Journals →  Eurasian Mining →  2024 →  #2 →  Back

PHYSICS OF ROCKS AND PROCESSES
ArticleName Monitoring of geological environment during mining using land and in-mine seismic surveys
DOI 10.17580/em.2024.02.08
ArticleAuthor Tsarev R. I., Prigara А. М., Zhukov А. А., Mitskevich А. А.
ArticleAuthorData

VNII Galurgii JSC, Perm, Russia1 ; Perm State National Research University, Perm, Russia2

Tsarev R. I.1, 2, Head of Direction, Associate Professor, Candidate of Engineering Sciences, Roman.Tsarev@uralkali.com
Prigara А. М.1, 2, Head of Direction, Chair of State Examinations Commission, Candidate of Engineering Sciences

 

VNII Galurgii JSC, Perm, Russia
Zhukov А. А., Head of Laboratory, Candidate of Engineering Sciences
Mitskevich А. А., Engineer

Abstract

This research aims to assess feasibility of control over geological environment in the course of mining operations with the help of land and in-mine seismic and detection of possible changes in hypsometry of geological boundaries and in physical and mechanical properties of rocks in time (monitoring). The subject of research is the salt strata and overlying rocks at the Verkhnekamskoye Potash Deposit situated in the area of the Berezniki and Solikamsk towns in the Perm Krai. The line of the land seismic survey coincides in plan view with one of the underground seismic lines. The land seismic study involved excitation of spherical waves by blasting explosive charges embedded in blastholes and the reflected wave method of the common depth point (RWM CDP). In the in-mine seismic study and monitoring at the inner points of the test environment, the point force was excited by an impact directional source with recording of shear waves using RWM CDP with separation of reflections (SWSR). As known, stopping operations induce subsidence of ground surface which may cause changes in properties of rock mass above stopes. Within the research framework, the data of land and in-mine seismic are correlated with each other and with the acoustic logging (AL) and underground testing results. The results prove a good agreement between the recorded data on locations of the main reflecting boundaries and on temporal thicknesses of the main lithologic types. Within the research, the major advantages and limitations of the discussed geophysical methods are determined. Land seismic is convenient to study geological structure and detecting large changes connected with strong subsidence and deformation, and is suitable for monitoring critical sites of the geological environment, with a complex geological and tectonic situation, after mine closure—with a view to controlling solution of salt strata. In-mine seismic allows highly detailed monitoring sensitive to even minor changes in the geological environment.

keywords Verkhnekamskoe salt deposit, potassium salt, mining operations, geophysics, seismic exploration, monitoring, surface-and-underground surveys, longitudinal waves, shear waves
References

1. Ivanov A. A. Verkhnekamskoe salt deposit. Leningrad : Nedra, 1975. 217 p.
2. Kopnin V. I. The Verkhnekamsk deposit of potassium, potassium–magnesium and rock salts and natural brines. Minerals and Mining Engineering. 1995. No. 6. pp. 10–43.
3. Kudryashov A. I. The Verkhnekamsk Salt Deposit. 2nd Revised Edition. Moscow : Epsilon Plus, 2013. 371 p.
4. Shokin Yu. P. Causes of Flooding of Potash Mines with Underground Water and Brines in East and West Germany. Leningrad : VNIIG, 1969. Vol. 51. pp. 23–40.
5. Shiman M. I. Flooding Prevention in Potash Mines. Moscow : Nedra, 1992. 160 p.
6. Boganik G. N., Gurvich I. I. Seismic Exploration. Tver : AIS, 2006. 375 p.
7. Bondarev V. I. Seismic Exploration. Yekaterinburg: UGGU. 2007. 703 p.
8. Tsarev R. I., Zhukov A. A., Prigara A. M., Shkuratskiy D. N. Technology and specificity of surface seismic in the Verkhnekamskoe salt deposit. Gornyi Zhurnal. 2021. No. 4. pp. 17–26.
9. Monk D. J. Survey Design and Seismic Acquisition for Land, Marine and In-Between in Light of New Technology and Techniques. USA : Society of Exploration Geophysicists, 2020. 214 p.
10. Sheriff R. E. Encyclopedic Dictionary of Applied Geophysics, 4th Ed. USA : Society of Exploration Geophysicists, 2002. 442 p.
11. Yilmaz O. Seismic Data Analysis. Processing, Inversion and Interpretation of Seismic Data. USA: Society of Exploration Geophysicists, 2001. Vol. I. 1028 p.
12. Zhukov A. A., Prigara A. M., Tsarev R. I., Shustkina I. Yu. Method of mine seismic survey for studying geological structure features of Verkhnekamskoye salt deposit. MIAB. 2019. No. 4. pp. 121–136.
13. Tsarev R. I., Prigara A. M., Zhukov A. A. Capabilities of in-mine seismic with transverse waves. Engineering and Mine Geophysics 2019 — International Conference Proceedings. Gelendzhik, 2019.
14. Prigara A. M., Gribkov D. S., Zhukov A. A., Tsarev R. I. Detailed study of structure and composition of waterproof strata by mine seismic survey at the Verkhnekamskoe salt deposit. Eurasian Mining. 2023. No. 2. pp. 18–22.
15. Golubev B. M. Salt strata structure at the Upper Kama (Verkhnekamsk) Deposit: Thesis of Dissertation of Candidate of Geologo-Mineralogical Sciences. Perm : PGU, 1972.
16. Jackson M. P. A., Hudec M. R. Salt tectonics: Principles and practice. Cambridge University Press, 2017. 513 p.
17. Ampilov Yu. P. From seismic interpretation to modeling and appraisal of oil and gas reservoirs. Moscow : Spektr, 2008. 384 p.
18. Tsarev R. I. The rationale for selecting the geological environment model in the seismic CDP survey forward solution on the Verkhnekamskoye salt deposit. Journal of Geophysics. 2018. No. 5. pp. 18–23.
19. Mahlalela V., Manzi M. Interpretation of legacy 3D seismic data from Oryx Mine in South Africa using seismic attributes. NSG2022 4th Conference on Geophysics for Mineral Exploration and Mining. 2022. Vol. 2022. pp. 1–5.
20. Rapetsoa M. K., Manzi M. S. D., Westgate M. et al. Cost‐effective in‐mine seismic experiments to image platinum deposits and associated geological structures at Maseve platinum mine, South Africa. Near Surface Geophysics. 2022. Vol. 20, Iss. 6. pp. 572–589.
21. Xavier M., Spinola M., Santos L. E. Velocity model building for seismic modeling and depth imaging applied to carbonate reservoirs in presence of karst. The 8th International Congress of the Brazilian Geophysical Society. Rio de Janeiro, Brazil. 2023.

Full content Monitoring of geological environment during mining using land and in-mine seismic surveys
Back