ArticleName |
Justification of functional organization and contents of modeling cluster concept for geomechanical research of convergent mining technologies |
ArticleAuthorData |
NUST MISIS College of Mining, Moscow, Russia:
Galchenko Yu. P., Expert, Doctor of Engineering Sciences, Professor Eremenko V. A., Director of Research Center for Applied Geomechanics and Convergent Mining Technologies, Doctor of Engineering Sciences, Professor of the Russian Academy of Sciences, prof.eremenko@gmail.com Vysotin N. G., Senior Lecturer Kosyreva M. A., Post-Graduate Student |
Abstract |
The new scientific school on the nature-like convergent mining technologies, which assume preventive negotiation of geomechanical consequences of mining-induced damage in the lithosphere, requires adjustment of the conventional modeling methods using the factor of time. In the framework of the main theories of similarity, the comparative studies of different model material composition are carried out, and the formula of solidifying mixtures is justified for equivalent materials for modeling joint loading of manmade and natural components of geotechnical systems. An original procedure is proposed for the construction of block models by means of gluing, such that the unit block sizes are determined in terms of sizes blocks generated by joint systems, and the number and location of gluing points are selected as function of condition of healed joints. The new procedure efficiency is checked by the method of calibration and comparison of the modeling data with the quantitative assessments of the real-life rock masses. For different mining systems, the interpolating functions of the influence factor are plotted to image the rock mass stability categories. The new instrumentation is created for the integrated test workbenches, which provides integrated patterns of strength, deformation and acoustic characteristics of physical models of the proposed convergent geotechnical systems, the obtained values of the strength and deformation characteristics of the physical models made it possible to calibrated the relevant numerical models based on the retrospective analysis of deformation process evolution. It has been proved for the first time that the values of microstrains can be used as the indicators of the secondary stress field in the structure of anthropogenically altered subsoil as an independent object in the lithosphere. The study was supported by the Russian Science Foundation, Project No. 19-17-00034. |
References |
1. Kirpichev M. V. Theory of similarity. Moscow: AN SSSR, 1953. 93 p. 2. Glushikhin F. P., Kuznetsov G. N., Shklyarsky M. F. et al. Modeling in geomechanics. Moscow : Nedra, 1991. 240 p. 3. Pokrovsky G. I., Fedorov I. S. Centrifugal modeling to solve engineering problems. Moscow, 1953. 4. Galchenko Yu. P., Leizer V. I., Vysotin N. G., Yakusheva E. D. Procedure justification for laboratory research of secondary stress field in creation and application of convergent technology for underground mining of rock salt. GIAB. 2019. No. 11. pp. 35–47. 5. Zuev B. Yu., Istomin R. S., Kovshov S. V., Kitsis B. M. Physical modeling the formation of roof collapse zones in Vorkuta coal mines. Bulletin of the Mineral Research and Exploration. 2020. No. 1. pp. 225–234. 6. Rib S. V., Govorukhin Yu. M. Integrated research method for geomechanical processes by combining physical and numerical modeling. Izvestiya TulGU. Nauki o Zemle. 2018. No. 2. pp. 363–378. 7. Sidorov D., Ponomarenko T. Reduction of the ore losses emerging within the deep mining of bauxite deposits at the mines of OJSC Sevuralboksitruda. IOP Conference Series: Earth and Environmental Sci. 2019. 302. 012051. DOI: 10.1088/1755-1315/302/1/012051 8. Aptukov V. N., Volegov S. V. Modeling concentration of residual stresses and damages in salt rock cores. Journal of Mining Science. 2020. Vol. 56. No. 3. pp. 331–338. 9. Rybin V. V., Konstantinov K. N., Kagan M. M., Panasenko I. G. Methodology of integrated stability monitoring in mines. Gornyi Zhurnal. 2020. No. 1. pp. 53–57. DOI: 10.17580/gzh.2020.01.10 10. Eremenko A. A., Konurin A. I., Shtirts V. A., Prib V. V. Identification of higher rock pressure zones in rockburst-hazardous iron ore deposits. Gornyi Zhurnal. 2020. No. 1. pp. 78–81. DOI: 10.17580/gzh.2020.01.15 11. Yu L., Ignatov Y., Ivannikov A., Khotchenkov E., Krasnoshtanov D. Common features in the manifestation of natural and induced geodynamic events in the eastern regions of Russia and China. IOP Conference Series: Earth and Environm ental Science. 2019. Vol. 324(1),012004. DOI: 10.1088/1755-1315/324/1/012004 12. Kong L., Ostadhassan M., Li C., Tamimi N. Rock physics and geomechanics of 3D printed rocks. ARMA 51st U.S. Rock Mechanics and Geomechanics Symposium. San Francisco, California, USA, 2017. pp. 1–8. 13. Gell E. M., Walley S. M, Braithwaite C. H. Review of the validity of the use of artificial specimens for characterizing the mechanical properties of rocks. Rock Mechanics and Rock Engineering. 2019. No. 3. pp. 1–13. 14. Trubetskoy K. N., Myaskov A. V., Galchenko Yu. P., Eremenko V. A. Creation and justification of convergent technologies for underground mining of thick solid mineral deposits. Gornyi Zhurnal. 2019. No. 5. pp. 6–13. DOI: 10.17580/gzh.2019.05.01 15. Trubetskoy K. N., Galchenko Yu. P. Nature-like geotechnology for integrated subsoil use: Problems and prospects. Moscow: Nauchtekhlitizdat, 2020. 368 p. 16. Myaskov A. V. Methodological framework for the ecological and economic justification of preservation of natural ecosystems in mining regions. GIAB. 2011. No. 1. pp. 399–401. 17. Eremenko V. A., Galchenko Yu. P., Vysotin N. G., Leizer V. I., Kosyreva M. A. Strength, deformation and acoustic characteristics of physical models of frame and honeycomb underground structures. Journal of Mining Science. 2020. Vol. 56. No. 6. pp. 962–971. |