Analyzing stability of protective structures as the elements of geotechnical tailing pond safety

Vasyl Tymoshchuk¹, Leonid Rudakov², Dmytro Pikarenia³, Olha Orlinska³, Hennadii Hapich²

¹Dnipro University of Technology, Dnipro, Ukraine

²Dnipro State Agrarian and Economic University, Dnipro, Ukraine

³Technical University “Metinvest Polytechnic” LLC

Min. miner. depos. 2023, 17(4):116-122

https://doi.org/10.33271/mining17.04.116

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      ABSTRACT

      Purpose is the assessment of soil retaining wall stability to ensure geotechnical safety during the radioactive waste tailing pond closure and further recultivation (or rehabilitation) in Kamianske town (Ukraine).

      Methods. Geomechanical stability of the protective structure has been assessed relying upon the analysis of geological-hydrogeological, engineering-geological, and geotechnical conditions of the certain tailing pond area using a deformation elastic-plastic model of a medium implemented on the basis of finite-element method. For the purpose, the dam slopes have been detalized taking into consideration their geometry as well as changes in vertical section of rock material characteristics in accordance with the earlier geophysical studies; exploration drilling; and engineering-geological surveys.

      Findings. Stability coefficients of protective tailing pond dam have been identified within the typical areas of a hydraulic structure; it provides high reliability and representativeness of the whole structure health in time as well as under various conditions of the industrial waste water saturation. It has been defined that the stability coefficients varies from k_s = 1.372 to 4.758. Comparison of the indicators between 2022 and 2016 demonstrates a tendency of the slope stability coefficient decrease due to water saturation and groundwater level rise. Nevertheless, design characteristics of the structure make it possible to ensure satisfactory a stability coefficient along the whole dam length being 1.13 times higher than the standard one (i.e. k_s = 1.250).

      Originality. The dependence of the tailing pond protective dam stability upon a water supply degree at the forecasted groundwater level rise at the expense of atmospheric and melt water ingress to the tailing pond has been defined. The danger of complete radioactive waste water saturation is a significant reduction in the stability coefficient of the protective structure, which can be supported by predictive modelling data. If strength parameters of a dam material decline for the most critical area then the strength coefficient decreases starting from 1.532 in terms of the current groundwater level down to 1.372 as for the forecasted dam water supply. The figure is more than 10% of its initial stability.

      Practical implications. The obtained results substantiate the necessity; moreover, they are of practical value while improving hydrological, hydrogeological, and geotechnical monitoring of the analyzed tailing pond to ensure its radiation safety under different conditions of further behaviour during closure, recultivation, or rehabilitation.

      Keywords: tailing pond, environmental safety, radiation safety, protective dam, slope stability

