SOCAR Proceedings

SOCAR Proceedings

Published by "OilGasScientificResearchProject" Institute of State Oil Company of Azerbaijan Republic (SOCAR).

SOCAR Proceedings is published from 1930 and is intended for oil and gas industry specialists, post-graduate (students) and scientific workers. 

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On-line ISSN: 2218-8622
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Socar Proceedings
Issue 1, 2022

G. S. Martynova, D. А. Huseynov, O. P. Maksakova, R. G. Nanajanova

The Institute of Geology and Geophysics, ANAS, Baku, Azerbaijan

Applied aspects of geochemical parameters of oil


The given paper provides data on the fingerprints of Azerbaijani oils using biomarkers (GC/MS) and microelement composition (ICP/MS), as well as the main geochemical parameters of oil, such as CPI, Ki, QI, ITC, Ts/Tm, Pr/Ph, etc., and data on correlation dependencies of geochemical parameters on the horizon at particular oilfield. Characterization of oil accumulations belonging to the mid-Pliocene in the Caspian Sea in terms of hydrocarbons - biomarkers and geochemical parameters makes it possible to predict the composition and the predominant type of oil in the field with similar geological structure.

Keywords: oil biomarkers; chromatographymass spectrometry; mass spectrometry with inductively coupled plasma; oil fingerprint.

References

  1. Wang, Z. D., Fingas, M., Page, D. S. (1999). Oil spill identification. Journal of Chromatography A, 843, 369-411.
  2. Nordtest. (1991). Nordtest method, NT Chem 001, Ed. 2. Finland: Nordtest, Espoo.
  3. Semenov, V. V., Begak, O. J., Ivakhnjuk, G. К. (2009). Identification method of sources of oil pollution. RU Patent 2365900.
  4. Guliev, I.S., Babaev, F. R., Martynova, G. S. (2014). Oils fingerprint in Azerbaijan. Geology, Geophysics and Development of Oil and Gas Fields, 6, 54-60.
  5. Babayev, F. R., Punanova, S. A. (2014). Geochemical aspects of trace element composition of oils. Moscow: Nedra.
  6. Ehjde, I., Sulsen, K. (2008). Fingerprinting of complex mixtures, containing hydrocarbons. RU Patent 2341792.
  7. Ashe, T. R., Kelly, J. D., Lau, T. C., Pho, R. T.-K. (1997). Method for predicting chemical or physical properties of complex mixtures. US Patent 5602755A.
  8. Babaev, F. R., Punanova, S. A., Martynova, G. S. (2014). Typification of oils of South-Caspian region on the basis of microelement content. Oilfield Engineering, 7, 38-42.
  9. Martynova, G. S., Maksakova, O. P., Nanajanova, R. G., et al. (2016). Geochemical differentiation of oil in Guneshli field. East European Scientific Journal, 9, 120-127.


DOI: 10.5510/OGP20220100623

E-mail: martgs@rambler.ru

R. A. Umurzakov1, T. Kh. Shoymuratov2, A. S. Ibragimov3, H.F. Khudoiberdiyev2

1Tashkent state technical University Named after Islam Karimov, Tashkent, Uzbekistan; 2JSC «IGIRNIGM», Tashkent, Uzbekistan; 3SE «Hydroingeo», Tashkent, Uzbekistan

Geodynamic prerequisites and reflection of signs of fluid migration in hydrogeochemical indicators of formation water in the Bukhara-Khiva region


The article describes the results of a study of changes in the composition and hydrogeochemical parameters of individual areas and fields of the Bukhara-Khiva region based on well materials. Vertical zonality of hydrogeochemical parameters associated with deep fluid flow and heat and mass transfer is noted. The manifestation of tectonodynamic conditions in the Mesozoic-Cenozoic history of the region, which served as a prerequisite for the formation of weakened zones (channels of deep heat and mass transfer) in the field of tensile stresses for the vertical migration of fluids and juvenile gases, is noted. A hydrogeological criterion for identifying zones of deep heat and mass transfer and vertical fluid migration is proposed.

Keywords: wells; oil and gas; formation waters; fluids; hydrogeochemical indicators of formation waters; heat and mass transfer.

References

  1. Degazaciya zemli: geodinamika, geoflyuidy, neft', gaz i ih paragenezy /otv. red. Dmitrievskij, A. N., Valyaev, B. M. (2008). Materialy Vserossijskoj konferencii. Moskva: GEOS.
  2. Syvorotkin, V. L. (2002). Glubinnaya degazaciya Zemli i global'nye katastrofy. Moskva: OOO «Geoinformcentr».
  3. Ritman, A. (1964). Volcanoes and their activities. Moscow: Mir.
  4. Larin, N. V. (2005). Our land. Moscow: Agar.
  5. Pavlenkova, N. I., Pavlenkova, G. A. (2014). Stroenie zemnoj kory i verhnej mantii Severnoj Evrazii po dannym sejsmicheskogo profilirovaniya s yadernymi vzryvami. Moskva: GEOS.
  6. Abidov, A. A. (2010). The genesis of oil and gas and the methodology of searches of it’s deposits. Tashkent: «Fan» AS RUz.
  7. Umurzakov, R. A. (2016). Processy glubinnoj degazacii Zemli i aktual'nost' novyh teoreticheskih koncepcij v neftegazovoj geologii. Vestnik TashGTU, 3, 190-194.
  8. Abidov, A. A., Umurzakov, R. A., Abidov, X. A., i dr. (2017). Netraditsionnie metodi poiskov zalejey uglevodorodov v svete mikstgeneticheskoy kontseptsiи proisxojdeniya nefti i gaza. Tashkent: Fan va texnologiya.
  9. Yuldashev, G. Yu. (2018). Integration of geoelectric and thermo-geochemical surveys in the search for oil and gas prospects in the Bukhara-Khiva region. SOCAR Proceedings, 1, 21-27.
  10. Umurzakov, R. A. (2016, oktyabr'). O sostoyanii problemy izucheniya i metodike rekonstrukcii paleotektonicheskih napryazhenij zemnoj kory otdel'nyh etapov geologicheskoj istorii. Materialy vserossijskoj konferencii s mezhdunarodnym uchastiem «Tektonofizika i aktual'nye voprosy nauk o Zemle». T.2. Moskva: IFZ.
  11. Berzin, A. G., Rudykh, I. V., Berzin, S. A. (2006). Features of multilayered reservoirs formation of hydrocarbon fields of Nepsko-Botuoba anteclise. Oil and Gas Geology, 5, 14-21.
  12. Lavrov, I. V., Papukhin, S. P., Manasyan, A. E., et al. (2017). Detection of disjunctive dislocations by a complex of geological and geophysical methods in order to search for oil and gas traps. Oil and Gas Territory, 10, 38–45.
  13. (1978). Geological dictionary. Vol. 1. Moscow: Nedra.
  14. Kugaenko, Yu., Saltykov, V., Sinitsyn, V., Chebrov, V. (2005, April). Passive seismic monitoring in hydrothermal field: seismic emission tomography. In: Proceedings World Geothermal Congress. Antalya, Turkey.
  15. Shojmuratov, T. H. (2018). Gidrogeologicheskie kriterii neftegazonosnosti mezozojskoj vodonapornoj sistemy Buharo-Hivinskogo regiona. Aftoreferat dissertacii na soiskanie uchenoj stepeni doktora geologo-mineralogicheskih nauk. Tashkent: IGIRNIGM.
  16. Shojmuratov, T. H., Mumindzhanov, T. I., Sadykov, YU. M., Hudajberdiev, H. F. (2016, oktyabr'). Zony glubinnoj flyuidomigracii i ih gidrogeohimicheskie osobennosti. Materialy mezhdunarodnoj konferencii «Aktual'nye problemy sovremennoj sejsmologii». Tashkent.
  17. Kireeva, T. A. (2009). K metodike ocenki endogennoj sostavlyayushchej glubokih podzemnyh vod. Vestnik MGU, Seriya «Geologiya», 1, 54-57.


DOI: 10.5510/OGP20220100624

E-mail: raxim.umurzakov@tdtu.uz; umruzok54@gmail.com

Ad.A. Aliyev1, O.R. Abbasov1, A.M. Aghayev2, A.I. Khuduzade3, E.H. Hasanov4

1Geology and Geophysics Institute, ANAS, Baku, Azerbaijan; 2Azerbaijan State Oil and Industrial University, Baku, Azerbaijan; 3«Azneft» PU, SOCAR, Baku, Azerbaijan; 4Department of Geophysics and Geology, SOCAR, Baku, Azerbaijan

Mineralogy, geochemistry and paleoweathering characteristics of Paleogene-Miocene oil shales in Azerbaijan


The Paleogene-Miocene oil shales studied in the paper were taken from the outcrops and ejecta of mud volcanoes in Shamakhi-Gobustan and Absheron regions. The geological age, mineralogy, and chemical composition of the samples were studied by analytical investigations. Minerals found oil shales were described in detail in the relevant categories. Some appropriate classifications were made in connection with the chemical composition of samples. The indices such as CIA, CIW, PIA, "RR = SiO2/Al2O3" - chemical weathering index, the diagrams like "(Al2O - K2O) – CaO – Na2O", "A-CN-K", and also reflecting mobility characteristics of elements, and estimates on large-ion lithophile elements were used to study the paleoweathering characteristics.

Keywords: oil shale; geochemistry; mineral; paleoweathering.

