Submit an Article
Become a reviewer
RU
Vol 228
Pages:
705-716
Download volume:
RUS ENG
Article

Features of mathematical modeling of natural gas production and transport systems in the Russia’s arctic zone

Authors:
E. A. Bondarev1
I. I. Rozhin2
K. K. Argunova3
About authors
  • 1 — Ph.D., Dr.Sci. Chief Researcher Institute of Oil and Gas Problems, Siberian Division RAS
  • 2 — Ph.D., Dr.Sci. Leading Researcher Institute of Oil and Gas Problems, Siberian Division RAS
  • 3 — Ph.D. Senior Researcher Institute of Oil and Gas Problems, Siberian Division RAS
Date submitted:
2017-07-24
Date accepted:
2017-09-19
Date published:
2017-12-22

Abstract

The necessity of accounting for real gas properties, thermal interaction with permafrost rocks and the possibility of formation (dissociation) of gas hydrates in these objects for adequate description of the operation of gas wells and main gas pipelines in the regions of the Far North by appropriate mathematical models is shown. Mathematical models that take into account the non-isothermal gas flow within the framework of pipe hydraulics, the change of the area of tube cross-section due to the formation of hydrates and the dependence of the heat transfer coefficient between gas and hydrate layer on the varying flow area over time are proposed. The corresponding conjugate problem of heat exchange between the imperfect gas in the well and the environment (rocks) is reduced to solving differential equations describing the non-isothermal flow of gas in the pipes and the heat transfer equations in rocks with the corresponding conjugation conditions. In the quasi-stationary mathematical model of hydrate formation (dissociation), the dependence of the gas-hydrate transition temperature on the pressure of gas is taken into account. Established that the formation of hydrates in wells, even at low reservoir temperatures and a thick layer of permafrost, takes a fairly long period of time, which allows to quickly prevent the creation of emergency situations in gas supply systems. Some decisions taken in the design of the first section of the main gas pipeline «Power of Siberia» have been analyzed by methods of mathematical modeling. In particular, it is shown that if the gas is not dried sufficiently, the outlet pressure may drop below the allowable limit in about 6-7 hours. At the same time, for completely dry gas, it is possible to reduce the cost of thermal insulation of the pipeline at least two fold.

Область исследования:
Oil and gas
Keywords:
natural gases hydrates permafrost rocks conjugate heat exchange problem gas well gas pipeline heat insulation computer experiment
10.25515/pmi.2017.6.705
Go to volume 228

