Submit an Article
Become a reviewer
RU
Vol 243
Pages:
305-312
Download volume:
RUS ENG
Article

Description of steady inflow of fluid to wells with different configurations and various partial drilling-in

Authors:
Valery A. Iktissanov
About authors
  • Ph.D., Dr.Sci. Professor Tatar Oil Research and Design Institute
Date submitted:
2020-06-15
Date accepted:
2020-06-15
Date published:
2020-06-30

Abstract

There are many equations of steady inflow of fluid to the wells depending on the type of well, presence or absence of artificial or natural fractures passing through the well, different degrees of drilling-in of the wellbores. For some complex cases, analytical solutions describing the inflow of fluid to the well have not yet been obtained. An alternative to many equations is the use of numerical methods, but this approach has a significant disadvantage – a considerable counting time. In this regard, it is important to develop a more general analytical approach to describe different types of wells with different formation drilling-in and presence or absence of fractures. Creation of this method is possible during modeling of fractures by a set of nodes-vertical wells passing from a roof to floor, and modeling of a wellbore (wellbores, perforation) by a set of nodes – spheres close to each other. As a result, based on this approach, a calculation algorithm was developed and widely tested, in which total inflow to the well consists of the flow rate of each node taking into account the interference between the nodes and considering the impermeable roof and floor of the formation. Performed modeling confirmed a number of known patterns for horizontal wells, perforation, partial drilling-in of a formation, and also allowed solving a number of problems.

Область исследования:
Oil and gas
Keywords:
spherical flow radial flow steady filtration wells fracture partial drilling-in perforation
10.31897/pmi.2020.3.305
Go to volume 243
Access statistics
Abstract Views
1787
Full-Text Views
355
Cited
Scopus:
14
Crossref:
7
Cited By
1. Enhancement of cleaning efficiency in slant wells using self-opening circulation sub. Gornyi Zhurnal. 2024, Vol. 2024, P. 18-23. DOI: 10.17580/gzh.2024.11.03 [Scopus]
2. Adaptation of transient well test results. Journal of Mining Institute. 25 December 2023, Vol. 264, P. 919-925. [Scopus] (cited: 4)
3. Justification of the optimal type of well completion profile based on a retrospective assessment of the technical and economic performance indicators. Georesursy. 30 March 2023, Vol. 25, P. 119-129. DOI: 10.18599/grs.2023.1.12 [Scopus] (cited: 2)
4. Increasing the efficiency of the development of hard-to-recovery oil and gas condensate field reserves by constructing multilateral horizontal wells. Socar Proceedings. 2023, P. 50-64. DOI: 10.5510/OGP20230400915 [Scopus]
5. Analytical and semi-analytical methods for modeling liquid inflow to a horizontal well (review). Georesursy. 2023, Vol. 25, P. 252-259. DOI: 10.18599/grs.2023.4.23 [Scopus]
6. Development of technological solutions for reliable killing of wells by temporarily blocking a productive formation under ALRP conditions (on the example of the Cenomanian gas deposits). Journal of Mining Institute. 30 December 2022, Vol. 258, P. 895-905. DOI: 10.31897/PMI.2022.99 [Scopus] (cited: 10)
7. Facilities Construction Engineering for the Avaldsnes Section of the Johan Sverdrup Field in the North Sea. Energies. June-2 2022, Vol. 15, DOI: 10.3390/en15124388 [Scopus] (cited: 9)
8. Review: Horizontal, directionally drilled and radial collector wells. Hydrogeology Journal. March 2022, Vol. 30, P. 329-357. DOI: 10.1007/s10040-021-02425-w [Scopus] (cited: 24)
9. Operational method for determining bottom hole pressure in mechanized oil producing wells, based on the application of multivariate regression analysis. Petroleum Research. December 2021, Vol. 6, P. 351-360. DOI: 10.1016/j.ptlrs.2021.05.010 [Scopus] (cited: 29)
10. Conditions for effective application of the decline curve analysis method. Energies. October-2 2021, Vol. 14, DOI: 10.3390/en14206461 [Scopus] (cited: 6)
11. Mechanism of deformation in rock mass surrounding intersection of mine shaft and salt bed. Gornyi Zhurnal. 2021, Vol. 2021, P. 21-26. DOI: 10.17580/gzh.2021.02.02 [Scopus] (cited: 7)
12. Estimation of the reliability of determination of filtering parameters of productive formations using multi-dimensional regression analysis. Socar Proceedings. 2021, P. 50-59. DOI: 10.5510/OGP2021SI100509 [Scopus] (cited: 4)
13. Study of Gas Wells Operation Regimes in Complicated Conditions. Perm Journal of Petroleum and Mining Engineering. 2021, Vol. 21, P. 36-41. DOI: 10.15593/2712-8008/2021.1.6 [Scopus] (cited: 5)
14. On negative values of skin factor. Neftyanoe Khozyaystvo Oil Industry. December 2020, Vol. 2020, P. 101-105. DOI: 10.24887/0028-2448-2020-12-101-105 [Scopus] (cited: 2)
Article Menu
Description of steady inflow of fluid to wells with different configurations and various partial drilling-in

Similar articles

Multi-terminal dc grid overall control with modular multilevel converters
2020 Miguel Jiménez Carrizosa, Nikola Stankovic, Jean-Claude Vannier, Yaroslav E. Shklyarskiy, Aleksei I. Bardanov
Mathematical model of the liquefied methane phase transition in the cryogenic tank of a vehicle
2020 Otari N. Didmanidze, Alexander S. Afanasev, Ramil T. Khakimov
Revisiting the evolution of deformation zones under platform conditions in the case study of the Kungur Ice Cave (Cis-Urals)
2020 Nataliya V. Lavrova
The age of mineralization of Mayskoe gold ore deposit (Central Chukotka): results of Re-Os isotopic dating
2020 Dmitry S. Artemiev, Robert Sh. Krymsky, Boris V. Belyatsky, Dmitry S. Ashikhmin
Study of the technogenesis of the Degtyarsky mine by audio-magnetotelluric express sounding
2020 Vadim A. Davydov
Deep structure and geodynamic conditions of granitoid magmatism in the Eastern Russia
2020 Viktor I. Alekseev