Влияние агрессивных сред на прочностные характеристики стеклопластиковых и углепластиковых композитов, используемых в нефтегазовой промышленности

Авторы

D.A. Kornienko ¹ , Yu.S. Dubinov ² , P.E. Alexandrina ²

¹ Сколковский институт науки и технологий (Сколтех), территория инновационного центра "Сколково", Большой бульвар, 30, стр. 1, Москва, 121205, Россия

² Российский государственный университет нефти и газа (национальный исследовательский университет) имени И.М. Губкина, Ленинский проспект, 65, корп. 1, Москва, 119991, Россия

10.17586/2687-0568-2025-7-1-1-9

Rev. Adv. Mater. Technol., 2025, vol. 7, no. 1, pp. 1–9

Аннотация

Протяженность российской нефтегазопроводной системы составляет более 290000 км; она используется для транспортировки воды, нефти, газа и нефтепродуктов. Несмотря на то, что расчетный срок службы этих трубопроводов составляет 30 лет, фактический срок службы часто колеблется от 10 до 20 лет из-за суровых условий эксплуатации, при этом поломки возникают еще раньше. Использование инновационных материалов таких как металлические и неметаллические композиты, в перспективе, может продлить срок эксплуатации нефтегазового оборудования. Однако недостаточная изученность их взаимодействия с агрессивной средой и отсутствие единых стандартов затрудняют масштабное внедрение данных материалов. В данной работе были исследованы изменения предела прочности и относительного удлинения неметаллических композиционных материалов после воздействия на образцы рабочих сред с различной кислотностью и химическим составом, получены уравнения зависимостей

Ключевые слова

слоистые неметаллические композиты; стеклопластики; углепластики; агрессивная среда; стойкость к коррозии

