Serhii Nehrii, Tetiana Nehrii, Sergey Kultaev, Oksana Zolotarova. Providing resistance of protection means on the soft adjoining rocks
- Details
- Parent Category: Geo-Technical Mechanics, 2020
- Category: Geo-Technical Mechanics, 2020, Issue 155
Geoteh. meh. 2020, 155, 20-31
https://doi.org/10.1051/e3sconf/202016800033
PROVIDING RESISTANCE OF PROTECTION MEANS ON THE SOFT ADJOINING ROCKS
1Serhii Nehrii, 1Tetiana Nehrii, 2Sergey Kultaev, 1Oksana Zolotarova
1Donetsk National Technical University, 2State Enterprise "Mine named after M.S. Surhai"
Language: English
Abstract. Problems of maintaining of development the roadways in conditions of the soft adjoining rocks have been considered. The engineering solution for resistance of rigid protection means by building local reinforced zones under these constructions has been suggested. Combination of protection means and reinforced zones has reduced roof rock subsidence. The operation of protection means and reinforced zones as a holistic construction has been viewed on physical and numerical models. Based on simulation results, the efficiency of deepening of protective means below the footwall, the alternative to which can be creation of the reinforced zones in the footwall rocks, has been established. Factors that have to be taken into consideration when setting parameters of a local reinforced zone under the protective means have been identified.
REFERENCES
1. Nehrii, S., Nehrii, T., Bachurin, L., Piskurska, H. Problems of mining the prospective coal-bearing areas in Donbas. E3S Web Conf. Ukrainian School of Mining Engineering, 123 (2019). https://doi.org/10.1051/e3sconf /201912301011
2. Borzyh, A.F., Skrypnik, K.E., Trofimov, E.V., Posohov, E.V. (2015). Ohrana vyemochnyh vyrabotok s pomoshchyu tehnologicheskih tselikov. Coal of Ukraine, 5, 3-11
3. Baysarov, L.V. (2004). Parameters ground and the combined method technology development of support of repeatedly used working. Dr. PhD Tech. NMU, Dnepropetrovsk
4. Borzyh, A.F. (1998). Razrabotka sposobov ohrany podgotovitelnyh vyrabotok pri otrabotke pologih ugolnyh plastov vostochnogo regiona Ukrainskogo Donbassa. Dr. Sci. Tech. DonSTU, Donetsk
5. Bondarenko, V.I., Kovalevska, I.A., Symanovych, H.A., Koval, O.I., Fomichov, V.V. (2012). Eksperymentalni doslidzhennia stiikosti vyimkovykh vyrobok, yaki povtorno vykorystovuiutsia na polohykh plastakh Donbasu. Dnipropetrovsk: LizunovPres
6. Dimanshteyn, A.S., Lisichkin, V.G., Mininberg, V.Ya., Hutornoy, V.F. (1982). Issledovanie deformatsiy vyemochnyh vyrabotok pri razlichnyh sposobah ih ohrany. Coal of Ukraine, 10, 3-5
7. Nehrii, S. (2019). Determination of displacement the roof of the mining workings in the zone of influence of longwall face. Journal of Donetsk Mining Institute, (44), 41-52. https://doi.org/10.31474/1999-981x-2019-1-41-52
8. I. Farmer. Coal mine structures. Chapman and Hall, London (1985). http://doi.org/10.1007/978-94-009-4834-1
9. Кasyan, N.N. (2002). Geomechanical basis of management of a zone of the destroyed rocks around of roadway for maintenance of their stability on the big depths: Dr. Sci. Tech. DonNTU, Donetsk
10. Isaenkov, О., Sahno, І. (2017). Substantiation parameters of local soil strengthening consolidation of breeds with extensible mixtures. Journal of Donetsk Mining Institute, 1(40), 35-40. https://doi.org/10.31474/1999-981x-2017-1-35-40
11. Sahno, І., Isaenkov, О., Liashok, Y., Rodzin, S. Sposib ukriplennia pidoshvy hirnychoi vyrobky. Patent No 116603, Ukraine
12. Shvetsov, G.I., Noskov, I.V., Slobodyan, A.D., Goskova, G.S. (1991). Osnovaniya i fundamenty. Spravochnik. Moskva: Vyisshaya shkola
13. J. Guo, G. Feng, P. Wang, T. Qi, X. Zhang, Y. Yan. Roof Strata Behavior and Support Resistance Determination for Ultra-Thick Longwall Top Coal Caving Panel: A Case Study of the Tashan Coal Mine. Energies, 11, 1041. (2018). http://doi.org/10.3390/en11051041
14. G. Li, S. Cao, F. Luo, Y. Li, Y. Wei. Research on mining-induced deformation and stress, insights from physical modeling and theoretical analysis. Arabian Journal of Geosciences, 11, 1-9. (2018). http://doi.org/10.1007/s12517-018-3422-9
15. R. Gao, B. Yu, H. Xia, H. Duan. Reduction of Stress Acting on a Thick, Deep Coal Seam by Protective-Seam Mining. Energies, 10, 1209. (2017). http://doi.org/10.3390/en10081209
16. C.O. Aksoy, G. Gulsev Uyar. Non-deformable support system in swelling and squeezing rocks. Rock Mechanics and Engineering, 4: Excavation, Support and Monitoring. 179-203. (2017)
17. N. El. Houari, M.A. Allal and N. Abou Bekr. Numerical Simulation of the Mechanical Response of the Tunnels in the Saturated Soils by Plaxis. Jordan Journal of Civil Engineering, 5, 1, 9-31. (2011)
18. M. Hilar, V. John. Numerical modelling of the brezno tunnel re-excavation. ECCOMAS Thematic Conference on Computational Methods in Tunnelling (EURO:TUN 2007) J. Eberhardsteiner et.al. (eds.) Vienna, Austria, August 27-29, 2007
19. N. Radouane, M. Boukelloul, M. Fredj. Stability Analysis of Underground Mining and their Application on the Mine Chaabte El Hamra, Algeria. Procedia Earth and Planetary Science, 15, 237-243. (2015). https://doi.org/10.1016/j.proeps.2015.08.058
20. Sakhno, I.G. (2014). Impact of rigidity of a protective construction on the stress-strain state of the rock mass around the roadways supported after the longwall. Geo-Technical Mechanics, 115, 176-187
21. Nehrii, S., Sakhno, S., Sakhno, I., Nehrii, Т. Analyzing kinetics of deformation of boundary rocks of mine workings. Mining of Mineral Deposits, 12, 4, 115-123. (2018). https://doi.org/10.15407/mining12.04.115
22. Fadeev, A.B. (1987). Metod konechnyh elementov v geomehanike. Moskva: Nedra.
23. Bondarenko, Yu.V. (1991). Nauchnye osnovy bezlyudnoy i bezothodnoy tehnologii vyemki vesma tonkih pologih plastov. Dr. Sci. Tech. DPI, Donetsk
24. Nehrii, S., Rikhert, S.V. (2016). Opredelenie parametrov zhestkikh okhrannykh sooruzheniy v usloviyakh slabykh vmeshchayushchikh porod. Materialy konferentsii "Perspektivy razvitiya stroitelnykh tekhnologiy", 96-100