References

  1. Aliyev, Ad. A., Belov, I. S., Ibadzade, A. J. (2002). Oil shales in Azerbaijan (geology, geochemistry and prospects of their use). Proceedings of IG ANAS, 30, 5-24.
  2. Aliyev, Ad. A., Bayramov, A. A., Abbasov, O. R., Mammadova, A. N. (2014). Reserves of oil shale and natural bitumen. National Atlas of the Republic of Azerbaijan, Map (Scale 1:1000000). Baku: State Land and Cartography Committee (Azerbaijan).
  3. Aliyev, Ad. A., Abbasov, O. R., Ibadzade, A. J., Mammadova, A. N. (2018). Genesis and organic geochemical characteristics of oil shale in Eastern Azerbaijan. SOCAR Proceedings, 3, 4-15.
  4. Aliyev, Ad. A., Aliyev, Ch. S., Feyzullayev, A. A., et al. (2015). Geology of Azerbaijan. Vol. II. Baku: PH «Elm».
  5. Abbasov, O. R. (2009). Distribution regularities of shales of Paleogene-Miocene sediments in Gobustan. PhD Thesis. Baku: Institute of Geology and Geophysics, ANAS.
  6. Aliyev, Ad. A., Abbasov, O. R., Ibadzade, A. J., Mammadova, A. N. (2015). Prospects of using of Azerbaijan oil shale.Proceedings of the ANAS, 2(1), 43-47.
  7. Guliyev, I. S., Kerimov, V. Yu., Mustaev, R. N., Bondarev, A. V. (2018). The estimation of the generation potential of the low permeable shale strata. SOCAR Proceedings, 1, 4-20.
  8. Guliyev, I. S., Kerimov, V. Yu., Osipov, A. V., Mustaev, R. N. (2017). Generation and accumulation of hydrocarbons at great depths under the Earth's Crust. SOCAR Proceedings, 1, 4-16.
  9. Salmanov, A. M., Maharramov, B. I., Huseynov, R. M., Xalilov, E. F. (2016). Tectonic features of Miocene sediments of South-West Apsheron in accordance with the new data. SOCAR Proceedings, 1, 4-12.
  10. Huseynov, B. B., Salmanov, A. M., Maharramov, B. I. (2017). Prospect estimation of the shale HC Maykop deposits river interfluves of Kura and Gabirri. SOCAR Proceedings, 4, 4-15.
  11. Aliyev, A., Abbasov, O., Agayev, A. (2019). Mineralogy and geochemistry of oil shale in Azerbaijan: classification, palaeoweathering and maturity features. Visnyk of V. N. Karazin Kharkiv National University, Series «Geology. Geography. Ecology», 50, 11-26.
  12. Aliyev, A.A., Abbasov, O.R. (2020). Distribution patterns, organic geochemistry and mineralogy of oil shales in Azerbaijan. Gornyi Zhurnal. 8, 13-18.
  13. Aslanov, B. S., Magerramov, B. I., Huduzade, A. I. (2016). To the assessment hydrocarbon potential zone buried uplifts «Saatli-Goychay-Mugan». SOCAR Proceedings, 2, 4-10.
  14. Abbasov, O. (2015). Oil shale of Azerbaijan: geology, geochemistry and probable reserves. International Journal of Research Studies in Science, Engineering and Technology, 2(9), 31-37.
  15. Aliyev, A., Abbasov, O. (2018, February). Organic geochemical characteristics of oil shale in Azerbaijan. In: The 36th National and the 3rd International Geosciences Congress. Tehran, Iran.
  16. Aliyev, Ad. A., Belov, I. S., Aliyev, G-M.A. (2000). Oil shales of Miocene in Azerbaijan. Azerbaijan Oil Industry, 5, 7-11.
  17. Aliyev, Ad. A., Belov, I. S., Bayramov, T. А. (2003). Oil shale of Paleogene-Miocene in Azerbaijan. Geologist of Azerbaijan. Scientific Bulletin, 8, 68-80.
  18. Abbasov, O. R. (2017). Distribution regularities and geochemistry of oil shales in Azerbaijan. Mineral Resources of Ukraine, 2, 22-30.
  19. Aliyev, Ad. A., Bayramov, A. A. (2000). Regularity of the spatio-temporal distribution of mud volcanoes of the South Caspian depression in the light of a new tectonic concept. Proceedings of IG ANAS, 35, 25-24.
  20. Odonne, F., Imbert, P. Dupuis, M., et al. (2020). Mud volcano growth by radial expansion: Examples from onshore Azerbaijan. Marine and Petroleum Geology, 112, 104051.
  21. Odonne, F., Imbert, Dominique Remy, et al. (2022). Surface structure, activity and microgravimetry modeling delineate contrasted mud chamber types below flat and conical mud volcanoes from Azerbaijan. Marine and Petroleum Geology, 134, 105315.
  22. Baloglanov, E.E., Abbasov, O.R., Akhundov, R.V. (2018). Mud volcanoes of the world: Classifications, activities and environmental hazard (informational-analytical review). European Journal of Natural History, 2018, 5, 12-26.
  23. Baldermann Andre, Abbasov Orhan, Bayramova Aygun, et al. (2020). New insights into fluid-rock interaction mechanisms at mud volcanoes: Implications for fluid origin and mud provenance at Bahar and Zenbil (Azerbaijan). Chemical Geology, 537, 119479.
  24. Aliyev, Ad. A., Guliyev, I. S., Dadashev, F. G., Rahmanov, R. R. (2015). Atlas of mud volcanoes in the world. Baku: PH «Nafta-Press», «Sandro Teti Editore».
  25. Abbasov, O. R., Mamedova, A. N., Huseynov, A. R., Baloglanov, E. E. (2013). Some new data of geochemical researches of combustible slates of Azerbaijan. Geology, Geophysics and Development of Oil and Gas Fields, 2, 32-35.
  26. Abbasov, O. (2016). Organic compounds in ejected rocks of mud volcanoes as geological and geochemical indicators of source rock: a study of oil shale in Shamakhi-Gobustan region (Azerbaijan). International Journal of Current Advanced Research, 5(7), 1042-1046.
  27. Aliyev, Ad. A., Abbasov, O. R. (2019). Nature of the provenance and tectonic setting of oil shale (Middle Eocene) in the Greater Caucasus southeastern plunge. Geodynamics, 1(26), 43–59.
  28. Aliyev, Ad. A., Abbasov, O. R. (2019). Mineralogical and geochemical proxies for the Middle Eocene oil shales from the foothills of the Greater Caucasus, Azerbaijan: Implications for depositional environments and paleoclimate. Mineralia Slovaca, 51(2), 157-174.
  29. Crook, K. A. W. (1974). Lithogenesis and geotectonics: the significance of compositional variation in flysch arenites (greywackes). Society of Economical, Paleontological and Mineralogical Special Publications, 19, 304-310.
  30. Herron, M. M. (1988). Geochemical classification of terrigenous sands and shales from core and log data. Journal of Sedimentary Petrology, 58, 820-829.
  31. Nesbitt, H. W., Young, G. M. (1982). Early Proterozoic climates and plate motion inferred from major element chemistry of Lutites. Nature, 299, 715-717.
  32. Fedo, C. M., Nesbitt, H. W., Young, G. M. (1995). Unraveling the effects of potassium metasomatism in sedimentary rocks and paleosols, with implications for weathering conditions and provenance. Geology, 23, 921-924.
  33. Ruxton, B. P. (1968). Measures of the degree of chemical weathering of rocks. Journal of Geology, 76, 518-527.
  34. Nesbitt, H. W., Young, G. M., McLennan, S. M., Keays, R. R. (1996). Effects of chemical weathering and sorting on the petrogenesis of siliciclastic sediments, with implications for provenance studies. Journal of Geology, 104, 525-542.
  35. Cox, R., Lowe, D. R., Cullers, R. L. (1995). The influence of sediment recycling and basement composition on evolution of Mudrock chemistry in the Southwestern United States. Geochimica et Cosmochimica Acta, 59, 2919-2940.
  36. Selvaraj, K., Arthur, C. C. (2006). Moderate chemical weathering of subtropical Taiwan: constraints fromsolidphase geochemistry of sediments and sedimentary rocks. Journal of Geology, 114, 101-116.
  37. Aghayev, A. (2006). Geochemistry of sedimentation processes. Baku: PH «Adiloghlu». 38. Gharrabi, M., Velde, B., Sagon, J.-P. (1998). The transformation of illite to muscovite in pelitic rocks: Constraints from X-ray diffraction. Clays and Clay Minerals, 46, 79-88.
  38. Kortenski, J., Sotirov, A. (2002). Trace and major elements content and distribution in Neogene lignite from the Sofia Basin, Bulgaria. International Journal of Coal Geology, 52, 63-82.
  39. Hawkins, P. J. (1978). Relationship between diagenesis, porosity reduction and oil replacement in Late Carbonifereous sandstone reservoirs, Bothamsall oil field, E. Midlands. Journal of Geological Society, London, 135, 7-24.
  40. Rodrigo, D. L., Luiz, F. D. R. (2002). The role of depositional setting and diagenesis on the reservoir quality of Devonian sandstones from the Solimones Basin, Brazilian Amazonia. Marine and Petroleum Geology, 19, 1047-1071.
  41. Feng, R., Kerrich, R. (1990). Geochemistry of fine-grained clastic sediments in the Archaean Abitibi Greenstone Belt, Canada: implications for provenance and tectonic setting. Geochimica et Cosmochimica Acta, 54, 1061-1081.
  42. McLennan, S. M., Taylor, S. R., Eriksson, K. A. (1983). Geochemistry of Archean shales from the Pilbara Supergroup, Western Australia. Geochimica et Cosmochimica Acta, 47, 1211-1222.
  43. Nath, B. N., Kunzendorf, H., Pluger, W. L. (2000). Influence of provenance, weathering and sedimentary processes on the elemental ratio of the fine-grained fraction of the bed load sediments from the Vembanad Lake and the adjoining continental shelf, southwest Coast of India. Journal of Sedimentary Research, 70, 1081-1094.
  44. Osae, S., Asiedu, D. K., Yakubo, B., et al. (2006). Provenance and tectonic setting of Late Proterozoic Buem sandstones of southeastern Ghana: Evidence from geochemistry and detrital modes. Journal of African Earth Sciences, 44, 85-96.
  45. Potter, P. E. (1978). Petrology and chemistry of modern big river sands. The Journal of Geology, 86(4), 423-449.
  46. Oni, S. O., Olatunji, A. S., Ehinola, O. A. (2014). Determination of provenance and tectonic settings of Niger Delta clastic facies using well-y, Onshore Delta State, Nigeria. Journal of Geochemistry, Article ID 960139.
  47. Nesbitt, H. W., Markovics, G., Price, R. C. (1980). Chemical processes affecting alkalies and alkaline earths during continental weathering. Geochimica et Cosmochimica Acta, 44, 1659-1666.
  48. Dutta, P., Suttner, L. (1986). Alluvial sandstone composition and paleoclimate authigenic mineralogy. Journal of Sedimentary Petrology, 56, 346-358.
  49. Nesbitt, H. W., Young, G. M. (1989). Formation and diagenesis of weathering profiles. Journal of Geology, 97(2), 129-147.
  50. Turekian, K. K., Wedepohl, K. H. (1961). Distribution of the Elements in some major units of the Earth's crust. Geological Society of America, Bulletin, 72, 175-192.


DOI: 10.5510/OGP20220100625

E-mail: arastun.khuduzadeh@socar.az

B. T. Ratov1, N. A. Bondarenko2, V. A. Mechnik2, V. V. Strelchuk3, T. A. Prikhna2, V. M. Kolodnitsky2, A. S. Nikolenko3, P. M. Lytvyn3, I. M. Danylenko3, V. E. Moshchsl2, A. R. Borash4, A. B. Muzaparova5

V.Bakul Institute for Superhard Materials of the NAS of Ukraine, Kyiv, Ukraine

A study of the structure and strength properties of the WC–Co drill insert with different CrB2 content sintered by vacuum hot pressing


The optimal ratios of the components of the WC–Co‒CrB2 system have been established, at which a finely dispersed structure is formed with a simultaneous improvement in physical and mechanical properties. It is shown that the introduction of CrB2 (in concentration CCrB2 = 4% wt) leads to a twofold increase in fracture toughness (from KIc = 4.4 MPa ∙ m1/2 to KIc = 9.8 MPa ∙ m1/2) with a slight decrease hardness (from H = 15.1 to 13.9 GPa), as well as to an increase in the ultimate bending (from σ = 2000 to 2500 MPa) and compression (from σ = 5300 to 6000 MPa) strength of sintered composite specimens. Creation of the WC–Co‒CrB2 composite materials with improved mechanical and operational properties is essential for optimizing the designs of drilling tools for various technological purposes, increasing their reliability, energy saving, and improving operational properties.

