Scientific monographs
Temperature effects on railway rolling stock components: monograph
- Oleksij Fomin

- Alyona Lovska

Анотація
The purpose of the book is to highlight the features of temperature effects on the components of railway rolling stock and to create measures to improve the efficiency of its operation. Theoretical provisions, methodological bases and practical decisions on determination of temperature influence on components of rolling stock of railways at operational modes of loading are provided.
The monograph is intended for scientific and technical specialists whose activities are related to the design and study of mechanics of rolling stock structures, including scientists, designers, designers, researchers, doctoral students and graduate students.
The monograph can be used as a textbook for undergraduates and bachelors in relevant specialties.
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REVIEWERS:
MASLIYEV Vyacheslav - Doctor of Technical Sciences, Professor, Department of Electric Transport and Heat Engineering, National Technical University «Kharkiv Polytechnic Institute», Ukraine
SAPRONOVA Svitlana - Professor, Doctor of Technical Sciences, Department of cars and carriage facilities, State University of Infrastructure and Technologies, Ukraine
USTENKO Oleksander - Doctor of Technical Sciences, Professor, Dean of the Faculty of Mechanics and Energy, Ukrainian State University of Railway Transport, Ukraine
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CONTENTS:
INTRDUCTION
SECTION 1
DESIGN FEATURES AND MAIN CHARACTERISTICS OF HOPPER CARS FOR TRANSPORTATION OF HOT PELLETS AND SINTER
1.1 Analysis of structures and main characteristics of hopper cars for transportation of hot pellets and sinter of the operated fleet
1.2 Patent analysis of load-bearing structures of hopper cars for transportation of pellets and hot sinter
1.3 Analysis of literature sources to determine the temperature effect on the components of rolling stock
1.4 The main measures of labor protection and features of repair of load-bearing structures of hopper cars for transportation of hot pellets and sinter
Conclusions to the section 1
SECTION 2
DETERMINING THE LOAD OF THE LOAD-BEARING STRUCTURE OF THE HOPPER CAR AND CREATING MEASURES TO INCREASE THE EFFICIENCY OF TRANSPORTATION OF HIGH-TEMPERATURE CARGOES
2.1 Determining the load of the load-bearing structure of the hopper car due to temperature effects
2.2 Improvement of the supporting structure of the hopper car to ensure its durability in operation
2.3 Improvement of the load-bearing structure of the hopper car by using cladding made of heat-resistant composite material
2.4 Determining the strength of the load-bearing structure of the gondola car during defrosting of the cargo in it
2.5 Adaptation of load-bearing structures of gondola cars for transportation of high-temperature cargoes
2.5.1 Determining the load bearing structure of gondola car when transporting high-temperature cargoes in it
2.5.2 Measures to adapt the load-bearing structure of the gondola car to the transportation of high-temperature cargo
2.6 Design features and determination of the load-bearing structure of the car for the transportation of high-temperature, bulk/liquid cargo during operational modes
Conclusions to the section 2
SECTION 3
IMPROVEMENT OF ELEMENTS OF TRIBOTECHNICAL PAIRS OF BRAKES OF MOVING VEHICLES
3.1 Study of the load of brake pads under temperature influence
3.2 Calculations of the thermal regime and wear of brake pads
3.3 Justification of the creation of promising disc brakes for passenger cars
Conclusions to the section 3
GENERAL CONCLUSIONS
REFERENCES
APPENDIX A. Patent designs of temperature-resistant components of rolling stock
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Year of publication: 2022
Language: English
Authors: Fomin O., Lovska A.
Translation: No
Translator: -
Type: Paperbook
Number of pages: 144
Format: 148x210x12mm
ISBN: 979-8-88831-318-3
UDC: 629.463
Посилання
- http://transport.in.ua/informatsiya/inform-zhd-perevozki/vagony-harakteristiki/hopper-okatyshej-20-471/
- Kharitonov M. I., Pankin V. N. Freight cars. Part I (gondola cars and covered wagons): Tutorial for laboratory work / M. I. Kharitonov, V. N. Pankin. – Khabarovsk: Publishing House of the Far Eastern State University of Communications, 2003. – 96 p.: 45 illustrations.
