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Журналы →  Gornyi Zhurnal →  2019 →  №8 →  Назад

INDUSTRY SAFETY AND LABOUR PROTECTION
Название Mathematical modeling of thermodynamic processes in air handling systems at potash mines
DOI 10.17580/gzh.2019.08.16
Автор Kazakov B. P., Shalimov A. V., Semin M. A., Klyukin Yu. A.
Информация об авторе

Mining Institute, Ural Branch, Russian Academy of Sciences, Perm, Russia:

B. P. Kazakov, Chief Researcher, Professor, Doctor of Engineering Sciences, aero_kaz@mail.ru
A. V. Shalimov, Leading Researcher, Doctor of Engineering Sciences
M. A. Semin, Researcher, Candidate of Engineering Sciences
Yu. A. Klyukin, Leading Researcher
Реферат

The intake air heaters at potash mines allow creating and maintaining microclimatic conditions, which are necessary for the safe operation of the shaft lining. In the CIS, the most widely used intake air heaters warm up cold atmosphere air to the required temperatures before it is supplied to the mine. In the Republic of Belarus, according to the Safety Regulations the temperature of the air in the intake shafts 5 m below the surface should be equal or more than +2 ° C. The mines of the Starobinsky potash deposit use exhaust system of ventilation with U-tube layout. In mines with the exhaust system of ventilation, one of the most difficult problems is ensuring uniform temperatures of the shaft lining. To solve this problem, a series of numerical experiments are performed to determine efficient geometry parameters with the fastest air streams mixing, compare different layouts of air heaters, and to assess shock losses at the junction of cold and heated air streams. The results of the research were used to formulate recommendations for sealing the intake shaft house in order to ensure effective heating of the lining in compliance with the requirement of paragraph 170 of the Safety Regulations. The effectiveness of intake shaft lining heating with exhaust system of ventilation and air heaters without any auxiliary fans depends on the quantitative ratio between cold and heated air, as well as on stream mixing in the junction. The presented research shows that with quantitatively equal air leakages through intake shaft house, two ventilation drifts, used for supplying the heated air in the shaft, are more effective than one ventilation drift.
Ключевые слова Potash mines, intake air heaters, heat exchangers, intake shaft, gravitational convection, computational fluid dynamics
Библиографический список

1. Kaledina N. O., Kobylkin S. S. Ventilation of blind roadways in coal mines: problems and solutions. Eurasian Mining. 2015. No. 2. pp. 26–30. DOI: 10.17580/em.2015.02.07
2. Sbarba H. D., Fytas K., Paraszczak J. Economics of exhaust air heat recovery systems for mine ventilation. International Journal of Mining, Reclamation and Environment. 2012. Vol. 26, No. 3. pp. 185–198.
3. De Souza E. Application of ventilation management programs for improved mine safety. International Journal of Mining Science and Technology. 2017. Vol. 27, Iss . 4. pp. 647–650.
4. Levin L. Yu., Semin M. A., Klyukin Yu. A. Estimation of suballo-cated conditioned air distribution system efficiency as a method of mine microclimatic pa rameters control. GIAB. 2013. No. 12. pp. 185–189.
5. Anderson R., De Souza E. Implementation of a Heat Management Control System. Proceedings of the 16th North American Mine Ventilation Symposium. Golden, 2017. pp. 23– 30.
6. Litvinovskaya N. A., Andreiko S. S. Modeling sudden failure of flo or of underground excavations in undermined salt rock mass. Eurasian Mining. 2015. No. 2. pp. 15–17. DOI: 10.17580/em.2015.02.04
7. Alymenko N. I., Nikolaev A. V., Kamenskikh A. A. Shaft options for placing of the mine air heater installation on the stand of a pithead. Izvestiya vuzov. Gornyi zhurnal. 2015. No. 2. pp. 99–106.
8. Available at: http://www.pravo.by/document/?guid=12551&p0=W21226503p&p1=1 (accessed: 23.04.2019).
9. Altshul A. D., Kiselev P. G. Hydraulics and a erodynamics (basic fluid mechanics). 2nd enlarged and revised edition. Moscow : Stroyizdat, 1975. 329 p.
10. Idelchik I. E. Shock losses in nonuniform velocity flow. Compensating action of a resistance to shock arranged behind a diffuser. Trudy TsAGI. 1948. No. 662.
11. Thompson M. K., Thompson J. M. ANSYS Mechanical APDL for Finite Element Analysis. Oxford : Elsevier, 2017. 466 p.
12. Heating , Ventilating, and Air-Conditioning Applications: 2015 ASHRAE Handbook. Atlanta : American Society of Heating, Refrigerating and Air-Conditioning Engineers, 2015. 1341 p.
13. Kaledina N. O., Kobylkin S. S., Kobylkin A. S. The calculation method to ensure safe parameters of ventilation conditions of goaf in coal mines. Eurasian Mining. 2016. No. 1. pp. 41–44. DOI: 10.17580/em.2016.01.07
14. ANSYS Fluent Theory Guide. Canonsburg : ANSYS, 2011. 862 p.
15. Fletcher C. A. J. Computational Techniques for Fluid Dynamics. 2nd ed. Berlin : Springer-Verlag, 1988. Vol. 1. Fundamental and General Techniques. 410 p.
16. Levin L. Yu., Semin M. A., Klyukin Yu. A., Kiryakov A. S. Evaluation of air velocity in ventilation passa ges. Gornyi Zhurnal. 2016. No. 3. pp. 68–72. DOI: 10.17580/gzh.2016.03.14
17. Mohammadi B., Pironneau O. Analysis of the K-Epsilon Turbulence Model. Chichester : John Wiley & Sons, 1994. 212 p.
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