Keywords: composite; composition; concentration; structure; hardness; fracture toughness.

References

  1. Saito, H., Iwabuchi, A., Shimizu, T. (2006). Effects of Co content and WC grain size on wear of WC cemented carbide. Wear, 261(2), 126-132.
  2. Ishikawa, K., Iwabuchi, A., Shimizu, T. (2003). Influence of EDM on the wear characteristics of WC–Co cemented carbide. Journal - Japanese Society of Tribologists, 48(11), 928-935.
  3. O’quigley, D. G. F., Luyckx, S., James, M. N. (1997). An empirical ranking of a wide range of WC–Co grades in terms of their abrasion resistance measured by the ASTM standard B 611-85 test. International Journal of Refractory Metals and Hard Materials, 15(1-3), 73-79.
  4. Menendez, E., Sort, J., Concustell, A., et al. (2007). Microstructural evolution during solid-state sintering of ballmilled nanocompositeWC–10 mass % Co powder. Nanotechnology, 18, 185609.
  5. Yang, M. C., Xu, J., Hu, Z. Q. (2004). Synthesis of WC–TiC35–Co10 nanocomposite powder by a novel method. International Journal of Refractory Metals and Hard Materials, 22(1), 1-7.
  6. Milman, Yu. V., Luyckx, S., Northrop, I. T. (1999). Influence of temperature, grain size and cobalt content on the hardness of WC–Co alloys. International Journal of Refractory Metals and Hard Materials, 17(1-3), 39-44.
  7. Carol, D. F. (1997). Sintering and microstructural development in WC/Co-based alloys made with superfine WC powder. International Journal of Refractory Metals and Hard Materials, 17(1-3), 123-132.
  8. Bondarenko, N. A., Mechnik, V. A. (2011). The influence of transition area diamond-matrix on wear resistance and operation properties of drilling tool produced by ISM. SOCAR Proceedings, 2, 18-24.
  9. Belnap, D., Griffo, A. (2004). Homogeneous and structured PCD/WC-Co materials for drilling. Diamond and Related Materials, 13(10), 1914-1922.
  10. Bondarenko, N. A., Zhukovsky, A. N., Mechnik, V. A. (2006). Analysis of the basic theories of sintering of materials. 1. Sintering under isothermal and nonisothermal conditions (a review). Sverkhtverdye Materialy, 6, 3-17.
  11. Kolodnits’kyi, V. M., Bagirov, O. E. (2017). On the structure formation of diamond-containing composites used in drilling and stone-working tools (a review). Journal of Superhard Materials, 39(1), 1-17.
  12. Bondarenko, N. A., Mechnik, V. A. (2012). Drilling oil and gas wells by ISM diamond tools. SOCAR Proceedings, 3, 6-12.
  13. Lisovsky, A. F., Bondarenko, N. A. (2014). The role of interphase and contact surfaces in the formations of structures and properties of diamond–(WC–Co) composites. A review. Journal of Superhard Materials, 36(3). 145-155.
  14. Novikov, M. V., Mechnyk, V.A ., Bondarenko, M .O., et al. (2015). Composite materials of diamond−(Co–Cu–Sn) system with improved mechanical characteristics. Part 1. The influence of hot re-pressing on the structure and properties of diamond−(Co–Cu–Sn) composite. Journal of Superhard Materials, 37(6), 402-416.
  15. Tarrado, J. M., Roa, J. J., Valle, V., et al. (2015). Fracture and fatigue behavior of WC–Co and WC–Co,Ni cemented carbides. International Journal of Refractory Metals and Hard Materials, 49(3), 184-191.
  16. Wang, X., Hwang, K. S., Koopman, M., et al. (2013). Mechanical properties and wear resistance of functionally graded WC–Co. International Journal of Refractory Metals and Hard Materials, 36, 46-51.
  17. Lisovsky, A. F., Bondarenko, N. A., Davidenko, S. A. (2016). Structure and properties of the diamond WC–6Co composite doped by 1.5 wt.% of CrSi2. Journal of Superhard Materials, 38(6), 382-392.
  18. Bondarenko, N. A. (2018). ISM high-performance tools for drilling of oil and gas wells. Review. Journal of Superhard Materials, 40(5), 355-364.
  19. Novikov, N. V., Tsypin, N. V., Maistrenko, А. L., Vovchanovskyy, Y. F. (1983). Composite diamond-containing materials based on hard alloys. Journal of Superhard Materials, 2, 3-5.
  20. Azcona, I., Ordonez, A., Sanchez, J. M., Castro, F. (2002). Hot isostatic pressing of ultrafine tungsten carbide–cobalt hardmetals. Journal of Materials Science, 37(19), 4189-4195.
  21. Mechnik, V. A., Bondarenko, N. A., Dub, S. N., et al. (2018). A study of microstructure of Fe–Cu–Ni–Sn and Fe–Cu–Ni–Sn–VN metal matrix for diamond containing composites. Materials Characterization, 146, 209-216.
  22. Mechnik, V. A., Bondarenko, N. A., Kolodnitskyi, V. M., et al. (2020). Effect of vacuum hot pressing temperature on the mechanical and tribological properties of the Fe–Cu–Ni–Sn–VN composites. Powder Metallurgy and Metal Ceramics, 58(11-12), 679-691.
  23. Howe’s, V. R. (1962). The graphitization of diamond. Proceedings of the Physical Society, 80(3), 648-662.
  24. Seal, M. (1963). The effect of surface orientation on the graphitization of diamond. Physica Status Solidi, 3 (4), 658-664.
  25. Ponomarev, S. S., Shatov, A. V., Mikhailov, A. A., Firstov, S. A. (2015). Carbon distribution in WC-based cemented carbides. International Journal of Refractory Metals and Hard Materials, 49 (3), 42-56.
  26. Zhukovskij, A. N., Majstrenko, A. L., Mechnik, V. A., Bondarenko, N. A. (2002). The stress-strain state of the bonding around the diamond grain exposed to normal and tangent loading components. Part 1. Model. Friction and Wear, 23(2), 146-153.
  27. Zhukovskij, A. N., Majstrenko, A. L., Mechnik, V. A., Bondarenko, N. A. (2002). Stress-strain state of the matrix around the diamond grain exposed to the normal and tangent loading components. Part 2. Analysis. Friction and Wear, 23(4), 393-396.
  28. Aleksandrov, V. A., Akekseenko, N. A., Mechnik, V. A. (1984). Study of force and energy parameters in cutting granite with diamond disc saws. Journal of Superhard Materials, 6(6), 46-52.
  29. Aleksandrov, V. A., Zhukovskij, A. N., Mechnik, V. A. (1994). Temperature field and wear of heterogeneous diamond wheel under conditions of convectional heat transfer. Part 2. Friction and Wear, 15 (2), 196-201.
  30. Dutka, V. A., Kolodnitskij, V. M., Zabolotnyj, S. D., et al. (2004). Simulation of the temperature level in rock destruction elements of drilling bits. Journal of Superhard Materials, 2, 66-73.
  31. Dutka, V. A., Kolodnitskij, V. M., Mel’nichuk, O. V., Zabolotnyj, S. D. (2005). Mathematical model for thermal processes occurring in the interaction between rock destruction elements of drilling bits and rock mass. Journal of Superhard Materials, 1, 67-77.
  32. Arenas, F., Arenas, I.B., Ochoa, J., Cho, S.A. (1999). Influence of VC on the microstructure and mechanical properties of WC–Co sintered cemented carbides. International Journal of Refractory Metals and Hard Materials, 17 (1-3), 91-97.
  33. Bock, A., Zeiler, B. (2002). Production and characterization of ultrafine WC powders. International Journal of Refractory Metals and Hard Materials, 20 (1), 23-30.
  34. Yang, M. C., Xu, J., Hu, Z. Q. (2004). Synthesis of WC–TiC35–Co10 nanocomposite powder by a novel method. International Journal of Refractory Metals and Hard Materials, 22 (1), 1-7.
  35. Bondarenko, N. A., Mechnik, V. A., Hasanov, R. A., Kolodnitsky, V. N. (2020). Microstructure of WC – Co – VN carbide catrix for drilling tools diamond-containing materials. SOCAR Proceedings, 3, 21-30.
  36. Nikolenko, S. V., Verhoturov, A. D., Dvornik, M. I., et al. (2008).Application of AL2O3 nanopowder as grain growth inhibitor in WC-8%Co alloy. Voprosy Materialovedeniya, 54(2), 100-105.
  37. Kurlov, A. S., Rempel, A. A., Blagoveshchensky, Yu. V., et al. (2011). Hard alloys WC‒6 mass. %Co and WC‒10 mass. % Co based on nanocrystalline powders. Doklady Akademii Nauk, 439(20), 215-220.
  38. Chuldeev, V. N., Mosknicheva, A. V., Lopatin, Yu. G., et al. (2011). Sintering of WC and WC–Co nanopowders with various inhibitory additives by the method of electro-pulse plasma sintering. Doklady Akademii Nauk, 436(5), 623-626.
  39. Gordeev, I. Yu., Abkaryan, A. K., Zeer, G. M. (2012). Design and invertigation investigation of hard metals and ceramics composites modified by nano-particles. Journal Perspektivnye materialy, 5, 76-88.
  40. Franca, L. F. P., Mostofi, M., Richard, T. (2015). Interface laws for impregnated diamond tools for a given state of wear. International Journal of Refractory Metals and Hard Materials, 73, 184-193.
  41. Richter, V., Ruthendorf, M. V. (1999). On hardness and toughness of ultrafine and nanocrystalline hard materials. International Journal of Refractory Metals and Hard Materials, 17(1-3), 141-152.
  42. Porat, R., Berger, S., Rosen, A. (1996). Dilatometric study of the sintering mechanism of nanocrystalline cemented carbides. Nanostructured Materials, 7(4), 429-436.
  43. Bondarenko, N. A., Novikov, N. V., Mechnik, V. A., et al. (2004). Structural peculiarities of highly wear-resistant superhard composites of the diamond–WC–6Co carbide system. Journal of Superhard Materials, 6, 3-15.
  44. Novikov, N. V., Bondarenko, N. A., Zhukovskii, A. N., Mechnik, V. A. (2005). The effect of diffusion and chemical reactions on the structure and properties of drill bit inserts. 1. Kinetic description of systems Cdiamond‒VK6 and Cdiamond‒ (VK6‒CrB2‒W2B5). Physical Mesomechanics , 8(2), 99-106.
  45. Kodash, V. Y., Gevorkian, E. S. (2003). Tungsten carbide cutting tool materials. Patent US-6617271-B1.
  46. Evans, A. G., Charles, E. A. (1976). Fracture toughness determinations by indentation. Journal of the American Ceramic Society, 59 (7-8), 371-372.
  47. Brookes Kenneth, J. A. (1992). World directory and handbook hard materials. UK: International Carbide Data.


