| 光谱学与光谱分析 |
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| Research on Reducing Mold Flux’s Radiative Heat Transfer Based on FTIR and XRD |
| DIAO Jiang,XIE Bing* |
| College of Material Sciences and Engineering, Chongqing University, Chongqing 400044, China |
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Abstract The mold fluxes samples containing transition metal oxides TiO2 were designed based on the composition of commercial mold fluxes in continuous casting of steel, and the relation between radiative heat transfer and the content of TiO2 was obtained through FTIR spectrum analysis and XRD analysis. The result of FTIR analysis indicates that TiO2 has a great negative effect on infrared transmittance of flux samples in the wavelength range of 1-6 μm. The result of XRD analysis indicates that crystallization of cuspidine was restrained with addition of TiO2, and CaTiO3 and other phases were found in the samples. The decrease in cuspidine phase is beneficial to strand lubrication in the mold. Radiation heat flux from the strand to the mold was calculated using a radiative heat transfer model concluded in previous study. Addition of TiO2 was found to result in a remarkable decrease in radiation heat flux for both glassy and crystalline samples, and the heat flux tended to decrease with increasing TiO2, with the maximal decrease reaching 30%. As a result of great refraction and scatter at surface and grain boundaries of samples, the negative effect of crystalline samples was much larger than that of the glassy ones.
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Received: 2007-10-22
Accepted: 2008-01-26
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Corresponding Authors:
XIE Bing
E-mail: bingxie@cqu.edu.cn
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[1] CHI Jing-hao, GAN Yong-nian(迟景灏, 甘永年). CC Mold Fluxes(连铸保护渣). Shenyang: Northeastern University Press(沈阳:东北大学出版社), 1992. 5.
[2] ZHU Guo-ling, ZHANG He-lin, XI Chang-suo, et al(朱果灵, 张贺林, 席常锁, 等). Iron and Steel(钢铁), 1993, 28(8): 27.
[3] LIU Cheng-jun, ZHU Ying-xiong, JIANG Mao-fa, et al(刘承军, 朱英雄, 姜茂发, 等). Steelmaking(炼钢), 2001, 17(3): 42.
[4] ZENG Jian-hua, CHEN Tian-ming, ZHAO Qi-cheng, et al(曾建华, 陈天明, 赵启成, 等). Iron Steel Vanadium Titanium(钢铁钒钛), 2000, 21(4): 9.
[5] Wang W L, Cramb A W. ISIJ International, 2005, 45(12): 1864.
[6] LU Sheng-yi(卢盛意). Quality of Casting Blank(连铸坯质量). Beijing: Metallurgical Industry Press(北京: 冶金工业出版社), 2000. 12.
[7] CAI Kai-ke, CHENG Shi-fu(蔡开科, 程士富). Continuous Casting Theory and Technology(连续铸钢原理与工艺). Beijing: Metallurgical Industry Press(北京: 冶金工业出版社), 1994. 12.
[8] Kawamoto M, Tsukaguchi Y, Nishida N, et al. ISIJ International, 1997, 37(2): 134.
[9] Ohmiya S, Tacke K H, Schwerdtfeger K. Ironmaking and Steelmaking, 1983, 10(1): 24.
[10] Yamauchi A, Sorimachi K, Sakuraya T, et al. ISIJ International, 1993, 33(1): 140.
[11] Mills K C. The Making, Shaping and Treating of Steel, 11th Edition, Casting Volume, Chapter 8, Mold Powders for Continuous Casting, The AISE Steel Foundation, Pittsburgh, PA, 2003. 40.
[12] XUE Li-hui, JIN Yun, XU Chao(薛里辉, 金 云, 许 超). Chinese Journal of Light Scattering(光散射学报), 1999, 11(3): 269.
[13] XU Jian, HU Guo-jun(徐 键, 胡国君). Journal of the Chinese Ceramic Society(硅酸盐学报), 1997, 25(3): 301.
[14] DIAO Jiang, XIE Bing, WANG Nanhui, et al. ISIJ International, 2007, 47(9): 1294.
[15] Susa M, Nagata K,Mills K C. Ironmaking and Steelmaking, 1993,20(5): 372.
[16] CHO J, Shibata H, Emi T, et al. ISIJ International, 1998, 38(3):268.
[17] ZHENG Yu-ying, WANG Can-yao, FU Ming-lian(郑玉婴, 王灿耀, 傅明连). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2005, 25(11): 1813.
[18] HAN Wen-dian, QIU Sheng-tao, GAN Yong, et al(韩文殿, 仇圣桃, 干 勇, 等). Journal of Iron and Steel Research(钢铁研究学报), 2006, 18(1): 9. |
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