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PHYSICS OF ROCKS AND PROCESSES
Название Geomechanical assessment and substantiation of mining conditions and mining method for Irtysh deposit
DOI 10.17580/gzh.2018.01.08
Автор Zhirnov A. A., Shaposhnik Yu. N., Nikolsky A. M., Neverov S. A.
Информация об авторе

Vostoktsvetmet, Ust-Kamenogorsk, Kazakhstan:

A. A. Zhirnov, Chief Geotechnical Engineer

 

Institute of Mining, Siberian Branch, Russian Academy of Sciences, Novosibirsk, Russia:
Yu. N. Shaposhnik, Leading Researcher, Doctor of Engineering Sciences

S. A. Neverov, Head of a Laboratory, Candidate of Engineering Sciences, nsa_nsk@mail.ru

 

Mining PRO, Novosibirsk, Russia:
A. M. Nikolsky, Director, Candidate of Engineering Sciences

Реферат

For Irtysh polymetal sulphide deposit, a 3D geomechanical model of stress state of surrounding rock mass around a mine has been constructed based on the input data on actual in situ stress field measurements. The in situ studies with direct instrumental measurements using the method of slotter borehole drilling outside the influence zone of abatement pressure reveal nearly equicomponent initial stress field with major horizontal forces oriented across the strike of the deposit. The geomechanical modeling describes general condition of underground excavations at operating levels, qualitative and quantitative distributions of stresses, concentration of stresses and formation of large damage area. The most aggravating effect of rock pressure is observed in heavily fractured rock mass at the boundaries of mined-out areas in the footwall and hanging wall of the ore body, as well as in the pillars, floors and roofs of open stopes (voids). It is proved that instability areas dynamically appear in the above-averaged fractured rock mass of Irtysh deposit. Based on the geomechanical analysis of the current geotechnical situation, the numerical modeling of the mine structure elements has been carried out for a mining depth of more than 700 m. The application ranges and safe operation parameters are determined for geotechnologies which are currently in use at the deposit, namely, stoping with shrinkage, sublevel open stoping, sublevel caving and room-and-pillar mining. It has been proved that in heavily fractured rock mass, the mining systems with the current parameters fail to ensure the required safety of mine operation and it is necessary to adjust design parameters of pillars and spans.

Ключевые слова Stress state, mining depth, geomechanical model, geotechnology, mining system, parameters, stability, safety
Библиографический список

1. Makarov A. B. Practical geomechanics : tutorial for mining engineers. Moscow : Gornaya kniga, 2006. 391 p.
2. Yun R. B., Makarov A. B., Aldambergenov M. K., Nigmatzyanov I. S., Zaytsev O. N. Substantiation of low horizons mining in Irtish mine. Karaganda : TsNTI, 2001. 78 p.
3. Neverov S. A. Types of orebodies on the basis of the occurrence depth and stress state. Part I: Modern concept of the stress state versus depth. Fiziko-tekhnicheskie problemy razrabotki poleznykh iskopaemykh. 2012. No. 2. pp. 56–70.
4. Neverov S. A. Types of orebodies on the basis of the occurrence depth and stress state. Part II: Orebody tectonotypes and geomedium models. Fiziko-tekhnicheskie problemy razrabotki poleznykh iskopaemykh. 2012. No. 3. pp. 25–35.
5. Makarov A. B., Ogorodnikov S. V., Kalmurzaev K. A. Definition of natural stress state of the massif of Maleevskoe deposit. Gornyi Zhurnal. 2013. No. 5. pp. 57–61.
6. Shkuratnik V. L., Nikolenko P. V. Methods of definition of stress-strain state of rock massif. Moscow : Izdatelstvo MGGU, 2012. 111 p.
7. Makarov A. B. Assessment of natural stress field in massif for observations of rock movement. Gornyi Zhurnal. 2006. No. 2. pp. 33–36.
8. Wang J., Wang Y., Cao Q., Ju Y., Mao L. Behavior of microcontacts in rock joints under direct shear creep loading. International Journal of Rock Mechanics and Mining Sciences. 2015. Vol. 78. pp. 217–229.
9. Karaman K., Cihangir F., Kesimal A. A comparative assessment of rock mass deformation modulus. International Journal of Mining Science and Technology. 2015. Vol. 25, Iss. 5. pp. 735–740.
10. Karaman K., Kaya А., Kesimal A. Use of the point load index in estimation of the strength rating for the RMR syste. Journal of African Earth Sciences. 2015. Vol. 106. pp. 40–49.
11. Lu W., Yang J., Yan P., Chen M., Zhou C. et al. Dynamic response of rock mass induced by the transient release of in-situ stress. International Journal of Rock Mechanics and Mining Sciences. 2012. Vol. 53. pp. 129–141.
12. Zienkiewicz O. The finite element method in engineering science. Translated from English. Moscow : Mir, 1975. 543 p.
13. Neverov A. A. Geomechanical substantiation of modified room-work in flat thick deposits with ore drawing under overhang. Fiziko-tekhnicheskie problemy razrabotki poleznykh iskopaemykh. 2012. No. 6. pp. 87–97.
14. Neverov A. A. Geomechanical assessment of combination geotechnology for thick flat-dipping ore bodies. Fiziko-tekhnicheskie problemy razrabotki poleznykh iskopaemykh. 2014. No. 1. pp. 119–131.
15. Neverov S. A., Neverov A. A. Geomechanical assessment of ore drawpoint stability in mining with caving. Fiziko-tekhnicheskie problemy razrabotki poleznykh iskopaemykh. 2013. No. 2. pp. 113–122.
16. Isaev K. O., Makarov A. B., Kondratov A. I., Sosunov Yu. A. Geomechanical substantiation of technology of mining of Irtish mine low horizons with caving. Gornyi Zhurnal. 2002. No. 5. pp. 29–30.

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