Ссылки

1.    S. Ebadzadsahraei, M.H. Vakili, Comparison of Corrosion Resistance of Fiberglass/Epoxy and Fiberglass/Polyester Composite Pipes for Application in Natural Gas Transportation, Journal of Pipeline Systems Engineering and Practice, 2019, vol. 10, no. 3, pp. 8-15.
2.    İ.Y. Sülü, Ş. Temiz, Mechanical behavior of pressurized composite pipes made of various materials, Materials Testing, 2021, vol. 62, no. 4, pp. 38-52.
3.    M.Y. Abdellah, R. Alfattani, I.A. Alnaser, G.T. Abdel-Jaber, Stress Distribution and Fracture Toughness of Underground Reinforced Plastic Pipe Composite, Polymers, 2021, vol. 13, no. 13, art. no. 2194.
4.    K. Yu, E.V. Morozov, M.A. Ashraf, K. Shankar, Analysis of flexural behavior of reinforced thermoplastic pipes considering material nonlinearity, Composite Structures, 2015, vol. 119, pp. 385-393.
5.    D.V. Berkov, I.I. Kostyuk, P.E. Yudin, A.G. Verevkin, Possibility assessment for using protective coatings and polymer materials on tubing to prevent inorganic scaling on the inner surface of pipes, International Review of Applied Sciences and Engineering, 2024, in press (available online).
6.    M.V. Bogatov, P.E. Yudin, A.G. Verevkin, D.V. Berkov, Prevention of the formation of asphalt, resin and paraffin deposits on the surface of tubing by applying internal coatings, Petroleum Engineering, 2022, vol. 20, no. 1, pp. 74-81 (in Russian).
7.    X. Chen, H. Wang, C. Wang, W. Zhang, C. Lv, Y. Zhu, A novel antiscaling and anti-corrosive polymer-based functional coating, Journal of the Taiwan Institute of Chemical Engineers, 2019, vol. 97, pp. 397-405.
8.    A.A. Hijies, F. Waluyo, K. Singh, A. Benslimani, Innovative Approach to Enhanced Well Integrity Evaluation in Unconventional Completions with Fiberglass Casings, Paper presented at the International Petroleum Technology Conference, Bangkok, Thailand, March 2023.
9.    F. Aichinger, M.-H. Beddelem, G. Germain, L. Hirsinger, L. Gerbaud, R. Studer, Drilling Inside Fiberglass Casing, Wear Prediction and Management in Geothermal Wells, Paper presented at the IADC/SPE Asia Pacific Drilling Technology Conference and Exhibition, Bangkok, Thailand, August 2022.
10.    R. Atlasov, M. Nikolaeva, V. Karamzin, Development of Drilling and Casing Technologies for Permafrost Areas, IOP Conference Series: Earth and Environmental Science, 2019, vol. 272, art. no. 022078.
11.    D.S. Alexandrova, I.V. Zlobina, A.S. Egorov, A.V. Anisimov, Influence of unfavorable climatic factors characteristic of the arctic zone on the properties of polymeric materials and composites: a review, Voprosy Materialovedeniya, 2023, no. 4(116), pp. 144-168 (in Russian).
12.    I.M. Zaripov, A.R. Iskhakov, R.I. Kateev, A.M. Zaripov, Experience in the construction of wells with an operational column made up of fiberglass casing pipes in PJSC Tatneft, Neftyanoe Khozyaystvo, 2018, no. 7, pp. 18-19 (in Russian).
13.    Yu.A. Gavrilyuk, A.A. Agafonov, D.A. Nazarov, V.K. Miller, Case history of fiber-glass pipes at the fields of Udmurtneft JSC, ROSNEFT Scientific and Technical Newsletter (Nauchno-technicheskiy Vestnik OAO "NK "Rosneft"), 2014, no. 1, pp. 44-47 (in Russian).
14.    C. Carpenter, Nonmetallic-Based Tubulars Provide Superior Integrity, Cost Savings, Journal of Petroleum Technology, 2024, vol. 76, no. 7, pp. 82-84.
15.    Y. Chao, Y. Ji, D. Zang, Z. Li, H. Wang, Y. Ren, Research on high-power and high-efficiency emission of cross-well electromagnetic logging, Geophysics, 2024, vol. 89, no. 4, pp. D243-D254.
16.    V. Aleksandrovych, O. Havryliuk, V. Sukhov, The impact of complex engineering and geological conditions on the durability of the polymer pipeline, Visnyk of V.N. Karazin Kharkiv National University, Series "Geology. Geography. Ecology", 2022, no. 57, pp. 8-16.
17.    D.A. Fedoseev, I.N. Lyapin, M.E. Koval, G.G. Gilaev, The potential of using casing pipes made of composite materials, Onshore and Offshore Oil and Gas Well Construction, 2021, no. 3(339), pp. 34-38 (in Russian).
18.    S. Heintz, Norman Wells field replaces steel flowlines with fiberglass, Oil and Gas Journal, 2005, vol. 103, no. 24, pp. 39-41.
19.    G.G. Goicoechea, N.G. Pérez de Eulate, M.U. Andia, A.E. Arruti, F.J. Vallejo Rasero, Development and validation of an automatic manufacturing process for fiberglass composites, DYNA, 2023, vol. 98, no. 5, pp. 495-498.
20.    Y. Guo, M. Zhou, G.-Z. Yin, E. Kalali, N. Wang, D.-Y. Wang, Basalt Fiber-Based Flame Retardant Epoxy Composites: Preparation, Thermal Properties, and Flame Retardancy, Materials, 2021, vol. 14, no. 4, art. no. 902.
21.    M. Megahed, A. Fathy, D. Morsy, F. Shehata, Mechanical Performance of glass/epoxy composites enhanced by micro- and nanosized aluminum particles, Journal of Industrial Textiles, 2021, vol. 51, no. 1, pp. 68-92.
22.    A.K. Prygaev, Yu.S. Dubinov, D.A. Kornienko, A.N. Galansky, The study of the rotation angle of the matrix layer in nonmetallic composites in the manufacture of pipes and reservoirs for liquefied natural gas, Problems of Gathering Treatment and Transportation of Oil and Oil Products, 2023, no. 1(141), pp. 214-222 (in Russian).
23.    GOST 32656-2017. Polymer composites. Test methods. Tensile test methods, Standartinform, Moscow, 2017, 31 p. (in Russian).
24.    GOST 51858-2020. Crude petroleum. General specifications, Standartinform, Moscow, 2020, 16 p. (in Russian).
25.    M. Schoßig, C. Bierögel, W. Grellmann, T. Mecklenburg, Mechanical behavior of glass-fiber reinforced thermoplastic materials under high strain rates, Polymer Testing, 2008, vol. 27, no. 7, pp. 893-900.
26.    S. Elshafie, G. Whittleston, Evaluating the Efficiency of Basalt and Glass Fibres on Resisting the Alkaline, Acid, and Thermal Environments, American Journal of Materials Science, 2016, vol. 6, no. 1, pp. 19-34.
27.    Y. Ou, D. Zhu, Tensile behavior of glass fiber reinforced composite at different strain rates and temperatures, Construction and Building Materials, 2015, vol. 96, no. 2, pp. 648-656.
28.    Y. Ou, D. Zhu, H. Zhang, L. Huang, Y. Yao, B. Mobasher, Mechanical characterization of the tensile properties of glass fiber and its reinforced polymer (GFRP) composites under varying strain rates and temperatures, Polymers, 2016, vol. 8, no. 5, art. no. 196.
29.    K. Naresh, K. Shankar, R. Velmurugan, N.K. Gupta, Statistical analysis of the tensile strength of GFRP, CFRP and hybrid composites, Thin-Walled Structures, 2018, vol. 126, pp. 150-161.
30.    A.E. Armenakas, C.A. Sciammarella, Experimental investigation of the failure mechanism of fiber-reinforced composites subjected to uniaxial tension, Experimental Mechanics, 1973, vol. 13, no. 2, pp. 49-58.
31.    G. Hota, W. Barker, A. Manalo, Degradation mechanism of glass fiber/vinylester-based composite materials under accelerated and natural aging, Construction and Building Materials, 2020, vol. 256, art. no. 119462.
32.    K. Deng, B. Luo, H. Suo, K. Zhang, L. Wang, H. Cheng, B. Liang, Characterization of material degradation mechanism of carbon fiber reinforced epoxy resin composites under ultraviolet radiation and salt-fog synergistic environment, Polymer Composites, 2024, vol. 45, no. 1, pp. 805-824.

Том 7, № 1

Страницы 1-9

Файлы

текст статьи

аннотация

XML файл

История

Поступила в редакцию: 12 Января 2025

Принята: 01 Февраля 2025

Доступна онлайн: 05 Февраля 2025

© 2025 ITMO University.
This is an open access article under the terms
of the CC BY-NC 4.0 license.
Metadata is available under the terms of the CC BY 4.0 license