Decision Making Based on the Results of Automatic Diagnostics of Parts and Assemblies of Rolling Stock

The article reviews a preventive maintenance system for repairs, the main disadvantage of which is that it is essentially an open system of technical control that does not take into account objective assessment of rolling stock «as it is». The objective of the study was to review and summarize the existing researches and to word the proposals to develop the system of rolling stock maintenance. Based on the analysis of the researches in that field it is proposed to reduce material and labor costs for maintenance of cars by making the system of technical diagnostics closed. As a feedback, it is advisable to use an automatic test diagnostic control system that detects car defects while the train is running. It will significantly reduce the number of manual operations for inspecting rolling stock in the arrival parks of sorting stations and automate decision-making on possibility of subsequent operation of controlled rolling stock based on its actual condition.
A technique is proposed for evaluating the results of technical diagnostics of rolling stock in which probabilistic estimates are used, dividing the most significant defects of the controlled object into three classes according to the degree of their significance for operation safety. It has been established that Weibull distribution corresponds to fatigue defective phenomena, while Rayleigh distribution corresponds to wear phenomena with constant or periodic workload.
To identify defective car wheels and axle boxes, a dynamic system is proposed, which includes: the controlled object which is a wheel or axle box, automatic test diagnostic equipment and a resolver for deciding on further operation of the identified defective car. The optimal equation of the separating function of «false alarm» and «acceptance» is obtained on the basis of the Bayes criterion, which minimizes the average risk of making a wrong decision.

railway, traffic safety, rolling stock, test diagnostics, classification of defects

1. Rosenberg, E. N., Dzyuba, Yu. V., Batraev, V. V. [et al]. On the directions of development of the digital railway [O napravleniyakh razvitiya tsifrovoi zheleznoi dorogi]. Avtomatika, svyaz, informatika, 2018, Iss. 1, pp. 9–13.

2. Boynik, A. V., Zagariy, G. I., Koshevoy, S. V. [et al]. Diagnostics of railway automation devices and devices of moving units [Diagnostirovanie ustroistv zheleznodorozhnoi avtomatiki i agregatov podvizhnykh edinits]. Kharkov, Private Enterprise Publishing House «Novoe slovo», 2008, 304 p.

3. Senko, V. I. Gursky, E. P., Chernin, I. L. [et al]. Freight cars of railways: Study guide [Gruzovie vagony zheleznykh dorog: Ucheb. posobie]. Ed. by V. I. Senko. Gomel, BelSUT, 2018, 531 p.

4. Nagovitsin, V.S. Diagnostic systems for railway rolling stock based on information technology [Sistemy diagnostiki zheleznodorozhnogo podvizhnogo sostava na osnove informatsionnykh tekhnologii]. Moscow, VINITI RAS publ., 2004, 248 p.

5. Ivanova, T. V., Nalabordin, D. G. Assessment of precautionary states of an axle box unit of a freight car [Otsenka predotkaznykh sostoyanii buksovogo uzla gruzovogo vagona]. Vagony i vagonnoe khozyaistvo, 2017, Iss. 1, pp. 46–47.

6. Mishin, I. M. Maintenance and repair of cars abroad [Tekhnicheskoe obsluzhivanie i remont vagonov za rubezhom]. Vagony i vagonnoe khozyaistvo, 2018, Iss. 1, pp. 44–45.

7. Burchenkov, V. V., Kholodilov, O. V. Technical diagnostics of the state of rolling stock and the prospects for its development in Western Europe and the USA [Tekhnicheskaya diagnostika sostoyaniya podvizhnogo sostava i perspektivy ee razvitiya v Zapadnoi Evrope i SShA]. Vestnik BelGUT; Science and transport, 2017, Iss. 1, pp. 5–9.

8. Gartner, E. US Railways: Features of freight and passenger transportation [Zheleznie dorogi SShA: osobennosti gruzovykh i passazhirskikh perevozok]. Zheleznie dorogi mira, 2007, Iss. 4, pp. 9–32.

9. Shobel, A. Remote monitoring of the technical condition of rolling stock [Distantsionniy monitoring tekhnicheskogo sostoyaniya podvizhnogo sostava]. Zheleznie dorogi mira, 2013, Iss. 6, pp. 54–59.

10. Krivorudchenko, V. F., Akhmedzhanov, R. A. Modern methods of technical diagnostics and nondestructive testing of parts and components of rolling stock of railway transport [Sovremennie metody tekhnichekoi diagnostiki i nerazrushayushchego kontrolya detalei i uzlov podvizhnogo sostava zheleznodorozhnogo transporta]. Moscow, Marshrut publ., 2005, 436 p.

11. Gondorov, V. A. Modern diagnostic tools for rolling stock in moving train [Sovremennie sredstva diagnostiki podvizhnogo sostava na khodu poezda]. Vagony i vegonnoe khozyaistvo, 2017, Iss. 4, pp. 36–37.

12. Trestman, E. E., Lozinsky, S. N., Obraztsov, V. L. Automation of control of axle boxes in trains [Avtomatizatsiya kontrolya buksovykh uzlov v poezdakh]. Moscow, Transport publ., 1983, 352 p.

13. Guidance document on repair and maintenance of wheel sets with axle boxes of freight cars of the main railways of 1520 (1524) mm gauge. «Technical control of wheel sets and their elements», RD VNIIZhT 05.27.01- 2017 [Rukovodyashchiy document po remontu i tekhnicheskomu obsluzhivaniyu kolesnykh par s buksovymi uzlami gruzovykh vagonov magistralnykh zheleznykh dorog kolei 1520 (1524) mm. «Tekhnicheskiy control kolesnykh par I ikh elementov», RD VNIIZhT 05.27.01-2017].

14. Redeker, R. Remote monitoring of technical means of railways [Udalenniy monitoring tekhnicheskikh sredstv zheleznykh dorog]. Zheleznie dorogi mira, 2012, Iss. 10, pp. 66–68.

15. Burchenkov, V. V. Automation of control of the technical condition of rolling stock [Avtomatizatsiya kontrolya tekhnicheskogo sostoyaniya podvizhnogo sostava]. Gomel, BelGUT publ., 2008, 235 p.

16. Schobel, A. Floor monitoring systems of rolling stock [Napolnie sistemy monitoring podvizhnogo sostava]. Zheleznie dorogi mira, 2014, Iss. 3, pp. 51–59.

17. Lozinsky, S. N., Alekseev, A. G., Karpenko, P. N. Equipment for automatic detection of overheated axle boxes in trains [Apparatura avtomaticheskogo obnaruzheniya peregretykh buks v poezdakh]. Moscow, Transport publ., 1978, 160 p.

18. Mironov, A. A. Prospective directions for improvement of control means KTSM-02 and ASK PS [Perspektivnie napravleniya sovershenstvovaniya sredstv kontrolya KTSM-02 i ASK PS]. Avtomatika, svyaz, informatika, 2009, Iss. 1, pp. 38–41.

19. Baranov, L. A. Level quantization and temporal discretization in digital control systems [Kvantovanie po urovnyu i vremennaya diskretizatsiya v tsifrovykh sistemakh upravleniya]. Moscow, Energoatomizdat publ., 1990, 304 p.

20. Negrey, V. Ya., Burchenkov, V. V. Prospects for the use of digital technologies at marshalling yards [Perspektivy ispolzovaniya tsifrovykh tekhnologii na sortirovochnykh stantsiyakh]. Proceedings of the seventh scientific and technical conference «Intelligent control systems in railway transport. Computer and mathematical modeling (ISUZhT-2018, Moscow)». Moscow, Publishing house of OJSC NIIAS, 2018, pp. 153–154.