20 t 3流T形中间包流场优化

炼钢 ›› 2015, Vol. 31 ›› Issue (2): 17-20.

20 t 3流T形中间包流场优化

赵冠夫

(山东钢铁股份有限公司莱芜分公司特钢事业部，山东莱芜 271104)

收稿日期:2014-07-30 修回日期:2014-08-23 接受日期:1900-01-01 出版日期:2015-04-05 发布日期:2015-04-23
通讯作者: 赵冠夫 E-mail:zhaoguanfu@126.com

Optimization on the flow distribution of 20 t three strand T shape tundish

Received:2014-07-30 Revised:2014-08-23 Accepted:1900-01-01 Online:2015-04-05 Published:2015-04-23

摘要/Abstract

摘要： 依据相似原理利用水模型试验测定了20 t 3流T形中间包不同试验方案下的RTD曲线，通过分析各方案的RTD曲线和混合模型计算结果，得出中间包挡墙最佳优化方案；优化后中间包钢液混匀时间由近250 s降低至约100 s，平均停留时间由500 s以上提高到1 000 s以上，包内死区体积比由近60 %降至约20 %，实测各流钢液温度差由5.33 ℃降至1.17 ℃，50 μm以上铸坯大型夹杂物均不超过6.5 mg/10 kg；钢中小粒径夹杂物尺寸基本不超过6 μm。生产实践表明，中间包新挡墙设置有利于均匀钢液温度以及增大夹杂物碰撞上浮去除的几率。

关键词: 中间包, 水模试验, 钢水流场, 优化

Abstract: Based on the similarity principle，RTD curves of different testing schemes were investigated in 20 t three strand T shape tundish by using water model test. By analyzing of the scheme of RTD curves and the mixed model calculation results, the best optimization solution was concluded for the tundish retaining wall. After the flow optimization, mixing evenly time of liquid steel decreased from nearly 250 s to about 100 s, mean residence time increased from 500 s to 1 000 s, package dead volume decreased from nearly 60 % to about 20 %, every flow liquid steel temperature difference decreased from 5.33 ℃ to 1.17 ℃. The large inclusions (more than 50 μm) was not more than 6.5 mg/10 kg in slab, the small diameter inclusion size was less than 6 μm in steel. The production practice shows that the new tundish retaining wall is beneficial to the uniform temperature of molten steel and the probability of collision removal rate of inclusions.

Key words: tundish, water model experiment, molten steel flow field, optimization

赵冠夫. 20 t 3流T形中间包流场优化[J]. 炼钢, 2015, 31(2): 17-20.

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