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
2021, 09 September

DOI: 10.14489/td.2021.09.pp.016-025

Markov A. A., Maksimova E. A.
PROBLEMS OF HIGH-SPEED RAIL FLAW DETECTION
(pp. 16-25)

Abstract. The main factors that reduce the quality of non-destructive testing of rails during high-speed scanning are considered. The most significant factors are the quality and volume of obtaining primary information about the condition of the monitored rails. It is shown that, at high-speed (up to 120 km/h) control, the compression of the defect location zone is clearly manifested and the length of the areas with acoustic contact violations increases. Analysis of real flaw diagrams of diagnostic complexes shows that with an increase in the scanning speed, the length of the location zone even from such large reflectors in the rails, such as bolt holes, significantly decreases. The average length of the instability zone of the bottom signal over the welded joints of the rails also increases significantly. The compression of the location zones of the reflectors can be compensated by expanding the aperture of the ultrasonic transducers. Improving the quality of the acoustic contact requires further improvement of the design of the search system and the systems for supplying the contacting liquid to the transducers, depending on the scanning speed. The Magnetic Flux Leakage(MFL) method can effectively detect defects in the rail head up to 20 mm deep at high speeds. Mathematical modeling of the magnetic flux in the controlled rails is performed. This allows us to start creating a new rail magnetization system with an increased interpole distance for high speeds. The introduction of modern methods for processing a significant flow of flaw detection information using neural networks requires the formation of a large sample base of training signals from real defects in different sections of rails. This is a complex task in its own right. For the first time, the issues of checking the operability of flaw detection devices in real control conditions are raised. Testing of ultrasonic equipment at high speeds is proposed to be carried out with the help of special electronic-acoustic simulators of defects. They are installed on different surfaces of the rails on which the diagnostic complexes pass. Operational quality control of ultrasonic rail inspection can be evaluated by statistical analysis of signal parameters from structural elements (bolt holes). The choice between the monitoring performance and the required reliability of detecting rail defects must be made based on the results of real passes of diagnostic complexes at operating scanning speeds.

Keywords: high-speed rail testing, diagnostic complex, carflaw detector, ultrasonic flaw detection, acoustic contact, magnetic method, welded joints of rails, automatic decryption of B-scan, integral parameter.

A. A. Markov, E. A. Maksimova (Radioavionica JSC, St. Petersburg, 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.  

1. Blinkova S. A., Zaharov I. V. (2018). Development of high-speed and high-speed traffic on the railways of Russia and the world. Nauka i obrazovanie transportu, (1), pp. 227 – 231. [in Russian language]
2. Roslovets A. A. (2021). Diagnostics on guard of safety. Put' i putevoe hozyaystvo, (6), pp. 3 – 8. [in Russian language]
3. Tarabrin V. F. (2021). System of standardization and metrological support of speed defective means of rails in their production and operation. Kontrol'. Diagnostika, Vol. 24, (5), pp. 14 – 29. [in Russian language] DOI: 10.14489/td.2021.05.pp.014-029
4. Markov A. A. (1989). Features of estimation of conditional sizes of defects at significant scanning speeds. Defektoskopiya, (3), pp. 8 – 16. [in Russian language]
5. Mosyagin V. V., Vasil'ev S. A., Mahovikov S. P. Method for high-speed ultrasonic testing of rails. Invention patent No. 2715885. [in Russian language]
6. Markov A. A., Maksimova E. A. (2021). Analysis of the parameters of ultrasonic signals at high-speed control of rails. Defektoskopiya, (3), pp. 3 – 16. [in Russian language]
7. Shur E. A., Fedin V. M., Borts A. I. et al. (2019). Ways to eliminate increased damage to rails in the area of welded joints. Vestnik VNIIZhT, Vol. 78, (4), pp. 210 – 217. [in Russian language]
8. Markov A. A., Maksimova E. A. (2021). Analysis of the parameters of bottom signals in the zone of welded joints of rails during high-speed ultrasonic testing. Defektoskopiya, (5), pp. 45 – 55. [in Russian language]
9. Regulations on the interpretation of the results of non-destructive testing of rails. (2018). Available at: sdo-kaskor-aspt.ru [in Russian language]
10. Shur E. A., Borts A. I., Zagranichek K. L., Vasil'eva S. A. (2021). Causes of rail breaks. Put' i putevoe hozyaystvo, (5), pp. 9 – 14. [in Russian language]
11. Markov A. A., Antipov A. G., Maksimova E. A. (2019). The depth of detection of defects by the magnetic method during high-speed control of rails. Put' i putevoe hozyaystvo, (10), pp. 26 – 31. [in Russian language]
12. Markov A. A., Antipov A. G., Karelin M. V. (2018). Evaluation of the reliability of automatic recognition of signals from structural elements of a rail track by the magnetodynamic method. Kontrol'. Diagnostika, (3), pp. 16 – 27. [in Russian language] DOI: 10.14489/td.2018.03.pp.016-027
13. Markov A. A., Maksimova E. A. (2019). Automation of signal analysis of multichannel rail control: problems and suggestions. V mire nerazrushayushchego kontrolya, Vol. 22, (4), pp. 76 – 80. [in Russian language]
14. Orjelik V., Aharoni R., Krug G. (2002). Comparative Data Analysis for Optimal High-Speed Railways Testing. Abstracts of the 8th European Conference on NDT (ECNDT 2002). Barcelona.
15. Tarabrin V. F., Zverev A. V., Gorbunov O. E. (2013). The hardware-software complex "ASTRA" for registration and interpretation of railway rails complex diagnostics results. Kontrol'. Diagnostika, (10), pp. 33 – 47. [in Russian language]
16. Malenichev A. A., Sulimova V. V., Krasotkina O. V. et al. (2013). Application of the paired alignment procedure for marking joints on an ultrasonic defectogram of a rail track. Izvestiya Tul'skogo gosudarstvennogo universiteta. Tekhnicheskie nauki, (9-1), pp. 115 – 127. [in Russian language]
17. Shishkin V. V., Stenyushkin D. I., Bron M. G. (2014). Mathematical models and methods for decoding ultrasonic defectograms of railway rails in real time. Avtomatizatsiya protsessov upravleniya, 38(4), pp. 61 – 67. [in Russian language]
18. Kuz'min E. V., Gorbunov O. E., Plotnikov P. O., Tyukin V. A., Bashkin V. A. (2018). Application of neural networks for recognition of structural elements of rails on magnetic and eddy-current defectograms. Modelirovanie i analiz informatsionnyh sistem, Vol. 25, 78(6), pp. 667 – 679. [in Russian language]
19. Detection of rail defects using ultrasonic testing. (2019). Zheleznye dorogi mira, (8), pp. 68 – 72. [in Russian language]
20. Markov A. A., Maksimova E. A., Antipov A. G. (2019). Analysis of the development of rail defects based on the results of multichannel periodic inspection. Defektoskopiya, (12), pp. 3 – 15. [in Russian language]
21. Markov A. A., Mironov F. S. (1997). Principles of construction of electronic-acoustic simulators for training and certification of specialists in ultrasonic testing of products. Defektoskopiya, (6), pp. 22 – 38. [in Russian language]

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