M.M. Aliev, A.A. Dyakonov, Z.F. Ismagilova, A.M. Gimranov
DOI: https://doi.org/10.25689/NP.2024.3.204-221
Abstract
The main purpose of reservoir pressure maintenance planning is not only additional production, but also the reduction of capital and operating costs. For example in PJSC TATNEFT, the specific electricity consumption for the production of one ton of crude oil is 49.3 kWh/t. Basically, electricity is spent on: artificial oil lift – 51 %; reservoir pressure maintenance system – 34 %; costs associated with the organization of production at the enterprise – 9 %; oil treatment – 6 %.
The key issue of the article is to create a tool that allows to optimize the system of pressure maintenance during reconstruction with minimal efforts. The text gives a valuable information on the use of fiberglass pipelines and volumetric pumping equipment. Petroleum Experts software is used to automate decision-making processes.
In the process of research created models of reservoir pressure maintenance systems, developed and implemented algorithms for selecting the diameter of pipelines and calculating capital and operating costs for various reconstruction option. Approbation of the developed methods and models was carried out at the PJSC TATNEFT objects.
References
2. V.A. Konnov, R.B. Fattakhov, A.A. Arsentev O napravleniyah razvitiya sistemy podderzhaniya plastovogo davleniya [On areas of reservoir pressure maintenance system development]. Almetyevsk State Oil Institute scientific papers. Almetyevsk, 2010, pp. 98-102. (in Russian)
3. A.G. Khalimov Primenenie stekloplastikovyh trub v kachestve truboprovodov v dobyvayushchih skvazhinah i skvazhinah sistemy PPD [Application of fiberglass pipes as pipelines for producing wells and reservoir pressure maintenance systems]. Inzhenernaya Praktika [Engineering Practice]. 2020, No.2. (in Russian)
4. A.V. Strekalov Model sistemy podderzhaniya plastovogo davleniya [A model of reservoir pressure maintenance system]. Tomsk Polytechnical University Review. 2011, Vol.318, No.1. (in Russian)
5. Sokolov D.V., Barakhtenko E.A. Optimization of transmission capacity of energy water pipeline networks with a tree-shaped configuration and multiple sources. Energy. 2020, Vol.210, Article 118469. (in English)
6. Alexandros Skretas, Sotirios Gyftakis, Effie Marcoulaki. A demonstration of sustainable pipeline routing optimization using detailed financial and environmental assessment. Journal of Cleaner Production. 2022, Vol. 362, Article 132305. (in English)
7. Mohamad Mohamadi, Baghmolaei Mohamad Mahmoudy, Dariush Jafari Rezvan, Mohamad iBaghmolaei, Firooz Tabkhi. Assessing and optimization of pipeline system performance using intelligent systems. Journal of Natural Gas Science and Engineering. 2014, Vol. 18, pp. 64-76. (in English)
8. Jun Zhou, Guangchuan Liang, Tao Deng, Jing Gong. Route Optimization of Pipeline in Gas-Liquid Two-Phase Flow Based on Genetic Algorithm. Hindawi. 2017, Article 1620303. (in English)
9. M.S. Korolev, S.S. Korolev Ocenka effektivnosti i optimizaciya sistem podderzhaniya plastovogo davleniya [Performance evaluation and optimization of reservoir pressure maintenance systems]. Territoriya Neftegaz [Oil and Gas Territory]. 2009, No.8, pp.74-78. (in Russian)
10. A.A. Galimyanova, A.S. Kardopoltsev, A.R. Garipov, A.A. Mironenko, A.A. Maksimov Kompleksnyj podhod k optimizacii sistemy podderzhaniya plastovogo davleniya achimovskih otlozhenij [Integrated approach to optimization of reservoir pressure maintenance system in the Achimovsky deposits]. Oborudovaniya i Tekhnologii Dlya Neftegazovogo Kompleksa [Equipment and Technologies for Oil and Gas Sector]. 2018, No. 8, pp. 56-62. (in Russian)
11. RD 153-39.0-751-12. Guidelines for selection and calculation of economically feasible package plan for optimization of energy consumption by Tatneft’s reservoir pressure maintenance system. Bugulma, TatNIPIneft Institute, 2011, 136 p. (in Russian)
12. СR 284.1325800.2016. Field pipelines for oil and gas: design and work rules. Moscow, Standartinform, 2017, 109 p. (in Russian)
13. Industry-specific building regulations “Field steel pipeline layout and planning” (VSN 51-3-85 Mingazprom, VSN 2.38-85 Minnefteprom), Moscow, 1985, 97 p. (in Russian)
Authors
M.M. Aliev, Doctor of Technical Sciences, Professor, Head of the Department "Transport and Storage of Oil and Gas", Almetyevsk State University of Technology – Higher Petroleum School
2, Lenin Str., Almetyevsk, 423462, Russian Federation
E-mail: mmaliev@rambler.ru
A.A. Dyakonov, Doctor of Technical Sciences, Professor, Rector of Almetyevsk State University of Technology – Higher Petroleum School
2, Lenin Str., Almetyevsk, 423462, Russian Federation
E-mail: dyakonovaa@agni-rt.ru
Z.F. Ismagilova, Candidate of Technical Sciences, Associate Professor of the Department of Transport and Storage of Oil and Gas, Almetyevsk State University of Technology – Higher Petroleum School
2, Lenin Str., Almetyevsk, 423462, Russian Federation
E-mail: ismagilovazf@agni-rt.ru
A.M. Gimranov, post-graduate student, Almetyevsk State University of Technology – Higher Petroleum School
2, Lenin Str., Almetyevsk, 423462, Russian Federation
E-mail: gimranovam@agni-rt.ru
For citation:
M.M. Aliev, A.A. Dyakonov, Z.F. Ismagilova, A.M. Gimranov Rekonstruktsiya sistemy podderzhaniya plastovogo davleniya (SPPD) s avtomatizatsiyey protsessov prinyatiya resheniy pri pomoshchi tsifrovoy modeli [Reconstruction of reservoir pressure maintenance system (RPMS) with automation of decision-making processes using a digital model]. Neftyanaya Provintsiya, No. 3(39), 2024. pp. 204-221. DOI https://doi.org/10.25689/NP.2024.3.204-221. EDN ZBFZAP (in Russian)