Strength requirements for locomotive load-bearing structures: a literature review
Аннотация
This analytical article explores the strength assessment of locomotive load-bearing structures, focusing on the critical role these components play in railway safety and efficiency. The article examines international and national standards, including EN 12663, EN 13749, and GOST 34939-2023, outlining their requirements for structural design, fatigue resistance, and testing methodologies. It highlights key aspects such as permissible stresses, material selection, and advanced evaluation methods, providing a framework for structural health monitoring and maintenance optimization. By addressing emerging technologies and their potential impact, this study offers valuable insights into the challenges and opportunities in modern railway engineering, emphasizing the necessity of rigorous and standardized approaches to structural analysis.
Литература
[1] Yusufov, A., Khamidov, O., Zayniddinov, N., & Abdurasulov, S. (2023). Prediction of the stress-strain state of the bogie frames of shunting locomotives using the finite element method. In E3S Web of Conferences (Vol. 401, p. 03041). EDP Sciences.
[2] Abdurasulov, S., Zayniddinov, N., Yusufov, A., & Jamilov, S. (2023). Analysis of stress-strain state of bogie frame of PE2U and PE2M industrial traction unit. In E3S Web of Conferences (Vol. 401, p. 04022). EDP Sciences.
[3] Zayniddinov, N., & Abdurasulov, S. (2022). Durability analysis of locomotive load bearing welded structures. Science and Innovation, 1(8), 176-181.
[4] Vega, B., & Pérez, J. Á. (2024). Comparative analysis of fatigue strength of a freight wagon frame. Welding in the World, 68(2), 321-332.
[5] Zhao, W., & Zeng, Y. (2023, June). Comparative study of static strength and fatigue strength tests and simulation analysis of an exit subway bogie frame. In Third International Conference on Mechanical Design and Simulation (MDS 2023) (Vol. 12639, pp. 880-892). SPIE.
[6] Slavchev, S., Maznichki, V., Stoilov, V., Enev, S., & Purgic, S. (2018). Comparative analysis of fatigue strength of an y25ls-k bogie frame by methods of UIC AND DVS 1612. Czech Republic.
[7] Dizo, J., harusinec, J., & Blatnicky, M. Computation of modal properties of two types of freight wagon bogie frames using the finite element method. Manufacturing Technology [online]. 2018, 18 (2).
[8] Šťastniak, P., Moravčík, M., Baran, P., & Smetanka, L. (2018). Computer aided structural analysis of newly developed railway bogie frame. In MATEC Web of conferences (Vol. 157, p. 02051). EDP Sciences.
[9] Boronenko, Y., & Rahimov, R. (2021). Experimental determination of forces through measurements of strains in the side frame of the bogie. Transport problems, 16.
[10] Wang, Q., Zhou, J., Wang, T., Gong, D., Sun, Y., Chen, J., & You, T. (2021). Extrapolation of the dynamic stress spectrum of train bogie frame based on kernel density estimation method. Fatigue & Fracture of Engineering Materials & Structures, 44(7), 1783-1798.
[11] Qu, S., Wang, J., Zhang, D., Li, D., & Wei, L. (2021). Failure analysis on bogie frame with fatigue cracks caused by hunting instability. Engineering Failure Analysis, 128, 105584.
[12] de Cisneros Fonfría, J. J. J., Olmeda, E., Sanz, S., Garrosa, M., & Díaz, V. (2024). Failure analysis of a train coach underframe. Engineering Failure Analysis, 156, 107756.
[13] Kassner, M. (2012). Fatigue strength analysis of a welded railway vehicle structure by different methods. International journal of fatigue, 34(1), 103-111.
[14] Xiu, R., Spiryagin, M., Wu, Q., Yang, S., & Liu, Y. (2020). Fatigue life assessment methods for railway vehicle bogie frames. Engineering Failure Analysis, 116, 104725.
[15] Mukhamedova, Z., Fayzibayev, S., Mukhamedova, D., Batirbekova, A. M., Jurayeva, K., Ibragimova, G., & Ergasheva, Z. (2024). Calculating the fatigue strength of load-bearing structures of special self-propelled rolling stock. Scientific Reports, 14(1), 19205.
[16] Хамидов, О. Р., Юсуфов, А. М. У., Зайниддинов, Н. С. У., Жамилов, Ш. Ф. У., & Абдурасулов, Ш. Х. (2023). Оценка долговечности сварных несущих конструкций локомотивов. Universum: технические науки, (2-3 (107)), 48-53.
[17] Abdurasulov, S. X., Zayniddinov, N. S. O. G. L., & Yusufov, A. M. O. G. L. (2023). Sanoat lokomotivlarining xizmat muddatini uzaytirishda bajariladigan asosiy ishlar. International scientific journal of Biruni, 2(3), 55-62.
[18] Abdurasulov, S., Zayniddinov, N., & Yusufov, A. (2023). O‘zbekiston Respublikasi tog‘-kon sanoatida foydalanilayotgan tortish agregatlari parkining tahlili. Journal of Research and Innovation, 1(9), 16-24.
[19] Khamidov, O. R., Yusufov, A. M., Kodirov, N. S., & Abdurasulov, S. X. (2023). Determination of the resource of parts and assembly of the traction rolling stock using non-destructive testing methods. In Железнодорожный подвижной состав: проблемы, решения, перспективы (pp. 510-514).
[20] European Committee for Standardization (CEN). (2010). EN 12663: Railway applications. Structural requirements of railway vehicle bodies.
[21] European Committee for Standardization (CEN). (2011). EN 13749: Railway applications. Wheelsets and bogies. Method of specifying the structural requirements of bogie frames.
