Abstract:The samples of diameter 10 mm were made to simulate slab surface. The variation of hot ductility and microstructure morphology of slab surface during the period of intensive cooling and reheating treatment under surface structure controlled cooling was studied with the Gleeble-2000D hot simulation tester. The theoretical basis will be provided to apply on vertical bending caster of surface structure control cooling. The results show that: the hot ductility of the samples is deteriorated because of the form of widmanstatten structure and film-like proeutectoid ferrite along grain boundary during the period of intensive cooling. However, the treatment of reheating can effectively eliminate the deterioration of hot ductility producing during the period of intensive cooling, which makes the reduced area of the samples increasing to over 40%. Therefore, the treatment of intensive cooling should be accomplished before the slab enters the segment of bending. The slab can enter the bending segments during the period of reheating when the controlled cooling is applied on vertical bending caster.
赵新宇,刘洋,甄新刚,王海宝,王文军,邹扬. 控制冷却下强冷及返温阶段板坯表面热塑性及组织形貌变化规律[J]. 钢铁, 2013, 48(7): 32-35.
ZHAO Xin-yu,LIU Yang,ZHEN Xin-gang,WANG Hai-bao,WANG Wen-jun,ZOU Yang. Variation of Hot Ductility and Microstructure Morphology of Slab Surface During Period of Intensive Cooling and Reheating Under Controlled Cooling. Iron and Steel, 2013, 48(7): 32-35.
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