References

  1. Argunova K.K., Bondarev E.A., Rozhin I.I. Mathematical models of hydrate formation in gas wells. Kriosfera Zemli. 2011. Vol.15. N2, p.65-69 (in Russian).
  2. Argunova K.K., Bondarev E.A., Rozhin I.I. Properties of real gas and their analytical representation. Gazokhimiya. 2010. N6 (16), p.52-54 (in Russian).
  3. Argunova K.K. Numerical study of nonlinear effects in models of natural gas production. The author ... Candidate of Physics and Mathematics. Yakutskii gosudarstvennyi universitet im. M.K.Ammosova. Yakutsk, 2005, p.18 (in Russian).
  4. Bondarev E.A., Argunova K.K. Mathematical models of hydrate formation in gas wells. Informatsionnye i matematicheskie tekhnologii v nauke i upravlenii: Trudy XIV Baikal'skoi vserossiiskoi konferentsii. Irkutsk: ISEM SO RAN, 2009. Iss.3, p.41-51 (in Russian).
  5. Budak B.M., Solov'eva E.N., Uspenskii A.B. A difference method with smoothing of the coefficients for the solution of the Stefan problem. Zhurnal vychisl. matematiki i mat. fiziki. 1965. Vol.5. N5, p.828-840 (in Russian).
  6. Vukalovich M.P., Novikov I.I. Equation of state of real gas. Мoscow– Leningrad: Gosenergoizdat, 1948, p.340 (in Russian).
  7. Latonov V.V., Gurevich G.R. Calculation of the compressibility of natural gases. Gazovaya promyshlennost'. 1969. N2, p.7-9 (in Russian).
  8. Argunova K.K., Bondarev E.A., Nikolaev V.E., Rozhin I.I. Determination of the interval of hydrate formation in wells drilled in permafrost rocks. Elektronnyi nauchnyi zhurnal «Neftegazovoe delo». 2008. URL: www.ogbus.ru/authors/Argunova/ Argunova_2.pdf, p.11 (in Russian). (data obrashcheniya 2.10.2017).
  9. Perepelichenko V.F. Prospects for developing a unique oil and gas condensate field of Yakutia. Elektronnyi nauchnyi zhurnal «Georesursy. Geoenergetika. Geopolitika». 2012. Iss.1(5). URL: oilgasjournal.ru/vol_5/perepelich.pdf, p.8 (in Russian). (data obrashcheniya 4.09.2017).
  10. Samarskii A.A., Moiseenko B.D. Economical scheme of end-to-end calculations for multidimensional Stefan problems. Zhurnal vychisl. matematiki i mat. fiziki. 1965. Vol.5. N5, p.816-827 (in Russian).
  11. Isaev S.I., Kozhinov I.A., Kofanov V.I., Leont'ev A.I., Mironov B.M., Nikitin V.M., Petrazhitskii G.B., Samoilov M.S., Khvostov V.I., Shishov E.V. Theory of heat and mass transfer. Мoscow: Vysshaya shkola, 1979, p.495 (in Russian).
  12. Bondarev E.A., Vasil'ev V.I., Voevodin A.F., Pavlov N.N., Shadrina A.P. Thermohydrodynamics of gas production and transport systems. Novosibirsk: Nauka. Sibirskoe otdelenie, 1988, p.272 (in Russian).
  13. Tikhonov A.N., Samarskii A.A. Equations of mathematical physics. Мoscow: Nauka, 1977, p.736 (in Russian)
  14. Bondarev E.A. Modeling the formation of hydrates in gas wells in their thermal interaction with rocks / E.A.Bondarev, I.I.Rozhin, K.K.Argunova // Journal of Engineering Physics and Thermophysics. 2014. Vol. 87. N 4. Р. 900-907. DOI: 10.1007/s10891-014-1087-0.
  15. Kay W.B. Density of hydrocarbon gases and vapors at high temperature and pressures // Industrial & Engineering Chemistry Research. 1936. Vol. 28. P. 1014-1019.
  16. Sloan E.D. Clathrate hydrates of natural gases / E.D.Sloan, C.A.Koh. Boca Raton: Taylor & Francis Group/CRC Press, 2008. 720 p.
Access statistics
Abstract Views
1745
Full-Text Views
364
Cited
Scopus:
18
Crossref:
0
Cited By
1. Algorithm for determining the gas flow rate by the half-division method for pressure measurements in hydrate formation in a well. E3s Web of Conferences. 20 November 2024, Vol. 592, DOI: 10.1051/e3sconf/202459204007 [Scopus]
2. Mass flow rate determination under reservoir conditions changing in the problem of gas extraction with hydrate plug formation. E3s Web of Conferences. 20 November 2024, Vol. 592, DOI: 10.1051/e3sconf/202459205017 [Scopus]
3. SIMULATION OF HYDRATE PLUG FORMATION DURING JOINT OPERATION OF A GAS-BEARING RESERVOIR AND A WELL UNDER THE EQUILIBRIUM CONDITIONS OF HYDRATE FORMATION DEPENDING ON STRATUM WATER COMPOSITION. Journal of Applied Mechanics and Technical Physics. April 2023, Vol. 64, P. 284-296. DOI: 10.1134/S002189442302013X [Scopus] (cited: 2)
4. Dynamics investigation of the natural gas specific humidity in the bottomhole zone and the hole of gas wells. Aip Conference Proceedings. 6 September 2022, Vol. 2528, DOI: 10.1063/5.0106588 [Scopus] (cited: 1)