[22] Interstate Council for Standardization, Metrology and Certification. (2023). GOST 34939: Locomotives. Requirements for bearing structure strength and dynamic properties.
[23] Abdurasulov, S. (2023). Requirements for the strength of load-bearing structures of locomotives. Acta of Turin Polytechnic University in Tashkent, 13(4), 44-48.
[2] Abdurasulov, S., Zayniddinov, N., Yusufov, A., & Jamilov, S. (2023). Analysis of stress-strain state of bogie frame of PE2U and PE2M industrial traction unit. In E3S Web of Conferences (Vol. 401, p. 04022). EDP Sciences.
[3] Zayniddinov, N., & Abdurasulov, S. (2022). Durability analysis of locomotive load bearing welded structures. Science and Innovation, 1(8), 176-181.
[4] Vega, B., & Pérez, J. Á. (2024). Comparative analysis of fatigue strength of a freight wagon frame. Welding in the World, 68(2), 321-332.
[5] Zhao, W., & Zeng, Y. (2023, June). Comparative study of static strength and fatigue strength tests and simulation analysis of an exit subway bogie frame. In Third International Conference on Mechanical Design and Simulation (MDS 2023) (Vol. 12639, pp. 880-892). SPIE.
[6] Slavchev, S., Maznichki, V., Stoilov, V., Enev, S., & Purgic, S. (2018). Comparative analysis of fatigue strength of an y25ls-k bogie frame by methods of UIC AND DVS 1612. Czech Republic.
[7] Dizo, J., harusinec, J., & Blatnicky, M. Computation of modal properties of two types of freight wagon bogie frames using the finite element method. Manufacturing Technology [online]. 2018, 18 (2).
[8] Šťastniak, P., Moravčík, M., Baran, P., & Smetanka, L. (2018). Computer aided structural analysis of newly developed railway bogie frame. In MATEC Web of conferences (Vol. 157, p. 02051). EDP Sciences.
[9] Boronenko, Y., & Rahimov, R. (2021). Experimental determination of forces through measurements of strains in the side frame of the bogie. Transport problems, 16.
[10] Wang, Q., Zhou, J., Wang, T., Gong, D., Sun, Y., Chen, J., & You, T. (2021). Extrapolation of the dynamic stress spectrum of train bogie frame based on kernel density estimation method. Fatigue & Fracture of Engineering Materials & Structures, 44(7), 1783-1798.
[11] Qu, S., Wang, J., Zhang, D., Li, D., & Wei, L. (2021). Failure analysis on bogie frame with fatigue cracks caused by hunting instability. Engineering Failure Analysis, 128, 105584.
[12] de Cisneros Fonfría, J. J. J., Olmeda, E., Sanz, S., Garrosa, M., & Díaz, V. (2024). Failure analysis of a train coach underframe. Engineering Failure Analysis, 156, 107756.
[13] Kassner, M. (2012). Fatigue strength analysis of a welded railway vehicle structure by different methods. International journal of fatigue, 34(1), 103-111.
[14] Xiu, R., Spiryagin, M., Wu, Q., Yang, S., & Liu, Y. (2020). Fatigue life assessment methods for railway vehicle bogie frames. Engineering Failure Analysis, 116, 104725.
[15] Mukhamedova, Z., Fayzibayev, S., Mukhamedova, D., Batirbekova, A. M., Jurayeva, K., Ibragimova, G., & Ergasheva, Z. (2024). Calculating the fatigue strength of load-bearing structures of special self-propelled rolling stock. Scientific Reports, 14(1), 19205.
[16] Хамидов, О. Р., Юсуфов, А. М. У., Зайниддинов, Н. С. У., Жамилов, Ш. Ф. У., & Абдурасулов, Ш. Х. (2023). Оценка долговечности сварных несущих конструкций локомотивов. Universum: технические науки, (2-3 (107)), 48-53.
[17] Abdurasulov, S. X., Zayniddinov, N. S. O. G. L., & Yusufov, A. M. O. G. L. (2023). Sanoat lokomotivlarining xizmat muddatini uzaytirishda bajariladigan asosiy ishlar. International scientific journal of Biruni, 2(3), 55-62.
[18] Abdurasulov, S., Zayniddinov, N., & Yusufov, A. (2023). O‘zbekiston Respublikasi tog‘-kon sanoatida foydalanilayotgan tortish agregatlari parkining tahlili. Journal of Research and Innovation, 1(9), 16-24.
[19] Khamidov, O. R., Yusufov, A. M., Kodirov, N. S., & Abdurasulov, S. X. (2023). Determination of the resource of parts and assembly of the traction rolling stock using non-destructive testing methods. In Железнодорожный подвижной состав: проблемы, решения, перспективы (pp. 510-514).
[20] European Committee for Standardization (CEN). (2010). EN 12663: Railway applications. Structural requirements of railway vehicle bodies.
[21] European Committee for Standardization (CEN). (2011). EN 13749: Railway applications. Wheelsets and bogies. Method of specifying the structural requirements of bogie frames.
[22] Interstate Council for Standardization, Metrology and Certification. (2023). GOST 34939: Locomotives. Requirements for bearing structure strength and dynamic properties.
[23] Abdurasulov, S. (2023). Requirements for the strength of load-bearing structures of locomotives. Acta of Turin Polytechnic University in Tashkent, 13(4), 44-48.
Опубликован
2025-03-31
Как цитировать
Abdurasulov, S., Zayniddinov, N., & Kosimov, K. (2025). Strength requirements for locomotive load-bearing structures: a literature review. Международный научный журнал «Инженер», 3(1), 14-18. https://doi.org/10.56143/3030-3893-2025-1-14-18
Раздел
Машиностроение
