2015-Sustainable Industrial Processing Summit
SIPS 2015 Volume 2: Gudenau Intl. Symp. / Iron and Steel Making
Editors: | Kongoli F, Kleinschmidt G, Pook H, Ohno K, Wu K |
Publisher: | Flogen Star OUTREACH |
Publication Year: | 2015 |
Pages: | 340 pages |
ISBN: | 978-1-987820-25-6 |
ISSN: | 2291-1227 (Metals and Materials Processing in a Clean Environment Series) |
< CD shopping page
A Study Dynamic Reaction Process in Metallurgical Engineering
Keng
Wu1; Li
Zhu2; Yuan
She2; Ruiling
Du2; LIU
Qi-hang1;
1STATE KEY LABORATORY OF ADVANCED METALLURGY, UNIVERSITY OF SCIENCE AND TECHNOLOGY BEIJING, Bejing, China; 2UNIVERSITY OF SCIENCE AND TECHNOLOGY BEIJING, Beijing, China;
Type of Paper: Regular
Id Paper: 74
Topic: 2Abstract:
Reaction kinetics of metallurgical physical chemistry which was successfully applied in metallurgy (as ferrous metallurgy, non-ferrous metallurgy) became an important theoretical foundation for subject system of traditional metallurgy. Not only the research methods were very perfect, but also the independent structures and systems of it had been formed. the development of the subject system of metallurgical reaction engineering was discussed and the idea for establishing the subject system of metallurgical reaction engineering was proposed. Considering the deficiency of fundamental physical data of metallurgical applications, the idea of researching on the metallurgical reaction engineering and metallurgical reaction project respectively was proposed. Metallurgical reaction engineering was the basic part of this subject (determining definite solution conditions by basic experiment and building models considering comprehensive definite conditions). Metallurgical reaction project was the applied part of amplifying and optimizing simulation results during actual production.One of the important tasks of metallurgical reaction engineering was the simulation of metallurgical process, then the mechanism of reaction process and the conversion time of different control links should be obtained accurately. Therefore, the methods and results of reaction kinetics in metallurgical physical chemistry were not very suitable for metallurgical reaction engineering. In order to provide necessary transmission and reaction kinetics parameters as well as the conversion time of different control links for definite conditions of solving transmission and reaction equations in metallurgical reaction engineering, a new idea for researching kinetics mechanisms in metallurgical reaction engineering by employing sectional method was proposed. Then the comparison of results between the two methods and the further development of sectional method were discussed in this paper. As a research method for reaction kinetics in metallurgical reaction engineering, sectional method could not only satisfy the self needs of metallurgical reaction engineering, but also provide necessary guarantees for establishing its independent subject system.
Keywords:
metallurgical reaction engineering; subject system; stepwise attempt method; Energy£»reaction process kinetics
References:
[1] Y.Qu, J.Liu, The introduction of metallurgical reaction engineering [M]. (Beijing: Metallurgical Industry Press, 1988).
[2] Y.Qu, S.Q.Li. Observe and think about metallurgical reaction engineering problems from a broad view [C]. (Shenyang: Northeast University, 1998.1).
[3] X.H. Huang, Principles of Steel Metallurgy (Beijing: Metallurgical Industry Press, 1981), 99-102
[4] X.Z.Zhang,M.L.Wu, Y.S.Shen,Metallurgy transport principle[M]. (Beijing: Metallurgical Industry Press, 1988).
[5] J.H.Wei, “Mass,heat and momentum transfer and mathematics metallurgy process” [J]. Journal of Xian metallurgy and construction engineering,1983(1): 104.
[6] Z.G.Luo,Metallurgy transport principle [M]. (Liaoning: Northeast University Press, 2013).
[7] J.H.Wei, H.T.Hu, “Metallurgy processes and non-equilibrium thermodynamics”[J]. Journal of Baotou University of Iron and Steel Technology, 2002, 21(3): 197.
[8] Y.S.Shen, B.W.Li, M.L.Wu. Basis of Metallurgy transport principle [M]. (Beijing: Metallurgical Industry Press, 1999).
[9] Welty J R, Wicks C E, Wilson R E, et al. Momentum、Heat and Mass Transfer Principle [M]. (Beijing: Chemical Industry Press, 2005).
[10] K.Wu, Metallurgy transport principle [M]. (Beijing: Metallurgical Industry Press, 2011).
[11] Gudenau H W. Foreign exchange report[R]. (Beijing: Rheinisch-Westfaelische Technische Hochschule Aachen, 2013).
[12] B.X.Yu, Research on liquid permeability of dead stock in shousteel BF[D]. (Beijing: University of Science and Technology Beijing, 2007).
[13] J.Q.Zhang. Broadband amorphous ribbons molding theory and process control[R]. (Beijing: University of Science and Technology Beijing, 2013).
[14] Ishida M, Wen C Y. Comparison of Kinetic and Diffusional Models for Solid-Gas Reactions[J]. AIChE J, 1968, 14 (2): 311.
[15] Smith J M. Chemical Reaction Engineering[M]. 3rd ed. New York: McGraw-Hill, 1981.
[16] Levenspiel O. Chemical and Catalytic Reaction Engineering [M]. 3rd ed. New York: John Wiley and Sons, 1999.
[17] Sakae Yagi, Daizo Kunii. Studies on effective thermal conductivities in packed beds [J] . AIChE J, 1957, 3 (3): 373.
[18] Szekely J, Evans J W. A Structural Model for Gas-Solid Reactions With a Moving Boundary-II: The Effect of Grain Size, Porosity and Temperature on the Reaction of Porous Pellets[J]. Chem Eng Sci, 1971, 26(11): 1901.
[19] J.Liu, J.R.Wang, B.Z.Sun. “Theoretical study of activation energy of coal”[J]. Journal of China Coal Society, 1999, 24(3): 316-320.
[20] X.Y.Bai,S.J.Qu,L.B.Wang,“Basic research and simulation of rectifying crude phenol recovered from low temperature coal tar”[J]. Journal of China Coal Society, 2011,36(4): 659-663.Full Text:
Click here to access the Full TextCite this article as:
Wu K, Zhu L, She Y, Du R, Qi-hang L. A Study Dynamic Reaction Process in Metallurgical Engineering. In: Kongoli F, Kleinschmidt G, Pook H, Ohno K, Wu K, editors. Sustainable Industrial Processing Summit SIPS 2015 Volume 2: Gudenau Intl. Symp. / Iron and Steel Making. Volume 2. Montreal(Canada): FLOGEN Star Outreach. 2015. p. 115-128.