Substantiation of the method ensuring the safe development of the pit reserves of kimberlite ore deposits in the conditions of the Udachny mine

K. A. Anisimov; V. P. Zubov

doi:10.1051/e3sconf/202126603013

All issues

Volume 266 (2021)

E3S Web Conf., 266 (2021) 03013

References

Open Access

Issue		E3S Web Conf. Volume 266, 2021 Topical Issues of Rational Use of Natural Resources 2021


Article Number		03013
Number of page(s)		12
Section		Geotechnologies of Subsurface Development: Modern Challenges and Prospects
DOI		https://doi.org/10.1051/e3sconf/202126603013
Published online		04 June 2021

Tishkov M. 2018. Evaluation of caving as mining method for the Udachnaya underground diamond mine project. Caving 2018: pp. 835–846. [Google Scholar]
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Kosukhin, N.I. & Sidorov, D.V. & Beloglazov, I.I. & Timofeyev, V.Y. 2019. Assessment of Stress-Strain and Shock Bump Hazard of Rock Massin the Zones of High -Amplitude Tectonic Dislocations. IOP Conference Series: Earth and Environmental Science (Vol 224): pp.1–5. [Google Scholar]
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Kovalenko, A.A. & Tishkov, M.V. 2016. Evaluation of development of the Udachnaya pipe field. Mining Information and Analytical Bulletin (12): 173–174. [Google Scholar]
Chadwick, J. 2012. Automated Finsch. International Mining: pp. 10–13. [Google Scholar]
Jacques, J.-S. Thompson, S. 2019. Rio Tinto Interim Results 2019. England: Rio Tinto. [Google Scholar]
Zuev, B.Yu. & Zubov, V.P. & Fedorov, A.S. 2019. Application prospects for models of equivalent materials in studies of geomechanical processes in underground mining of solid minerals. Eurasianmining (1): 8–12. [Google Scholar]
Trushko, V.L. & Protosenya, A.G. 2019. Prospects of geomechanics development in the context of new technological paradigm. Notes of MiningInstitute (Vol. 236): pp. 162–166. [Google Scholar]
Chaadaev, A.S. & Zyryanov, I.V. & Bondarenko, I.F. 2017. State and prospects of development of mining technologies at diamond mining enterprises of PAO Alrosa. Mining Industry (2): pp. 6–13. [Google Scholar]
Balek, A.E. & Efremov, E.Yu. 2016. Justification of the geomechanical conditions of the underground mining of the Udachnaya diamond pipe. Innovative geotechnologies in the development of ore deposits: pp. 173–176. [Google Scholar]
Kovalsky, E.R. & Leisle, A.V. & Karpov G.N. 2020. Evaluation of displacements of the mine workings contour in abutmen tpressure zones. International Journal of Advanced Science and Technology (Vol 29): pp. 1951–1959. [Google Scholar]
Drozdov, A.V. 2009. Geotechnological problems of developing the deep horizons of the Udachnaya pipe. Subsoil use problems: issues of integrated development of deep-seated mineral deposits: pp. 110–121. [Google Scholar]
Drozdov, A.V. 2011. Mining and geological features of the deep horizons of the Udachnaya pipe. Mining Information and Analytical Bulletin (1): pp. 153–165. [Google Scholar]
Bartlett, S.C. 2018. Brief report by independent experts on the reserves and resources of diamond deposits of the ALROSA group of companies. England: Micon International Co Limited. [Google Scholar]
Balek, A.E. & Sashurin, A.D. 2019. The problem of assessing the natural stress-strain state of a rock mass during subsurface development. Mining Information and Analytical Bulletin (special issue): pp. 9–23. [Google Scholar]
Bokiy, I.B. & Zoteev, O.V. & Pul, V.V. 2019. Analysis of the process of subsidence of the rock cushion during mining of the western ore body of the Udachnaya pipe using a collapse system. Mining Journal (2):pp. 43–46. [Google Scholar]
Jakubec J. & Legace, D. & Boggis, B. & Clark L.M. & Lewis P.A. 2018. Underground mining at Ekati and Diavik diamond mines. Caving 2018: pp. 73–88. [Google Scholar]
Piven, G.F. 2011. Technologies for the development of sub-quarry reserves of the Udachnaya pipe. Notes of the Mining Institute (1): pp.359–361. [Google Scholar]
Carlson, J.A. 2016 Ekati diamond mine, Northwest Territories, Canada, NI 43–101 Technical report. [Google Scholar]
Sokolov, I.V. & Smirnov, A.A. & Antipin, Yu.G. & Nikitin, I.V. & Tishkov, M.V. 2018. Justification of the thickness of the safety cushion when working out the quarry reserves of the Udachnaya pipe with caving systems. Technology mining operations (2): pp. 52–62. [Google Scholar]
Slyshenko I.I. & Mishedchenko O.A. 2018. Reasons of the rock massive deformations in the underground developing of the Udachnaya pipe of Alrosa. Mine surveying and subsurface use No 1 (93): pp. 24–31. [Google Scholar]
Cleaver, B. 2019. The Diamond Insight Report 2019. England: De Beers Group. [Google Scholar]
Drozdov, A.V. 2015. Mining, geological and technological problems in the construction of the Udachnaya underground mine. Mining Information and Analytical Bulletin (2): pp. 125–131. [Google Scholar]
Kostrovitsky S.I. 2010. What is kimberlites? Materials of the 6th International School of Earth Sciences ISES-2010: pp. 77–81. [Google Scholar]
Pokrovsky, G.I. & Fedorov, I.S. 1971. Erection of hydraulic engineering earthworks with a directed explosion. Moscow: Nedra. [Google Scholar]
Yakubovskiy, M.M., Sankovsky, A.A. 2017. Drilling and blasting design based on invariable mining parameters. Journal of Industrial Pollution Control (Vol. 33): pp. 931–936. [Google Scholar]
Zharovkin A.V. 2009. Improving the technology of calculating dangerous distances by scattering pieces of rocks during massive explosions in open pits. Notes of the Mining Institute (Vol.180): pp. 135–139. [Google Scholar]
Zuev, B.Yu. & Zubov, V.P. & Smychnik, A.D. 2019. Determination of static and dynamic stresses in physical models of layered and block rock masses. Mining Journal (7): pp. 61–70. [Google Scholar]

