钢液凝固与冷却过程及固体钢加热过程钢中非金属夹杂物成分动力学转变的几个概念和特征曲线 |
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引用本文: | 张月鑫,张立峰,王举金,任英,任强,杨文. 钢液凝固与冷却过程及固体钢加热过程钢中非金属夹杂物成分动力学转变的几个概念和特征曲线[J]. 工程科学学报, 2023, 45(3): 369-379. DOI: 10.13374/j.issn2095-9389.2021.11.01.005 |
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作者姓名: | 张月鑫 张立峰 王举金 任英 任强 杨文 |
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作者单位: | 1.北京科技大学冶金与生态工程学院,北京 100083 |
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基金项目: | 国家自然科学基金资助项目(U1860206,51725402);河北省省级科技计划资助项目(20591001D) |
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摘 要: | 利用钢中非金属夹杂物成分变化的集成模型,介绍了夹杂物成分随时间和冷却速率的变化,提出了夹杂物成分转变分数的概念,然后介绍了夹杂物成分转变的等温转变曲线(TTT)、连续冷却转变曲线(CCT)和等径转变曲线(TDT)的概念及应用.该集成模型考虑了钢液流动、传热、凝固和元素偏析,也考虑了钢与夹杂物反应的热力学和动力学.然后以管线钢、重轨钢和轴承钢为例,进一步分析讨论了钢液凝固与冷却过程中的冷却速率、固体钢加热过程中的加热温度和加热时间、钢成分以及夹杂物尺寸等参数对夹杂物成分转变的影响.这些概念和特征曲线能够直观展示在钢液凝固冷却过程及固体钢加热过程钢中非金属夹杂物的成分转变,将钢中夹杂物的控制方略从钢液拓展到固体钢中.
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关 键 词: | 夹杂物 动力学模型 转变分数 冷却速率 等温转变 连续冷却转变 等径转变 |
收稿时间: | 2021-11-01 |
Concepts and characteristic curves for the kinetic transformation of nonmetallic inclusions in liquid steel during solidification and cooling and in solid steel during heating process |
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Affiliation: | 1.School of Metallurgical and Ecological Engineering, University of Science and Technology Beijing, Beijing 100083, China2.School of Mechanical and Materials Engineering, North China University of Technology, Beijing 100144, China3.School of Mechanical Engineering, Yanshan University, Qinhuangdao 066004, China |
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Abstract: | The composition of nonmetallic inclusions in the steel varied continuously during the solidification and cooling process of the molten steel and the heating process of the solid steel. To quantitatively evaluate this evolution of inclusion composition, this study proposes an integrated model and discusses the effect of the cooling rate during continuous casting and the holding time during the heating process on the transformation of the inclusion composition. Besides, a concept of transformation fraction of inclusion composition was put forward. Using this concept, several characteristic curves with a significant application value were raised, including the isothermal transformation curve (time-temperature-transformation, TTT), continuous cooling transformation curve (CCT), and equal diameter transformation curve (time diameter transformation, TDT). The integrated model consisted of the fluid flow, heat transfer, solidification and element segregation, thermodynamic equilibrium between the steel and inclusions, mass transfer kinetics in the steel and inclusions, and the variation of the spatial position of the calculation domain. Employing the integrated model, the spatial distribution of inclusion composition in blooms was obtained. Since the transformation of inclusion composition was mainly due to reactions between CaO and CaS, the transformation fraction was used to characterize the extent of the transformation, which was defined as the ratio of the content of CaS in inclusions at a certain time to that in thermodynamic equilibrium at room temperature. The continuous cooling transformation curve of the inclusion composition in the bearing steel was obtained to analyze the effect of the cooling rate on the inclusion composition during the solidification and cooling of liquid steel. At a fixed cooling rate, the transformation fraction of the inclusion composition increased with the reaction time. Simultaneously, the critical cooling rate of different types of steel could be obtained intuitively using these curves. The isothermal transformation curve of the inclusion composition in the heavy rail steel was also acquired to estimate the effect of the heating temperature and holding time on the inclusion composition in solid steels. With the increase of the holding time and heating temperature, the transformation fraction of the inclusion composition had an apparent increase. Moreover, the influence of the steel composition and inclusion size on the transformation of the inclusion composition could be determined using the equal diameter transformation curve in pipeline steel at 1473 K. Inclusions with a small size almost transformed completely within 60 min, while larger inclusions only exhibit a slight change even after heating for several hours. These concepts and characteristic curves can intuitively show the composition transformation of nonmetallic inclusions in steels during the solidification and cooling of liquid steel and heating of solid steel, expanding the control strategy of inclusions in steels from liquid steel to solid steel. |
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