      REFERENCES

1. Hu, Q.-H., Weng, J.-Q., & Wang, J.-S. (2010). Sources of anthropogenic radionuclides in the environment: A review. Journal of Environmental Radioactivity, 101(6), 426-437. https://doi.org/10.1016/j.jenvrad.2008.08.004
2. Kossoff, D., Dubbin, W.E., Alfredsson, M., Edwards, S.J., Macklin, M.G., & Hudson-Edwards, K.A. (2014). Mine tailings dams: Characteristics, failure, environmental impacts, and remediation. Applied Geochemistry, (51), 229-245. https://doi.org/10.1016/j.apgeochem.2014.09.010
3. WISE (World Information Service on Energy) uranium project: Chronology of major tailings dam failure. (2023). Retrieved from: https://www.wise-uranium.org/mdaf.html
4. Yim, M.S. (2022). Policy and regulations for nuclear waste management. Nuclear Waste Management, (83), 9-50. https://doi.org/10.1007/978-94-024-2106-4_2
5. Smith, D.K., Knapp, R.B., Rosenberg, N.D., & Tompson, A.F.B. (2003). International cooperation to address the radioactive legacy in states of the former Soviet Union. The Science and Culture Series – Nuclear Strategy and Peace Technology, 534-544. https://doi.org/10.1142/9789812702753_0060
6. Korovin, V., Korovin, Yu., Laszkiewicz, G., Laszkiewicz, G., Lee, L., Koshik, Y., Shmatkov, G., Semenets, G., & Merkulov, V. (2001). Problem of radioactive pollution as a result of Uranium ores processing. Scientific and Technical Aspects of International Cooperation in Chernobyl, Ukraine, 461-476.
7. Voitsekhovich, O., Lavrora, T., Skalskiy, A.S., & Ryazantsev, V.F. (2007). The strategy on rehabilitation of the former uranium facilities at the “Pridneprovsky Chemical Plant” in Ukraine. Proceedings of the 11^th International Conference on Environmental Remediation and Radioactive Waste Management, Parts A and B, 959-963. https://doi.org/10.1115/ICEM2007-7196
8. Korovin, V.Yu., Valiaiev, O.M., Pohorielov, Yu.M., Shestak, Yu.G., Lavrova, T.V., & Haneklaus, N. (2021). Uranium sorption from radioactive waste of uranium ore processing at Pridneprovsk Chemical Plant. Geo-Technical Mechanics, (157), 212-222. https://doi.org/10.15407/geotm2021.157.212
9. Singh, S., Kumar, A., & Sitharam, T.G. (2022). Stability analysis of tailings dam using finite element approach and conventional limit equilibrium approach. Lecture Notes in Civil Engineering, (185), 91-103. https://doi.org/10.1007/978-981-16-5601-9_9
10. Sitharam, T.G., & Hegde, A. (2016). Stability analysis of rock-fill tailing dam: An Indian case study. International Journal of Geotechnical Engineering, 11(4), 332-342. https://doi.org/10.1080/19386362.2016.1221574
11. Rios, A.C., Porfírio, M., & Assis, A. (2018). A probabilistic approach to the stability of a dam under rapid drawdown conditions. PanAm Unsaturated Soils 2017. https://doi.org/10.1061/9780784481691.012
12. Zhang, C., Ma, C., Xiong, J., & Jiang, Q. (2022). Tailings dam geotechnical stability improvement due to flocculants treated fine tailings dewatering. Geotechnical and Geological Engineering, 41(2), 759-772. https://doi.org/10.1007/s10706-022-02300-9
13. Chang, B., Du, C., Wang, Y., Chu, X., & Zhang, L. (2022). Modeling of permeability coefficient calculations based on the mesostructure parameters of tailings. ACS Omega, 7(7), 5625-5635. https://doi.org/10.1021/acsomega.1c03676
14. Yi, Y., Wei, S., & Shufen, L. (2011). Tailings dam stability analysis of the process of recovery. Procedia Engineering, (26), 1782-1787. https://doi.org/10.1016/j.proeng.2011.11.2367
15. IAEA. (2006). Radiological conditions in the Dnieper River basin: Assessment by an international expert team and recommendations for an action plan. Wien, Austria: International Atomic Energy Agency.
16. Korychenskyi, K.O., Lavrova, T.V., & Voitsekhovych, O.V. (2021). Ecological and economic aspects of phosphogypsum safety management at the former uranium production site “Pridniproivsky Chemical Plant”, (36), 96-110. https://doi.org/10.26565/1992-4224-2021-36-08
17. Bugai, D.O., Dzhepo, S.P., Skalskyy, O.S., Kubko, Y.I., & Saprykin, V.Y. (2018). Soilwater monitoring and mathemaical modeling of radioactive contamination of soilwater in Chernobyl exclusion zone and for the uranium facilities of the former Pridneprovsky chemical plant (Kamyanske). Geological Journal, (4), 47-57. https://doi.org/10.30836/igs.1025-6814.2018.4.148466
18. Rudakov, D., Pikarenia, D., Orlinska, O., Rudakov, L., & Hapich, H. (2023). A predictive assessment of the uranium ore tailings impact on surface water contamination: Case study of the city of Kamianske, Ukraine. Journal of Environmental Radioactivity, (268-269), 107246. https://doi.org/10.1016/j.jenvrad.2023.107246
19. Management of radioactive waste from the mining and milling of ores: Safety guide. (2002). Wien, Austria: International Atomic Energy Agency.
20. Kovalets, I.V., Asker, C., Khalchenkov, A.V., Persson, C., & Lavrova, T.V. (2017). Atmospheric dispersion of radon around uranium mill tailings of the former Pridneprovsky Chemical Plant in Ukraine. Journal of Environmental Radioactivity, (172), 173-190. https://doi.org/10.1016/j.jenvrad.2017.03.025
21. Hapich, H., Pikarenia, D., Orlinska, O., Kovalenko, V., Rudakov, L., Chushkina, I., Maksymova, N., Makarova, T., & Katsevych, V. (2022). Improving the system of technical diagnostics and environmentally safe operation of soil hydraulic structures on rivers. Eastern-European Journal of Enterprise Technologies, 2(10(116)), 18-29. https://doi.org/10.15587/1729-4061.2022.255167
22. Hapich, H., Orlinska, O., Pikarenia, D., Chushkina, I., Pavlychenko, A., & Roubík, H. (2023). Prospective methods for determining water losses from irrigation systems to ensure food and water security of Ukraine. Naukovyi Visnyk Natsionalnoho Hirnychoho Universytetu, (2), 154-160. https://doi.org/10.33271/nvngu/2023-2/154
23. DBN V.1.2-14-2018. (2018). General principles of ensuring the reliability and structural safety of buildings and structures. Kyiv, Ukraine: Ministry of Regions of Ukraine, 36 p.
24. DBN V.2.4-3:2010. (2010). Hydrotechnical structures. Basic provisions. Kyiv, Ukraine: Ministry of Regional Construction of Ukraine, 39 p.
25. Tymoshchuk, V., Tіshkov, V., & Soroka, Y. (2018). Hydro and geomechanіcal stabіlіty assessment of the Bund wall bottom slope of the Dnіprovsk taіlіng dump. Mіnіng of Mіneral Deposіts, 12(1), 39-47. https://doі.org/10.15407/mіnіng12.01.039
26. Hapich, H., Andrieiev, V., Kovalenko, V., Hrytsan, Y., & Pavlychenko, A. (2022). Study of fragmentation impact of riverbeds by artificial waters on the quality of water resources. Naukovyi Visnyk Natsionalnoho Hirnychoho Universytetu, (3), 185-189. https://doi.org/10.33271/nvngu/2022-3/185
27. Hapich, H., Andrieiev, V., Kovalenko, V., & Makarova, T. (2022). The analysis of spatial distribution of artificial reservoirs as anthropogenic fragmentation elements of rivers in the Dnipropetrovsk Region, Ukraine. Journal of Water and Land Development, 53(IV-VI), 80-85. https://doi.org/10.24425/jwld.2022.140783
28. Voitsekhovitch, O., Soroka, Y., & Lavrova, T. (2006). Uranium mining and ore processing in Ukraine – radioecological effects on the Dnipro River Water Ecosystem and human health. Radioactivity in the Environment, (8), 206-214. https://doi.org/10.1016/s1569-4860(05)08014-9