DOI: 10.5510/OGP20220100626

E-mail: vlad.me4nik@ukr.net

H. Kh. Melikov1, Sh. Z. Ismayilov1, A. A. Suleymanov1, N. F. Mammadli2

1Azerbaijan State Oil Academy, Baku, Azerbaijan; 2«OilGasScientificResearchProject» Institute, SOCAR, Baku, Azerbaijan

Diagnosing multiphase flow regime in multilayered reservoir by distributed temperature sensor measurements


The article discusses the possibility of diagnosing the multiphase flow regime in the multilayered reservoir by using DTS (distributed temperature sensing) data. The analysis of the theoretical and actual curves of temperature build up and drawdown, corresponding to the main modes of multiphase flow of formation fluids are given in this article. The possibility of diagnosis of the multiphase flow regime is found based on analysis and interpretation of the characteristics of temperature build-up and drawdown in different intervals of the reservoir at the start of the well or shut in, or by changing opening degree of the choke. The possibility of diagnosing water breakthrough (WBT) intervals, based on the analysis of the changes in temperature curves according to the DTS is shown. For a more detailed analysis and interpretation of temperature change curves in the wells more frequent DTS measurements are required. It is necessary to conduct a comparative analysis of the dynamics of the temperature and pressure redistribution in the productive zone of the well, with the results of geophysical logging, production logging, taking samples of reservoir fluids from different zones of productive layers in the multilayered reservoir, moisture metering, hydrometry and others.

Keywords: well; monitoring; multilayer reservoir; temperature profile; distributed temperature sensor; multiphase flow regime.

References

  1. Mirzajanzadeh, A. Kh., Aliev, N. A., Yusifzade, Kh. B., et al. (1997). Fragments on development of offshore oil and gas fields. Baku: Elm.
  2. Veliyev, E. F. (2021). Polymer dispersed system for in-situ fluid diversion. Prospecting and Development of Oil and Gas Fields, 1(78), 61-72.
  3. Suleimanov, B. A., Veliyev, E. F., Naghiyeva, N. V. (2021). Colloidal dispersion gels for in-depth permeability modification. Modern Physics Letters B, 35(01), 2150038.
  4. Suleimanov, B. A., Guseynova, N. I., Veliyev, E. F. (2017, October). Control of displacement front uniformity by fractal dimensions. SPE-187784-MS. In: SPE Russian Petroleum Technology Conference. Society of Petroleum Engineers.
  5. Suleimanov, B. A., Veliyev, E. F., Naghiyeva, N. V. (2020). Preformed particle gels for enhanced oil recovery. International Journal of Modern Physics B, 34(28), 2050260.
  6. Veliyev, E. F., Aliyev, A. A. (2021, October). Propagation of nano sized CDG deep into porous media. SPE-207024-MS. In: SPE Annual Caspian Technical Conference. Society of Petroleum Engineers.
  7. Veliyev, E. F. (2021). A combined method of enhanced oil recovery based on ASP technology. Prospecting and Development of Oil and Gas Fields, (4 (81)), 41-48.
  8. Veliyev, E. F., Aliyev, A. A., Mammadbayli, T. E. (2021). Machine learning application to predict the efficiency of water coning prevention. SOCAR Proceedings, 1, 104-113.
  9. Suleimanov, B. A., Veliyev, E. F., Aliyev, A. A. (2021). Impact of nanoparticle structure on the effectiveness of pickering emulsions for eor applications. ANAS Transactions, (1), 82-92.
  10. Veliyev, E. F. (2021). Prediction methods for coning process. Azerbaijan Oil Industry, (3), 18-25.
  11. Balakirov, Yu. A. (1970). Thermodynamic studies of oil and gas filtering in deposit. Moscow: Nedra.
  12. Rider, M. H., Kennedy, M. (2011). The geological interpretation of well logs. Sutherland: Rider-French.
  13. Brown, G. (2009). Downhole temperatures from optical fiber. Schlumberger Oilfield Review, 20(4), 34-39.
  14. (2009). The essentials of fiber-optic distributed temperature analysis. Schlumberger Educational Services.
  15. Brown, G., Algeroy, J., Lovell, J., et al. (2010). Permanent monitoring: taking it to the reservoir. Schlumberger Oilfield Review, 22(1), 34-41.
  16. Brown, G., Storer, D., McAllister, K., et al. (2003, October). Monitoring horizontal producers and injectors during cleanup and production using fiber-optic-distributed temperature measurements. SPE-84379-MS. In: SPE Annual Technical Conference and Exhibition. Society of Petroleum Engineers.
  17. Brown, G. A., Kennedy, B., Meling, T. (2000, October). Using fibre-optic distributed temperature measurements to provide real-time reservoir surveillance data on Wytch Farm field horizontal extended-reach wells. SPE-62952-MS. In: SPE Annual Technical Conference and Exhibition. Society of Petroleum Engineers.
  18. Fryer, V., Shu Xing, D., Otsubo, Y., et al. (2005, April). Monitoring of real-time temperature profiles across multizone reservoirs during production and shut-in periods using permanent fiber-optic distributed temperature systems. SPE-92962-MS. In: SPE Asia Pacific Oil and Gas Conference and Exhibition. Society of Petroleum Engineers.
  19. Denney, D. (2012). DTS Technology: Improving Acid Placement. Journal of Petroleum Technology, 64(6), 22-25.
  20. Gorgi, B., Medina, E., Gleaves, J., et al. (2014, November). Wellbore monitoring in carbonate reservoirs: value of DTS in acid stimulation through coiled tubing. SPE-171933-MS. In: Abu Dhabi International Petroleum Exhibition and Conference. Society of Petroleum Engineers.
  21. Villesca, J., Glasbergen, G., Attaway, D. J. (2011, June). Measuring fluid placement of sand consolidation treatments using DTS. SPE-144432-MS. In: SPE European Formation Damage Conference. Society of Petroleum Engineers.
  22. Valiullin, R. A., Ramazanov, A. Sh., Sharafutdinov, R. F. (1998). Thermometry of reservoirs with multiphase flow. Ufa: Bashkir State University.
  23. Tabatabaei, M., Tan, X., Hill, A. D., Zhu, D. (2011, October-November). Well performance diagnosis with temperature profile measurements. SPE-147448-MS. In: SPE Annual Technical Conference and Exhibition. Society of Petroleum Engineers
  24. Malikov, H. Kh., Suleymanov, A. A., Mammadli, N. F. (2017, November). Diagnosing multiphase flow regime in multilayered reservoir by distributed temperature sensor data. SPE-189034-MS. In: SPE Annual Caspian Conference and Exhibition. Society of Petroleum Engineers.
  25. Firoozabadi, A. (1999). Thermodynamics of hydrocarbon reservoirs. New York: McGraw-Hill.
  26. White, F. M. (2011). Fluid mechanics. New York: McGraw-Hill.
  27. Valiullin, R. A., Ramazanov, A. Sh., Sharafutdinov, R. F. (1994). Barothermal effect in three-phase flow through a porous medium with phase transitions. Fluid Dynamics, 28, 834-837.


DOI: 10.5510/OGP20220100627

E-mail: petrotech@asoiu.az

V. J. Abdullayev1, Kh. M. Gamzaev2

1«OilGasScientificResearchProject» Institute, SOCAR, Baku, Azerbaijan; 2Azerbaijan State Oil and Industry University, Baku, Azerbaijan

Numerical method for determining the coefficient of hydraulic resistance two-phase flow in a gas lift well


The process of stationary movement of a gas-liquid mixture in the lifting pipe of a gas-lift well is considered. To describe this two-phase flow, a mathematical model is proposed that includes the equation of flow motion and the continuity equation for each phase. The presented model is transformed to a single nonlinear ordinary differential equation with respect to pressure. Within the framework of the obtained model, the task is set to determine the hydraulic resistance coefficient of a two-phase flow according to an additionally specified condition with respect to pressure. An additional condition, presented in the form of a nonlinear algebraic equation, is transformed into an ordinary differential equation with respect to an unknown coefficient of hydraulic resistance by applying the method of differentiation by parameter. The solution of the resulting Cauchy problem is determined by the finite difference method. Based on the proposed computational algorithm, numerical experiments were carried out for model data.

Keywords: gas lift; two-phase flow; hydraulic resistance coefficient; parameter differentiation method; finite difference method.

