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Nowadays, the importance of maintenance and effective use of available railcars in the railway transport is growing, and researchers and technical experts are working to address this issue with the use of various techniques. The authors address the use of analytical technique, which includes mathematical solutions for flexural and longitudinal fluctuations of the bearing framework of a railcar body frame. The calculation is performed in connection with the modernization of the body frame of emergency and repair rail service car, taking into account the variability in section, mass, longitudinal stiffness, and bending stiffness. It allows for extension of the useful life of their operation, with special focus on vehicles owned by Joint-Stock Company "Uzbekistan Railways". The simulation of equivalent bearing body frame of emergency and repair rail service car was carried out using an elastic rod with variable parameters including stiffness and mass. The difference between the proposed model and the existing ones is due to the variability in cross section, mass, and the longitudinal and bending stiffness along the length of equivalent beam, which corresponds to the actual conditions of operation and data of the experimental studies conducted by the authors on the bearing frames of electric locomotives’ variable sections. The frequency analysis that was carried out with the use of the Mathcad 14 programming showed that the frequencies of natural oscillations change on n harmonicas = 1, 2, 3 … 5. As regards longitudinal oscillations of system, in case of introduction of the damping subfloor, the frequency of natural oscillations of the upgraded rail car frame λ1mn increases on comparing with standard λ1n (for example, in case of n = 5 the frequency is 0.587 and 0.602 Hz/m, respectively).
Czasopismo
Rocznik
Tom
Strony
93--102
Opis fizyczny
Bibliogr. 26 poz.
Twórcy
autor
- Tashkent Institute of Railway Transport Engineers 1, Adilkhodjaev Street, Mirabad district, Tashkent, Uzbekistan
autor
- Tashkent Institute of Railway Transport Engineers 1, Adilkhodjaev Street, Mirabad district, Tashkent, Uzbekistan
autor
- Tashkent Institute of Railway Transport Engineers 1, Adilkhodjaev Street, Mirabad district, Tashkent, Uzbekistan
Bibliografia
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- 13. Žygienė, R. & Bogdevičius, M. & Dabulevičienė, L. Mathematical model and simulation results of the dynamic system railway vehicle wheel-track with a flat. Science – Future of Lithuania. 2014. Vol. 6, No. 5. P. 531–537.
- 14. Khromova, G.A. & Babadjanov, A.A. Development of Analytical and Numerical Calculation Method to Dynamic Strength of the Bearing Body Frame of Governing Electric Locomotive. Proc. of the 6th International Scientific and Technical Conference "Train Operation Safety". Moscow: MIIT, 26÷28 October 2005. MIIT, Moscow. P. IY-87÷89.
- 15. Khromova, G.A. & Babadjanov, A.A. & Zakirov, Sh. A. Development of Analytical and Numerical Calculation Method to Dynamic Strength of the Bearing Body Frame of Governing Electric Locomotive. Journal Industrial Transport of Kazakhstan, Kazakh University of Railways. 2006. No 3 (9). P. 14-18.
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- 22. Челноков, И.И. Гидравлические гасители колебаний пассажирских вагонов. Москва: Транспорт. 1975. 73 p. [In Russian: Hydraulic quenchers of fluctuations of railway cars. Moscow: Transport].
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- 24. Myamlin, S. & Lingaitis, L.P. & Dailydka, S. & Vaičiūnas, G. & Bogdevičiusc, M. & Bureika, G. Determination of the dynamic characteristics of freight wagons with various bogie. Transport. 2015. Vol. 30. No. 1. P. 88-92.
- 25. Myamlin, S. & Ten, A. & Neduzha, L. & Shvets, A. Spatial Vibration of Cargo Cars in Computer Modelling with the Account of Their Inertia Properties. In: Proceedings of 15th International Conference. Mechanika. 2010. P. 325-328.
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Uwagi
PL
Opracowanie ze środków MNiSW w ramach umowy 812/P-DUN/2016 na działalność upowszechniającą naukę (zadania 2017).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-bd4aad09-3216-4d5f-984b-2b286ebfe22b