硼微合金化钢连铸坯角部裂纹控制

炼钢 ›› 2015, Vol. 31 ›› Issue (3): 22-26.

硼微合金化钢连铸坯角部裂纹控制

陈青¹,徐李军¹,仇圣桃²

1.钢铁研究总院连铸技术国家工程研究中心，北京 100081；2.天津钢铁集团，天津 300301；3.江西理工大学，江西赣州 341000

收稿日期:2014-07-10 修回日期:2014-11-20 接受日期:1900-01-01 出版日期:2015-06-05 发布日期:2015-06-08
通讯作者: 陈青 E-mail:237624181@qq.com

Industrial optimization experiment on billet transverse corner of boron micro-alloyed steel

Received:2014-07-10 Revised:2014-11-20 Accepted:1900-01-01 Online:2015-06-05 Published:2015-06-08

摘要/Abstract

摘要： 采用SEM对铸坯典型裂纹及金相组织进行了观察与能谱分析，发现硼微合金化钢裂纹敏感性高是由于BN的沿晶析出；采用Gleeble-3800热模拟试验机对3个加硼钢种高温力学性能进行了测试，并结合生产过程中连铸坯表面测温的结果，得出裂纹产生的外部因素是铸坯振痕过深以及低塑性温度区间弯曲矫直。根据试验研究及分析，对硼微合金化钢种采用先加铝脱氧后加钛固氮的成分优化，并采用优化振动参数为辅助手段。最终成功的将硼微合金化钢种的板材裂纹率从10%以上控制在1%以内。

关键词: 硼微合金化钢, 角部横裂纹, 析出物, 加钛固氮

Abstract: Typical cracks and microstructure were observed and analyzed by SEM, many precipitates were found along the grain which plays a significant role on the crack formation of boron micro-alloyed steels. High temperature mechanical properties of three boron micro-alloyed steels were tested by Gleeble-3800 thermal simulation testing machine and the actual slab temperature was measured in the continuous casting process. It shows that the external factors of transverse corner cracks is the deep oscillation mark and the straightening or bending process on low ductility temperature. According to the above research and analysis, the optimization scheme was concluded. The main optimization is adding titanium to nitrogen fixation after deoxidation by adding aluminum. The oscillation parameters was optimized as supplement. At last the crack rate of boron micro-alloyed steels was successful controlled from 10% to 1% .

Key words: boron micro-alloyed steel, transverse corner crack, precipitation, add titanium to nitrogen fixation

徐李军1，潘贻芳2，陈青3，仇圣桃1. 硼微合金化钢连铸坯角部裂纹控制[J]. 炼钢, 2015, 31(3): 22-26.

[1]	孙江波1，刘旋2，翟晓毅1，高建1. 20CrMnTi线材表面翘皮缺陷成因分析[J]. 炼钢, 2018, 34(5): 74-78.
[2]	刘启龙1,2，陶红标1，张慧1，刘国平2，刘学华3，臧红臣2. 倒角结构对连铸坯角部温度的影响及角横裂控制工业试验 [J]. 炼钢, 2018, 34(2): 31-37.
[3]	刘伟建1，王重君2，李双江3，王强1，蔡兆镇4，尹绍江1. 二冷强冷与回温工艺对微合金钢板坯边角裂纹的影响[J]. 炼钢, 2017, 33(5): 72-78.
[4]	王雷1，卿家胜1,2，窦坤1，张晓峰1，王宝1，黄运华3，刘青1 . YQ450NQR1高强耐候钢表面裂纹成因分析[J]. 炼钢, 2015, 31(4): 72-78.
[5]	康伟1，方恩俊2，李超2，于赋志1，张宁1，廖相巍1. 低合金钢宽厚铸坯直装工艺研究[J]. 炼钢, 2014, 30(6): 57-61.
[6]	艾西1，孙彦辉1，曾亚南1，刘瑞宁2，刘泳2. S355J2钢低温脆性区对表面横裂纹的影响研究[J]. 炼钢, 2014, 30(3): 69-73.
[7]	刘志明;张炯明. 微合金钢连铸坯热送热装析出物的研究[J]. , 2013, 29(3): 49-52.
[8]	白瑞国;;张兴利;田鹏;高海;. 热轧带钢Q235B边裂缺陷成因及控制[J]. , 2013, 29(2): 22-24,7.
[9]	罗衍昭;张炯明;肖超;刘志明;吴苏州. 热装微合金化中厚板表面裂纹的研究现状[J]. , 2011, 27(4): 74-78.
[10]	辛建卿 ;岳尔斌. Q345B钢连铸坯角裂形成原因分析[J]. , 2007, 23(06): 16-19.