References

  1. Veliyev, E. F. (2021). Polymer dispersed system for in-situ fluid diversion. Prospecting and Development of Oil and Gas Fields, 1(78), 61-72.
  2. Suleimanov, B. A., Veliyev, E. F., Naghiyeva, N. V. (2021). Colloidal dispersion gels for in-depth permeability modification. Modern Physics Letters B, 35(01), 2150038.
  3. Suleimanov, B. A., Guseynova, N. I., Veliyev, E. F. (2017, October). Control of displacement front uniformity by fractal dimensions. SPE-187784-MS. In: SPE Russian Petroleum Technology Conference. Society of Petroleum Engineers.
  4. Suleimanov, B. A., Veliyev, E. F., Naghiyeva, N. V. (2020). Preformed particle gels for enhanced oil recovery. International Journal of Modern Physics B, 34(28), 2050260.
  5. Veliyev, E. F. (2021). Prediction methods for coning process. Azerbaijan Oil Industry, 3, 18-25.
  6. Suleimanov, B. A., Veliyev, E. F., Aliyev, A. A. (2021). Impact of nanoparticle structure on the effectiveness of pickering emulsions for eor applications. ANAS Transactions, (1), 82-92.
  7. Veliyev, E. F. (2021). Application of amphiphilic block-polymer system for emulsion flooding. SOCAR Proceedings, (3), 78-86.
  8. Veliyev, E. F., Aliyev, A. A., Mammadbayli, T. E. (2021). Machine learning application to predict the efficiency of water coning prevention. SOCAR Proceedings, 1, 104-113.
  9. Suleimanov, B. А. (1997). Slip effect during filtration of gassed liquid. Colloid Journal, 59(6), 749-753.
  10. Suleimanov, B. А. (2011). Sand plug washing with gassy fluids. SOCAR Proceedings, 1, 30-36.
  11. Suleimanov, B. А., Azizov, Kh. F. (1995). Specific features of the flow of a gassed liquid in a porous body. Colloid Journal, 57(6), 818-823.
  12. Mirzadzhanzadeh, A. Kh., Ametov, I. M., Khasaev, A. M., Gusev, V. I. (1986). Technology and technics of oil extraction. Moscow: Nedra.
  13. Silash, A. P. (1980). Extraction and transport of oil and gas. Moscow: Nedra.
  14. Shoham, O. (2006). Mechanistic modeling of gas-liquid two-phase flow in pipes. USA: Society of Petroleum Engineers.
  15. Mokhov, M. A., Sakharov, V. A. (2008). Flowing and gas-lift well operation. Moscow: Nedra.
  16. Leonov, E. G., Isaev, V. I. (1987). Drilling hydroaeromechanics. Moscow: Nedra.
  17. Aliev, F. A., Ismailov, N. A. (2013). Inverse problem to determine the hydraulic resistance coefficient in the gas lift process. Applied and Computational Mathematics, 3, 306–313.
  18. Ramazanova, E. E., Gurbanov, R. S., Nasibov, N. B. (2010). A new approach to the study of gas-lift wells in the regime of steady withdrawals. Oil Industry, 6, 83-85.
  19. Abdullayev, V. J. (2021). New approach for two-phase flow calcuation of artifical lift. SOCAR Proceedings, 1, 49–55.
  20. Gamzayev, Kh. M., Yusifov, S. I. (1998). Simulation of gas-lift. Azerbaijan Oil Industry, 4, 32-33.
  21. Kadivar, A., Nemati, E. (2017). A computation fluid dynamic model for gas lift process simulation in a vertical oil well. Journal of Theoretical and Applied Mechanics, 1, 49-68.
  22. Ortega, J., Reinboldt, V. (1975). Iterative methods for solving nonlinear systems of equations with many variables. Moscow: Mir.
  23. Samarsky, A. A., Gilin, A. V. (1989). Numerical methods. Moscow: Nauka.


DOI: 10.5510/OGP20220100628

E-mail: vugar.abdullayev@socar.az

E. E. Bayramov

SOCAR, Baku, Azerbaijan

New combined well design to protect electric submersible pump from sand flow


The paper presents a new well construction in order to eliminate the unpleasant complications associated with the appearance of sand flow in the Electric Submersible Pumps (ESP), which is widely used in oil wells in the final stage of reservoir development. The new design is based on the combination of ESP with a Mixer based on the principle of ejector and centrifugal. The combined well construction limits the ESP to be in contact with the sand flow and prevents potential erosion and other complications. The design was modeled and tested in the laboratory condition.

Keywords: field; layer; pump; well construction; sand production; sand separator.

References

  1. Abdus, S., Mohammad, N. (2013). Flow analyses inside jet pumps used for oil wells. International Journal of Fluid Machinery and Systems, 6(1), 1-10.
  2. Abasova, S. M., Habibov, I. A. (2012). Elektrik merkezdenqachma nasoslarinda istismar zamani yaranan imtinalarin tehlili. «Xezerneftqazyataq – 2012» elmi–tecrubi konfrans, Baki.
  3. Diaz de Bonilla, S. G., Chen, H.-Y. (2019, July). Analytical and numerical studies of sand erosion in electrical submersible pump (ESP) systems. URTEC-2019-599-MS. In: SPE/AAPG/SEG Unconventional Resources Technology Conference. Society of Petroleum Engineers.
  4. Lyamaev, B. F. (1988). Hydrojet pumps and units. Leningrad: Mashinostroyeniye.
  5. Azizov, A. H., Qarayev, M. A., Heydarov, H. A., Agammadov, S. A. (2010). Hecmi hidravlik mashinlar. Bakı: ADNA.
  6. Haiwen, Z., Jianjun, Z., Zulin, Z., et al. (2019, May). Wear and its effect on electrical submersible pump ESP performance degradation by sandy flow: experiments and modeling. OTC-29480-MS. In: Offshore Technology Conference. Society of Petroleum Engineers.
  7. Haiwen, Z., Jianjun, Z., Zulin, Z., et al (2019, March). Experimental study of sand erosion in multistage electrical submersible pump ESP: performance degradation, wear and vibration. IPTC-19264-MS. In: International Petroleum Technology Conference. Society of Petroleum Engineers.
  8. Noui-Mehdi, M. N., Bukhamseen, A. Y. (2019). Advanced signal analysis of an electrical-submersible-pump failure owing to scaling. SPE Production & Operation, 34(02), 394–399.
  9. Topolnikov, A. S., Urazakov, K. R., Vahitova, R. I., Saracheva, D. A (2013). The method of calculation of parameters of jet pump attached to joint operation with submersible electric pump. Oil and Gas Business, 4, 201-211.
  10. Mishchenko, I. T., Gumerskiy, Kh. Kh., Mar'enko, V. P. (1996). Jet pumps for oil production. Moscow: Neft i Gaz Publ.
  11. Mallela, R., Chatterjee, D. (2011). Numerical investigations of the effect of geometry on the performance of jet pump. Journal of Mechanical Engineering Science, 225, 1-12.
  12. Ahmed, F. F., Hemidov, N. N., Bayramov, E. E. (2019). Lay sularinin tecridi proseslərinde sement dashinin elastikberk xasselerinin qiymetlendirilmesi. «Neftin Qazin Geotexnoloji Problemleri ve Kimya» Elmi-Tedqiqat Institutunun Elmi Eserleri. Baki: Azerkitab-212 MMC.


DOI: 10.5510/OGP20220100629

E-mail: elman.e.bayramov@socar.az

A. M. Svalov

Oil and Gas Research Institute RAS (OGRI RAS), Moscow, Russia

Features of the impact of high-amplitude short pulses of hydrodynamic pressure on perforation channels


The features of the impact of high-amplitude short pressure pulses on perforation channels in the bottomhole zone of the well are analyzed. It is shown that in the channels formed in the rock with the use of cumulative perforation and having a conical shape, there is an increase in pressure pulses when a certain condition is fulfilled, which limits the duration of this pulse. It has been established that in the negative phase of the pressure pulse, destruction of the cured rock layers adjacent to the walls of the perforation channel can occur, which improves the filtration-capacitive properties of the bottomhole zone of the well. It is shown that when using explosive charges of low mass, pressure pulses are formed with parameters similar to those of pulses generated by electric discharges in the wellbore. To apply the technology of explosive action with low-mass charges on the bottomhole zone, the standard equipment used for cumulative perforation of wells can be used. A method for screening pressure pulses is proposed, which increases the effectiveness of their impact on the bottomhole zone of the well and simultaneously reduces the excessive load on the casing pipes above the productive formation.

Keywords: bottomhole zone of a well; perforation channels; electric discharge impact; low-mass charges; reflecting screen.

References

  1. Gulyi, G. A. (1990). Scientific foundation of discharge-pulse technologies. Kiev: Naukova dumka.
  2. Molchanov, A. A. (1995, aprel'). Progressivnye tekhnologii, obespechivayushchie dopolnitel'noe izvlechenie nefti i gaza. Toplivno-energeticheskie resursy Rossii i drugih stran SNG. Materialy mezhdunarodnogo simpoziuma. Sankt-Peterburg: Sankt-Peterburgskij gornyj institut.
  3. Ageev, P. G., Ageev, N. P., Pashchenko, A. F., et al. (2019). Experimental study of plasma-impulse impact: intensity of pressure pulsations in the medium processed. Journal of Machinery Manufacture and Reliability, 48(2), 184-189.
  4. Landau, L. D., Lifshitz, E. M. (1988). Theoretical physics. Vol. 6. Hydrodynamics. Moscow: Nauka.
  5. Khristianovich, S. A. (1981). Continuum mechanics. Moscow: Nauka.
  6. Koul, R. (1950). Podvodnye vzryvy. Moskva: Izdatel'stvo inostrannoj literatury.
  7. Pashchenko, A. F., Ageev, P. G. (2015). Plazmenno-impul'snaya tekhnologiya povysheniya nefteotdachi: ocenka parametrov mekhanicheskogo vozdejstviya. Nauka i Tekhnika v Gazovoj Promyshlennosti, 3 (63), 17–26.
  8. Svalov, A. M. (2017). Novyj podhod k primeneniyu tekhnologij elektrorazryadnogo vozdejstviya na prizabojnye zony skvazhin. Tekhnologii Nefti i Gaza, 5, 24-29.


DOI: 10.5510/OGP20220100630

E-mail: svalov@ipng.ru

I. K. Akhmedova

«OilGasScientificResearchProject» Institute, SOCAR, Baku, Azerbaijan

The study of a new paraffin inhibitor in oil production


A new composition for controlling build up of paraffin has been developed. Preference was given to naphthenic acids, polypropylene glycol, caustic potassium and copper nanoparticles with size of 50 nm, bulk weight 5 g/cm3, specific surface area 12 m2/g. The optimal concentration of the hydrophobic reagent and its application technology under field conditions are recommended. The developed reagent is used in oil production, namely for ARPD control, in individual wells in Azerbaijan.

Keywords: well; wax deposition; inhibitor; nanoparticle; electrokinetic potential.

