电磁搅拌作用下水口深度对液面波动的影响
张 静,杨 龙,吴会平
燕山大学车辆与能源学院,河北 秦皇岛 066004
Influence of nozzle submerged depth on fluctuation of liquid level with electromagnetic stirring
ZHANG Jing,YANG Long,WU Hui-ping
College of Vehicles and Energy,Yanshan University,Qinhuangdao 066004,Hebei,China
摘要 结晶器内液面波动会影响连铸坯的质量,施加电磁搅拌使钢液的液面呈旋转抛物面。电磁搅拌电流过大或拉速过高会造成保护渣卷渣现象,对铸坯质量造成不利的影响。以某钢厂[?]250 mm连铸圆坯结晶器电磁搅拌为研究对象,采用电磁-流体单相耦合的方式及流体体积函数VOF模型,建立描述结晶器电磁搅拌作用下液面波动的数学模型,研究电磁搅拌作用下浸入式水口深度对液面波动的影响。研究表明,通过增大水口深度,能够改善因电磁搅拌强度过大或拉速过大造成的卷渣现象,减小水口附近的液面波动。
关键词 :
电磁搅拌,水口深度,液面波动, 连铸
Abstract :Billet quality is affected by the molten steel level behavior in mold. The molten steel level is a rotating parabolic surface with electromagnetic stirring. The liquid level fluctuation near the outlet of nozzle will be increased with the growing stirring intensity and casting speed, which can cause the slag entrapment to happen. Based on the parameters of [?]250 mm round billet continuous casting with mold electromagnetic stirrer in a steel plant, the combined method of turbulence model and multiphase-flow model(VOF) was adopted to establish the mathematical model and study the influence of nozzle submerged depth on the liquid level fluctuation in the mold with electromagnetic stirring. The results show that: increasing the submerged depth of nozzle can decrease the slag entrapment, which was caused by large current intensity and large casting speed.
收稿日期: 2015-04-07
出版日期: 2016-03-18
[1]
韩至成.电磁冶金学[M],北京:冶金工业出版社,2001.
[1]
韩至成.电磁冶金学[M],北京:冶金工业出版社,2001.
[2]
赫冀成.电磁场对改善钢材质量的作用[J].钢铁, 2005, 40(1):24-30
[2]
赫冀成.电磁场对改善钢材质量的作用[J].钢铁, 2005, 40(1):24-30
[3]
于艳,刘俊江,徐海澄.结晶器电磁搅拌对连铸坯质量的影响[J].钢铁, 2005, 40(2):31-32
[3]
于艳,刘俊江,徐海澄.结晶器电磁搅拌对连铸坯质量的影响[J].钢铁, 2005, 40(2):31-32
[4]
Beitelman L.Effects of casting parameters on stirring flow velocity and its control in continuous casting molds[J].Iron Steelmaker, 2003, 30(2):17-23
[4]
Beitelman L.Effects of casting parameters on stirring flow velocity and its control in continuous casting molds[J].Iron Steelmaker, 2003, 30(2):17-23
[5]
郭戈,乔俊飞.连铸过程控制理论与技术[M].北京:冶金工业出版社, 2003.
[5]
郭戈,乔俊飞.连铸过程控制理论与技术[M].北京:冶金工业出版社, 2003.
[6]
干勇,仇圣桃,萧泽强.连续铸钢过程数学物理模拟[M],北京:冶金工业出版社,2001.
[6]
干勇,仇圣桃,萧泽强.连续铸钢过程数学物理模拟[M],北京:冶金工业出版社,2001.
[7]
张静,王恩刚,邓安元,许秀杰,赫冀成.大圆坯连铸M-EMS参数对磁场和流场分布的影响[J].连铸, 2011, (5):10-14
[7]
张静,王恩刚,邓安元,许秀杰,赫冀成.大圆坯连铸M-EMS参数对磁场和流场分布的影响[J].连铸, 2011, (5):10-14
[8]
Hirt C W, Nichols B D.Volume of fluid (VOF) method for the dynamics of free boundaries[J].J.Comput. Phys, 1981, 39(1):201-225
[8]
Hirt C W, Nichols B D.Volume of fluid (VOF) method for the dynamics of free boundaries[J].J.Comput. Phys, 1981, 39(1):201-225
[9]
X.Huang;BG. Thomas;F. M. Najjar. Modeling superheat removal during continuous casting of steel slabs[J].Metallurgical Transactions B, 1992, 13(23):339-356
[9]
X.Huang;BG. Thomas;F. M. Najjar. Modeling superheat removal during continuous casting of steel slabs[J].Metallurgical Transactions B, 1992, 13(23):339-356
[1]
池仕荣. 2#连铸机矩形坯断面改造与生产实践
[2]
兰鹏, 铁占鹏, 张伟, 苗红生, 严清忠, 张家泉. 连铸坯点状偏析缺陷研究进展
[3]
张思远1,2,龙木军1,2,艾松元1,2,谭锴1,2,陈登福1,2,黄云伟1,2. 连铸坯氧化行为及其对铸坯冷却降温的影响
[4]
张利民. 低碳钢板坯夹渣缺陷分析及控制
[5]
周超 周干水. 越南某钢厂小方坯连铸试生产稳定性诊断分析
[6]
金晓晖 乔建基 牛井超. 数字化交付在连铸工程建设及生产中的应用
[7]
谢世正. 二冷辊式电磁搅拌对高强钢低倍组织与性能的影响
[8]
朱苗勇. 新一代高效连铸技术发展思考
[9]
王璞,李少翔,陈列,陈希青,王小松,张家泉. 电磁搅拌对大圆坯结晶器冶金行为影响的探讨
[10]
陈威,周海忱,王胜东,张立峰,杨文. 吹氩流量对结晶器流场影响的插钉工业试验
[11]
艾新港,韩东,李胜利,刘海啸,宁哲,曾红波. 外加液态保护渣连铸生产实践与前景展望
[12]
方一鸣, 周健, 张文健, 冯小龙, 栾振兴. 伺服电机驱动的结晶器振动集散控制系统
[13]
仲红刚,刘海宁,徐智帅,龚永勇,李仁兴,翟启杰. 脉冲磁致振荡凝固均质化技术及装备
[14]
赵俊学,王泽,赵忠宇,卢亮,施瑞盟,崔雅茹. 氟化物挥发对连铸保护渣熔点的影响
[15]
郭军力,文光华,符姣姣,唐萍,谷少鹏. 基于表面粗糙度对连铸钢碳当量计算方法的判断
2016, Vol. 51 
