ArticleName |
Ways to improve rotary-percussive drilling efficiency |
ArticleAuthorData |
Chinakal Institute of Mining, Siberian Branch, Russian Academy of Sciences, Novosibirsk, Russia:
A. S. Kondratenko, Director, Candidate of Engineering Sciences V. V. Timonin, Deputy Director, Candidate of Engineering Sciences, timonin@misd.ru V. N. Karpov, Researcher
Novosibirsk State Technical University, Novosibirsk, Russia: A. I. Popelyukh, Associate Professor, Candidate of Engineering Sciences |
Abstract |
This study is aimed to solve the problems connected with the improvement of the rotary–percussive drilling method in Russian mines which have faced the decline in the productivity of drill rigs and the drilling cost escalation in the last decade. The problem analysis based on the systematic field studies and test data on mass-produced DTH drilling machines has shown that the poor quality and low energy performance of the domestic manufacture machines 2–4 times behindhand their foreign analogs positively leads to the substitution of the domestic drilling equipment with the foreign machines. Within the analyzed range of problems, in order to compensate downtime due to drilling equipment failures, mines expand the drilling equipment life recorded in the annular drilling-and-blasting expenditure estimates by 10–15%. Defective drilling equipment worsens financial and economic indicators of mining activities, and mine executives are urged to find new suppliers of drilling tools and sometimes are forced to give up advanced mining technologies as they yield loss because of poor performance of drilling machines and tools. Operation of drilling machinery in the Abakan (formerly affiliated with EVRAZruda) and Tashtagol Mines is studied in this article. Both mines use DTH hammers in drilling blastholes with the diameter of 105, 160 and 250 mm. In the framework of the government policy of import substitution, the article illustrates governmental support of the Sweden research cluster materializing advanced ideas in development of new-generation drilling machines. The authors believe that getting out of the situation requires targeted supported provided by the government and private business to the domestic drilling equipment design engineers, which will allow machine building plants in Russia to compete successfully with the imported machines and, thereby, to improve efficiency of drilling in Russian mines. |
References |
1. Eremenko A. A., Eremenko V. A., Gaidin A. P. Geological and geomechanical conditions of iron ore mining in the Altai-Sayan folded zone. Novosibirsk : Nauka. 2009. 224 p. 2. Ilin S. A. Kovalenko V. S., Pastikhin D. B. Siberia as a prospective ground for the development of mineral resources by open-cut method. Gornyi Zhurnal. 2013. No. 3. pp. 63–67. 3. Esin N. N. Down-the-hole air drill hammers. Novosibirsk : Nauka. 1976. 100 p. 4. Esin N. N., Kostylev A. D., Gurkov K. S., Smolyanitsky B. N. Percussive pneumatic machines for hole drilling. Novosibirsk : Nauka. 1986. 216 p. 5. Alekseev S. E. Enclosed-type down-the-hole air hammers with full faces of hammering unit. Improvement of efficiency of air drilling machines: collection of scientific papers. Novosibirsk : IGD SO RAN. 1987. pp. 29–32. 6. Timonin V. V., Alekseev S. E., Karpov V. N., Chernienkov E. M. Influence of DTH Hammer Impact Energy on Drilling-with-Casing System Performance. Journal of Mining Science. 2018. Vol. 54, No. 1. 7. Mattis A. R., Zvorygin L. V., Labutin V. N. Creators of mining machines. Novosibirsk : IGD SO RAN. 2008. 248 p. 8. Eremenko V. A., Karpov V. N., Timonin V. V., Barnov N. G., Shakhtorin I. O. Basic trends in development of drilling equipment for ore mining with block caving method. Journal of Mining Science. 2015. Vol. 51, No. 6. pp. 1113–1125. 9. Shakhtorin I. O. Debugging of impact machines using modern software. Fundamentalnye i prikladnye voprosy gornyh nauk. 2017. Vol. 4, No. 1. pp. 72–76. 10. Beshenkov P. S., Polushin N. I., Gkhorbani S., Sorokin E. N. Stress distribution analysis of PDC drill bits by computer modeling. Eurasian Mining. 2017. No. 2. pp. 25–28. DOI: 10.17580/em.2017.02.06. 11. Improvement of efficiency and durability of impulse-generating machines for long hole drilling in rocks. Ed.: Simonov B. F. Novosibirsk : SO RAN. 2013. Vol. 43. 204 p. 12. Lyukhanov V. V., Alferov S. B. Application of the Machine Building Holding drilling tools and equipment – A guarantee of efficiency of drilling. Gornaya promyshlennost. 2010. No. 4. pp. 38– 42. 13. Potebenko A. N., Bolkiseva E. V., Regotunov A. S. Testing and application of drilling equipment in the Severo-Peschanskaya Mine of Bogoslavsky Mine Management. Gornyy informatsionnoanaliticheskiy byulleten. 2010. No. 11. pp. 333–339. 14. Vorobiev A. G., Timokhin D. V., Ivanova M. S., Popova G. I., Serebryannaya L. S. Innovatization as an instrument of overcoming of competitive lagging of russian metallurgy from the developing countries. Tsvetnye metally. 2014. No. 8. pp. 8–13. 15. Karpov V. N. Assessment Testing Procedure for Downhole Pneumatic Hammers under Production Conditions. Fundamentalnye i prikladnye voprosy gornykh nauk. 2016. Vol. 2. No. 3. pp. 74–80. 16. Buran blast hole drilling rigs. Amursky metallist. Available at: http://www.amurmet.com/buran1.shtml (accessed: 14.04.2018). 17. Secoroc rock drilling tools: DTH equipment: Product catalogue. Atlas Copco. 2015. 48 p. 18. A–Z of DTH drilling. Halco Rock Tools. 2016. 76 p. 19. Nariseti C., Mohanty B., Keskiniva M. Crack formation in rocks due to action of cemented carbide bits. Rock Fragmentation by Blasting: Fragblast 10: Proceedings of the 10th International Symposium on Rock Fragmentation by Blasting. Leiden : CRC Press. 2013. pp. 55–64. 20. Guo Yong, Yang Shu Yi, Liu De Shun, Zhang Long Yan, Chen Jian Wen. Impact performance for high frequency hydraulic rock drill drifter with sleeve valve. International Journal of Fluid Machinery and Systems. 2016. Vol. 9, No. 1. pp. 39–46. 21. DTH drilling tools catalog. Rockmore International. 2016. 84 p. 22. Sandvik’s New Pantera DTH. Mining Turkey: Mining and Earth Science Magazine. 2014. Vol. 3, No. 6. pp. 26–27. |