References

  1. Veliyev, E. F., Aliyev, A. A. (2021, October). Propagation of nano sized CDG deep into porous media. SPE-207024-MS. In: SPE Annual Caspian Technical Conference. Society of Petroleum Engineers.
  2. Suleimanov, B. A., Latifov, Y. A., Veliyev, E. F., Frampton, H. (2017, November). Low salinity and low hardness alkali water as displacement agent for secondary and tertiary flooding in sandstones. SPE-188998-MS. In: SPE Annual Caspian Technical Conference and Exhibition. Society of Petroleum Engineers.
  3. Panakhov, G. M., Suleimanov, B. A. (1995). Specific features of the flow of suspensions and oii disperse systems. Colloid Journal, 57(3), 386-390.
  4. Suleimanov, B. А., Askerov, М. S., Valiyev, G. А. (2000). Potential of re-development of horizon PK-5 (north) of Surakhany field. Azerbaijan Oil Industry, (5), 16-21.
  5. Veliyev, E. F. (2021). Polymer dispersed system for in-situ fluid diversion. Prospecting and Development of Oil and Gas Fields, 1(78), 61-72.
  6. Suleimanov, B. A., Veliyev, E. F., Naghiyeva, N. V. (2021). Colloidal dispersion gels for in-depth permeability
    modification. Modern Physics Letters B, 35(01), 2150038.
  7. Suleimanov, B. A., Guseynova, N. I., Veliyev, E. F. (2017, October). Control of displacement front uniformity by fractal dimensions. SPE-187784-MS. In: SPE Russian Petroleum Technology Conference. Society of Petroleum Engineers.
  8. Suleimanov, B. A., Veliyev, E. F., Naghiyeva, N. V. (2020). Preformed particle gels for enhanced oil recovery. International Journal of Modern Physics B, 34(28), 2050260.
  9. Veliyev, E. F. (2021). A combined method of enhanced oil recovery based on ASP technology. Prospecting and Development of Oil and Gas Fields, (4 (81)), 41-48.
  10. Veliyev, E. F., Aliyev, A. A., Mammadbayli, T. E. (2021). Machine learning application to predict the efficiency of water coning prevention. SOCAR Proceedings, 1, 104-113.
  11. Suleimanov, B. A., Veliyev, E. F., Aliyev, A. A. (2021). Impact of nanoparticle structure on the effectiveness of pickering emulsions for EOR applications. ANAS Transactions, (1), 82-92.
  12. Ismailov, R. G., Veliev, E. F. (2021). Emulsifying composition for increase of oil recovery efficiency of high viscous oils. Azerbaijan Oil Industry, (5), 22-28.
  13. Sorokin, A., Havkin, A. (2007). Physical and chemical mechanism of production asphalted, resinous and of paraffin formations in the wells. Drilling and Oil, 10, 30-31.
  14. Ivanova, L.V., Burov, E. A., Koshelev, V. N. (2011). Asphaltene-resin-paraffin deposits in the processes of oil production, transportation and storage. Oil and Gas Business, 1.
  15. Glushchenko, V. N., Shipiguzov, L. M., Yurpalov, I. A. (2007). Estimation of an efficiency of asphaltene-tarparaffin deposits inhibitors. Oil Industry, 5, 84-87.
  16. Nagimov, N. M., Ishkaev, R. K., Sharifullin, A. V., Kozin, V. G. (2001). A new series of hydrocarbon composites to remove asphalt, resin, and paraffin deposits. Oilfield Engineering, 9, 25-29.
  17. Lebedev, N. A., Yudina, T. V., Safarov, R. R., et al. (2002). The development of the complex reagent based on phenolformaldehyde resin. Oilfield Engineering, 4, 34-38.


DOI: 10.5510/OGP20220100631

E-mail: ilhame7007@gmail.com

F. S. Ismayilov1, Q. Q. Ismayilov2, N. M. Safarov1

1«OilGasScientificResearchProject» Institute, SOCAR, Baku, Azerbaijan; 2Azerbaijan State University of Oil and Industry, Baku, Azerbaijan

On the possibility of regulation of rheophysical properties multicomponent mixtures based on rheotechnology


The article deals with the regulation of the rheophysical properties of multicomponent mixtures on the basis of the purposeful application of a new direction in science-rheotechnology. The data of rotoviscometry once again confirmed that the sequence of mixing the constituent components of the oil-water-sand mixture directly affects the rheology of the newly formed systems. The method of changing the order of entering the constituent components shows the prospects for increasing the efficiency of the processes of extraction, collection and transport of oils and their mixtures based on the creation of new rheological methods based on the regulation of the rheophysical properties of the heterophase systems under consideration.

Keywords: constituent components of the mixture; rheology; structural viscosity; anomalous index; graph-analytical method.

References

  1. Gumbatov, G. G., Bagirov, O. T., Sariyev, S. K., et.al. (2002). Regulation of technogenic processes to increase the production capacity of wells. Baku: Maarif.
  2. Safieva, R. Z., Sunyaev, R. Z. (2007). Physico-chemical properties of oil dispersed systems oil and gas technologies. Moscow-Izhevsk: Institute of Computer Research. Research Center «Regular and Chaotic Dynamics».
  3. Sattarov, R. M. (1982). Scientific basis for diagnosing and determining the properties of rheologically complex systems used in oil and gas production. Doctoral Dissertation Thesis. Baku.
  4. Mirzajanzade, A. Kh., Khasanov, M. M., Bakhtizin, R. N. (1999). Sketches on the modeling of complex systems in oil production. Ufa: Gilem.
  5. Suleimanov, B. A., Panahov, G. M., Abbasov, E. M. (1996). On the influence of the formation of an emulsion in reservoir conditions on the operation of oil producing wells. Azerbaijan Oil Industry, 5, 26-29.
  6. Suleymanov, B. A. (1997). Theoretical and practical foundations of the use of heterogeneous systems to improve the efficiency of technological processes in oil production. Doctoral Dissertation Thesis. Baku: ASUOI.
  7. Fortier, A. (1971). Mechanics of suspensions. Moscow: Mir.
  8. Ismayilov, F. S., Ismayilov, G. G., Safarov, N. M., et al. (2014).Transportation method of high viscosity oils through the pipeline. Patent of the Republic of Azerbaijan İ 2004 0032.
  9. Ismayilov, G. G., Safarov, N. M. (2011). To the question of studying the effect of free-flowing fillers on the rheological properties of oil-water emulsions. Proceedings of High Technical Educational Institutions of Azerbaijan, 3(73), 26-32.
  10. Ismayilov, G. G., Safarov, N. M. (2013, November). On the prospects for the use of rheological technologies in processes of oil and gas production on the basis of «Mirzadjanzadeh emulsions». In: The international scientific conference dedicated to the 85th anniversary of the academician A.Kh. Mirzajanzadeh. Baku: ASUOI.
  11. Ismayilov, G. G., Safarov, N. M. (2010). Rheotechnology of viscous-free systems (monography). Baku: MSM.
  12. Ismayilov, G. G., Safarov, N. M. (2011). Rheotechnology of heterogeneous systems and its reflection, in effects manifested during oil and gas production. News of ANAS (Series of Earth Sciences), 4, 49-55.
  13. Ametov, I. M., Sherstnev, N. M. (1989). Application of composite systems in technological operations of well operation. Moscow: Nedra.
  14. Ismayilov, F. S., Ismayilov, G. G., Safarov, N. M. (2010). Loose chimney sweeps (about perspectives of application of viscous-free systems in oil production). Oil of Russia, 10, 84-85.
  15. Panahov, G. M. (1995). Development and implementation of new composite systems in oil and gas production. Doctoral Dissertation Thesis. Baku.


DOI: 10.5510/OGP20220100632

E-mail: natik_safarov@mail.ru

V. M. Shamilov

SOCAR, Баку, Азербайджан

Production of modified multi-walled carbon nanotubes and their application for stimulation from oil recovery


In the presented work, the possibility of using modified multi-walled carbon nanotubes (MWCNTs) as reagents for increasing the oil recovery factor is considered. Carbon nanotubes were obtained by the method of chemical combination from the gas phase. Ethylene was used as the raw material. Further, the nanotubes were modified to obtain a stable aqueous MWCNT ash, subsequently used as an additive to the polyacrylamide solution.

Keywords: nanotechnologies; multi-walled carbon nanotubes; oil recovery enhancement.

References

  1. Veliyev, E. F. (2021). Polymer dispersed system for in-situ fluid diversion. Prospecting and Development of Oil and Gas Fields, 1(78), 61-72.
  2. Suleimanov, B. A., Veliyev, E. F., Naghiyeva, N. V. (2021). Colloidal dispersion gels for in-depth permeability modification. Modern Physics Letters B, 35(01), 2150038.
  3. Suleimanov, B. A., Guseynova, N. I., Veliyev, E. F. (2017, October). Control of displacement front uniformity by fractal dimensions. SPE-187784-MS. In: SPE Russian Petroleum Technology Conference. Society of Petroleum Engineers.
  4. Suleimanov, B. A., Veliyev, E. F., Naghiyeva, N. V. (2020). Preformed particle gels for enhanced oil recovery. International Journal of Modern Physics B, 34(28), 2050260.
  5. Veliyev, E. F., Aliyev, A. A. (2021, October). Propagation of nano sized CDG deep into porous media. SPE-207024-MS. In: SPE Annual Caspian Technical Conference. Society of Petroleum Engineers.
  6. Suleimanov, B. A., Veliyev, E. F., Aliyev, A. A. (2021). Impact of nanoparticle structure on the effectiveness of pickering emulsions for eor applications. ANAS Transactions, (1), 82-92.
  7. Suleimanov, B. A., Veliyev, E. F. (2016). The effect of particle size distribution and the nano-sized additives on the quality of annulus isolation in well cementing. SOCAR proceedings, 4, 4-10.
  8. Suleimanov, B. A., Dyshin, O. A., Veliyev, E. F. (2016, October). Compressive strength of polymer nanogels used for enhanced oil recovery EOR. SPE-181960-MS. In: SPE Russian Petroleum Technology Conference and Exhibition Society of Petroleum Engineers.
  9. Veliyev, E. F., Aliyev, A. A., Mammadbayli, T. E. (2021). Machine learning application to predict the efficiency of water coning prevention. SOCAR Proceedings, 1, 104-113.
  10. Shamilov, V. M., Babayev, E. R., Aliyeva, N. F. (2017). Polymer nanocomposites based on carboxymethylcellulose and nanoparticles (Al and Cu) for enhanced oil recovery. Oil and Gas Territory, 3, 14-15.
  11. Suleimanov, B. A., Ismaylov, F. S., Veliyev, E. F. (2014). On the metal nanoparticles effect on the strength of polymer gels based on carboxymethyl cellulose, applying at oil recovery. Oil Industry, 1, 86-88.
  12. Alsaba, M. T., Al Dushaishi M. F., Abbas A. K. (2020). A comprehensive review of nanoparticles applications in the oil and gas industry. Journal of Petroleum Exploration and Production Technology, 10, 1389-1399.
  13. Shamilov, V. M. (2020). Potential applications of carbon nanomaterials in oil recovery. SOCAR Proceedings, 3, 90-107.
  14. Feng, Y., Liu, S., Liu, H., et al. (2018). Study on mechanical performance of set cement modified with CNT. Drilling Fluid and Completion Fluid, 35(6), 93-97.
  15. Hajiabadi, S. H., Aghaei, H., Kalateh-Aghamohammadi, M., Shorgasthi, M. (2020). An overview on the significance of carbon-based nanomaterials in upstream oil and gas industry. Journal of Petroleum Science and Engineering, 186, 106783.
  16. Hamza, M. F., Sinnathambi, C. M., Merican, Z. M. (2017). Recent advancement of hybrid materials used in chemical enhanced oil recovery (CEOR): A review. IOP Conference Series: Materials Science and Engineering, 206, 012007.
  17. Raman, N. S., Mohanasundaram, P., Seshubabu, N., et al. (2015). Process for simultaneous production of carbon nanotube and a product gas from crude oil and its products. WO Patent 2015101917.
  18. Prasek, J., Drbohlavova, J., Chomoucka, J., et al. (2011). Methods for carbon nanotubes synthesis - review. Journal of Materials Chemistry, 21(40), 15872-15884.


