|
DOI: 10.14489/td.2026.01.pp.051-057
Surkaev A. L., Svetlichnaya V. B., Matveeva T. A., Mustafina J. A., Rakhmankulova G. A.
MODELING OF A PHYSICAL EXPERIMENT OF PIPELINE DIAGNOSTICS USING THE SHOCK WAVE METHOD
(pp. 51-57)
Abstract. The paper proposes a diagnostic method for identifying potentially hazardous sections of pipelines intended for liquid and gas flows, based on the use of a fast-flowing shock-wave effect of an electric discharge. The validity of the proposed diagnostic method is confirmed by the results of a physical experiment simulating the processes of shock-wave action on the internal surfaces of the pipes being diagnosed. An information-measuring system is presented for studying the spatio-temporal parameters of incident and interacting shock waves of axial direction of an electric explosion of a conductor in a discharge chamber with a condensed medium.
Keywords: pipeline diagnostics, electrical explosion of conductors, shock wave, waveguide piezoelectric pressure transducer, condensed medium, discharge chamber.
A. L. Surkaev, V. B. Svetlichnaya, T. A. Matveeva, J. A. Mustafina, G. A. Rakhmankulova (Volgograd State Technical University, Volgograd, Russia) ) E-mail:
Данный адрес e-mail защищен от спам-ботов, Вам необходимо включить Javascript для его просмотра.
,
Данный адрес e-mail защищен от спам-ботов, Вам необходимо включить Javascript для его просмотра.
,
Данный адрес e-mail защищен от спам-ботов, Вам необходимо включить Javascript для его просмотра.
,
Данный адрес e-mail защищен от спам-ботов, Вам необходимо включить Javascript для его просмотра.
,
Данный адрес e-mail защищен от спам-ботов, Вам необходимо включить Javascript для его просмотра.
1. Gorshkov, A. S., & Rymkevich, P. P. (2019). Wear and damage of heating networks: Solving the problem of quality and reliability of energy supply. Energosberezhenie, (5). [in Russian language].
2. Andreeva, S. A. (2017). Innovative methods for diagnostics of heating networks. Novosti Teplosnabzheniya, 4(200). http://www.rosteplo.ru/nt/200 [in Russian language].
3. Manservigi, L., Bahlawan, H., Losi, E., Morini, M., & Stoppato, A. (2022). A diagnostic approach for fault detection and identification in district heating networks. Energy, 251(2), 123988. https://doi.org/10.1016/j.energy.2022.123988
4. Sokolov, E. Y. (1982). District heating and heat networks. Energoizdat. [in Russian language].
5. Popyrin, L. S., Svetlov, K. S., & Belyaeva, G. M. (1989). Research of heat supply systems. Nauka. [in Russian language].
6. Zhukov, V. G. (2022). Mechanics. Strength of materials: A textbook. Lan. [in Russian language].
7. Krivitsky, E. V. (1986). Dynamics of an electric explosion in a liquid. Naukova Dumka. [in Russian language].
8. Ryazantsev, Y. P. (1990). Electric discharge in a liquid and its use in metalworking. INII "Elektronika". [in Russian language].
9. Surkaev, A. L., Kumysh, M. M., & Usachev, V. I. (2021). Elements of the physics of an electric explosion of conductors in gaseous and condensed media. Volgograd State Technical University Publishing House. [in Russian language].
10. Beskaravainyi, N. M., & Pozdeev, V. A. (1981). Theoretical foundations of measuring impulse pressures in liquid media. Naukova Dumka. [in Russian language].
11. Surkaev, A. L., Mukha, Y. P., & Surkaev, V. A. (2004). Waveguide piezoceramic pressure sensor (Patent No. RU 2241212 C2). Russian Federal Service for Intellectual Property. [in Russian language].
12. Surkaev, A. L., Kantsedalov, D. A., Usachev, V. I., & Surkaev, V. A. (2021). Waveguide sensor of impulse pressures (Patent No. RU 204491 U1). Russian Federal Service for Intellectual Property. [in Russian language].
13. Surkaev, A. L., & Mukha, Y. P. (2020). A method for measuring the pressure of a shock-acoustic wave from an electric explosion of a conductor in a discharge chamber with a condensed medium. Kontrol'. Diagnostika, 23(8), 50–55. [in Russian language].
14. Isakovich, M. A. (1973). General acoustics. Nauka. [in Russian language].
15. Surkaev, A. L., Kul’kov, V. G., & Talyzov, G. N. (2001). Experimental investigation of the interaction of two acoustic shock waves. Technical Physics Letters, 27(6), 487–488.
16. Surkaev, A. L., & Mukha, Y. P. (2002). Studying the effect of nonlinearity of interacting acoustic shock waves. Technical Physics Letters, 28(8), 640–641.
17. Surkaev, A. L., Surkaev, V. A., & Kumysh, M. M. (2010). Electrohydroimpulse method of pressing pipes in hard-to-reach places (Patent No. RU 2378074 C1). Russian Federal Service for Intellectual Property. [in Russian language].
18. Surkaev, A. L., Surkaev, V. A., & Kumysh, M. M. (2010). Electrohydroimpulse method of pressing pipes in hard-to-reach places (Patent No. RU 2378075 C1). Russian Federal Service for Intellectual Property. [in Russian language].
19. Kosenkov, V. M. (2014). Using circular membranes to determine the mechanical efficiency of an electric discharge in water. Elektronnaya Obrabotka Materialov, 50(2), 81–90. [in Russian language].
20. Kochetkov, I. I., & Pinaev, A. V. (2015). Shock-wave processes during the explosion of conductors in water and bubble media. Fizika Goreniya i Vzryva, 51(6), 109–119. [in Russian language].
This article is available in electronic format (PDF).
The cost of a single article is 700 rubles. (including VAT 20%). After you place an order within a few days, you will receive following documents to your specified e-mail: account on payment and receipt to pay in the bank.
After depositing your payment on our bank account we send you file of the article by e-mail.
To order articles please copy the article doi:
10.14489/td.2026.01.pp.051-057
and fill out the form
|
Current Issue
Разработка концепции и создание сайта - ООО «Издательский дом «СПЕКТР»