姜东滨, 智建国, 宋海, 高勇, 张立峰. 连铸坯脱氢退火数值模拟[J]. 工程科学学报, 2020, 42(7): 862-868. DOI: 10.13374/j.issn2095-9389.2020.03.16.003
引用本文: 姜东滨, 智建国, 宋海, 高勇, 张立峰. 连铸坯脱氢退火数值模拟[J]. 工程科学学报, 2020, 42(7): 862-868. DOI: 10.13374/j.issn2095-9389.2020.03.16.003
JIANG Dong-bin, ZHI Jian-guo, SONG Hai, GAO Yong, ZHANG Li-feng. Numerical simulation of dehydrogenation annealing in bloom[J]. Chinese Journal of Engineering, 2020, 42(7): 862-868. DOI: 10.13374/j.issn2095-9389.2020.03.16.003
Citation: JIANG Dong-bin, ZHI Jian-guo, SONG Hai, GAO Yong, ZHANG Li-feng. Numerical simulation of dehydrogenation annealing in bloom[J]. Chinese Journal of Engineering, 2020, 42(7): 862-868. DOI: 10.13374/j.issn2095-9389.2020.03.16.003

连铸坯脱氢退火数值模拟

Numerical simulation of dehydrogenation annealing in bloom

  • 摘要: 采用数学模拟方法研究钢轨钢连铸坯脱氢退火行为,分析不同退火温度、退火时间条件下连铸坯脱氢效果,优化了脱氢退火工艺。在脱氢退火过程中,连铸坯角部和边部的氢含量快速降低,而连铸坯中心氢含量在加热段后期开始降低;随着退火温度的升高,连铸坯中心脱氢的起始点明显提前,最大脱氢速率显著增加。随着均热段时间逐渐延长,连铸坯中心氢含量明显降低,但脱氢速率的增加幅度逐渐减小。通过优化脱氢退火工艺参数,连铸坯中心氢的质量分数能够降低至0.6×10−6,脱氢效果显著。

     

    Abstract: Due to moisture in the ore, auxiliary material, and ladle refractory material, the hydrogen element is easily enriched in molten steel. In the metallurgy process, some hydrogen atoms form bubbles and are removed by gravity, whearas others solidify in the strand and remain in the produced steel. When the hydrogen content reaches a certain critical value, the enriched hydrogen atoms congregate to produce a white spot, which greatly reduces the strength and toughness of the steel product, and leads to brittle fracture during its service period. At present, the RH (Ruhrstahl–Heraeus) and VD (vacuum degasser) refining processes are commonly applied in steel plants, which can reduce the hydrogen content to less than 2×10−6. With the demand for high quality steel, the hydrogen content must be further decreased, so hydrogen diffusion in solid steel during the annealing process is gradually attracting increasing attention. In this study, a two-dimensional model was built to investigate the characteristic of dehydrogenation in the bloom annealing process of rail steel. Moreover, the effect of annealing temperature and annealing time on hydrogen diffusion were analyzed, and the annealing parameters were optimized. During the dehydrogenation annealing process, the hydrogen content at the corners and edges of the bloom are found to decrease rapidly, while that in the center of the strand begin to decrease in the later heating stage. As the annealing temperature increases, the starting point of dehydrogenation in the bloom center moves ahead and the maximum dehydrogenation rate increases significantly. With the extension of the soaking period, the central hydrogen content of bloom decreases significantly, but the increase rate of the dehydrogenation gradually decreases. By optimizing the bloom annealing parameters, the hydrogen content in the bloom can be steadily reduced to 0.6×10−6, which fully meets the requirement of high quality steel production.

     

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