FACTOR MODEL OF VIBRODYNAMIC LOAD EFFECT ON PIPELINE RELIABILITY
Abstract and keywords
Abstract (English):
Purpose: To build a factor model of vibrodynamic loading influence on pipeline reliability based on the results of laboratory tests carried out taking into account the amplitude-frequency characteristics of the vibration process of the operating pipeline, obtained during full-scale tests at the railway station. On the basis of the factor model to determine the most significant factors affecting the reliability of pipelines under the action of vibrodynamic loading and to propose ways to improve their reliability. Methods: The plan of fractional factor experiment of 25-2 type was used to carry out laboratory tests of pipeline reliability under the influence of stresses of familiar constant cycle. The experiments were carried out on a test bench with a pulsating cylinder of type PC with a maximum load of 200 kN. Voltages were applied to the pipeline under test from control panels of static (from soil) and dynamic (from rolling stock) loads. Impulse shape was sinusoidal, the closest to natural one, cycle frequency — 300 c/min. The regression equation coefficients were calculated on a computer using the multiple linear correlation program. The significance of the regression coefficients was assessed by Student's test. Fisher's test was used to check the adequacy of the model to the experimental data. Adequacy of the regression equation to the physics of the phenomenon was tested using Student's test. Results: Tests of the pipeline with application of fractional factor experiment of 25-2 type allowed to build a factor model of the process under study in the form of polynomial of the first degree. It has been established that the main factors influencing pipeline reliability under vibrodynamic loading are train load, vibration amplitude of the pipeline and the depth of its embedding. The vibration frequency of the pipeline has no significant influence on the pipeline reliability. However, from the regression equation it follows that the pipeline vibration frequency depends on its diameter. Practical significance: The equation of linear regression is obtained, which is transformed by switching from coded values of factors to natural values, which can be used for practical purposes to determine the intensity of failures and the duration of operation of pipelines between failures.

Keywords:
Factor influence model, experiment planning, factor matrix, amplitude-frequency characteristics of the oscillatory process of the pipeline, full factor experiment, fractional factor experiment
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References

1. Postnova E. V. Model' vibrodinamicheskih vozdeystviy podvizhnogo sostava na zheleznodorozhnye truboprovody / E. V. Postnova, E. V. Runev // III Betankurovskiy mezhdunarodnyy inzhenernyy forum: sbornik trudov. — 2021. — S. 105–108.

2. Menli R. Analiz i obrabotka zapisey kolebaniy / R. Menli. — M.: Mashinostroenie, 1982. — 367 s.

3. Postnova E. Mathematical model for assessing the reliability of water supply networks / E. Postnova, E. Runev // Lecture Notes in Networks and Systems. — 2022. — Vol. 402. — Pp. 343–351.

4. Adler Yu. P. Planirovanie eksperimenta pri poiske optimal'nyh usloviy / Yu. P. Adler, E. V. Markova, Yu. V. Granovskiy. — M.: Nauka, 1976. — 254 s.

5. Belov I. V. Matematicheskie metody v planirovanii na zheleznodorozhnom transporte / I. V. Belov, A. B. Kaplan. — M.: Transport, 1972. — 248 s.

6. Yakovleva T. G. Modelirovanie prochnosti i ustoychivosti zemlyanogo polotna / T. G. Yakovleva, D. I. Ivanov. — M.: Transport, 1980. — 255 s.

7. Prokudin I. V. Prochnost' i deformativnost' zheleznodorozhnogo zemlyanogo polotna iz glinistyh gruntov, vosprinimayuschih vibrodinamicheskuyu nagruzku: avtoref. disc. … d-ra tehn. nauk. MIIZhT / I. V. Prokudin. — M., 1983. — 41 s.

8. Frishman M. A. Zemlyanoe polotno zheleznyh dorog / M. A. Frishman, I. N. Hohlov, V. P. Titov. — M.: Transport, 1972. — 287 s.

9. Spravochnik po elektropodvizhnomu sostavu, teplovozam i dizel'-poezdam / Pod obsch. red. A. I. Tischenko. — M.: Transport, 1976. — T. 1. — 429 s.

10. Dzhonson N. Statistika i planirovanie eksperimenta v tehnike i nauke / N. Dzhonson, F. Lion. — M.: Mir, 1980. — 610 s.

11. Ventcel' E. S. Issledovanie operaciy / E. S. Ventcel'. — M.: Vysshaya shkola, 2001. — 207 s.

12. Yasnopol'skiy S. A. Postroenie empiricheskih formul i podbor ih parametrov metodom naimen'shih kvadratov i metodom srednih / S. A. Yasnopol'skiy. — M.: Izd-vo MISiS, 1972. — 23 s.

13. Shor Ya. B., Tablicy dlya analiza i kontrolya nadezhnosti / Ya. B. Shor, F. I. Kuz'min. — M.: Sovetskoe radio, 1968. — 284 s.

14. Petrov A. Yu. Tehnologiya raboty passazhirskoy stancii: uchebnoe posobie / A. Yu. Petrov, P. K. Rybin, I. N. Shutov. — SPb.: PGUPS, 2008. — 41.

15. Dubinskiy V. A. Tehnologicheskiy process raboty passazhirskoy tehnicheskoy stancii / V.A. Dubinskiy i dr. — SPb.: PGUPS, 1997. — Ch. 1 — 26 s., Ch. 2 — 40 s.

16. Normativy dlya sostavleniya grafika dvizheniya poezdov OAO «Rossiyskie zheleznye dorogi». — M.: Tehnoinform, 2006.

17. Il'in Yu. A. Nadezhnost' vodoprovodnyh sooruzheniy i oborudovaniya / Yu. A. Il'in. — M.: Stroyizdat, 1985. — 240 s.

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