Effect of Different Argon Blowing Modes on Refining Effect of Molten Steel

doi:10.20057/j.1003-8620.2023-00149

Special Steel ›› 2024, Vol. 45 ›› Issue (1): 54-60.DOI: 10.20057/j.1003-8620.2023-00149

• Smelting and Solidification • Previous Articles Next Articles

Effect of Different Argon Blowing Modes on Refining Effect of Molten Steel

Yang　Fengguo¹， Wang　Xiaoying²， Zhou　Mingxing¹， Zheng　Bing³， Xu　Dong^2，4

1 Whole Processes of High Quality Fastener Application Technology Research Center of Universities in Hebei Province， Hebei Taihang Iron and Steel Group Co.，Ltd.， Handan 056305， China；
2 Technology Innovation Center for High Quality Cold Heading Steel of Hebei Province， Hebei University of Engineering， Handan 056038， China；
3 College of Materials and Metallurgy， Liaoning Science and Technology University， Anshan 114051， China；
4 Engineering Research Center for High Toughness Wind Tower Steel of Hebei Province， Hebei University of Engineering， Handan 056035， China

Received:2023-07-19 Online:2024-01-30 Published:2024-02-01

不同钢包底吹氩模式对钢液精炼效果的影响

杨风国¹，王晓英²，周明星¹，郑冰³，徐东^2，4

1 河北太行钢铁集团有限公司河北省高校高端紧固件全流程应用技术研发中心，邯郸 056305；
2 河北工程大学河北省高品质冷镦钢技术创新中心，邯郸 056038；
3 辽宁科技大学材料与冶金学院，鞍山114051；
4 河北工程大学河北省高韧性风塔钢工程研究中心，邯郸 056305

作者简介:杨风国（1970—），男，工程师

Abstract

Abstract: In this paper， one 180 t double-hole bottom argon blowing ladle is taken as the research object. Based on the specific production conditions， six modes of argon bottom blowing in ladle are numerically simulated， and combined with the field test， it is compared with the argon blowing mode currently adopted. The results show that：（1） The mixing time of molten steel decreases with the increase of argon blowing amount. When argon blowing amount is constant， the argon blowing mode with differential flow rate is stronger than that with constant flow rate. （2） Different modes of argon blowing at the bottom of ladle have different locations and areas of slag holes. When the total flow rate is constant， the maximum velocity of molten steel surface in the differential flow argon blowing mode is greater than that in the constant flow argon blowing mode， which is easy to cause slag entrapment. （3） The fluctuation of slag layer thickness at the slag line in differential flow argon blowing mode is greater than that in constant flow argon blowing mode， and the greater the flow difference， the more severe the fluctuation. （4） The differential flow argon blowing mode further strengthens the refining effect of molten steel by argon blowing at the bottom of ladle through the cooperation of "strong-weak" streams. And the industrial test shows that the number of larger inclusions in steel is obviously more than that in argon blowing mode （400 L/min-600 L/min） with constant flow rate （500 L/min-500 L/min）.

Key words: Ladle Argon Blowing, Numerical Simulation, Mixing Time, Slag Eye

摘要： 以180 t双孔底吹氩钢包为研究对象，对6种钢包底吹氩模式进行数值模拟，并结合现场试验与当前采用的吹氩模式进行对比。研究发现：（1）钢液的混匀时间随吹氩量的增加而减少，吹氩量一定时，差流量吹氩模式对钢液的搅拌强于等流量吹氩模式。（2）不同的钢包底吹氩模式，渣眼形成的位置不同，渣眼面积也不同。总流量一定时，差流量吹氩模式钢液面最大流速大于等流量吹氩模式，易发生钢液卷渣。（3）差流量吹氩模式渣线处渣层厚度的波动大于等流量吹氩模式，且流量差值越大，波动越剧烈。（4）差流量吹氩模式通过“强-弱”流股的配合，进一步强化了钢包底吹氩的钢液精炼效果。工业试验表明，采取等流量吹氩模式（500 L/min-500 L/min），钢中的较大夹杂物的数目明显多于差流量吹氩模式（400 L/min-600 L/min）。

关键词: 钢包吹氩, 数值模拟, 混匀时间, 渣眼

CLC Number:

TF769

Yang　Fengguo, Wang　Xiaoying, Zhou　Mingxing, Zheng　Bing, Xu　Dong. Effect of Different Argon Blowing Modes on Refining Effect of Molten Steel[J]. Special Steel, 2024, 45(1): 54-60.

杨风国, 王晓英, 周明星, 郑冰, 徐东. 不同钢包底吹氩模式对钢液精炼效果的影响[J]. 特殊钢, 2024, 45(1): 54-60.

References

［1］王时松，郭晓晨，姜文欢，等. 100t底吹氩钢包流场数值模拟及现场实践［J］. 中国冶金， 2018， 28（12）： 51-55.
［2］马　骏，沈巧珍，阳　方，等. 底吹氩钢包内三维流场的数值模拟［J］. 武汉科技大学学报， 2010， 33（2）： 124-128.
［3］张真铭，蔡茜娜，熊辉辉，等. 120 t钢包底吹氩工艺优化水模型研究［J］. 特殊钢， 2017， 38（4）： 9-12.
［4］赵红光，王宏丹，任兵芝，等. 120 t钢包底吹氩混匀过程的数值模拟研究［J］. 热加工工艺， 2018， 47（11）： 76-78+83.
［5］陈兴华，胡志勇，李家通，等. 120 t吹氩钢包流场与温度场的优化［J］. 材料与冶金学报， 2022， 21（3）： 157-161.
［6］杨亚迪，赵　晶，崔剑征. 180t钢包底吹氩过程钢液流场特性数值模拟［J］. 特殊钢， 2021， 42（5）： 6-10.
［7］钟良才，李　壮，梁　锋，等. 120t精炼钢包底吹氩物理模拟［J］. 过程工程学报， 2010， 10（S1）： 103-107.
［8］胡群，李小松，张家泉，等. 差流量吹氩模式对150 t钢包混匀与顶渣行为的影响［J］. 钢铁，2020，55（12）：31-38.
［9］卢　叶，唐　萍，文光华，等. 透气砖布置和吹氩流量对钢包内钢液流动行为的影响［J］. 钢铁研究学报， 2014， 26（7）： 41-47.
［10］ Tang H Y， Liu J W， Zhang S， et al. A novel dual plugs gas blowing mode for efficient ladle metallurgy［J］. Ironmaking & Steelmaking， 2019， 46（5）： 405-415.
［11］刘风刚，任　英，段豪剑，等. 钢包软吹过程优化数学模拟和工业试验研究［J］. 炼钢， 2019， 35（6）： 24-30.
［12］肖　震，郑淑国，朱苗勇. 浇注钢包环出钢口四孔透气塞吹氩控制下渣工艺［J］. 钢铁研究学报， 2022， 34（2）： 133-141.
［13］任　英，张立峰，李燕龙，等. 底吹氩钢包内钢液流动与合金扩散的数值模拟［J］. 钢铁研究学报， 2014， 26（7）： 28-34.
［14］巨建涛，王　睿，折　媛，等. 钢包底吹氩去除钢中夹杂物的数值模拟［J］. 过程工程学报， 2015， 15（1）： 68-73.
［15］ Asai S，Kawachi M，Muchi I. Mass transfer rate in ladle refining process［J］. Injection Metallurgy，1983，12：4-9.

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Effect of Different Argon Blowing Modes on Refining Effect of Molten Steel

不同钢包底吹氩模式对钢液精炼效果的影响

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