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PHYSICS OF ROCKS AND PROCESSES
Название Integrated multi-level geofluid mechanics monitoring system for mine waterworks
DOI 10.17580/em.2018.02.02
Автор Melnikov N. N., Kalashnik A. I., Kalashnik N. A.
Информация об авторе

Mining Institute, Kola Science Center, Russian Academy of Sciences, Apatity, Russia

Melnikov N. N., Academician of the Russian Academy of Sciences
Kalashnik A. I., Head of Laboratory, Candidate of Engineering Sciences, kalashnik@goi.kolasc.net.ru
Kalashnik N. A., Researcher

Реферат

The article sets out a methodical framework of an integrated multi-level geofluid mechanics monitoring system for the mining and processing industry and illustrates the system implementation in the Kola Peninsula. The system is based on the multi-disciplinary observations, including ground-based and GPS (satellite) survey, geological engineering, hydrogeological and geotechnical measurements, aerial photography, geomechanical assessment, as well as subsurface, ground-based and spaceborn radar sensing. The structure of the system provides five monitoring levels, out of which the first four levels (subsurface, groundbased, airborn and spaceborn) are related with the daylight surface, while the fifth level (computer) means geofluid mechanics modeling and multi-version prediction in the analysis of various combinations of nature and technology impacts. The actual observations and subsatellite sites at waterworks of tailings ponds are illustrated in terms of processing plants of Kovdor GOK, Kola MMC, Oleniy Ruchey GOK and OLKON companies. Within the last 4 years, the integrated research into the state of these structures has been carried out jointly with the multi-level and different-scale scheduled measurements using check and control bench marks. From the obtained evidence, characteristics of the mechanical strength as well as permeability and deformation behavior of waterworks dams are revealed. The implemented research proves that the multi-level geofluid mechanics monitoring of waterworks within the systematic multi-disciplinary investigations enables early-stage detection of hazardous seepage, deformations and damages, as well as well-timed response and command decision-making to prevent emergencies and accidents. The experience gained in the integration of space, subsurface and ground-based radar sensing into surveying and hydrogeological observations makes it possible to state that the created system can efficiently be used in the geofluid mechanics monitoring of waterworks in the mining and processing industry.

The study was supported by the Russian Foundation for Basic Research, Project No. 15-29-06037.

Ключевые слова Multi-level monitoring, multi-disciplinary integrated research, waterworks, mines
Библиографический список

1. Melnikov N. N., Kalashnik A. I. Multi-level geodynamic monitoring system for man-made and production objects of petroleum industry in the west of the Russian Arctic. Arktika: ekologiya i ekono mika. 2015. No. 3 (19). pp. 66–75.
2. Bychkov I. V., Vladimirov D. Ya., Oparin V. N., Potapov V. P., Shokin Yu. I. Mining information science and Big Data concept for integrated safety monitoring in subsoil management. Journal of Mining Science. 2016. Vol. 52. No. 6. pp. 1195–1209.
3. Hartwig M. E. Detection of mine slope motions in Brazil as revealed by satellite radar interferograms. Bulletin of Engineering Geology and the Environment. 2016. Vol. 75 (2), Iss. 2. pp. 605–621.
4. Alabyan A. M., Zelentsov V. A., Krylenko I. N., Potryasaev S. A., Sokolov B. V., Yusupov R. M. Creation of intelligent information systems for operational prediction of river stream rises. Vestnik RAN. 2016. Vol. 86. No. 2. pp. 127–137.
5. Jiang H., Lin P., Fan Q., Qiang M. Real-time safety risk assessment based on a real-time location system for hydropower construction sites. The Scientific World Journal. 2014. Jul 9. p. 14.
6. Melnikov N. N., Kalashnik A. I., Kalashnik N. A., Zaporozhets D. V. The use of modern methods for complex studies of the hydrotechnical structure of the Barents Sea region. MSTU vestnik. 2017. Vol. 20, No. 1. pp. 13–20.
7. Melnikov N. N., Kalashnik A. I., Zaporozhets D. V. Diakov A. Yu., Maksimov D. A. Experience of the radar subsurface sensing in the west of the Russian Arctic. Problemy Arktiki i Antarktiki. 2016. No. 1. pp. 39–49.
8. Zelentsov V. A., Kovalev A. P., Okhtilev M. Yu., Sokolov B. V., Yusupov R. M. Creation and application methodology of the intelligent information technology of complexity objects space and ground-based monitoring. SPIIRAS Proceedings. 2013. No. 5 (28). pp. 7–81.
9. Kozhaev Zh. T., Mukhamedgalieva M. A., Imansakipova B. B., Mustafin M. G. Geoinformation system for geomechanical monitoring of ore deposits using spaceborn radar interferometry methods. Gornyy Zhurnal. 2017. No. 2. pp. 39–44. DOI: 10.17580/gzh.2017.02.07.
10. Mikhailov V. O., Kiseleva E. A., Smolyaninova E. I., Golubev V. I., Dmitriev P. N., Timoshkina E. P., Khairetdinov S. A. Review of the results of application of different methods for SAR image processing to study and monitor landslide activity in the Big Sochi region. Sovremennye problemy distantsionnogo zondirovaniya Zemli iz kosmosa. 2016. Vol. 13. No. 6. pp. 137–147.
11. Ferretti A. Satellite InSAR Data: Reservoir Monitoring from Space. EAGE Publications bv. 2014. 160 p.
12. Kalashnik N. A. Computer modeling of mechanical strength and seepage resistance of a tailings pond dam. Int. Conf. Proc.: Modern Innovative Technologies of Mining and Transport Engineer Training. 2016. No. 3. pp. 304–308.
13. Zaki M. J., Vagner M. Jr. Data Mining and analysis. Fundamental Concepts and Algorithm. New York : Cambridge University Press. 2014. 607 p.
14. Naticchia B., Vaccarini M., Carbonari A. A monitoring system for real-time interference control on large construction sites. Automation in Construction. 2013. Vol. 29. pp. 148–160.

Полный текст статьи Integrated multi-level geofluid mechanics monitoring system for mine waterworks
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