Журналы →  Gornyi Zhurnal →  2020 →  №10 →  Назад

DEVELOPMENT OF DEPOSITS
Название Temperature effect on implementation of mining system improvement for the potash-bearing strata in Starobin deposit
DOI 10.17580/gzh.2020.10.07
Автор Zubov V. P., Sokol D. G.
Информация об авторе

Saint-Petersburg Mining University, Saint-Petersburg, Russia:
V. P. Zubov, Head of Chair, Doctor of Engineering Sciences, spggi_zubov@mail.ru
D. G. Sokol, Mining Engineer

Реферат

Currently mines of Belaruskali actively expand production capacities in the conditions of great depth of productive strata and high concentration of mining operations. High power loading of mining equipment in combination with complicated geotechnical conditions are the major causes of increased air temperatures in longwalls. In view of the intended social and technological improvement, one of the current tasks of the top priority is normalization of temperature conditions in longwalls pursuant to the effective standards. The data required for the set task solution were obtained during underground investigation of geotechnical situations which have influence on temperature of intake air currents in longwalls. This article presents the research findings on the formation of temperature conditions in longwall mining. At the great mining depths (500–600 m and more), the temperature of intake air currents exceeds the maximal allowable values. It is expedient to change to the specially designed pillarless mining flow charts capable to ensure independent ventilation of longwall and power train, and to enable heat transfer between intake air flow and rocks in mined-out areas.

Ключевые слова Potash-bearing stratum, longwall, air temperature, power train, sanitary standards, process flow chart, independent ventilation of longwall and power train
Библиографический список

1. Guidelines on Application of Mining Methods at the Starobin Deposit. Belaruskali–Institute of Mining. Soligorsk, 2018. 146 p.
2. Zubov V. P., Smychnik A. D., Kirienko V. M., Dakuko N. A. Mining concept for potash stratum III in Belaruskali mines. Gornaya mekhanika i mashinostroenie. 2005. No. 4. pp. 66–71.
3. Andreyko S. S., Ivanov O. V., Nesterov E. A., Golovatiy I. I., Beresnev S. P. Research of salt rocks gas content of potash layer in the Krasnoslobodsky mine field. Eurasian Mining. 2013. No. 2. pp. 38–41.
4. Garnishevsky A. A. An assessment of a required support’s capacity in order to keep the fore-head space of lower longwall faces with hard roof in a secure state by slicing pillarless mining of the Third potash seam. Gornaya mekhanika i mashinostroenie. 2016. No. 1. pp. 5–12.
5. Zubov V. P., Smychnik A. D. Floor salt and rock outbursts in mined-out areas in longwalls and their prevention techniques. Gornyi Zhurnal. 1998. No. 11-12. pp. 28–31.
6. Kalugin P. A. Technological support of efficient mining in salt strata with difficult roof : thesis of inauguration of Dissertation … of Candidate of Engineering Sciences. Saint-Petersburg, 2001. 24 p.
7. Smychnik A. D., Zubov V. P., Kalugin P. A., Kirienko V. M. Process flow charts for Belaruskali mines : Current situation, problems and improvement prospects. Gornyi Zhurnal. 2003. No. 7. pp. 45–50.
8. Golovaty I. I. Belaruskali—The world’s top producer of potash fertilizers. Gornyi Zhurnal. 2018. No. 8. pp. 4–9.
9. Levin L. Yu., Zaitsev A. V., Butakov S. V., Semin M. A. Normalization of microclimate in deep potash mines. Gornyi Zhurnal. 2018. No. 8. pp. 97–102. DOI: 10.17580/gzh.2018.08.14
10. Shcherban A. N., Kremnev O. A., Zhuravlenko V. Ya. Manual on Thermal Control in Mines. 3rd enlarged and revised edition. Moscow : Nedra, 1977. 359 p.
11. Mackay L., Bluhm S., Van Rensburg J. Refrigeration and cooling concepts for ultra-deep platinum mining. Platinum in Transition “Boom or Bus” : Proceedings of the 4th International Platinum Conference. Sun Sity, 2010. pp. 285–292.
12. Funnel R. C., Bluhm S. J., Sheer T. J. Optimization of Cooling Resources in Deep Stopes. Proceedings of the 7th International Mine Ventilation Congress. Cracow, 2001. pp. 391–398.
13. Jianwei Cheng, Yan Wu, Haiming Xu, Jin Liu, Yekang Yang et al. Comprehensive and Integrated Mine Ventilation Consultation Model – CIMVCM. Tunnell ing and Underground Space Technology. 2015. Vol. 45. pp. 166–180.
14. Belle B., Biffi M. Cooling pathways for deep Australia n longwall coal mines of the future. International Journal of Mining Science and Technology. 2018. Vol. 28, Iss. 6. pp. 865–875.
15. Gangrade V., Schatzel S. J., Harteis S. P. A Field Study of Longwall Mine Ventilation Using Tracer Gas in a Trona Mine. Mining, Metallurgy & Exploration. 2019. Vol. 36, Iss. 6. pp. 1201–1211.
16. Manohar Rao A., Ramalingeswarudu S. V. S. S., Venkateswarlu G. Planning of Ventilation Requirements for Deep Mechanised Long Wall Faces—A Cas e Study of Adriyala Longwall Project of The Singareni Collieries Company Limited (SCCL). Procedia Earth and Planetary Science. 2015. Vol. 11. pp. 548–556.
17. Schatzel S. J., Gangrade V., Addis J. D., Hollerich C. A., Chasko L. L. Face Ventilation on a Bleederless Longwall Panel. Mining, Metallurgy & Exploration. 2019. Vol. 36, Iss. 3. pp. 531–539.
18. Federal performance requirements in industrial safety area : Rules of safety during mining operations and processing of solid minerals. Iss. 78. Series 03. Inter-branch documents for the issues of industrial safety and soil protection. Moscow : ZAO NTTs PB, 2019. 272 p.

Language of full-text русский
Полный текст статьи Получить
Назад