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[1] Tishkov M. 2018. Evaluation of caving as mining method for the Udachnaya underground diamond mine project. Caving 2018: pp. 835–846. [Google Scholar]

[2] Kovalenko, A. A. & Ikh, I.L. 2016. Improving the technology of mining reserves of the Udachnaya pipe using development systems with self-collapse of ore. Innovative geotechnologies in the development of ore deposits: pp. 69–74. [Google Scholar]

[3] Kosukhin, N.I. & Sidorov, D.V. & Beloglazov, I.I. & Timofeyev, V.Y. 2019. Assessment of Stress-Strain and Shock Bump Hazard of Rock Massin the Zones of High -Amplitude Tectonic Dislocations. IOP Conference Series: Earth and Environmental Science (Vol 224): pp.1–5. [Google Scholar]

[4] Nikitin, I.V. 2017. Optimization of opening parameters during underground mining of open-pit reserves of a kimberlite deposit. Topical Issues of Rational Use of Natural Resources (1) pp. 21–28. [Google Scholar]

[5] Kovalenko, A.A. & Tishkov, M.V. 2016. Evaluation of development of the Udachnaya pipe field. Mining Information and Analytical Bulletin (12): 173–174. [Google Scholar]

[6] Chadwick, J. 2012. Automated Finsch. International Mining: pp. 10–13. [Google Scholar]

[7] Jacques, J.-S. Thompson, S. 2019. Rio Tinto Interim Results 2019. England: Rio Tinto. [Google Scholar]

[8] Zuev, B.Yu. & Zubov, V.P. & Fedorov, A.S. 2019. Application prospects for models of equivalent materials in studies of geomechanical processes in underground mining of solid minerals. Eurasianmining (1): 8–12. [Google Scholar]

[9] Trushko, V.L. & Protosenya, A.G. 2019. Prospects of geomechanics development in the context of new technological paradigm. Notes of MiningInstitute (Vol. 236): pp. 162–166. [Google Scholar]

[10] Chaadaev, A.S. & Zyryanov, I.V. & Bondarenko, I.F. 2017. State and prospects of development of mining technologies at diamond mining enterprises of PAO Alrosa. Mining Industry (2): pp. 6–13. [Google Scholar]

