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Vol 223
Pages:
125-130
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Article

Justified selection of a seam degassing technology to ensure safety of intensive coal mining

Authors:
S. V. Slastunov1
E. P. Yutyaev2
About authors
  • 1 — Ph.D., Dr.Sci. professor National University of Science and Technology «MISIS»
  • 2 — general director JSC «SUEK-Kuzbass»
Date submitted:
2016-09-06
Date accepted:
2016-11-13
Date published:
2017-02-22

Abstract

The paper contains main aspects of methodological approach to objective analytic assessment of maximum permissible output of the mine faces from the viewpoint of gas factor. Analytic forecast is centered around the assessment of methane inflow into the face area from all possible sources, based on fundamental physical laws, modern tools of mathematical modeling and in-situ tests of main properties and state parameters of the gas-bearing coal formation. Objective and reliable estimation of permissible outputs is a starting point for justified selection of a seam degassing technology, that has to be based on time factor and predicted value of gas recovery from a coal seam to a degassing well. Recommendations have been formulated on the selection of degassing technology for the coal seam «Boldyrevsky» of the Kirov mine, based on the use of cutting-edge technological schemes (hydraulic fracture, carried out from development workings, etc.), successfully implemented on the mentioned site.

Область исследования:
(Archived) Geoecology and occupational health and safety
Keywords:
gas factor permissible output forecast methodology selection of seam degassing technology hydraulic fracture practical recommendations
10.18454/pmi.2017.1.125
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Cited
Scopus:
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Cited By
1. Improvement of technological schemes of mining of coal seams prone to spontaneous combustion and rock bumps. Journal of Mining Institute. 25 December 2023, Vol. 264, P. 949-961. [Scopus] (cited: 35)
2. Improvement of Intensive In-Seam Gas Drainage Technology at Kirova Mine in Kuznetsk Coal Basin. Energies. February-1 2022, Vol. 15, DOI: 10.3390/en15031047 [Scopus] (cited: 26)
3. Justification of technologies parameters for intensive mining of prone to spontaneous combustion thick coal seams. Mining Informational and Analytical Bulletin. 2022, P. 83-99. DOI: 10.25018/0236_1493_2022_61_0_83 [Scopus] (cited: 3)
4. High productive longwall mining of multiple gassy seams: best practice and recommendations. Acta Montanistica Slovaca. 2022, Vol. 27, P. 152-162. DOI: 10.46544/AMS.v27i1.11 [Scopus] (cited: 37)
5. Prospects for development of a technological structure of underground coal mines. Mining Informational and Analytical Bulletin. 2022, P. 35-53. DOI: 10.25018/0236_1493_2022_61_0_35 [Scopus] (cited: 13)
6. Improving the efficiency of the technology and organization of the longwall face move during the intensive flat-lying coal seams mining at the kuzbass mines. Journal of Mining Institute. 20 September 2021, Vol. 249, P. 342-350. DOI: 10.31897/PMI.2021.3.3 [Scopus] (cited: 31)
7. Predicting Methane Emissions from Multiple Gas-Bearing Coal Seams to Longwall Goafs at Russian Mines. Arpn Journal of Engineering and Applied Sciences. April 2021, Vol. 16, P. 851-857. [Scopus] (cited: 12)
8. Designing In-Seam Gas Drainage Technology Based on Hydrodynamic Approach. Iop Conference Series Earth and Environmental Science. 14 April 2020, Vol. 459, DOI: 10.1088/1755-1315/459/5/052076 [Scopus] (cited: 1)
9. A study of gas drainage methods efficiency in Kotinskaya mine in Russia. Arpn Journal of Engineering and Applied Sciences. 20 February 2020, Vol. 15, P. 530-535. [Scopus] (cited: 7)
10. Comprehensive gas drainage technology by hydraulic splitting of coal seam using surface holes. Mining Informational and Analytical Bulletin. 2020, Vol. 2020, P. 5-14. DOI: 10.25018/0236-1493-2020-1-0-5-14 [Scopus] (cited: 2)
11. Testing of integrated degasifying treatment technology based on hydraulic splitting of coal seam using surface holes. Mining Informational and Analytical Bulletin. 2020, Vol. 2020, P. 58-70. DOI: 10.25018/0236-1493-2020-2-0-58-70 [Scopus] (cited: 8)
12. Testing data on operational control of shearers in high-productive longwalls. Mining Informational and Analytical Bulletin. 2020, Vol. 2020, P. 36-46. DOI: 10.25018/0236-1493-2020-1-0-36-46 [Scopus] (cited: 2)
13. Spatial non-linearity of methane release dynamics in underground boreholes for sustainable mining. Journal of Mining Institute. 2020, Vol. 245, P. 522-530. DOI: 10.31897/PMI.2020.5.3 [Scopus] (cited: 24)
14. Modeling of cutter-loader control in high production longwalls. Mining Informational and Analytical Bulletin. 2019, Vol. 2019, P. 30-40. DOI: 10.25018/0236-1493-2019-04-0-30-40 [Scopus] (cited: 1)
15. The implementation of modern occupational safety and health system as an element of sustainable development of coal mining enterprises. Innovation Based Development of the Mineral Resources Sector Challenges and Prospects 11th Conference of the Russian German Raw Materials 2018. 2019, P. 571-577. [Scopus] (cited: 15)
16. Numerical study of the air-gas dynamic processes when working out the Mosshny seam with longwall faces. Arpn Journal of Engineering and Applied Sciences. 1 February 2018, Vol. 13, P. 1534-1538. [Scopus] (cited: 25)
17. Identification of rational parameters of hydraulic fracturing in terms of fluid injection rate optimization. Mining Informational and Analytical Bulletin. 2018, Vol. 2018, P. 90-96. DOI: 10.25018/0236-1493-2018-9-0-90-96 [Scopus]
18. Efficiency of improved underground hydraulic fracturing in coal bed degassing. Gornyi Zhurnal. 2018, P. 83-87. DOI: 10.17580/gzh.2018.01.15 [Scopus] (cited: 10)
19. Influence of face advance rate on geomechanical and gas-dynamic processes in longwalls in gassy mines. Eurasian Mining. 2018, P. 3-8. DOI: 10.17580/em.2018.01.01 [Scopus] (cited: 30)
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Justified selection of a seam degassing technology to ensure safety of intensive coal mining

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