Precipitation characteristic of high strength steels microalloyed with titanium produced by compact strip production 被引量：7

Precipitation characteristic of high strength steels microalloyed with titanium produced by compact strip production

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摘要 Transmission electron microscopy （TEM） and physics-chemical phase analysis were employed to investigate the precipitates in high strength steels microalloyed with Ti produced by compact strip production （CSP）. It was seen that precipitates in Ti microalloyed steels mainly included TiN, Ti4C2S2, and TiC. The size of TiN particles varied from 50 to 500 nm, and they could precipitate during or before soaking. The Ti4C2S2 with the size of 40-100 nm might precipitate before rolling, and the TiC particles with the size of 5-50 nm precipitated heterogeneously. High Ti content would lead to the presence of bigger TiC particles that precipitated in austenite, and by contrast, TiC particles that precipitated in ferrite and the transformation of austenite to ferrite was smaller. They were less than 30 nm and mainly responsible for precipitate strengthening. It should be noted that the TiC particles in higher Ti content were generally smaller than those in the steel with a lower Ti content. Transmission electron microscopy （TEM） and physics-chemical phase analysis were employed to investigate the precipitates in high strength steels microalloyed with Ti produced by compact strip production （CSP）. It was seen that precipitates in Ti microalloyed steels mainly included TiN, Ti4C2S2, and TiC. The size of TiN particles varied from 50 to 500 nm, and they could precipitate during or before soaking. The Ti4C2S2 with the size of 40-100 nm might precipitate before rolling, and the TiC particles with the size of 5-50 nm precipitated heterogeneously. High Ti content would lead to the presence of bigger TiC particles that precipitated in austenite, and by contrast, TiC particles that precipitated in ferrite and the transformation of austenite to ferrite was smaller. They were less than 30 nm and mainly responsible for precipitate strengthening. It should be noted that the TiC particles in higher Ti content were generally smaller than those in the steel with a lower Ti content.

作者 Jian Zhou Yonglin Kang Xinping Mao

机构地区 School of Materials Science and Engineering CSP Institute for Technology

出处《Journal of University of Science and Technology Beijing》 CSCD 2008年第4期389-395,共7页 北京科技大学学报（英文版）

关键词 compact strip production （CSP） PRECIPITATION Ti microalloyed steels nanometer particle compact strip production （CSP） precipitation Ti microalloyed steels nanometer particle

分类号 TG142 [金属学及工艺—金属材料]

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参考文献11

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Precipitation characteristic of high strength steels microalloyed with titanium produced by compact strip production 被引量：7

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