5. Modeling of natural gas hydrates formation during joint operation of a reservoir and a gas well. Aip Conference Proceedings. 6 September 2022, Vol. 2528, DOI: 10.1063/5.0106587 [Scopus] (cited: 1)
6. Optimization of Integrated Systems for Natural Gas Production, Conversion, and Transportation. Process Integration and Optimization for Sustainability. September 2022, Vol. 6, P. 621-631. DOI: 10.1007/s41660-022-00233-7 [Scopus]
7. Investigation of the flow rate influence on the hydrate formation in the bottom-hole zone, bore and well pipelines. Aip Conference Proceedings. 5 March 2021, Vol. 2328, DOI: 10.1063/5.0044586 [Scopus] (cited: 1)
8. Electrotechnical complex for autonomous power supply of oil leakage detection systems and stop valves drive control systems for pipelines in arctic region. Journal of Physics Conference Series. 8 February 2021, Vol. 1753, DOI: 10.1088/1742-6596/1753/1/012062 [Scopus] (cited: 7)
9. Method for determining the mass flow for pressure measurements of gas hydrates formation in the well. Journal of Siberian Federal University Mathematics and Physics. 2021, Vol. 14, P. 193-203. DOI: 10.17516/1997-1397-2021-14-2-193-203 [Scopus] (cited: 4)
10. Stress-stain state of a vertical steel tank affected by bottom sediments in conditions of extreme temperature differences. Advances in Raw Material Industries for Sustainable Development Goals. 2021, P. 314-321. [Scopus] (cited: 3)
11. Information Support for the Process of Multiphase Flows Transportation Based on the Introduction of a Radioisotope Non-Separation Hydrocarbon Measuring System. Proceedings of the 2020 IEEE Conference of Russian Young Researchers in Electrical and Electronic Engineering Eiconrus 2020. January 2020, P. 674-679. DOI: 10.1109/EIConRus49466.2020.9039314 [Scopus] (cited: 6)
12. Problem of conjugate heat transfer between main gas pipeline and frozen ground. E3s Web of Conferences. 14 June 2019, Vol. 102, DOI: 10.1051/e3sconf/201910201001 [Scopus] (cited: 2)
13. Generalization of the algorithm of determining mass flow rate by measuring pressure in gas transportation systems. E3s Web of Conferences. 14 June 2019, Vol. 102, DOI: 10.1051/e3sconf/201910201002 [Scopus]
14. Generalized Mathematical Model of Hydrate Formation in Gas Pipelines. Journal of Applied Mechanics and Technical Physics. 1 May 2019, Vol. 60, P. 503-509. DOI: 10.1134/S002189441903012X [Scopus] (cited: 3)
15. Management and modeling technologies of sustainable development of Russian regions. International Journal of Recent Technology and Engineering. May 2019, Vol. 8, P. 2703-2707. [Scopus] (cited: 1)
16. Alternative to mathematical models of gas production: Numerical experiment. Iop Conference Series Earth and Environmental Science. 30 October 2018, Vol. 193, DOI: 10.1088/1755-1315/193/1/012007 [Scopus]
17. Moisture content of natural gas in bottom hole zone. Journal of Mining Institute. 2018, Vol. 233, P. 492-497. DOI: 10.31897/pmi.2018.5.492 [Scopus] (cited: 10)
18. Justification of economic benefits of arctic lng transportation by sea. Journal of Mining Institute. 2018, Vol. 233, P. 554-560. DOI: 10.31897/pmi.2018.5.554 [Scopus] (cited: 17)
Article Menu
Features of mathematical modeling of natural gas production and transport systems in the Russia’s arctic zone

Similar articles

About rock pressure loads on tunnel linings constructed using trenchless method
2017 K. P. Bezrodnyi, M. O. Lebedev
Pedagogical experiment of the first rector of the Ural state mining institute P.P. Von Weymarn as an effort to reform the higher education institution in 1917-1920
2017 N. G. Valiev, A. G. Shorin
Sustainable development of crude ore resources and benefication facilities of JSC «Apatit» based on best engineering solutions
2017 A. A. Gurev
Research of mining and geological conditions for geological exploration in Pre-Caucasian region
2017 R. A. Gasumov, V. A. Gridin, V. G. Kopchenkov, B. F. Galai, S. A. Dudaev
Modern methods of analytical control of industrial gases
2017 O. V. Cheremisina, S. Z. El-Salim
Assessment of widespread air pollution in the megacity using geographic information systems
2017 M. A. Pashkevich, T. A. Petrova