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PHYSICS OF ROCKS AND PROCESSES
Название Influence of face advance rate on geomechanical and gas-dynamic processes in longwalls in gassy mines
DOI 10.17580/em.2018.01.01
Автор Sidorenko A. A., Sirenko Yu. G., Sidorenko S. A.
Информация об авторе

Saint-Petersburg Mining University, Saint Petersburg, Russia:

Sidorenko A. A., Associate Professor, Candidate of Engineering Sciences, sidorenkoaa@mail.ru
Sirenko Yu. G., Associate Professor, Candidate of Engineering Sciences
Sidorenko S. A., Associate Professor, Candidate of Engineering Sciences

Реферат

The article highlights currentness of studies into the influence of mine production rate on geomechanical and gas-dynamic processes in longwalls. It is shown that, despite the quick pace improvement in mining technique, there is essential backwardness of methodical and regulatory framework used to determine basic parameters of geomechanical and gas dynamic phenomena. The normative documents currently in force in Russia in calculating main roof caving steps in longwalls and the earlier research data on influence of longwall face advance rate on rock pressure phenomena in are analyzed. The research findings on undulating nature of change in methane content in high-production longwalls, which is related with movement processes in undermined rock mass, are examined. The field studies carried out in Zapolyarnaya Mine, Vorkutaugol reveal disagreement between the actual and calculated steps of main roof caving and recommend on improvement of the current calculation procedure. In Kotinskaya Mine, SUEK-Kuzbass, investigations of methane emission in longwalls determine the periodic nature of methane release maximums along a longwall panel. As the main causes of wide variation range of roof caving span (25–40 m), the authors show variable lithilogical composition and strength characteristics of roof rocks along longwall panels, significant range of output per face and the presence geological discontinuities. The future directions for research aimed to enhance safety and efficiency of high-production mining in series of gasbearing coal seams are defined.

The authors express their deep gratitude to A. M. Cherdantsev, Chief Engineer, Yalevsky Mine, for the assistance in collection and processing of mine data, and for the participation in the research of influence of longwall face advance rate on geomechanical and gas-dynamic processes in longwall panels.

Ключевые слова Underground mining, gas-bearing coal seams, longwall face advance, longwall panel, main roof, methane emission
Библиографический список

1. Stebnev A. V., Mukhortikov S. G., Zadkov D. A., Gabov V. V. Analysis of operation of powered longwall systems in mines of SUEK-Kuzbass. Eurasian Mining. 2017. No. 2. pp. 28–32. DOI: 10.17580/em.2017.02.07
2. Slastunov S. V., Yutyaev E. P. Justifies selection of a seam degassing technology to ensure safety of intensive coal mining. Zapiski Gornogo instituta. 2017. Vol. 223. pp. 125–130. DOI: 10.18454/PMI.2017.1.130
3. Smolin I. A., Kuznetsova A. V., Makarov P. V., Trubitsyn A. A., Trubitsyna N. V. Voroshilov S. P. Stress state modeling in rock mass around a tunnel at different face advance rates. Vestnik Nauchnogo tsentra bezopasnosti rabot v ugolnoi promyshlennosti. 2010. No. 2. pp. 5–13.
4. Shabanimashcool M., Jing L., Li C. C. Discontinuous Modelling of Stratum Cave-In in a Longwall Coal Mine in the Arctic Area. Geotechnical and Geological Engineering. 2014. Vol. 32. Iss. 5. pp. 1239–1252.
5. Hosseini N., Goshtasbi K., Oraee-Mirzamani B., Gholinejad M. Calculation of periodic roof weighting interval in longwall mining using finite element method. Arab. J. Geosci. 2014, Vol. 7. pp. 1951–1956.
6. Song G., Yang S. Investigation into strata behaviour and fractured zone height in a high-seam longwall coal mine. The Journal of the Southern African Institute of Mining and Metallurgy. 2015. Vol. 115. pp. 781–788.
7. Shubina E. A., Lukianov V. G. Problems of calculating gas emission in longwall with regard to geomechanics and gas-dynamics and the relevant solutions. Izvestiya Tomskogo politekhnicheskogo universiteta. 2015. Vol. 326. No. 3. pp. 13–18.
8. Pak G. A., Dridzh N. A., Dolgonosov V. N. Interconnection of main roof caving and gas-dynamic events in coal mines. Ugol. 2014. No. 1. pp. 56–58.
9. Kudinov Yu. V. Dependence of methane content of longwall face on nonuniformity of coal production. Vestnik Nauchnogo tsentra bezopasnosti rabot v ugolnoi promyshlennosti. 2016. No. 3. pp. 45–48.
10. Wedding W. C. Multiscale modeling of the mine ventilation system and flow through the gob. Theses and Dissertations–Mining Engineering. 2014. p. 11.
11. Qin R., Teng L., Yuan S., Shi L. Numerical simulation gob gas field of the roof tunnel drainage method. AGH Journal of Mining and Geoengineering. 2012. Vol. 36. No. 3. pp. 283–290.
12. Guidelines on Coal Mine Ventilation Design. Makeevka : MakNII. 1989. p. 319.
13. Temporal Guidelines on Calculation of Initial and Subsequent Roof Caving Steps in Longwall Mining along the Strike of Coal Seams in Kuzbass. Kemerovo : VostNII. 1973. p. 26.
14. Recommendations on Determination of Initial Caving Increment for Main and Immediate Roof in Longwalls of Vorkutaugol. Vorkuta : PechorNIIproekt. 2001. p. 22.
15. Shinkevich M. V., Ryabkov N. V., Kozyreva E. N. Dynamics of geomechanical behavior of face rock mass during longwall advance. Gornyi informatsionno-analiticheskii byulleten. 2010. No. 3. pp. 356–359.
16. Polevshchikov A. Ya., Kozyreva N. G. Gas-kinetic pattern of rock mass under mining. Gornyi informatsionno-analiticheskii byulleten. 2002. No. 11. pp. 117–120.
17. Dolgonosov V. N., Pak G. A., Starostina O. V. Basic provisions of the procedure for integrated geomechanical and geodynamic control in mines. Inter-Expo Geo-Sibir. 2013. Vol. 1. No. 3. pp. 112–115.
18. Pozdeev I. A. Analysis of gas-dynamic processes and control in longwall influence zone. Vestnik Sibirskogo gosudarstvennogo universiteta. 2013. No. 4(6). pp. 25–29.
19. Korshunov G. I. Efficient and safe mining technology for outburst- and rockburst-hazardous gently dipping coal beds. Doctor of Engineering Sciences Dissertation. 1995. p. 445.
20. Balusu R., Yarlagadda S., Ren T., Su S. Strategic Review of Gas Management Options for Reduced GHG Emissions. CSIRO Earth Science & Resource Engineering, 2010. Avaiable at: http://undergroundcoal.com.au/outburst/pdfs/C17057FinalReport.pdf (accessed: 04.06.18).

Полный текст статьи Influence of face advance rate on geomechanical and gas-dynamic processes in longwalls in gassy mines
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