Журнал Российского общества по неразрушающему контролю и технической диагностике
The journal of the Russian society for non-destructive testing and technical diagnostic
 
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23 | 11 | 2024
2020, 12 December

DOI: 10.14489/td.2020.12.pp.058-063

Sidorov M. M., Golikov N. I., Tihonov R. P.
EVALUATION OF THE STRESSED DEFORMED STATE OF MAIN GAS PIPELINES RUNNING IN PERMANENTLY FROZEN GROUNDS
(pp. 58-63)

Abstract. The work evaluates the stress deformed state of the section of the interfield gas collecting main, running in permanently frozen grounds. The object of research is a section of a pipeline with an arched discharge formed as a result of loss of stability as a result of thermal erosion of permanently frozen grounds to disturbance of the vegetation cover. The determination of stresses was carried out by the X-ray method using portable equipment. The experimental data were analyzed with the calculated. The calculated data were obtained by measuring the spatial position of the gas pipeline section. The obtained values of the acting stresses and the estimates of the critical indicators of the gas pipeline monitoring section made it possible to reasonably estimate the stress state. The methodology for determining the acting stresses of pipelines using portable X-ray equipment can be successfully applied to estimate the stressed-deformed state of pipeline systems running in the zone of permafrost.

Keywords: stressed deformed state, permanently frozen grounds, main gas pipelines, mechanical stresses, X-ray method.

M. M. Sidorov, N. I. Golikov, R. P. Tihonov (Larionov Institute of Physical and Technical Problems of the North, the Siberian Branch of the Russian Academy of Science, Federal Research Center ‘Yakut Scientific Center of the Siberian Branch of the Russian Academy of Sciences’, Yakutsk, Russia)

1. Kapitonova T. A., Struchkova G. P., Levin A. I., Nikolaeva M. V. (2019). Analysis of the statistics of accidents and failures of the Mastakh - Berge - Yakutsk main gas pipeline. Neftegazovoe delo, Vol. 17, (6), pp. 49 – 57. [in Russian language] DOI: 10.17122/ngdelo-2019-6-49-57.
2. Chuhareva N. V., Tihonova T. V., Mironov S. A. (2011). Analysis of the causes of accidents during the operation of gas pipelines in the Far North in the period from 2000 to 2010. Neftegazovoe delo, (3), pp. 231 – 243. [in Russian language]
3. Bol'shakov A. M., Golikov N. I., Syromyatnikova A. S. et al. (2007). Destruction and damage during long-term operation of oil and gas industry facilities. Gazovaya promyshlennost', (7), pp. 89 – 91. [in Russian language]
4. Ermolenko Yu. G., Bol'shakov A. M., Cheremkin M. K., Tugi R. E. (2003). On the technical condition of the main gas pipelines of Yakutia. Bezopasnost' truda v promyshlennosti, (10), pp. 5 – 7. [in Russian language]
5. Islamov R. R., Aginey R. V., Isupova E. V. (2017). Analysis of means and methods for monitoring the stress state of underground oil and gas pipelines operating in difficult engineering and geological conditions. Transport i hranenie nefteproduktov i uglevodorodnogo syr'ya, (6), pp. 31 – 40. [in Russian language]
6. Antonov A. A., Steklov O. I., Antonov A. A. (jr.), Sidorin Yг. V. (2010). Study of technological residual stresses in welded joints of main pipelines. Zagotovitel'nye proizvodstva v mashinostroenii, (3), pp. 13 – 19. [in Russian language]
7. Withers P. J., Bhadeshia H. K. D. H. (2001). Residual stress. Part 1. Measurement techniques. Materials Science and Technology, Vol. 17, pp. 355 – 365.
8. Yablokova N. A., Trofimov V. V. (2013). Investigation of the stress-strain state of compressor blades by methods of X-ray structural analysis. Zavodskaya laboratoriya. Diagnostiki materialov, Vol. 79, (1), pp. 36 – 44. [in Russian language]
9. Javadi Y., Pirzaman H. S., Raeisi M. H., Najafabadi M. A. (2013). Ultrasonic inspection of a welded stainless steel pipe to evaluate residual stresses through thickness. Materials and Design, Vol. 49, pp. 591 – 601.
10. Antipov B. N., Angalev A. M., Vengrinovich V. L. et al. (2008). Equipment for monitoring the stress-strain state of pipelines and structures. Oborudovanie i tekhnologii dlya neftegazovogo kompleksa, (3), pp. 66 – 69. [in Russian language]
11. Vasil'ev D. M., Trofimov V. V. (1988). The current state of the X-ray method for measuring macrostresses. Zavodskaya laboratoriya, (7), pp. 20 – 29. [in Russian language]
12. Gurova T., Estefen S. F., Leontiev A. et al. (2017). De Time-dependent redistribution behavior of residual stress after repair welding. Weld World, 61, pp. 507–515.
13. Yasin E. M., Chernikin V. I. (1967). Stability of underground pipelines. Moscow: Nedra. [in Russian language]

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