DOI: 10.5510/OGP20220100633

E-mail: valeh.shamilov@socar.az

Sh. P. Kazimov

«OilGasScientificResearchProject» İnstitute, SOCAR, Baku, Azerbaıjan

Enhanced oil recovery in water-flooded and hard  to recover reservoirs


The article is devoted to enhanced oil recovery (EOR) by displacement of residual oil with chemical agents in hard to recover reservoirs. SOCAR Oil Refinery alkaline waste (AW) is used as chemical product for EOR in the researches. Researches were carried out on pure AW and its solutions in different densities. 10% solution of water with AW decreases interfacial tension from 27 mN/m to 1.0 mN/m. PH value respectively increases from 7.5 to 9.5. Then, the researches were performed in simulated reservoir model. Primarly, the interlayer was created from solutions with AW in different densities, and then the displacement was carried out. Final oil recovery rate was 0.453 during oil displacement without AW. This ratio was respectively 0.54, 0.571 and 0.573 during displacement of oil with 5%, 10%, 15% solutions of AW. EOR with AW solution was carried out in QLD4 horizon in Goshanohur area of Balakhany-Sabunchu-Ramana oil field. 2500 tons incremental oil was produced.

Keywords: enhanced oil recovery; residual oil; oil displacement; oil field; well.

References

  1. Sedov, L. I. (1957). Similarity and dimensional methods in mechanics. 4th edition. Moscow: Nedra.
  2. Gasimov, A. M. (2000). Enhancement of oil recovery in hard to recover reservoirs. Baku: Chashioglu.
  3. Veliyev, E. F. (2021). Polymer dispersed system for in-situ fluid diversion. Prospecting and Development of Oil and Gas Fields, 1(78), 61-72.
  4. Suleimanov, B. A., Veliyev, E. F., Naghiyeva, N. V. (2021). Colloidal dispersion gels for in-depth permeability modification. Modern Physics Letters B, 35(01), 2150038.
  5. Suleimanov, B. A., Guseynova, N. I., Veliyev, E. F. (2017, October). Control of displacement front uniformity by fractal dimensions. SPE-187784-MS. In: SPE Russian Petroleum Technology Conference. Society of Petroleum Engineers.
  6. Suleimanov, B. A., Veliyev, E. F., Naghiyeva, N. V. (2020). Preformed particle gels for enhanced oil recovery. International Journal of Modern Physics B, 34(28), 2050260.
  7. Veliyev, E. F., Aliyev, A. A., Mammadbayli, T. E. (2021). Machine learning application to predict the efficiency of water coning prevention. SOCAR Proceedings, 1, 104-113.
  8. Suleimanov, B. A., Latifov, Y. A., Veliyev, E. F., Frampton, H. (2017, November). Low salinity and low hardness alkali water as displacement agent for secondary and tertiary flooding in sandstones. SPE-188998-MS. In: SPE Annual Caspian Technical Conference and Exhibition. Society of Petroleum Engineers.
  9. Ismailov, R. G., Veliev, E. F. (2021). Emulsifying composition for increase of oil recovery efficiency of high viscous oils. Azerbaijan Oil Industry, (5), 22-28.
  10. Veliyev, E. F., Aliyev, A. A. (2021, October). Propagation of nano sized CDG deep into porous media. SPE-207024-MS. In: SPE Annual Caspian Technical Conference. Society of Petroleum Engineers.
  11. Veliyev, E. F. (2021). A combined method of enhanced oil recovery based on ASP technology. Prospecting and Development of Oil and Gas Fields, (4 (81)), 41-48.
  12. Suleimanov, B. A., Veliyev, E. F., & Aliyev, A. A. (2021). Impact of nanoparticle structure on the effectiveness of pickering emulsions for eor applications. ANAS Transactions, 1, 82-92.
  13. Panakhov, G. M., Suleimanov, B. A. (1995). Specific features of the flow of suspensions and oii disperse systems. Colloid Journal, 57(3), 386-390.
  14. Suleimanov, B. А., Askerov, М. S., Valiyev, G. А. (2000). Potential of re-development of horizon PK-5 (north) of Surakhany field. Azerbaijan Oil Industry, (5), 16-21.
  15. Suleimanov, B. А. (1997). Slip effect during filtration of gassed liquid. Colloid Journal, 59(6), 749-753.
  16. Suleimanov, B. А. (2011). Sand plug washing with gassy fluids. SOCAR Proceedings, 1, 30-36.
  17. Suleimanov, B. А., Azizov, Kh. F. (1995). Specific features of the flow of a gassed liquid in a porous body. Colloid Journal, 57(6), 818-823.
  18. Masket, M. (1953). Physical bases of oil production technology. NY-Toronto-London: McGRAW-Hill Co.
  19. Mehdiyev, U. Sh., Kazımov, Sh. P., Gasymly, A. M. (2010).Enhancement of oil recovery using local industrial by-products. Azerbaijan Oil Industry, 3, 22-25.


DOI: 10.5510/OGP20220100634

E-mail: shukurali.kazimov@socar.az

A. R. Deryaev

Scientific-Research Institute of Natural Gas, SC «Turkmengaz», Ashgabat, Turkmenistan

Well design development for multilayer horizons for the simultaneous separate operation by one well


The positive effects of applying the technology for simultaneous separate operation (hereinafter referred to as SSO) include the reduction in capital investments for the construction of wells for each of the operational facilities, the cutback of operating costs and the development period of a multi-layer horizon, the increase in hydrocarbon production and the final oil recovery period from profitable operation of wells. In addition, the use of this technology contributes to increasing the utilization rate of downhole equipment and enhancing the reliability of the downhole device. The simultaneous separate operation technology is economically efficient due to the production of additional oil, a high profitability index and a low payback period.

Keywords: azimuth, zenith angle; off-vertical; well profile; doublelift tubing; liner filter; packers; valves.

References

  1. Gabdulov, R. R., Agofonov, A. A., Slivka, P. I., Nikishov, V. I. (2010). Opyt primeneniya tekhnologij dlya ORE mnogoplastovyh mestorozhdenij v OAO «NK «Rosneft'»». Inzhenernaya praktika, 1, 30-37.
  2. Garipov, O. M., Leonov, V. A., SHarifov, M. 3. (2007). Tekhnologii i oborudovanie dlya odnovremenno razdel'noj zakachki vody v neskol'ko plastov odnoj skvazhinoj. Vestnik nedropol'zovatelya, 17.
  3. Garipov, O. M. (2009). Supervising at development, installation and service of multipacker systems for simultaneously-separate exploration and the general tendencies of hi-tech service development. Oil Industry, 9, 58-61.
  4. Garifov, K. M. (2010). Istoriya i sovremennoe sostoyanie tekhniki i tekhnologii ORE plastov v OAO «Tatneft'». Inzhenernaya praktika, 1, 19-29.
  5. Garifov, K. M., Glukhoed, A. V., Ibragimov, N. G., et al. (2010). Tatneft OAO experience of dual completion technologies. Oil Indystry, 7, 55-57.
  6. Eliyashevskij, I. V., Storonskij, M. N., Orsulyak. YA. M. (1982). Tipovye zadachi i raschety v burenii. Moskva: Nedra.
  7. Kalinin, A. G. (2008). Burenie neftyanyh i gazovyh skvazhin. Moskva: CentrLitNefteGaz.
  8. Garifov, K. M., Gluhoded, A. V., Kubarev, P. N., Balboshin, V. A. (2011). Rezul'taty vnedreniya ORE plastov OAO «Tatneft'». Poslednie razrabotki kompanii po ORE. Inzhenernaya praktika, 3, 4-12.
  9. (1973). Metodicheskie ukazaniya po vyboru konstrukcij neftyanyh i gazovyh skvazhin, proektiruemyh dlya bureniya razvedochnyh i ekspluatacionnyh na ploshchadyah. Moskva: Minnefteprom.
  10. Deryaev, A. R. (2013). Razrabotka konstrukcii skvazhin dlya metoda odnovremenno-razdel'noj ekspluatacii neskol'kih neftyanyh plastov. Nauka i tekhnika v Turkmenistane, 6, 71-77.
  11. Deryaev, A. R., Esedulaev, R. E. (2017) Osnovy tekhnologii bureniya pri osvoenii neftegazovyh plastov metodom ORE. Nauchnaya monografiya. Ashgabat: Ylym.


DOI: 10.5510/OGP20220100635

E-mail: burawtehnik@yandex.com

A. A. Shiraliev

PA «Azneft», SOCAR, Baku, Azerbaijan

Hydrogasdynamic modeling of optimization of underground gas storage development


On the basis of large-scale gas-hydrodynamic balance models, the problem of optimizing the cyclic development of underground gas storage (UGS) facilities has been formulated and solved. An algorithm has been developed that allows optimal control of the UGS development process, taking into account the limitations on the flow rates of certain wells. For its implementation, a specific model structure of the Kalmaz UGS facility was selected. It is shown that optimal regulation of the values of flow rates and depressions of wells ensures minimal flooding of well products during the extraction of total gas, the values of reception and repression of wells ensure maximum removal of the gas-water boundary from the bottom of the well during the injection of total gas.

Keywords: optimization; underground gas storage; extraction; injection; flow rate; depression; repression.

References

  1. Lure, M. V., Didkovskaya, A. S., Varchev, D. V., YAkovleva, N. V. (2004). Podzemnoe hranenie gaza. Moskva: Neft i gaz.
  2. Gill, Ph. E., Murray, W., Wright, M. H. (1982). Practical optimization. United Kingdom: Emerald Group Publishing Limited.
  3. Feyzullaev, H. A. (1992). CHislennoe issledovanie zadach teorii nestatsionarnoy filtratsii gaza i gazokondensatnoy smesi v poristoy srede. Dissertatsiya na soiskanie uchenoy stepeni kandidata tehnicheskih nauk. Baku.
  4. Vyakhirev, R. I., Gritsenko, A. I., Ter-Sarkisov, R. M. (2002). Development and operation of gas fields. Moscow: Nedra-Business Center.
  5. Ermilov, O. M., Remizov, V. V, SHirkovskiy, A. I., CHugunov, L. S. (1996). Fizika plasta, dobyicha i podzemnoe hranenie gaza. Moskva: Nauka.
  6. Agaev, G. S., Palatnik, B. M. (1990). Operativnoe regulirovanie razrabotki krupnoy gazovoy zaleji. Gazovaya promyishlennost, 10, 28-33.
  7. Buzinov, S. N., Umrikin, I. D., Buzinov, S. N., Umrikin, I. D. (1984). Investigations of petroleum and gas wells and pools. Moscow: Nedra.
  8. Vyahirev, R. I. Korataev, YU. P. (1999). Teoriya i opyit razrabotki mestorojdeniy prirodnyih gazov. Moskva: OAO Izdatelstvo Nedra.
  9. Feyzullaev, H. A., Samedova, G. E., Feyzullaeva, N. M. (2021). Optimizatsiya protsessa razrabotki gazokondensatnyih zalejey v rejime istoscheniya. Vestnik BGU. Seriya fiziko-matematicheskih nauk, 3, 59-70.
  10. Gurbanov, A. N. (2014). Povyishenie effektivnosti tehnologii podgotovki gaza k transportu na podzemnyih gazohranilischah Azerbaydjana. Neftegazovaya energetika, 2(22), 57-62.


