"FINAL-STRUCTURE PREDICTION OF CONTINUOUSLY CAST BILLETS" . . . . "000303371300011" . . "FINAL-STRUCTURE PREDICTION OF CONTINUOUSLY CAST BILLETS"@en . "Klime\u0161, Lubom\u00EDr" . "46" . . "Kavi\u010Dka, Franti\u0161ek" . "In steel production, controlling and monitoring quality, grade and structure of final steel products are very important issues. It has been shown that the temperature distribution, the magnitude of temperature gradients, as well as the cooling strategy during the continuous steel casting have a significant impact on material properties, the structure and any defect formation of cast products. The paper describes an accurate computational tool intended for investigating the transient phenomena in continuously cast billets, for developing the caster control techniques and also for determining the optimum cooling strategy in order to meet all quality requirements. The numerical model of the temperature field is based on the finite-difference implementation of the 3D energy-balance equation using the enthalpy approach. This allows us to analyse the temperature field along the entire cast billet. Since the steel billets are produced constantly 24 hours per day, the transient temperature field is being comp"@en . . . . "FINAL-STRUCTURE PREDICTION OF CONTINUOUSLY CAST BILLETS"@en . . . "\u0160t\u011Btina, Josef" . "1580-2949" . . . . "6"^^ . "RIV/00216305:26210/12:PU97595!RIV13-GA0-26210___" . "136511" . "In steel production, controlling and monitoring quality, grade and structure of final steel products are very important issues. It has been shown that the temperature distribution, the magnitude of temperature gradients, as well as the cooling strategy during the continuous steel casting have a significant impact on material properties, the structure and any defect formation of cast products. The paper describes an accurate computational tool intended for investigating the transient phenomena in continuously cast billets, for developing the caster control techniques and also for determining the optimum cooling strategy in order to meet all quality requirements. The numerical model of the temperature field is based on the finite-difference implementation of the 3D energy-balance equation using the enthalpy approach. This allows us to analyse the temperature field along the entire cast billet. Since the steel billets are produced constantly 24 hours per day, the transient temperature field is being comp" . . "[63773458C914]" . "4"^^ . . . "concast billet, numerical model, solidification"@en . "FINAL-STRUCTURE PREDICTION OF CONTINUOUSLY CAST BILLETS" . . "26210" . "2" . "P(ED0002/01/01), P(GA106/08/0606), P(GA106/09/0940), P(GAP107/11/1566), S" . "SI - Slovinsk\u00E1 republika" . . "4"^^ . "RIV/00216305:26210/12:PU97595" . "Materiali in tehnologije" . . . . "Mauder, Tom\u00E1\u0161" . . .