Experience in creating the oil production tubing with thermal insulation based on basalt and glass fibers
Authors: Komkov M.A., Tarasov V.A.
Published in issue: #10(130)/2022
DOI: 10.18698/2308-6033-2022-10-2222
Category: Metallurgy and Science of Materials | Chapter: Powder Metallurgy and Composite Materials
The paper presents results of design, development, manufacturing technologies, and experimental studies of prototypes of the multilayer tubing with thermal insulation from short basalt fibers and an outer shell of wound glass fiber. New multilayer tube was designed with hardening of the composite outer layer in the section exposed to hydraulic tongs impact during installation and tubes’ lowering into the oil wells. It was demonstrated that high-temperature and low-density thermal insulation of the tubes could be provided with the short basalt superthin fibers by grinding and cleaning them from impurities using the liquid method. Thermal and strength tests of the tube samples with the shortened regular part were made on the certified equipment and showed permissible temperature on the coating outer surface with more than twice higher safety margin of the fiberglass shell regarding tension and torsion.
References
[1] Suchkov B.M. Temperaturnye rezhimy rabotayuschikh skvazhin i teplovye metody dobychi nefti [Temperature regimes of the operating wells and thermal methods in oil production]. Izhevsk, Institut kompiuternykh issledovaniy, 2007, 408 p.
[2] Kudinov V.I. Osnovy neftegazopromyslovogo dela [Fundamentals of the oil and gas industry]. Moscow—Izhevsk, Institut kompiuternykh issledovaniy, 2004, 720 p.
[3] Moiseev V.A., Andrienko V.G., Frolov V.I., Klokotov Yu.N. Teploizolyatsiya neftepromyslovykh paroprovodov dlya transportirovki para s zakriticheskimi parametrami [Thermal insulation of the oilfield steam pipelines for transporting steam with supercritical parameters]. Neftyanoe khozyaistvo — Oil Industry, 2012, no. 1, pp. 92–94.
[4] Moiseev V.A., Moiseev A.V., Frolov V.I., Komkov M.A., Zelinsky R.V. Termobaryernoe pokrytie dlya termoisolirovannykh NKT novogo pokoleniya [Thermal barrier coating for thermally insulated tubing of new generation]. Birzha intellektualnoy sobstevennosti — Intellectual Property Exchange, 2013, vol. XII, no. 11, pp. 17–20.
[5] Komkov M.A., Badanina Yu.V., Timofeev M.P. Razrabotka i issledovanie termostoykikh pokrytiy truboprovodov iz korotkikh bazaltovykh volokon [Development and research of heat-resistant pipeline coatings of short basalt fibers]. Inzhenerny zhurnal: nauka i innovatsii — Engineering Journal: Science and Innovation, 2014, iss. 2. http://dx.doi.org/10.18698/2308-6033-2014-2-1203
[6] Badanina Yu.V., Komkov M.A., Tarasov V.A., Timofeev M.P., Moiseev A.V. Modelirovanie i eksperimentalnoye opredelenie tekhnologicheskikh parametrov zhidkostnogo formirovaniya bazaltovoy teploizolyatsii nasosno-kompressornykh trub [Simulation and experimental determination of technological parameters of the liquid molding of the tubing basalt thermal insulation]. Nauka i obrazovanie. MGTU im. N.E. Baumana. Elektron. Zhurnal — Science and education. BMSTU Electronic journal, 2015, no. 04, pp. 13–28. https://doi.org/10.7463/0315.0761820
[7] Komkov M.A., Moiseev V.A., Tarasov V.A., Timofeev M.P. Umenshenie negativnogo vliyaniya na biosferu dobychi tyazheloy nefti i ekologicheski chistaya tekhnologiya zakachki para sverkhkriticheskikh parametrov v neftyanye plasty za schet sozdaniya novykh nasosno-kompressornykh trub s ekologicheski chistym teplozaschitnym pokrytiem [Reducing negative impact on the heavy oil production biosphere and environmentally friendly technology for pumping supercritical steam into the oil reservoirs by creating new tubing with environmentally friendly heat-protection coating]. Geofizicheskie protsessy i biosfera — Geophysical processes and biosphere, 2015, vol. 14, no. 1, pp. 70–79.
[8] Komkov M.A., Badanina Yu.V., Tarasov V.A., Filimonov A.S. Analiz strukturnykh i teplofizicheskikh kharakteristik vysokoporistoy bazaltovoy teploizolyatsii nasosno-kompressornykh trub [Analysis of structural and thermophysical characteristics of the highly porous basalt thermal insulation for tubing]. Inzhenerny zhurnal: nauka i innovatsii — Engineering Journal: Science and Innovation, 2017, iss. 1 (61). http://dx.doi.org/10.18698/2308-6033-2017-1-1575
[9] Gofin M.Ya. Zharostoykie i teplozaschitnye konstruktsii mnogorazovykh aerokosmicheskikh apparatov [Heat-resistant and heat-shielding structures of reusable aerospace vehicles]. Moscow, CJSC TF Mir, 2003, 671 p.
[10] Komkov M.A., Bolotin Yu.Z., Vasileva T.V., Zarubina O.V. Razrabotka i eksperimentalnye issledovaniya teploizoliruyuschikh pokrytiy nasosno-kompressornykh trub na osnove bazaltovykh i steklyannykh volokon [Development and experimental studies of heat-insulating coatings for tubing based on basalt and glass fibers]. Inzhenerny zhurnal: nauka i innovatsii — Engineering Journal: Science and Innovation, 2019, iss. 7. http://dx.doi.org/10.18698/2308-6033-2019-7-1903
[11] Komkov M.A., Timofeev M.P., Larionova A.V. Otsenka ekspluatatsionnykh kharakteristik korotkovoloknistoy bazaltovoy teploizolyatsii pri kriogennykh temperaturakh [Evaluation of performance characteristics of the short-fiber basalt thermal insulation at cryogenic temperatures]. Izvestiya vysshikh uchebnykh zavedeniy. Mashinostroyenie — BMSTU Journal of Mechanical Engineering, 2020, no. 7, pp. 59–68. https://doi.org/10.18698/0536-1044-2020-7-59-68