[11] Balek, A.E. & Efremov, E.Yu. 2016. Justification of the geomechanical conditions of the underground mining of the Udachnaya diamond pipe. Innovative geotechnologies in the development of ore deposits: pp. 173–176. [Google Scholar]

[12] Kovalsky, E.R. & Leisle, A.V. & Karpov G.N. 2020. Evaluation of displacements of the mine workings contour in abutmen tpressure zones. International Journal of Advanced Science and Technology (Vol 29): pp. 1951–1959. [Google Scholar]

[13] Drozdov, A.V. 2009. Geotechnological problems of developing the deep horizons of the Udachnaya pipe. Subsoil use problems: issues of integrated development of deep-seated mineral deposits: pp. 110–121. [Google Scholar]

[14] Drozdov, A.V. 2011. Mining and geological features of the deep horizons of the Udachnaya pipe. Mining Information and Analytical Bulletin (1): pp. 153–165. [Google Scholar]

[15] Bartlett, S.C. 2018. Brief report by independent experts on the reserves and resources of diamond deposits of the ALROSA group of companies. England: Micon International Co Limited. [Google Scholar]

[16] Balek, A.E. & Sashurin, A.D. 2019. The problem of assessing the natural stress-strain state of a rock mass during subsurface development. Mining Information and Analytical Bulletin (special issue): pp. 9–23. [Google Scholar]

[17] Bokiy, I.B. & Zoteev, O.V. & Pul, V.V. 2019. Analysis of the process of subsidence of the rock cushion during mining of the western ore body of the Udachnaya pipe using a collapse system. Mining Journal (2):pp. 43–46. [Google Scholar]

[18] Jakubec J. & Legace, D. & Boggis, B. & Clark L.M. & Lewis P.A. 2018. Underground mining at Ekati and Diavik diamond mines. Caving 2018: pp. 73–88. [Google Scholar]

[19] Piven, G.F. 2011. Technologies for the development of sub-quarry reserves of the Udachnaya pipe. Notes of the Mining Institute (1): pp.359–361. [Google Scholar]

[20] Carlson, J.A. 2016 Ekati diamond mine, Northwest Territories, Canada, NI 43–101 Technical report. [Google Scholar]

[21] Sokolov, I.V. & Smirnov, A.A. & Antipin, Yu.G. & Nikitin, I.V. & Tishkov, M.V. 2018. Justification of the thickness of the safety cushion when working out the quarry reserves of the Udachnaya pipe with caving systems. Technology mining operations (2): pp. 52–62. [Google Scholar]

[22] Slyshenko I.I. & Mishedchenko O.A. 2018. Reasons of the rock massive deformations in the underground developing of the Udachnaya pipe of Alrosa. Mine surveying and subsurface use No 1 (93): pp. 24–31. [Google Scholar]

[23] Cleaver, B. 2019. The Diamond Insight Report 2019. England: De Beers Group. [Google Scholar]

[24] Drozdov, A.V. 2015. Mining, geological and technological problems in the construction of the Udachnaya underground mine. Mining Information and Analytical Bulletin (2): pp. 125–131. [Google Scholar]

[25] Kostrovitsky S.I. 2010. What is kimberlites? Materials of the 6th International School of Earth Sciences ISES-2010: pp. 77–81. [Google Scholar]

[26] Pokrovsky, G.I. & Fedorov, I.S. 1971. Erection of hydraulic engineering earthworks with a directed explosion. Moscow: Nedra. [Google Scholar]

[27] Yakubovskiy, M.M., Sankovsky, A.A. 2017. Drilling and blasting design based on invariable mining parameters. Journal of Industrial Pollution Control (Vol. 33): pp. 931–936. [Google Scholar]

[28] Zharovkin A.V. 2009. Improving the technology of calculating dangerous distances by scattering pieces of rocks during massive explosions in open pits. Notes of the Mining Institute (Vol.180): pp. 135–139. [Google Scholar]

[29] Zuev, B.Yu. & Zubov, V.P. & Smychnik, A.D. 2019. Determination of static and dynamic stresses in physical models of layered and block rock masses. Mining Journal (7): pp. 61–70. [Google Scholar]