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亚包晶钢铸坯脆性区对表面裂纹的影响 被引量:2

Influence of Strands' Brittle Zones on Surface Cracks of Hypo-peritectic Steel
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摘要 针对微合金亚包晶钢凝固过程中产生大量裂纹缺陷的现状,采用光学显微镜、扫描电镜及能谱分析仪对铸坯表面裂纹进行分析,并对析出物进行热力学计算,利用Gleeble-1500对铸坯热塑性进行分析研究。结果表明:裂纹处存在(Fe,Mn,Si,Al)(S,O)等夹杂物,加剧应力对基体的影响;裂纹处存在Ti-Al(C,N)夹杂物,增加了γ→α转变的脆性,横裂纹敏感性增加。高温脆性区易产生纵裂,断面收缩率(Z)最小值为37.59%,纵裂纹敏感区间为1454~1478℃。900~750℃为低温脆性区,易产生横裂纹,Z最小值为45.24%,横裂纹敏感区间900~750cc。896oC时,铁素体开始析出,使得晶界上进一步集中,导致裂纹发生。 In view of large amounts of cracks formed in the hypo-peritectic HSLA steel during solidifica- tion, the cracks on the surface of strands were analyzed by optical microscope, SEM and EDS, and the precipitates were studied by thermodynamic calculation. Furthermore, hot ductility was studied by Gleeble-1500. The results showed that steel matrix was deteriorated by inclusions (Fe, Mn, Si, AI) (S, O) in cracks, and transverse cracking sensitivity was increased by Ti-AI-(C,N) inclusions. The longitude cracks tend to appear in the high-temperature brittle zone with a longitude cracking sensitive range of 1 454 - 1 478 ℃, and the minimum value of Z was 37.59% ; the transverse cracks tend to ap- pear in the low-temperature brittle zone with a longitude cracking sensitive range of 900 - 750 ℃, and the minimum value of Z was 45.24%. Precipitating at 896 ℃, the ferrite led to strain concentration on the grain boundary, resuhting in crack formation.
作者 曾亚南 孙彦辉 艾西 马志飞 刘瑞宁 刘泳
机构地区 北京科技大学冶金与生态工程学院 河北钢铁集团石家庄钢铁有限责任公司
出处 《钢铁钒钛》 CAS 北大核心 2013年第6期79-84,共6页 Iron Steel Vanadium Titanium
基金 国家自然科学基金(51274032)资助项目
关键词 亚包晶钢 裂纹敏感区 脆性区 铁素体 析出物 hypo-peritectic steei, eraeking sensitive range, brittle zone, ferrite, precipitate
分类号 TF777 [冶金工程—钢铁冶金]
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钢铁钒钛
2013年 第6期

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