ArticleName |
Loosing of rocks by blasting without
disintegration at open pit mines |
ArticleAuthorData |
Institute of Mining, Far Eastern Branch, Russian Academy of Sciences, Khabarovsk, Russia
E. B. Shevkun, Chief Researcher, Professor, Doctor of Engineering Sciences, ev.shevkun@yandex.ru
E. N. Kazarina, Junior Researcher at Rock Fracture Sector
AVT-Amur LLC, Blagoveshchensk, Russia A. Yu. Plotnikov, Deputy Chief Engineer of Drilling and Blasting, Candidate of Engineering Sciences P. V. Nikulin, Managing Director, Malomir Mine |
Abstract |
The current fleet of single bucket excavators at open pit mines in the Far East of Russia consists mostly of hydraulic machines with bucket capacity of 4–36 m3. Reliable operation of such machines is only possible at high-quality fragmentation of strong rocks by blasting. At the same time, in open pit mining of high-value ores in strong rock masses, it is required to preserve natural ore and waste rock interfaces to reduce mixing of rocks in disintegration during preparation of strong rocks for excavation using special blasting techniques. Therefore, for the last ten years, the authors engaged themselves in development of a technology of blasting-induced loosening at open pit mines of Atlas Mining Group. The technology was aimed to ensure high-quality fragmentation of rocks by blasting at maximum preservation of initial ore–rock interfaces to reduce ore dilution without escalation of material costs. High results are achieved with delays longer than 100 ms between successively blasted charges: the mechanism of explosive rupture of rocks in multi-row short-delay blasting changes drastically as such delays enable formation of screening (reflective) surface represented by earlier blasted rock mass, which essentially alters interaction between the stress wave energy and rocks. As a consequence, the blasting energy is maximally spent for rock loosening at the minimal displacement of blasted rock mass owing to control of parameters of the reflected and refracted stress waves in rock mass at the same charge energy, and the kinetic energy of ejection is redirected to rock fragmentation. It is shown that blasting at delays longer than 200 ms increases the yield of broken rocks at the essentially decreased powder factor. The pattern of blastholes with the diameter of 5 m is increased to 6.5×6.5 m, and the yield of broken rocks is expanded to 30 m3/m. As against the delay intervals of 150–200 ms, dilution is reduced from 8.8 to 7.6 %, and the loss of useful materials is decreased by 22%. The authors would like to appreciate participation of S. I. Korneeva, Leading Researcher and Candidate of Engineering Sciences from the Institute of Mining, FEB RAS in this study. |
References |
1. Lysak Yu. A., Plotnikov A. Yu., Shevkun E. B., Leshchinsky A. V. Loose blasting of rocks at quarries of the Petropavlovsk group of companies. Gornyi Zhurnal. 2022. No. 2. pp. 45–50. 2. Silva J., Worsey T., Lusk B. Practical assessment of rock damage due to blasting. International Journal of Mining Science and Technology. 2019. Vol. 29, Iss. 3. pp. 379–385. 3. Qiu P., Yue Z., Yang R. Experimental study on mode-I and mixed-mode crack propagation under tangentially incident P waves, S waves and reflected waves in blasts. Engineering Fracture Mechanics. 2021. Vol. 247. ID 107664. 4. Ofoegbu G. I., Smart K. J. Modeling discrete fractures in continuum a nalysis and insights for fracture propagation and mechanical behavior of fractured rock. Results in Engineering. 2019. Vol. 4. ID 100070. 5. Shevkun E. B., Leshchinsky A .V., Shishkin E. A., Lysak Yu. A. Graphoanalytical method of determining the intensity of a preliminary destruction of the surrounding area blast holes. Vzryvnoe delo. 2018. No. 121/78. pp. 33–47. 6. Yang L.-Y., Ding C.-X. Fracture mechanism due to blast-imposed loa ding under high static stress conditions. International Journal of Rock Mechanics and Mining Sciences. 2018. Vol. 107. pp. 150–158. 7. Shekhar G., Gustafson A., Boeg-Jensen P., Malmgren L., Schunnesson H. Draw control strategies in sublevel caving mines—A baseline mapping of LKAB’s Malmberget and Kiirunavaara mines. The Journal of the Southern African Institute of Mining and Metallurgy. 2018. Vol. 118, No. 7. pp. 723–733. 8. Nesterov K. V., Kuzenkov M. V. Expanding Kola MMC’S resource base. Tsvetnye Metally. 2019. No. 11. pp. 16–21. 9. Tyupin V. N. Geomechanical behavior of jointed rock mass in the large-scale blast impact zone. Eurasian Mining. 2020. No. 2. pp. 11–14. 10. Zenkov I. V., Morin A. S., Vokin V. N., Kiryushina E. V. Cumulative production potential of quarries to supply crushed stone factories in Russia: An overview. Eurasian Mining. 2021. No. 1. pp. 45–48. 11. Gui Y. L., Zhao Z. Y., Jayasinghe L. B., Zhou H. Y., Goh A. T. C. et al. Blast wave induced spatial variation of ground vibr ation considering field geological conditions. International Journal of Rock Mechanics and Mining Sciences. 2018. Vol. 101. pp. 63–68. 12. Zharikov I. F. Increased efficiency of crushing rocks in deep pits. Vzryvnoe delo. 2018. No. 121/78. pp. 48–57. 13. Leshchinskiy A. V., Shevkun E. B. Deep-hole charge dispersion. Khabarovsk : Izdatelstvo TOGU, 2009. 154 p. 14. Galimyanov A. A. Justification of open pit mining technology parameters for closely spaced and inclined coal seams : Thesis of Dissertation of Candidate of Engineering Sciences. Khabarovsk, 2016. 19 p. 15. Andreev V. V. About features of short-delay blasting. Vzryvnoe delo. 2014. No. 112/69. pp. 220–222. 16. Mosinets V. N. Crushing and seismic action of blast in rocks. Moscow : Nedra, 1976. 271 p. 17. Plotnikov A. Yu. Technology for strong rock loosening by blasting at minimal mixing : Thesis of Dissertation of Candidate of Engineering Sciences. Khabarovsk, 2022. 24 p. 18. Shevkun E. B., Leshchinskiy A. V., Plotnikov A. Yu. et al. Method of development of local areas of mineralization in strong rocks. Patent RF, No. 2723419. Applied: 23.12.2019. Published: 11.06.2020. Bulletin No. 17. 19. Shtukarin N. G. Physics of an explosion in applied problems. Krasnoyarsk : Sitam, 2010. 309 p. |