St. Petersburg Mining University (St. Petersburg, Russia):

I. I. Beloglazov, Cand. Eng., Associate Prof., Chair of Automation of Technological Processes and Production Facilities
V. Yu. Bazhin, Dr. Eng., Prof., Head of the Chair of Automation of Technological Processes and Production Facilities, e-mail: bazhin-alfoil@mail.ru

The modern level of the development of computer engineering and software allows to simulate the processes with different degree of complication and to solve the problems connected with aerodynamic features of turbulent flows of withdrawn gases both in entrance and exit of coke batteries. The paper presents the results of aerodynamic simulation of gas medium using Ansys program in order to determine the temperature field above the surface of coke battery chimney shaft, as well as the results of registration of speed of withdrawn gases for adjusting the flame level. Realization of operation of continuous monitoring systems directly on chimney shaft makes it possible to control thermal state of a coke battery in general and provides lowering of harmful emissions in the atmosphere.

1. Duzhikh F. P. Industrial fuming and ventilation chimney shafts: Reference book. М.: Teplotekhnik. 2004. 464 p.
2. Elshin A. M., Izhorin M. N., Zhludev V. S., Ovcharenko E. G. Fuming chimney shafts. М.: Stroyizdat. 2001. 296 p.
3. Rikhter L. A. Thermal power stations and atmosphere protection. М.: Energiya. 1975, 312 p.

4. Kuhn-Gajdzik J., Krebber F., Überschär K., Huhn F. Possibilities for the configuration of the EnviBAT pressure regulation system at coke plant. Chernye metally. 2015. No. 2. pp. 45–49.
5. Alekseenko V. A., Pashkevich M. A., Alekseenko A. V. Metallisation and environmental management of mining site soils. Journal of Geochemical Exploration. 2017. Vol. 174. pp. 121–127 doi: 10.1016/j.gexplo.2016.06.010.
6. Alekseenko V. A., Alekseenko A. V. The abundances of chemical elements in urban soils. Journal of Geochemical Exploration. 2014. 147 (B). pp. 245–249.
7. Beloglazov I. I., Pedro A. A. Determination of electrode tip working temperature and ore-smelting bath thermal condition during downtime. Metallurgist. 2015. Vol. 59. Nos. 5–6. September. pp. 514–517.
8. Beloglazov I. I., Titov O. V. Effectiveness of different designs of refractory linings for rotary kilns in relation to their thermophysical properties. Refractories and Industrial Ceramics. 2015. Vol. 56. No. 3. pp. 260–262.
9. Koshkina V. S., Serova A. A., Timofeev V. Y. Environmental-Toxicological Characteristics of Waters and Their Sources at Magnitogorsk with its Iron and Steel Industry. IOP Conference Series: Materials Science and Engineering. 2016. (Aug.). Vol. 142. No. 1. p. 12117.
10. Kulov N. N., Gordeev L. S. Mathematical Modeling in Chemical Engineering and Biotechnology. Theoretical Foundations of Chemical Engineering. 2014. Vol. 48. No. 3. pp. 225.
11. Dvoretskii D. S., Dvoretskii S. I., Ostrovskii G. M., Polyakov B. B. A New Approach to the Optimal Design of Industrial Chemical-Engineering Apparatuses. Theoretical Foundations of Chemical Engineering. 2012. Vol. 46. No. 5. p. 437.
12. SP 20131.13330.2012. Building climatology.
13. Kaufman А. А., Filonenko Yu. Ya. Basics of the modern cokemaking technology. 2011. Vol. 1. 319 p.; 2012. Vol. 2. 154 p.
14. Isaev M. V., Sultanguzin I. A. 3-D simulation of burning processes in a furnace chamber of coke battery. Koks i khimiya. 2010. № 8. pp. 34–38.
15. Babushkin R. A., Gmyzov D. S., Ivanov Yu. P. Thermal-imaging diagnostics of fuming chimney shafts. Innovatsionnaya nauka. 2015. № 9. pp 52–57.
16. Salov Yu. V., Semashko V. A., Varnashov V. V., Overchenko I. V., Gordhenin S. D. Increase of reliability and ecological safety of external gas ducts and fuming chimney shafts of thermal power plants. Energosberezhenie i vodopodgotovka. 2009. № 2. pp. 54–57.
17. Emelyanchikov V. I., Eliseenko Yu. Yu. Monitoring of industrial emissions: measurement of concentration of contaminations in exhausted gases of stationary sources. Ecological systems and sensors. 2014. № 8. pp. 3–9.