Surface microstructure control of microalloyed steel during slab casting

IF 3.1 2区 材料科学 Q1 METALLURGY & METALLURGICAL ENGINEERING Journal of Iron and Steel Research(International) Pub Date : 2017-08-01 DOI:10.1016/S1006-706X(17)30120-6
Li-jun Xu, Shu-lan Zhang, Chun-gen Qiu, Sheng-tao Qiu, Xing-zhong Zhang
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引用次数: 3

Abstract

Lots of work has been done to investigate slab surface microstructure evolution during continuous casting in order to improve hot ductility and avoid transverse cracks. The slab surface microstructure after continuous casting was characterized by optical microscopy, and the precipitation behavior was investigated by transmission electron microscopy. At the same time, the mechanical properties of the slabs were measured using a Gleeble 1500D thermal simulator and the transformation temperatures were examined by means of a thermal dilatometer. The experimental results show that homogeneous microstructure without film-like ferrites and chain-like precipitates at grain boundary can be obtained through surface intensive cooling and transverse cracks do not occur on the slab surface. For the experimental steel, fine ferrite can form at slab surface when the water flow rate is larger than 1560 L/min at vertical section. As the distance to surface increases, microstructure turned to ferrite and pearlite. Moreover, nano-size carbonitrides precipitated in the ferrite grain and the size was larger at the junction of the dislocations. The mechanical experiment results show that the hot ductility of the sample deformed at 650 °C was better than that of the sample deformed at 750 °C. The reason is that film-like ferrite formed at the grain boundary in the sample deformed at 750 °C. Thus, the slab must be cooled quickly below Ar3 to prevent the occurrence of film-like ferrite and transverse cracks on the slab surface during casting.

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板坯连铸过程中微合金钢表面组织的控制
为了提高连铸坯的热延展性和避免横向裂纹,人们对连铸坯表面组织的演变进行了大量的研究。用金相显微镜对连铸坯的表面组织进行了表征,并用透射电镜对连铸坯的析出行为进行了研究。同时,用Gleeble 1500D热模拟器测量了板坯的力学性能,并用热膨胀仪检测了板坯的相变温度。实验结果表明:通过表面强化冷却可以获得均匀的组织,晶界处没有膜状铁素体和链状析出物,板坯表面不产生横向裂纹;对于实验钢,当垂直断面水流速度大于1560 L/min时,板坯表面可形成细铁素体。随着与表面距离的增加,组织转变为铁素体和珠光体。铁素体晶粒中有纳米碳氮化物析出,且位错交界处的碳氮化物尺寸较大。力学试验结果表明,650℃变形试样的热塑性优于750℃变形试样。原因是在750℃下变形的试样在晶界处形成了薄膜状的铁素体。因此,铸坯必须迅速冷却到Ar3以下,以防止铸坯表面出现膜状铁素体和横向裂纹。
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来源期刊
CiteScore
4.30
自引率
0.00%
发文量
2879
审稿时长
3.0 months
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