|
|
|
| Effect of mold flux on surface quality of 430 stainless steel billet |
| MA Jun-peng1,2, LI Huan1,3 |
1. State Key Laboratory of Advanced Stainless Steel Materials, Taiyuan Iron and Steel (Group) Co., Ltd., Taiyuan 030003, Shanxi, China;
2. No.2 Steelmaking Plant, Shanxi Taigang Stainless Steel Co., Ltd., Taiyuan 030003, Shanxi, China;
3. Technology Center, Shanxi Taigang Stainless Steel Co., Ltd., Taiyuan 030003, Shanxi, China |
|
|
|
|
Abstract In order to solve the quality problems such as scab and depression on the surface of 430 stainless steel continuous casting slab produced by TISCO, hemispherical point melting point instrument, viscometer and SEM were used to study the influence of mold flux physical properties, continuous casting mold vibration parameters and cooling strength on surface defects. The results show that the main reasons for the surface defects are the low viscosity and weak crystallinity of the mold flux. Therefore, by optimizing the chemical composition of the mold flux, the viscosity of the protective slag is increased from 0.20 to 0.33 Pa·s, and the uniformity of slag film is improved; And the basicity is increased from 1.00 to 1.16, which improves the ability of the slag to control heat transfer. Therefore, the surface defects of the slab are eliminated, and the slab realizes no grinding. At the same time, due to the influence of fluorine content and viscosity in the slag, the life of immersion nozzle has been significantly improved, and the number of continuous casting furnaces has been increased from 10 to 12 furnaces.
|
|
Received: 09 June 2020
|
|
|
|
| [1] |
陈兴润.430铁素体不锈钢板坯组织分析[J].冶金分析,2015,35(4):49.
|
| [2] |
Lo K H,Shek C H,Lai J K L. Recent developments in stainless steels[J]. Materials Science and Engineering Reports,2009,65(4/5/6):39.
|
| [3] |
李君荣. 提高304不锈钢板坯表面质量工艺实践[J]. 连铸,2017,42(3):75.
|
| [4] |
赵建平,王帅,冯帅,等.低碳低硅铝镇静钢铸坯表面凹陷的成因及控制[J]. 连铸,2020,45(2):31.
|
| [5] |
叶红刚,陈兴润,莫志斌,等. 430铁素体不锈钢连铸板坯振痕[J]. 连铸,2015,40(2):67.
|
| [6] |
李殿明,邵天明,杨宪礼. 连铸结晶器保护渣应用技术[M]. 北京:冶金工业出版社,2008,217.
|
| [7] |
ZHOU L,WANG W,MA F,et al. A kinetic study of the effect of basicity on the mold fluxes crystallization[J]. Metallurgical and Materials Transactions:B,2012,43(2):354.
|
| [8] |
朱先飞,文光华,蒲大志,等. 稳态导热下连铸保护渣固态渣膜有效导热系数的研究[J]. 连铸,2018,43(2):25.
|
| [9] |
孔祥涛,周德,陈宏,等. 小方坯连铸中碳钢铸坯表面缺陷与保护渣性能选择[J]. 钢铁,2010,45(8):99.
|
| [10] |
Sakamaki T,Yagi T,Susa M. Form of fluorine in Na2O-NaF-SiO2 slags determined by infrared spectroscopy[J]. Ironmaking and Steelmaking,2003,30(5):396.
|
| [11] |
何生平,王谦,尤静林,等. 用拉曼光谱研究保护渣中氟对硅酸盐微结构的影响[C]//第八届全国连铸学术会议论文集.海口:中国金属学会,2007:441.
|
| [12] |
高泽平,苏旺. 结晶器保护渣对浸入式水口蚀损的影响[J]. 湖南冶金,2000(3):17.
|
| [13] |
Lance C H,Brian G T. Mold flux entrainment mechanisms[J]. Baosteel Technical Research,2010(s1):23.
|
| [14] |
谢鸿旭,高金星,赵飞,等. 连铸保护渣与ZrO2-C质耐火材料的作用机制[C]//2018国际耐火材料学术会议. 杭州:中钢集团洛阳耐火材料研究院有限公司,2018:60.
|
| [1] |
ZHAO Xianjiu1,2,ZHANG Jieyu2,3,LI Chuanjun2,3. Analysis of formation mechanism about Ca-Mg-Al spineltype inclusions in cold thin rolling sheet[J]. JOURNAL OF IRON AND STEEL RESEARCH , 2022, 34(7): 664-671. |
| [2] |
WANG Xu-feng, WANG Qiang-qiang, ZHANG Xu-bin, WANG Qian, HE Sheng-ping. Effect of AlN on properties of CaO-SiO2 based mold fluxes for high-Al steel[J]. Iron and Steel, 2022, 57(5): 64-71. |
| [3] |
YAN Xiao-peng, LIU Lei, HAN Xiu-li, WANG Yin-hui, ZHANG Di. Effect of boron on microstructure of fluorine-free mold fluxes[J]. Iron and Steel, 2022, 57(5): 72-80. |
| [4] |
LIU Yan-bin, TANG Hai-yan, WANG Kai-min, MA Yu, SHANG Guang-hao, ZHANG Li-ping, ZHANG Jia-quan. Effect of submerged entry nozzle structures on liquid surface flow behavior of slab continuous casting mold[J]. CONTINUOUS CASTING, 2022, 41(3): 1-10. |
| [5] |
LIU Chang-wei, ZOU Zhuo-ming. Application of robot automatic mould fluxes adding technology in Ningbo Iron and Steel Works[J]. CONTINUOUS CASTING, 2022, 41(3): 71-75. |
| [6] |
PIAO Zhan-long, WANG Xing-juan, ZHANG Cai-jun, ZHU Li-guang, LI Shao-ying, WANG Bo. Steel-slag interface reaction behavior in continuous casting mold of high titanium steel[J]. Iron and Steel, 2022, 57(3): 61-70. |
|
|
|
|
2020, Vol. 39 
