Characteristics of the state and directions of development of methodological support for the study of textural heterogeneous rocks according to well logging data

Heterogeneous rocks are among the most difficult objects to study reservoir properties. In order to study in detail the methods of research and model such reservoirs, a characteristic of the state was reduced and an analysis was carried out the methodological support for the study of textural heterogeneous rocks according to well logging data. In this article, both fundamental approaches to modeling textured heterogeneous rocks and concepts that haven't become widespread among specialists are considered. After analyzing the existing approaches to the study and modeling of textured heterogeneous rocks, based on geological classifications, in particular the works of L. N. Botvinkina, we have instilled in the type of work the classification of such rocks by heterogeneity. In addition, in most cases textural heterogeneity is considered as the form of true layering, objects at the moment are studying by layered rocks, rocks can haven't only oblique, wavy, complex texture, etc. Therefore, the classification approach to the study and modeling of objects, the allocation of such rocks to structure will allow exploring textural heterogeneous rocks.

1. Dakhnov, V. N. (1955). Interpretatsiya rezul'tatov geofizicheskikh issledovaniy skvazhin. Moscow, Gostoptekhizdat Publ., 492 p. (In Russian).

2. Dol, G. G. Potentials of the joint venture in clay sands. Proceedings of the Questions of field geophysics Conference. Moscow, 1957, pp. 308-329. (In Russian).

3. Vendelstein, B. Yu. (1966). Issledovanie razrezov neftyanykh i gazovykh skvazhin metodom sobstvennykh potentsialov. Moscow, Nedra Publ., 206 p. (In Russian).

4. Mamyashev, V. G., & Glazunov, I. G. (1988). Petrofizicheskoe obespechenie opredeleniya ob''emnogo ostatochnogo vodonasyshcheniya slozhno postroennykh kollektorov. Information leaflet about scientific and technical achievement. OTSNTI VIZMS; No 36-88. Tyumen, 4 p. (In Russian).

5. Klein, J. D., Martin, P. R., & Allen, D. F. (1995). The Petrophysics of Electrically Ani-sotropic Reservoirs. SPWLA 36th Annual Logging Symposium, June 26-29, 1995. (In English). Available at: https://onepetro.org/SPWLAALS/proceedings-abstract/SPWLA-1995/All-SPWLA-1995/SPWLA-1995-HH/19205

6. Kobranova, V. N. (1962). Fizicheskie svoystva gornykh porod: (petrofizika). Moscow, Gostoptekhizdat Publ., 490 p. (In Russian).

7. Vendelstein, B. Yu., & Rezvanov, R. A. (1978). Geofizicheskie metody opredeleniya parametrov neftegazovykh kollektorov: (pri podschete zapasov i proektirovanii razrabotki mestorozhdeniy). Moscow, Nedra Publ., 318 p. (In Russian).

8. Mamyashev, V. G. (2014). Petrofizicheskie modeli porod osadochnogo chekhla Zapadno-Sibirskoy ravniny. Proceedings of the Substantiation of parameters for calculating oil and gas reserves in deposits of Western Siberia conference. Tyumen, December, 4-5, 2014. Tyumen, Tyumen State Oil and Gas University Publ., pp. 125-145. (In Russian).

9. Kosterina, V. A., & Kulapova, M. V. (2010). Classification of terrigenous reservoir by clays distribution character. Russian Geophysics, (5), рр. 18-23. (In Russian).

10. Rezvanov, R. A. (2004). Some myths in logging. Russian Geophysics, Special Issue, pp. 60-64. (In Russian).

11. Dakhnov, V. N. m(1982). Interpretatsiya rezul'tatov geofizicheskikh issledovaniy razrezov skvazhin. 2nd edition, revised. Moscow, Nedra Publ., 448 p. (In Russian).

12. Izmaylov, K. K. (2018). Obobshchennaya model' sopostavleniya "poristost' - glinistost'" terrigennykh osadochnykh porod Zapadno-Sibirskoy neftegazonosnoy provintsii. Proceedings of the Innovations in geology, geophysics, geography conference, Sevastopol, July, 04-07, 2018. Moscow, Pero Publ., pp. 61-62. (In Russian).

13. Mamyashev, V. G. (2018). Metodologicheskie osnovy petrofizicheskikh issledovaniy razrezov, predstavlennykh porodami neodnorodnogo stroeniya. Proceedings of the International Scientific and Practical Conference "Modern technologies of oil and gas geophysics". Tyumen, May, 17-18, 2018. Tyumen, Tyumen State Oil and Gas University Publ., pp. 102-107. (In Russian).

14. Thomas, E. C., & Stieber, S. J. (1975). The Distribution of Shale in Sandstones and its effect upon Porosity.SPWLA 16th Annual Logging Symposium, New Orleans, Louisiana, June 1975. (In English). Available at: https://onepetro.org/SPWLAALS/proceedings-abstract/SPWLA-1975/All-SPWLA-1975/SPWLA-1975-T/20024

15. Botvinkina, L. N. (1965). Metodicheskoe rukovodstvo po izucheniyu sloistosti. Moscow, Nauka Publ., 265 p. (In Russian).

16. Basin, Ya. N., Novgorodov, V. A., Zlotnikov, M. G., Feldman, A. Ya., & Cherednichenko, A. A. (1983). Metody radioaktivnogo i elektricheskogo karotazha pri opredelenii podschetnykh parametrov v peschanoglinistykh polimiktovykh razrezakh. Moscow, VIEMS Publ., 48 p. (In Russian).

17. Efimov, V. A. (1984). Petrofizicheskie modeli slozhno-postroennykh glinistykh kollektorov dlya otsenki ikh neftegazonasyshcheniya po dannym elektrometrii skvazhin (na primere nizhnemelovykh otlozheniy Srednego Priob'ya). Avtoref. diss. … kand. geol.-mineral. nauk. Tyumen, 24 p. (In Russian).

18. Malshakov, A. V., Efimov, V. A., Romanova, E. A., & Guzeev, V. V. (2006). Percolation conceptions about the mechanism of formation of residual oil saturation of polymictic reservoirs at their flooding. Oil Industry, (4), pp. 70-74. (In Russian).

19. Akinshin, A. V. (2016). A method for determining the area of texture components on photos of core samples of textural inhomogeneous rocks. Oil Industry, (1), pp. 28-31. (In Russian).

20. Bryukhanova, E. V. (2018). Petrofizicheskie kriterii tipizatsii porod neodnorodnogo stroeniya. Innovatsii v geologii, geofizike, geografii. Proceedings of the Innovations in geology, geophysics, geography conference, Sevastopol, July, 04-07, 2018. Moscow, Pero Publ., pp. 30-32. (In Russian).