Research of conditions of supporting underground pipeline and loads on protective coating

During the construction and operation of underground pipelines, there is a need to develop projects for the engineering protection of insulation coatings from the mechanical effects of coarse soil. The task is most relevant with significant variability of the laying conditions along the length of the route. In particular, the difficult laying conditions include the passage of the route in the areas of distribution of rocky, gravelly and permafrost soils. The appropriateness of applying the methods of engineering protection of the insulation coating from mechanical stress should be justified both economically and in terms of technical and operational indicators. Therefore, the task of analyzing the conditions of support of the underground pipeline and the study of the created forces in the supporting part of the pipeline is very relevant and characterized by insufficient knowledge. The article analyzes the effect of bedding soil and backfill on the amount of force arising in the protective coating of the supporting part of the pipeline in the presence of unevenness of the base and its particle size distribution. The results of modeling the contact problem using models of a discrete (granular) medium at the base of the pipeline are presented. The wall thickness of the pipes affects the change in created force in the supporting part of the pipeline (for pipes are 1 420 mm the maximum difference is 22 %). In the presence of unevenness of the base, the force in the supporting part can increase by 3–5 times.

1. Voronin, V. I., & Voronina, T. S. (1990) Izolyatsionnye pokrytiya podzemnykh nefteprovodov, Moscow, VNIIOENG Publ., 200 р. (In Russian).

2. Gizzatullin, R. R. (2003) Usovershenstvovanie metoda zashchity magistral'nykh truboprovodov ot korrozii v trassovykh usloviyakh na osnove razrabotannykh novykh izolyatsionnykh materialov. Аvtoref. dis. … dokt.tekhn. nauk. Ufa, 40 p. (In Russian).

3. Popov, V. A., Lukin, E. S., & Istomin, A. I. (2013). Metody i tekhnicheskie sredstva kontrolya kachestva zashchitnykh pokrytiy ob"ektov neftegazovoy otrasli na raznykh stadiyakh ikh zhiznennogo tsikla. Korroziya territorii neftegaz, 2(25)), pp. 42-44. (In Russian).

4. Khasanov, R. R. (2014) Problems of protective coatings of pipelines on the example of gas trunk pipelines of Western Kazakhstan. Neftegazovoe delo, 12(1), pp. 97-102 pp. (In Russian).

5. Vinogradov, S. V. (1980) Raschet podzemnykh truboprovodov na vneshnie nagruzki.Moscow, Stroyizdat Publ., 135 p. (In Russian).

6. Semenchenko, V. K. (Ed.) (1982). Izolyatsiya truboprovodov. Moscow, VNIIST, 154 p.(In Russian).

7. Veliyulin, I. I., & Khasanov R. R. (2019). The Effect of Gas-Line Wrapping Alternativeson Stress-Corrosion Resistance. Oil and Gas Territory, (1-2), pp. 52-56. (In Russian).

8. Brykov, E. E. (2008) The application of geosynthetical materials for protection of pipelines corrosion-resistant coating from galling. Truboprovodnyy transport: teoriya i praktika, (1(11)). pp. 38-45. (In Russian).

9. Matsyuk, R. A. Otsenka effektivnosti icpytaniy zashchitnykh pokrytiy truboprovodovmetodom penetratsii. (2018). Nadezhnost' i bezopasnost' magistral'nogo truboprovodnogo transporta. Sbornik tezisov IX Mezhdunarodnoy nauchno-tekhnicheskoy konferentsii (Novopolotsk, December 18-20, 2018). Novopolotsk, pp. 51-52. (In Russian).

10. Medvedeva, M. L., Muradov, A. V., & Prygaev, A. K. (2013). Korroziya i zashchita magistral'nykh truboprovodov i rezervuarovю Moscow, 250 p. (In Russian).

11. Pouraria, H., Sea, J. K., & Palk, J. K. (2016). CFD Simulation of the Effect of DifferentOils on Water Wetting and Internal Corrosion of Oil Pipelines. Proceedings of the ASME 2016 35th International Conference on Ocean, Offshore and Arctic Engineering, 5. UNSP V005T04A023. (In English). DOI: 10.1115/OMAE2016-54755

12. Datta, Sh., & Sarkar, Sh. (2016). A review on different pipeline fault detection methods.Journal of Loss Prevention in the Process Industries, 41, pp. 97–106. (In English). DOI: 10.1016/j.jlp.2016.03.010

13. Kandaurov, I. I. (1966). Mekhanika zernistykh sred i ee primenenie v stroitel'stve. Leningrad, Stroyizdat Publ., 320 p. (In Russian).

14. Kandaurov, I. I. (1988). Mekhanika zernistykh sred i eeprimenenie v stroitel'stve. 2ndedition, revised and supplemented. Leningrad, Stroyizdat, 280 p. (In Russian).

15. Litvinishen, E. (1955). Displacement of bulk media as a stochastic process. Bulletin ofthe Polish Academy of sciences. Technical sciences, (4). (In English).

16. Litwiniszyn, J. (1974). Stochastic methods in mechanics of granular bodies. Wien,Springer, 113 p. (In English).

17. Muller, R. A. (1962). K statisticheskoy teorii raspredeleniya napryazheniy v zernistomgruntovom osnovanii. Soil Mechanics and Foundation Engeneering, (4). (In Russian), pp. 4-6.

18. Brzakala, W. (1988). On propagation of shear stress in Kandaurov granular medium.Bulletin of the Polis Academy of sciences. Technical sciences, 36(7-9), pp. 407-413. (In English).

19. Matysiak, S. J. (1984). Distribution of stresses in the Kandaurov granular solid due to arigid puuch. Studia geotechnical et mechanica, 6(4), pp. 3-9. (In English).

20. Matysiak, S. J., Pusz, P. (1985). Axisymmetric Boussinesq problem for granular halfspace. Bulletin of the Polish Academy of sciences. Technical sciences, 33(7-8), pp. 351-358. (In English).

21. Matsyuk, R. A. (2017). Evaluation of the influence of the uneven base on a protectivecoating of underground pipeline. Truboprovodnyy transport: teoriya i praktika. (6(64)). pp. 56-59. (In Russian).