casting mould parameters using gennetic algorithms and other allied techniques. Ironmaking and Steelmaking 2000, 27 (3), 243–247.
- Chakraborti, N.; Kumar, K.S.; Roy, G.G. A heat transfer study of the continous caster mold using a finite volume apporach coupled with genetic algorithms. Journal of Materials Engineering and Performance 2003, 12 (4), 430–435.
- Miettinen, K. Using interactive multiobjective optimization in continuous casting of steel. Materials and Manufacturing Process 2007, 22, 585–593.
- Miettinen, K.; Makela, M.M.; Mannikko, T. Optimal control of continuous casting by nondifferentiable multiobjective optimization. Computational Optimization and Applications 1998, 11, 177–194.
- Karthik, K.; Miettinen, K. New perspective to continuous casting of steel with a hybrid evolutionary multiobjective algorithm. Materials and Manufacturing Process 2011, 26, 481–492.
- Lotov, A.V.; Kamenev, K.G.; Berezkin, V.E.; Miettinen, K. Optimal control of cooling process in continous casting of steel using a visualization- based multi-criteria approach. Applied Mathematical Modelling 2005, 29, 653–672.
- Chakraborti, N.; Gupta, R.S.P.; Tiwari, T.K. Optimisation of continuous casting process using genetic algorithms: Studies of spray and radiation cooling regions. Ironmaking and Steelmaking 2003, 30 (4), 273–278.
- Kumar, A.; Shaoo, D.; Chakraborty, S.; Chakraborti, N. Gas ingection in steelmaking vessels: Coupling a fluid dynamic analysis with a genetic algorithms-based pareto-optimality. Materials and Manufacturing Process 2005, 20, 363–379.
- Shin, H.J.; Kim, S.H.; Thomas, B.G.; Lee, G.G.; Park, J.M.; Sengupta, J. Measurement and prediction of lubrication, powder consumption, and oscillation mark profiles in ultra-low carbon steel slabs. Iron and Steel Institute of Japan International 2006, 46 (11), 1635–1644.
- Wang, X.D.; Yao, M.; Li, Z.; Zhang, X.B.; Chen, S.H. Optimization of oscillation model for slab continuous casting mold based on mold friction measurements in plant trial. Journal of Iron and Steel Research, International 2013, 20 (1), 13–20.
- Lopez, P.E.R.; Mills, K.C.; Lee, P.D.; Santillana, B. A unified mechanism for the formation of oscillation marks. Metallurgical and Materials Transactions B 2012, 43B, 109–122.
- Sengupta, J.; Thomas, B.G.; Shin, H.J.; Lee, G.G.; Kim, S.H. A new mechanism of hook formation during continuous casting of ultra-low-carbon steel slabs. Metallurgical and Materials Transaction 2006, 37A, 1590–1597.
- Ko, E.Y.; Choi, J.; Park, J.Y.; Sohn, I. Simulation of low carbon steel solidification and mold flux crystallization in continuous casting using a multi-mold simulatior. Metals and Materials International 2014, 20 (1), 141–151.