SAFETY
Original Paper
UDC 622.272:516.02 © S.V. Cherdantsev, P.A. Shlapakov, S.I. Goloskokov, A.Yu. Erastov, S.A. Khaymin, 2022
ISSN 0041-5790 (Print) • ISSN 2412-8333 (Online) • Ugol’ – Russian Coal Journal, 2022, № 1, pp. 26-32
DOI: http://dx.doi.org/10.18796/0041-5790-2022-1-26-32
Title
Determination of the time intervals characterizing the various stages of combustion of the gas-air mixture in the mine working
Authors
Cherdantsev S.V.1, Shlapakov P.A.1, Goloskokov S.I.1, Erastov A.Yu.1, Khaymin S.A.1
1Join-stock company "Scientific centre VOSTNII on industrial and ecological safety in mountain industry" (JC "NC VOSTNII"), Kemerovo, 650002, Russian Federation
Authors Information
Cherdantsev S.V., Doctor of Engineering Sciences, Chief Researcher, e-mail: svch01@yandex.ru
Shlapakov P.A., PhD (Engineering), Laboratory Head, е–mail:
Goloskokov S.I.,PhD (Engineering), Laboratory Head, е–mail: s.goloskokov@nc-vostnii.ru
Erastov A.Yu., Senior Researcher, e-mail: eractov_a_y@mail.ru
Khaymin S.A., Senior Researcher,е–mail: hsa007@mail.ru
Abstract
An indispensable attribute in the underground mining of coal deposits is methane, the danger of which manifests itself in two ways. On the one hand, being a gaseous substance, methane negatively manifests itself in various aero- and gas-dynamic processes, first of all, souffle emissions from underground cavities and sudden emissions into mine workings, which traditionally refer to dangerous phenomena during the mining of coal seams. On the other hand, mixing with air flows in the atmosphere of mine workings, methane forms gas-air mixtures that are predisposed to chemical reaction, manifested in the form of gorenje or detonation, which in coal mines can lead to catastrophic consequences. In this paper, the problem of the non-stationary gorenje process of a gas-air mixture in a mining of circular cross-section is considered. When setting the problem, it is assumed that the temperature gradient inside the considered region is very small, which is why the spatial distribution of temperatures is not taken into account. In the course of constructing the solution to the problem, formulas were obtained for determining the various time intervals characterizing the combustion process of the gas-air mixture. Gorenje Graphs of the dependences of the ignition period of the mixture on a number of its parameters are constructed, and some patterns of their influence on the ignition period of the mixture are revealed.
Keywords
Mining, Gas-air mixtures, Thermal conductivity equation, Newton's law of heat transfer, Rate of chemical reaction, Arrhenius law, Induction period.
References
1. Sidorov A.E. & Shevchuk V.G. Laminar flame in fine-particle dusts. Combustion, Explosion, and Shock Waves, 2011, Vol, 47, pp. 518–522.
2. Sidorov A.E., Shevchuk V.G. & Kondrat’ev E.N. Conductive-radiative model of a laminar flame in dust suspensions. Combustion, Explosion and Shock Waves,2013, Vol. 49, pp. 257–263.
3. Shevchuk V.G., Kondrat’ev E.N., Zolotko A.N et al. Wave regimes of dust combustion. Combustion, Explosion and Shock Waves. 2014, Vol. 50, pp. 80–86.
4. Vasilev A.A., Pinaev A.V., Trubisyn A.A. et al. What is burning in coal mines: methane or coal dust? Combustion, Explosion and Shock Waves. 2017, Vol. 53, Is. 1, pp. 8–14.
5. Vasiliev A. A. & Vasiliev V. A. Calculated and experimental parameters of combustion and detonation of mixtures of methane and coal dust. Scientific Bulletin of the center for safety in the coal industry, 2016, (2), pp. 8–39. (In Russ.).
6. Kurlenya M.V. & Skritsky V.A. Methane Explosions and Causes of Their Origin in Highly Productive Sections of Coal Mines. Journal of Mining Science, 2017, Vol. 53, Is. 5, pp 861–867.
7. Cherdantsev S. V., Filatov Yu. M. & Shlapakov P. A. Modes of diffusion combustion of fine dust-gas-air mixtures in the atmosphere of mine workings. Ugol’,2020, (2), pp. 27–32. (In Russ.). DOI: 10.18796/0041-5790-2020-2-27-32.
8. Cherdantsev S.V., Shlapakov P.A., Shlapakov Е.A. et al. Thermophysical and gas-dynamic conditions of deflagration and detonation processes in dust-gas-air flows of mine workings near the centers of self-heating. Chemical Physics and Mesoscopy, 2019, (2), pp. 179–189. (In Russ.).
9. Cherdantsev S.V., Shlapakov P.A., Goloskokov S.I. et al. Construction and implementation of a thermal model of aeromethane mixture combustion in mine atmosphere, considering its kinetics. Safety in industry, 2021, (9), pp. 7–14. (In Russ.).
10. Bykovskii F.A., Zhdan S.A. & Vedernikov E.F. Continuous detonation of methane/hydrogen-air mixtures in an annular cylindrical combustor. Combustion, Explosion and Shock Waves, 2018, Vol. 54, Is. 4, pp. 472–481.
11. Ershov A.P. & Rubtsov I.A. Detonation of low-density explosives. Combustion, Explosion and Shock Waves, 2019, Vol. 55, (1), pp. 114–120.
12. Denisov E.T., Sarkisov O.M. & Lichtenstein G.I. Chemical kinetics: Textbook for universities.: Chemistry, 2000, 568 p. (In Russ.).
13. Publ., (In Russ.).
14. Bartlme F. Gorenje Gazodynamika (translated from German). Moscow, Energoizdat Publ, 1975, 280 p. (In Russ.).
15. Frank-Kamenetsky D.A. Diffusion and heat transfer in chemical kinetics. Moscow, Nauka Publ, 1987, 502 p. (In Russ.).
For citation
Cherdantsev S.V., Shlapakov P.A., Goloskokov S.I., Erastov A.Yu. & Khaymin S.A. Determination of the time intervals characterizing the various stages of combustion of the gas-air mixture in the mine working. Ugol’, 2022, (1), pp. 26-32. (In Russ.). DOI: 10.18796/0041-5790-2022-1-26-32.
Paper info
Received November 12, 2021
Reviewed November 24, 2021
Accepted December 15, 2021