钢包底吹氩精炼混匀判据及合金加入位置研究

›› 2016, Vol. 32 ›› Issue (3): 12-17.

钢包底吹氩精炼混匀判据及合金加入位置研究

梅亚光¹,程树森¹,张鹏²,郑跃强³,李积鹏⁴,邹明³

1. 北京科技大学
2. 北京科技大学冶金与生态工程学院
3. 酒泉钢铁（集团）有限责任公司
4. 酒泉钢铁（集团）有限责任公司碳钢薄板厂

收稿日期:2016-01-06 修回日期:2016-01-12 接受日期:1900-01-01 出版日期:2016-06-05 发布日期:2016-06-15
通讯作者: 梅亚光 E-mail:myg_ustb@163.com
基金资助:
国家自然科学基金资助项目

Study of mixing criterion and alloy adding position during argon bottom blowing refining process

1. University of Science and Technology Beijing
2.

Received:2016-01-06 Revised:2016-01-12 Accepted:1900-01-01 Online:2016-06-05 Published:2016-06-15

摘要/Abstract

摘要： 在钢包底吹氩水模型试验中，传统混匀判据是通过在钢包模型中安装1~2个电导探头监测示踪剂浓度变化，从而判断混匀程度。由于钢包各处混匀时间差异较大，加之监测点位置选择的主观性，易造成混匀时间测量不准。针对该问题，通过数值计算的研究方法模拟了钢液的流动与混匀过程。计算结果表明：随着钢液混匀程度的增加，钢液中整体示踪剂浓度标准差降低，当整体示踪剂浓度标准差在约0.02以下时，钢包混匀程度已达到 100%，基于此提出在水模型试验中测量混匀时间时，可以在钢包中3个不同高度处各安装3个电导探头监测示踪剂浓度变化，当这9处监测点示踪剂浓度标准差小于0.02时，即可认为达到混匀。研究了不同示踪剂加入位置下的混匀时间，结果表明，在钢包一侧距离钢包中心约1/6R处加入示踪剂时，混匀时间最短为77.5 s，该位置为理想的合金加入位置。而在靠近气液两相区的钢包液面边缘处加入示踪剂时，混匀时间最长为137.3 s，在该位置加入合金则不利于钢液的快速混匀。

关键词: 底吹氩, 钢液流动, 混匀时间, 加入位置, 数值模拟

Abstract: In the hydraulic model experiments of bottom argon blowing refining process, the traditional mixing criterion was determining the mixing degree by monitoring the tracer concentration with the help of one or two conductivity electrodes which were set in the ladle model. Due to the difference between the local mixing time at different positions and the randomness in the choice of monitoring positions, the measured mixing time may not be realistic. In regard to this, the fluid flow and mixing process were simulated by numerical calculation. The result showed that with the increase of mixing degree, the standard deviation of tracer concentration decreased. When the standard deviation was lower than 0.02, the mixing degree was 100%. Based on this, it was raised that 9 conductivity electrodes should be set at three sections which were distributed alone the height. When the standard deviation of tracer concentration was lower than 0.02, the concentration could be believed to be uniform. The effect of adding position on mixing time was also studied in this paper. The result showed that the mixing time was about 77.5s when the tracer was added from the position which was located at a distance about 1/6 radius from the center. When the tracer was added from the edge which was close to the plume, the mixing time was about 137.3s. The former position was the ideal alloy adding position.

Key words: bottom argon blowing, fluid flow, mixing time, adding position, numerical simulation

中图分类号:

TF769.9

梅亚光程树森张鹏郑跃强李积鹏邹明. 钢包底吹氩精炼混匀判据及合金加入位置研究[J]. , 2016, 32(3): 12-17.

[1]	李琳1，2，周立磊1，2，李明明1，2，李强1，2，邹宗树1，2. 漩流氧枪应用于转炉炼钢的水模试验研究[J]. 炼钢, 2020, 36(3): 1-6.
[2]	颜慧成1, 丁剑1, 王现周1, 史进强1, 何顺生2, 唐笑宇2. 转炉底吹工艺水模试验与工业应用[J]. 炼钢, 2020, 36(2): 1-5.
[3]	蔡亦凡1，孙彦辉1，杨文中2，黎建全2，陈天明3，李志强3. 变径通道在八字型感应加热中间包中的应用[J]. 炼钢, 2020, 36(2): 42-47.
[4]	伍旋1,2，王明林2，张延玲1，张慧2，张开发2. 高拉速板坯结晶器流场影响因素的模拟研究[J]. 炼钢, 2020, 36(1): 27-33.
[5]	孙贞贞1,2，但斌斌1,2，牛清勇1,2，欧阳德刚3，容芷君1,2. KR法铁水脱硫搅拌流场的数值分析[J]. 炼钢, 2019, 35(6): 1-5.
[6]	宋景欣1，张发斌2. 基于热流密度分布模型的连铸倒角结晶器温度分布研究 [J]. 炼钢, 2019, 35(6): 35-40.
[7]	林大帅，李晓斐，张文涛，李艳峰，王景宁，刘剑锋. 轻压下对C610L连铸板坯内部品质的改善[J]. 炼钢, 2019, 35(5): 50-53.
[8]	周泉林,杨晓江1，张全1，孙建月2,3，杜文斌2,3，季伟烨2,3，钟良才2,3. 底枪支数和布置对复吹转炉熔池混匀的影响[J]. 炼钢, 2019, 35(4): 12-18.
[9]	张燕超1,2,张彩军1,2,王博1,2，周泉林2. 高马赫数氧枪枪位对100 t转炉自动炼钢熔池流速的影响[J]. 炼钢, 2019, 35(2): 1-10.
[10]	张旭孝1，林路2. 钢包底吹氩系统优化与工业试验[J]. 炼钢, 2019, 35(2): 25-29.
[11]	张燕超1,2，张彩军1,2,周泉林2. 高马赫数氧枪的数值模拟及优化实践[J]. 炼钢, 2018, 34(6): 1-6.
[12]	方瑞1,雷少武1,王建军2. 七流中间包的结构优化与数值模拟[J]. 炼钢, 2018, 34(6): 15-22.
[13]	李海英，刘东，张春奇. 蒸发冷却器内双流喷嘴雾化及蒸发特性数值模拟[J]. 炼钢, 2018, 34(6): 69-74.
[14]	汤磊, 张炯明, 翟明智. 连铸板坯轧制过程缩孔闭合行为的数值模拟[J]. 炼钢, 2018, 34(4): 59-65.
[15]	郭振和1，邓丽琴1，屈天鹏2. 吹氩钢包内气液两相流动及均混行为的数值模拟[J]. 炼钢, 2018, 34(3): 18-24.