氧含量对超低碳钢炼钢连铸过程夹杂物演变的影响

炼钢 ›› 2021, Vol. 37 ›› Issue (4): 38-48.

氧含量对超低碳钢炼钢连铸过程夹杂物演变的影响

黄淑媛1，罗钢2，杨健1，徐刚军2，周军军2，郑庆2

（1. 上海大学材料科学与工程学院省部共建高品质特殊钢冶金与制备国家重点实验室，上海 200444；
2.湖南华菱涟源钢铁有限公司, 湖南娄底 417000）

出版日期:2021-08-05 发布日期:2021-07-26

Effect of oxygen content on evolution of inclusions in ultra low carbon steel during steelmaking and continuous casting

Online:2021-08-05 Published:2021-07-26

摘要/Abstract

摘要： 针对不同氧含量超低碳钢的炼钢和连铸过程，分析了钢中夹杂物的演变规律及其原因。钢中最常见的夹杂物从转炉终点的Al₂O₃-CaO-MgO-SiO₂复合夹杂物，变为RH进站和脱碳终点的Al₂O₃-MnO, 再变为铝脱氧后和RH出站的Al₂O₃。由于连铸坯的冷却速度较慢，有利于TiN的充分析出，所以在中间包钢样中的TiN尺寸一般小于2 μm，而在连铸坯中的TiN尺寸一般大于2 μm；在中间包中常发现Al₂O₃-MnS复合夹杂，而在连铸坯中常发现Al₂O₃-MnS-TiN复合夹杂。中心夹杂物Al₂O₃尺寸较大时，Al₂O₃-TiN复合夹杂物的形状不规则；当Al₂O₃尺寸较小时，该复合夹杂的形状规则。因为大包钢水量为100 t时O31炉次中间包钢液氧质量分数（31×10^-6）高于O22炉次（22×10^-6），所以大包钢水量为100 t和50 t时O31炉次中间包含Al₂O₃夹杂物的数量高于O22炉次。因为铸坯中心最后凝固，S、Mn、Ti、N等元素的偏析造成大量细小的MnS、TiN和TiN-MnS析出物的生成，所以铸坯宽度1/2处的夹杂物数量密度最多。

关键词: 超低碳钢, 夹杂物演变, 热力学计算, 氧含量, 渣

Abstract:

For the process of steelmaking and continuous casting of ultra-low carbon steel with different oxygen contents, the evolution law of inclusions in steel were analyzed. The most common inclusions in steel change from the Al₂O₃-CaO-MgO-SiO₂composite inclusions at the end of converter to the Al₂O₃-MnO inclusions at the RH inlet and at the end of decarburization, and then to the Al₂O₃ inclusions after aluminum deoxidation and at the RH outlet. Because the slow cooling rate in continuous casting slab is conducive to the full precipitation of TiN, the size of TiN in tundish steel sample is generally smaller than 2 μm, while the size of TiN in continuous casting slab is generally larger than 2 μm. The composite inclusions of Al₂O₃-MnS are often found in tundish, while the composite inclusions of Al₂O₃-MnS-TiN are often found in continuous casting slab. When the size of the central Al₂O₃inclusion is large, the shape of the composite inclusion of Al₂O₃-TiN is irregular；when the size of the central Al₂O₃inclusion is small, the shape of the composite inclusion of Al₂O₃-TiN is regular. Because the oxygen mass fraction of heat O31 (31×10^-6) is higher than that of heat O22 (22×10^-6) in tundish at liquid steel quantity of ladle is 100 t, the number densities of the composite inclusions containing Al₂O₃ in tundish are higher than those of heat O22 at liquid steel quantity of ladle is 100 t and 50 t. Because of the final solidification in the center of the slab, the segregation of S, Mn, Ti, N and other elements results in the formation of a large number of fine MnS, TiN and TiN-MnS precipitates, the number density of inclusions at 1/2 of the slab width is the highest.

Key words: ultra-low carbon steel, evolution of inclusions, thermodynamic calculation, oxygen content, slag

黄淑媛, 罗钢, 杨健, 徐刚军, 周军军, 郑庆. 氧含量对超低碳钢炼钢连铸过程夹杂物演变的影响[J]. 炼钢, 2021, 37(4): 38-48.

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