共查询到19条相似文献,搜索用时 57 毫秒
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针对攀钢高强耐候乙字钢大方坯连铸二冷控制制度在连铸比水量和二冷区水量分配等方面存在的问题,通过采用延长喷水冷却区长度、适当增大连铸比水量、调整二冷区各回路的冷却能力及水量分配比例的方法,优化了YQ450NQR1大方坯连铸二冷制度.生产应用表明,高强耐候乙字钢大方坯内部质量明显提高,中心疏松评级≤1.0级的比例由79.71%增至90.70%,中心偏析<0.5级的比例由1.45%增至44.19%,无中心缩孔的比例由86.96%增至93.02%,无中心裂纹的比例由39.13%增至62.79%,无中间裂纹的比例由85.51%增至88.37%,无皮下裂纹的比例由78.26%增至97.67%,无角部内裂纹的比例由73.91%增至93.02%,为攀钢开发生产屈服强度450MPa级高强度耐大气腐蚀乙字钢提供了高质量的铸坯. 相似文献
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连铸二次冷却制度是控制铸坯质量的关键,以方坯连铸机工艺和设备条件为基础,基于目标温度建立方坯连铸凝固传热的数学模型,在验证模型可靠性的基础上对方坯二次冷却制度进行优化,在实践应用中取得良好效果。 相似文献
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《Baosteel Technical Research》2012,6(3):61-64
Dynamic model control technologies of secondary cooling and soft reduction of Baosteel are introduced. Model principle and control system architecture are summarized,as well as functions and features.Finally,applications of model technologies are discussed.The self-developed dynamic secondary cooling model and the dynamic soft reduction model have been applied on several casting machines inside and outside Baosteel,desired control effects were achieved with good stability and reliability.Temperature measurement results verified the correctness of model. 相似文献
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宝钢1930mm板坯连铸二冷传热模型的研究与开发 总被引:1,自引:0,他引:1
基于二维非稳态传热数学模型理论,并结合铸坯在连铸二冷区的实际热量散失规律,将二:冷区相邻夹辊之间传热分为夹辊接触传热、水聚集蒸发传热、水冲击传热和辐射传热4个过程,根据宝钢一炼钢1930mm板坯连铸机具体条件,建立其连铸二冷传热模型。利用面向对象的VisualBasic6.0高级语言对模型进行编程,开发出相应的连铸二冷仿真软件。利用红外线测温仪采集铸坯温度对模型结果进行验证,现场铸坯测温和仿真结果比较得出温差在20℃以内,偏差范嗣为1.0%~2.5%,说明仿真模型和仿真结果真实可靠。应用该仿真软件可以对宝钢1930mm连铸机的二冷工艺制度进行研究和优化,指导连铸生产。 相似文献
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Heavy reduction technology of the bloom is realised without modifying the hydraulic equipment if a crown roll is used. Experimental results of GCr15 showed that the ratio of reduction amount to broadening amount increased from 2.0 (flat roll reduction) to 4.4 (crown roll reduction), which indicated that reduction efficiency is significantly improved. It is evident that the enriched molten steel in the mushy zone will be squeezed out if the crown roll heavy reduction technology is adopted. Thus, centre segregation and V segregation is suppressed or even eliminated. The average centre carbon segregation index is reduced from 1.74 to 1.06, and negative segregation may occur. Meanwhile, the centre shrinkage cavity is clearly decreased and the centre porosity grade is remarkably reduced to 1.0. The calculation results of elastic–plastic FEM model showed that heavy reduction at the solidification end is very beneficial to improve the centre shrinkage cavity. 相似文献