Журналы →  Chernye Metally →  2020 →  №12 →  Назад

Iron and steelmaking
Название Improving the efficiency of electric arc furnaces through improved control algorithms for electrical modes
DOI 10.17580/chm.2020.12.02
Автор A. A. Nikolaev, G. P. Kornilov, P. G. Tulupov, G. V. Nikiforov
Информация об авторе

Nosov Magnitogorsk State Technical University (Magnitogorsk, Russia):

A. A. Nikolaev, Cand. Eng., Associate Prof., Head of the Dept. of Automated Electric Drive and Mechatronics, E-mail: aa.nikolaev@magtu.ru
G. P. Kornilov, Dr. Eng., Prof., Head of Dept. of Power Supply of Industrial Enterprises, E-mail: korn.mgn@mail.ru
P. G. Tulupov, Postgraduate student, Dept. of Automated Electric Drive and Mechatronics, E-mail: tulupov.pg@mail.ru
G. V. Nikiforov, Dr. Eng., Prof., Dept. of Power Supply of Industrial Enterprises

Реферат

The aim of this study is to increase the efficiency of electric arc furnace through the use of advanced control algorithms for electrical modes. It was established that despite the common structure of the electric control system, as well as the approach to diagnosing the stage of the technological process, the criteria for switching from one combination of the furnace transformer tap and operating curve to another for electric arc furnaces and ladle furnaces are different. So, for EAF it is advisable to use a system in which a separate analysis of the signals of the relative effective value of the total even and odd harmonics of electric arc current (voltage) should be applied. It’s important to note that at the initial stage of melting it’s preferable to use even harmonics, and at the final stage of melting - odd harmonics. In it’s turn, during melting in LF, the argon blow mode and the slag mode have a significant role. Intensive blowing modes lead to the appearance of a metal mirror with the occurrence of bursts that occure short-circuit of the electric arc and lead to not optimal electric mode. According to the results of the analysis, a number of recommendations have been formulated that can have practical application in modernizing of modern control systems, aimed at optimizing production energy costs and reducing the unit cost of the final product of the metallurgical cycle. Moreover, the experience of implementing the described ides shows (for shaft-type electric arc furnace with capacity 125 ton, 85 MVA and ladle furnace 25 MVA) that the economic effect is 2.5% in terms of saving electric energy and 2% in terms of saving the consumption of electrodes. It’s a significant indicator taking into account the high energy intensity of modern electric steelmaking shops.
This work was supported by the Ministry of Science and Higher Education of the Russian Federation (project No. FZRU-2020-0011).

Ключевые слова Electrometallurgy, electric arc furnace, ladle furnace, electric arc, harmonic composition of electric arc current, argon purge
Библиографический список

1. Nikolaev A. A., Tulupov P. G., Anufriev A. V. System for controlling electric mode of arc steel-making furnace. Patent RF, No. 176106. Applied: 13.06.2017. Published: 09.01.2018. Bulletin No. 1.
2. Nikolaev A. A., Russo Zh. Zh., Spymanski V., Tulupov P. G. Experimental study of the harmonic composition of arc currents for electric arc furnaces of various powers. Vestnik Magnitogorskogo gosudarstvennogo tekhnicheskogo universiteta im. G. I. Nosova. 2016. No. 3. pp. 106–120.
3. Cassie A. M. Nouvelle théorie des arcs de rupture et rigidité du circuit (New theory of breaker arcs and circuit rigidity). CIGRE Report. 1939. No. 102. pp. 588–608.
4. Bowman B., Krüger K. Arc Furnace Physics. Verlag Stahleisen GmbH. Düsseldorf, 2009. 246 p.
5. Matrosov A. P., Mironov Yu. M. Computer simulation of processes in electric circuits of arc furnaces. Elektrometallurgiya. 2006. No. 6. pp. 27–32.
6. Mees H., Hohl J., Krüger K. Dynamic Condition-Based Scrap Melt Control: Results of the Application at Thyssenkrupp Nirosta in Bochum. 10th European Electric Steelmaking Conference. Graz, 25–28 Sep., 2012. pp. 253–259.
7. Tuluevskiy Yu. N., Zinurov I. Yu. Innovations for electric arc furnaces. Scientific bases of selection: monograph. Series of monographs “Modern electrical technologies”. Vol. 12. Novosibirsk: Izdatelstvo NGTU, 2010. 347 p.
8. Dorndorf M., Wichert W., Schubert M. Holistic Control of EAF’s Energy and Material Flows. 3rd International Steel Conference on Developments in Metallurgical Process Technologies. Düsseldorf, June 11–15, 2007. pp. 513–520.
9. Kun R. Optimization of costs and productivity by eliminating hot spots and arc radiation in steel arc furnaces. Chernye Metally. 2004. No. 2. pp. 35–38.
10. Mironov Yu. M. Regularities of electrical modes of steel arc furnaces. Elektrichestvo. 2006. No. 6. pp. 56–62.
11. Ignatov I. I., Khainson А. V. Calculation of electrical parameters and modes of steel arc furnaces. Elektrichestvo. 1983. No. 8. pp. 62–65.
12. Jansen T., Krüger K., Schliephake H. et al. Advanced Foaming Slag Control. 10th European Electric Steelmaking Conference. Graz, 25–28 Sep., 2012. pp. 385–390.
13. Jansen Т., Krüger К., Schliephake H., Dettmer B., Deng J. DC-EDF power control using a sound based foaming slag signal. Chernye Metally. 2011. No. 2. pp. 20–25.
14. Nikolaev А. А. Improvement of the efficiency of arc steel-making furnaces and ladle-furnace installations through the use of improved algorithms for controlling electrical modes. Magnitogorsk: MGTU im. G. I. Nosova, 2015. 161 p.

Language of full-text русский
Полный текст статьи Получить
Назад