DOI: 10.5510/OGP20220100636

E-mail: shiraliyev.alam@gmail.com

E. F. Veliyev1,2, A. A. Aliyev1

1«OilGasScientificResearchProject» Institute, SOCAR, Baku, Azerbaijan; 2«Composite Materials» Scientific Research Center, Azerbaijan State University of Economics (UNEC), Baku, Azerbaijan

Comparative analysis of the geopolymer and Portland cement application as plugging material under conditions of incomplete displacement of drilling mud from the annulus


Portland cement is traditionally used in cementing of oil and gas wells. However, Portland cement has a number of shortcomings. The most important of these are the formation of microannuli between the cement plug and the rock or casing, as well as the formation of cracks and permeable channels in the cement matrix. Recent research shows that geopolymer can be a perspective alternate to portlandcement by overcoming beforementioned issues. The article comparatively analyzes the changes in the parameters of plugging materials containing geopolymer and Portland cement while contamination with water-based drilling mud. The results show that geopolymerbased solutions are more resistant to contamination with water-based drilling mud than Portland cement-based solutions. Thus, mixing Portland cement slurry with water-based drilling mud increases its viscosity and fluid loss, and sharply reduces its compressive strength. However, when a geopolymer solution is mixed with a water-based drilling fluid, its viscosity is almost unchanged, its fluid loss is reduced, and reduction in its compressive strength is less than in Portlandcement based material.

Keywords: portland cement; geopolymer; fly ash; cementing; water based mud; mud contamination.

References

  1. Suleimanov, B. A., Veliyev, E. F. (2016). The effect of particle size distribution and the nano-sized additives on the quality of annulus isolation in well cementing. SOCAR Proceedings, 4, 4-10.
  2. Wang, W., Taleghani, A. D. (2014). Three-dimensional analysis of cement sheath integrity around Wellbores. Journal of Petroleum Science and Engineering, 121, 38-51.
  3. Jafariesfad, N., Sangesland, S., Gawel, K., Torsæter, M. (2020). New materials and technologies for life-lasting cement sheath: a review of recent advances. SPE Drilling & Completion, 35(02), 262-278.
  4. Aliev, A. A. (2021). Improving the rheological properties of alkaline-activated geopolymers using water-free fluids. Prospecting and Development of Oil and Gas Fields, 3(80), 60-67.
  5. Davidovits, J. (1994). Properties of geopolymer cements. In First international conference on alkaline cements and concretes. Vol. 1. Kiev State Technical University, Ukraine: Scientific Research Institute on Binders and Materials.
  6. (2003). Fly ash facts for highway engineers. US Department of Transportation, Federal Highway Administration. American Coal Ash Association.
  7. Kong, D. L., Sanjayan, J. G. (2008). Damage behavior of geopolymer composites exposed to elevated temperatures. Cement and Concrete Composites, 30(10), 986-991.
  8. Adjei, S., Elkatatny, S., Aggrey, W. N., Abdelraouf, Y. (2022). Geopolymer as the future oil-well cement: A review. Journal of Petroleum Science and Engineering, 208, 109485.
  9. Leong, H. Y., Ong, D. E. L., Sanjayan, J. G., Nazari, A. (2016). The effect of different Na2O and K2O ratios of alkali activator on compressive strength of fly ash based-geopolymer. Construction and Building Materials, 106, 500-511.
  10. Al-Bakari, A. M., Kareem, A., Myint, S. (2012). Optimization of alkaline activator/fly ash ratio on the compressive strength of fly ash-based geopolymer. Kanger: University Malaysia Perlis (UniMAP).
  11. Ridha, S., Yerikania, U. (2015). The strength compatibility of nano-SiO2 geopolymer cement for oil well under HPHT conditions. Journal of Civil Engineering Research, 5(4A), 6-10.
  12. Sugumaran, M. (2015, October). Study on effect of low calcium fly ash on geopolymer cement for oil well cementing. SPE-176454-MS. In: SPE/IATMI Asia Pacific Oil & Gas Conference and Exhibition. Society of Petroleum Engineers.
  13. Ridha, S., Abd Hamid, A. I., Halim, A. A., Zamzuri, N. A. (2018, April). Elasticity and expansion test performance of geopolymer as oil well cement. IOP Conference Series: Earth and Environmental Science, 140(1), 012147.
  14. Uehara, M. (2010). New concrete with low environmental load using the geopolymer method. Quarterly Report of RTRI, 51(1), 1-7.
  15. Thokchom, S., Ghosh, P., Ghosh, S. (2009). Acid resistance of fly ash based geopolymer mortars. International Journal of Recent Trends in Engineering, 1(6), 36.
  16. Arbad, N., Teodoriu, C. (2020). A review of recent research on contamination of oil well cement with oil-based drilling fluid and the need of new and accurate correlations. ChemEngineering, 4(2), 28.
  17. Vipulanandan, C., Heidari, M., Qu, Q., et al. (2014, May). Behavior of piezoresistive smart cement contaminated with oil based drilling mud. OTC-25200-MS. In: Offshore Technology Conference. Society of Petroleum Engineers.
  18. Zheng, Y., She, C., Yao, K., et al. (2015). Contamination effects of drilling fluid additives on cement slurry. Natural Gas Industry B, 2(4), 354-359.
  19. Morgan, B. E., Dumbauld, G. K. (1952). Use of activated charcoal in cement to combat effects of contamination by drilling muds. Journal of Petroleum Technology, 4(09), 225-232.
  20. EI-Sayed, H. (1995). Effect of drilling muds contamination on cement slurry properties. In: Fourth Saudi
    Engineering Conference.
  21. Arbad, N., Rincon, F., Teodoriu, C., Amani, M. (2021). Experimental investigation of deterioration in mechanical properties of oil-based mud (OBM) contaminated API cement slurries & correlations for ultrasonic cement analysis. Journal of Petroleum Science and Engineering, 205, 108909.
  22. Katende, A., Lu, Y., Bunger, A., Radonjic, M. (2020). Experimental quantification of the effect of oil based drilling fluid contamination on properties of wellbore cement. Journal of Natural Gas Science and Engineering, 79, 103328.
  23. Liu, X., Aughenbaugh, K., Nair, S., et al. (2016, September). Solidification of synthetic-based drilling mud using geopolymers. SPE-180325-MS. In: SPE Deepwater Drilling and Completions Conference. Society of Petroleum Engineers.
  24. Arbad, N., Rincon, F., Teodoriu, C., Amani, M. (2021, November). Mechanical properties of API class C cement contaminated with oil-based mud OBM at elevated temperatures and early curing time. SPE-204302-MS. In: SPE International Conference on Oilfield Chemistry. Society of Petroleum Engineers.
  25. (2019). API RP 13B-1. Field Testing Water-based Drilling Fluids. The American Petroleum Institute.
  26. (2019). API SPEC 10A. Cements and materials for well cementing. The American Petroleum Institute.
  27. (2013). API RP 10B-2. Recommended practice for testing well cements. The American Petroleum Institute.
  28. Pang, X., Boul, P. J., Jimenez, W. C. (2014). Nanosilicas as accelerators in oilwell cementing at low temperatures. SPE Drilling & Completion, 29(01), 98-105.
  29. Maier, L. F. (1965). Understanding surface casing waiting-on-cement time. Journal of Canadian Petroleum Technology, 4(03), 140-147.
  30. Suppiah, R. R., Rahman, S. H. A., Irawan, S., Shafiq, N. (2016, November). Development of new formulation of geopolymer cement for oil well cementing. IPTC-18757-MS. In: International Petroleum Technology Conference. Society of Petroleum Engineers.


DOI: 10.5510/OGP20220100637

E-mail: elchinf.veliyev@socar.az

N. A. Buznikov1, V. A. Suleymanov2

1«Gazprom VNIIGAZ» LLC, Razvilka, Moscow Region, Russia; 2Gubkin Russian State University of Oil and Gas (National Research University), Moscow, Russia

Specific features of the multiphase fluid subsea pipeline operation at the liquid accumulation mode


The operation modes of an extensional subsea pipeline of multiphase fluid at the initial stage of the offshore gas condensate field development under the conditions of liquid accumulation are studied. By means of the dynamic simulation of the slug flow mode, the frequency and volume of liquid plugs removed from the pipeline are analyzed as a function of the gas flow rate. It is demonstrated that with a decrease of the gas flow rate, the steadystate hydraulic calculations predict significantly lower values of the liquid volume flow rate at the pipeline outlet compared to the results of the dynamic simulation. The dynamics of the liquid removal from the pipeline with an increase of the gas flow rate is studied. It is shown that the surge liquid volume increases sharply at a rapid growth of the gas flow rate, which leads to restrictions on the increase in the well flow rate.

Keywords: subsea pipeline; natural gas; multiphase fluid; liquid accumulation; slug flow.

References

  1. Bai, Y., Bai, Q. (2005). Subsea pipelines and risers. Amsterdam: Elsevier.
  2. Kharchenko, Y. A., Gritchenko, A. I. (2016). Hydrodynamic of gas-liquid flow and its application in the development of oil and gas offshore fields. Moscow: Gubkin Russian State University of Oil and Gas (NRU).
  3. Bendiksen, K. H., Malnes, D., Moe, R., Nuland, S. (1991). The dynamic two-fluid model OLGA: Theory and applications. SPE Production Engineering, 6(2), 171–180.
  4. Ellul, I. R. (2010, May). Dynamic multiphase simulation – the state of play. PSIG–1005. In: 41th PSIG Annual Meeting.
  5. Belt, R., Djoric, B., Kalali, S., et al. (2011, June). Comparison of commercial multiphase flow simulators with experimental and field databases. BHR-2011-I2. In: 15th International Conference on Multiphase Production Technology.
  6. Aziz, I. A. B. A., Brandt, I., Gunasekera, D., et al. (2015). Multiphase flow simulation – optimizing field productivity. Oilfield Review, 27(1), 26–37.
  7. Soave, G. (1972). Equilibrium constants from a modified Redlich–Kwong equation of state. Chemical Engineering Science, 27(6), 1197–1203.
  8. Péneloux, A., Rauzy, E., Fréze, R. (1982). A consistent correlation for Redlich–Kwong–Soave volumes. Fluid Phase Equilibria, 8(1), 7–23.
  9. Suleymanov, V. A., Buznikov, N. A. (2021). Multiphase flow assurance in an extensional subsea pipeline: Effects of the transported fluid composition and the pipeline route profile. SOCAR Proceedings, 3, 92-99.


DOI: 10.5510/OGP20220100638

E-mail: suleymanov.v@gubkin.ru