A comprehensive evaluation of the productive formation collector of the Kanevskoye field

At the present stage, the development of the oil and gas industry of the Russian Federation is impossible without replenishing the resource base, and therefore an urgent task is to conduct research, prospecting and evaluating petroleum potential in undiscovered areas of fields. The aim of the study is to conduct a comprehensive assessment of the reservoir of the productive formation of the Kanevskoye field. We have carried out mineralogical and petrographic studies, laboratory studies to assess the effective porosity of the core sample by the saturation method, particle size analysis, X-ray diffraction analysis. Our studies have shown that the considered initial sands under consideration, which formed the reservoir rocks of the productive horizon of the Kanevskoye field, were formed by coastal or beach type marine sediments. This is confirmed by the poorly rounded shape of the grains and the presence of glauconite in the rocks. The studied core sample is a fine-grained glauconite-feldspar-quartz sandstone with an admixture of aleurite fraction, with semi-rounded grains, pelitic cement, basal and porous-basal, silt-psammitic structure. The total porosity is 14.3 %. A comprehensive assessment of the reservoir of the productive formation of the Kanevskoye field has been carried out. The reservoir is productive. Therefore, it is necessary to make a project for conducting geological exploration.

1. Martynov, V. N. (2004). Formirovanie neftyanoy i gazovoy - krizis pereproizvodstva. Neft' Rossii, (8), pp. 20-24. (In Russian).

2. Shpurov, I. V., Pisarnitskiy, A. D., Purtova, I. P., & Varichenko, A. I. (2012). Trudnoizvlekaemye zapasy nefti Rossiyskoy Federatsii. Struktura, sostoyanie, perspektivy osvoeniya. Tyumen, ZapSibNIIGG Publ., 254 p. (In Russian).

3. Kostenevich, K. A., Belous, O. I., & Slyunkina, S. A. (2017). Vliyanie usloviy formirovaniya i postsedimentatsionnykh protsessov preobrazovaniya otlozheniy na strukturu pustotnogo prostranstva i fil'tratsionno-emkostnye svoystva porod-kollektorov produktivnogo gorizonta tyumenskoy svity Krasnoleninskogo svoda. Sovremennye problemy sedimentologii v neftegazovom inzhiniringe: trudy III Vserossiyskogo nauchno-prakticheskogo sedimentologicheskogo soveshchaniya, April, 10-12, 2017. Tomsk, TSPPS ND Publ., pp. 84-90. (In Russian).

4. Bronskova, E. I. (2016). Comprehensive analysis of April field geological structure to provide effective additional exploration and development of Tyumen suite deposits. Geology, Geophysics and Development of Oil and Gas Fields, (8), pp. 36-44. (In Russian).

5. Klubkov, S. V. (2015). Stimulirovanie razrabotki TRIZ pomozhet podderzhat' uroven' dobychi nefti v Rossii. Oil & Gas Journal Russia, (6), pp. 6-11. (In Russian).

6. Khuzin, R. R. (2012). Geotekhnologicheskie osnovy osvoeniya trudnoizvlekaemykh zapasov melkikh slozhnopostroennykh mestorozhdeniy nefti. Samara, Neft'. Gaz. Novatsii Publ., 384 p. (In Russian).

7. Medvedev, N. Ya. (1997). Geotekhnologicheskie osnovy razrabotki zalezhey s trudnoizvlekaemymi zapasami nefti, Moscow, VNIIOENG Publ., 336 p. (In Russian).

8. Ghorbani, Y., Franzidis, J.-P., & Petersen, J. (2016). Heap Leaching Technology - Current State, Innovations, and Future Directions: A review. Mineral Processing and Extractive Metallurgy Review, 37(2), pp. 73-119. (In English). DOI: 10.1080/08827508.2015.1115990

9. Kovalenko, I. V., & Sokhoshko, S. K. (2018). Modeling of the oil rims development of multi-zone oil rim reservoir. Oil and Gas Studies, (3), pp. 50-54. (In Russian). DOI: 10.31660/0445-0108-2018-3-50-54

10. Podnebesnykh, A. V. (2017). Perspectives of developing bitumen seeps of the Baikal rift valley. Oil and Gas Studies, (1), pp. 38-42. (In Russian). DOI: 10.31660/0445-0108-2017-1-38-42

11. Bulay, A. G., & Kruchinin, S. V. (2013). Neftyanaya promyshlennost' Rossii. Molodezhnyy nauchnyy forum: tekhnicheskie i matematicheskie nauki: elektronnyy sbornik statey po materialam V studencheskoy mezhdunarodnoy zaochnoy nauchno-prakticheskoy konferentsii. Moscow, MTSNO Publ., (5(5)), pp. 47-52. (In Russian). Available at: https://nauchforum.ru/studconf/tech/v/1524

12. De Oliveira, D. M., Sobral, L. G. S., Olson, G. J., & Olson, S. B. (2014). Acid leaching ofa copper ore by sulphur-oxidizing microorganisms. Hydrometallurgy, 147-148, pp. 223-227. (In English). DOI: 10.1016/j.hydromet.2014.05.019

13. Sinclair, L., & Thompson, J. (2015). In situ leaching of copper: Challenges and future prospects. Hydrometallurgy, 157, pp. 306-324. (In English). DOI: 10.1016/j.hydromet.2015.08.022

14. Niemann-Delius, Ch., Stoll, R. D., Drebenstedt, C., & Müllensiefen, K. (2009). Der Braunkohlentagebau: Bedeutung, Planung, Betrieb, Technik, Umwelt. Springer-Verlag, Berlin, Heidelberg, 605 p. (In German). DOI: 10.1007/978-3-540-78401-2

15. Panikarovskii, E. V., Panikarovskii, V. V., & Anashkina, A. E. (2019). Vankor oil field development experience. Oil and Gas Studies, (1), рр. 47-51. (In Russian). DOI: 10.31660/0445-0108-2019-1-47-51

16. Bembel, R. M., Sukhov, V. A., & Schetinin, I. A. (2017). Ways of increasing geological efficiency of hydrocarbon fields development in Western Siberia. Oil and Gas Studies, (6), pp. 6-10. (In Russian). DOI: 10.31660/0445-0108-2017-6-6-10

17. Yegorova, E. V., Klyuev, R.V., Bosikov, I. I., & Tsidaev, B. S. (2018). Evaluation of use of effective technologies for increasing sustainable development of natural and technical system of oil and gas complex. Sustainable development of mountain territories, 10(3(37)), pp. 392-403. (In Russian). DOI: 10.21177/1998-4502-2018-10-3-392-403

18. Bosikov, I. I., Klyuev, R. V., & Kelekhsaev, V. B. (2017). Method for determining of the ventilation object transfer function according to normal operation (by the example of mining and processing complex). 2017 International Conference on Industrial Engineering, Applications and Manufacturing (ICIEAM) (May, 16-19, 2017). (In English). Available at: https://doi.org/10.1109/icieam.2017.8076113

19. Khozhiev, K. K., & Bosikov, I. I. (2017). Integrated exploitability index for mineral deposits. Gornyi Zhurnal, (2), pp. 30-32. (In Russian). DOI: 10.17580/gzh.2017.02.05