Название |
Development of iron ore base in Gornaya Shoriya as the base for stable operation of Kuzbass metallurgy |
Реферат |
Iron ore deposits in Gornaya Shoriya are the mineral and raw material base of Kuzbass ferrous metallurgy. The powerful step ahead in development of local mining enterprises was done after transformation of the Mining administration of Kuznetsk integrated metallurgical works in the independent Scientific-production corporation “Sibruda”. The modern mining production facilities were established in 1990, and it is well-known in Russia and abroad. Since the beginning of 2000-ies, modernization of Kuzbass iron ore industry was conducted by “EvrazHolding” JSC, one of the largest Russian mining and metallurgical companies. It consolidated the actives of Kazskiy, Tashtagolskiy and Sheregeshskiy affiliates of “Evrasruda” JSC. Insufficient investments in reconstruction of mines and pits in the periods of lowering of global market prices for iron ore led to decrease of ore mining in Gornaya Shoriya from 9.8 mln. t in 1990 to 7.2 mln. t in 2005. Since 1932 until present time more than 500 mln. t of iron ore has been mined in Gornaya Shoriya. Production potential of mines is very high, owing to their positive economical and geographical factors, i.e. presence of the required industrial infrastructure and more than 4 mlrd. t of balanced and predicted reserves of magnetite ores in 200 km distance from customers. Collaboration with scientific centers, development and putting into practice the new investing projects for “Evrazruda” affiliates, use of the experience of mines and pits development and up-to-date innovation technologies for ore mining in the complicated mining and geological conditions allow to rise efficiency of usage of iron ore production potential in Gornaya Shoriya and to provide stability and economical safety of Kuzbass metallurgy. |
Библиографический список |
1. Orlov V. P., Antonenko L. К., Arkhipov G. I. et al. Iron-ore base of Russia. Мoscow: Geoinformatik, 2007. p. 871. 2. Antonenko L. К., Novikov А. А. The conditions and issues of development of the raw materials base for iron and steel industry. Gornyi zhurnal. 1994. No. 1. pp. 3–7. 3. Indukov Yu. V. Iron-ore deposits of Siberia as the basis for the local raw material base of iron and steel industry, history of study, issues, prospects. International scientific and practical forum «Raw material base of Siberia: history of development and prospects»; vol. II. Useful minerals: Tomsk, 2008. pp. 255–263. 4. Kovalev V. А., Kopytov А. I., Pershin V. V. Raw materials resources as important potential for innovation development of the Kuzbass's coal and metallurgical complex. Ugol. 2014. No. 2. pp. 6–9. 5 Kopytov А. I., Pershin V. V., Efremov A. V., Kopytov М. А. Methods and means for intensification of mining operations at minery. Beijing: Pekinskoe izdatelstvo gornoy promyshlennosti, 2004. p. 289. 6. Kurlenya M. V., Eremenko А. А., Shrepp B. V. Geomechanical issues of development of Siberia`s iron ore deposits. Novosibirsk: Nauka, 2001. p. 184. 7. Directions for safety mining at Mountain Shoriya`s deposits prone to and dangerous in view of shock bumps. Novosibirsk, Novokuzetsk: IGD SO RAN, VostNIGRI, SF VNIMI, NITs «Geomekhanika» SibGIU, 2015. p. 73. 8. Eremenko А. А., Bespalko А. А., Eremenko V. А., Yavorovich L. V. Diagnostics of geodynamic effects geohpysical signs and development of geotechnology for explotation of iron ore deposits. Novosibirsk: Nauka, 2016. p. 296. 9. Kopytov А. I., Pershin V. V. Development of Mountain Shoriya`s iron ore industry as the basis for creation of industrial, economicstability and competitive advantages of Kuzbass metallurgy. Vestnik KuzGTU. 2012. No. 3. pp. 170–175. 10. Eremenko А. А., Bashkov V. I., Aleksandrov А. А., Tatarnikov B. B. Experience of chamber development with fi lling of mined-out area at Tashtagol deposit. GIAB. 2013. No. 100. pp. 21–23. 11. Bashkov V. I. Development of broken working in the high pillar area of Tashtagol deposit. Diagnostics of geodynamic effects and development of geotechnology for explotation of iron ore deposits. Novosibirsk: Nauka, 2016. pp. 348–361. 12. Pershin V. V., Kopytov A. I., Voitov M. D., Zhuk I. V., Wetti A. A. Constructions parameters updating of protecting apron under deepening of vertical shafts. Taishan Academic Forum – Project on Mine Disaster Prevention and Control, October 17-20, 2014. Qingdao, China, 2014. pp. 21–24. 13. Carev T. J. Technologies Advances and Productivity: Trends in Sweden’s Mining Industry. Transaction of the Institution of Mining and Metallurgy Section — A. Mining Industry, 1986. Vol. V. 95. pp. A.45–A.46. 14. Kalenchuk K. S., Mercer R., Williams E. Large-magnitude seismicity at the Westwood mine, Quebec, Canada. Deep Mining 2017: Proceeding of the Eight International Conference on Deep and High Stress Mining. Perth: Australian Centre for Geomechanics, 2017. pp. 89–101. 15. Rajmeny P. K., Vakili A. Three-dimensional inelastic numeric backanalysis of observed rock mass response to mining in an Indian mine under high-stress conditions. Deep Mining 2017 : Proceeding of the Eight International Conference on Deep and High Stress Mining. Perth : Australian Centre for Geomechanics, 2017. pp. 329–342. 16. Sjöberg J., Perman F., Lope Álvarez D., Stöckel B.-M., Mäkitaavola K., Storvall E., Lavoie T. Deep sublevel cave mining and surface influence. Deep Mining 2017 : Proceeding of the Eight International Conference on Deep and High Stress Mining. Perth : Australian Centre for Geomechanics, 2017. pp. 357–372. |