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Study on the Evaporation Behaviour of Electrolytic Manganese Melt Under Reduced Pressure  

Hong, Seong-Hun (Division of Material Science and Engineering, Inha University)
Jeon, Byoung-Hyuk (Division of Material Science and Engineering, Inha University)
Wi, Chang-Hyun (Division of Material Science and Engineering, Inha University)
Shin, Dong-Yub (Division of Material Science and Engineering, Inha University)
You, Byung-Don (Division of Material Science and Engineering, Inha University)
Seo, Seong-Mo (Technical Research Laboratories, POSCO)
Park, Jong-Min (Technical Research Laboratories, POSCO)
Publication Information
Korean Journal of Metals and Materials / v.47, no.12, 2009 , pp. 828-833 More about this Journal
Abstract
As a fundamental study in the development of a distillation process for ferromanganese alloy melts, the evaporation behavior of an electrolytic manganese melt under reduced pressure was investigated. The melt temperature, vacuum degree, surface area of the melt, and reaction time were considered as experimental variables. The amount of vaporized manganese increases linearly as the reaction time increases, and the evaporation of manganese was promoted by increasing the temperature and surface area of the melt. In the pressure range below the equilibrium vapor pressure of manganese, the amount of vaporized manganese per unit surface area of the melt increased sharply with a decrease of the pressure in the reaction chamber. An empirical equation for the evaporation rate of manganese was derived by regression analysis. The evaporation coefficient of manganese was determined to be approximately $3.84{\times}10^{-3}(g{\cdot}K^{1/2})/(Pa{\cdot}cm^2{\cdot}min)$ under the investigated conditions.
Keywords
evaporation of manganese; reduced pressure; temperature; surface area of melt; reaction time;
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1 J. K. Jung, O. Y. Lee, Y. K. Park, D. E. Kim, K. G. Jin, S. K. Kim, and K. H. Song, J. Kor. Inst. Met. & Mater. 46, 627(2008)
2 K. Maya and T. Matsuo, Tetsu-to-Hagane. 82, 25 (1996)
3 I. Barin, Thermochemical Data of Pure substances 3rd ed., p. 1033-1034, VCH, Weinheim, (1989)
4 S. H. Hong, B. H. Jeon, B. D. You, J. D. Kim, P. Y. Jang, S. C. Kang, and C. H. Geum, J. Kor. Inst. Met. & Mater., (In Press)
5 B. D. You, B. W. LEE, and J. J. PAK, Metals and Materials 5, 497 (1999)   DOI
6 J. J. Moore, Chemical Metallurgy, 2nd ed., p. 260-262, Butterworth Heinemann Ltd, Oxford (1990)
7 B. D. You, J. Kor. Inst. Met. & Mater. 33, 1508 (1995)
8 D. S. Kozak and L. R. Matricardi, Iron and Steelmaker. 8, 28 (1981)
9 B. D. You, J. W. Han, and J. J. Pak, Steel Research. 71, 22(2000)
10 B. D. You, K. Y. Park, J. J. Pak, and J. W. Han, Metals and Materials. 5, 395 (1999)   DOI
11 Y. E. Lee, Proc. 6th Intern. Iron & Steel Congr., p. 327, ISIJ, Nagoya, Japan (1990)
12 R. F. Bunshah, J. M. Blocher, D. M. Mattox, T. D. Bonifield, G. E. Mcguire, J. G. Fish, M. Schwartz, P. B. Ghate, J. A. Thornton, B. E. Jacobson, and R. C. Tucker, Deposition Technologies for Films and Coatings, Noyes Publications, p. 90-92, Park Ridge, New Jersey (1982)
13 M. Fujita, H. Katayama, A. Yamamoto, and M. Matsuo, Tetsu-to-Hagane. 74, 64 (1988)