- https://www.kvsz.com/index.php/ua/produktsiya/vantazhne-vagonobuduvannya/vagoni-khoperi/item/2902-vahon-khoper-dlia-perevezennia-okatyshiv-model-20-7032
- https://vagon.by/model/20-480
- http://www.dvmash.biz/ru/hoperi/6-2010-06-15-13-11-34/48-20-4015-20-4015-01.html
- https://ukrailtrans.com.ua/4-osnyj-vagon-dlya-okatyshej-model-20-4015-01/
- https://vagon.by/model/20-9749
- https://vagon.by/model/20-471
- https://dmz-karpaty.com/services/car-building/19-9982
- https://ukrailtrans.com.ua/4-osnyj-vagon-dlya-okatyshej-model-20-793/
- Railway hopper gondola car for hot pellets and sinter: patent 122540 of Ukraine, IPC (2017.01) B61D 7/00 B61D 3/00. u2017 08482; application date 18.08.17; published on 10.01.18, Bull. No. 1.
- Railway hopper gondola car for hot coils and sinter: pat. 101213 of Ukraine, IPC (2013.01) B61D 7/00 B61F 1/02 (2006.01) B61D 7/16 (2006.01) B61D 06/17 (2006.01) B61D 08/17 (2006.01). a2011 03663; application date 28.03.11; published on 11.03.13, Bull. No. 5.
- Hopper car of the articulated type: pat. 145805 of Ukraine, IPC (2021.01)
- B61D 17/06 (2006.01) B61D 7/00. a2011 03663; application date 03.07.20; published on 06.01.21, Bull. No. 1.
- Hopper car with elastic elements in the load-bearing structure: pat. 148947 of Ukraine, IPC (2021.01) B61D 7/00. u2020 04026; application date 20.01.2021; published on 05.10.21, Bull. No. 40.
- Railway open hopper car: pat. 118389 of Ukraine, IPC (2006.01) B61F 1/02 (2006.01) B61F 1/10 (2006.01) B61D 7/00. a2017 01810; application date 06/26/2018; published on 10.01.2019, Bul. No. 1.
- Hopper car: pat. 98764 of Ukraine, IPC (2015.01) B61D 7/00. u2014 11358; application date 17.10.14; published on 12.05.15, Bul. No. 9.
- UA 98764 U, 12.05.2015
- http://um.co.ua/11/11-9/11-97694.html
- https://ua.all.biz/vagon-dlya-okatyshej-modeli-20-9839-gp-71tn-vkuz-g1828828
- DSTU 7598:2014. Freight cars. General requirements for calculations and design of new and modernized wagons of 1520 mm gauge (non-self-propelled). Kyiv, 2015. 162 p.
- GOST 33211–2014. Freight cars. Requirements for strength and dynamic qualities. Moscow, 2016. 54 p.
- Lukin V.V., Shadur L.A., Koturanov V.I., Khokhlov A.A., Anisimov P.S. Construction and calculation of wagons. Moscow, 2000. 731 p.
- Bogomaz G. I., Mekhov D. D., Pylypchenko O. P., Chernomashentseva Y. G. Loading of container-tanks located on a railway platform when hitting a car coupling. Collection of science works “Dynamics and motion control of mechanical systems”. Kyiv: Academy of Science, Institute of Technical Mechanics. 1992. P. 87–95.
- Dyomin Yu. V., Chernyak G. Yu. Fundamentals of wagon dynamics: tutorial Kyiv: Kyiv University of Economics and Transport Technologies, 2003. 269 p.
- Fomin Oleksij, Lovska Alyona. Establishing patterns in determining the dynamics and strength of a covered freight car, which exhausted its resource // Eastern-European Journal of Enterprise Technologies. 2020. Vol. 6. Issue 7 (108). P. 21 – 29. doi: 10.15587/1729-4061.2020.217162
- Kosmin V.V. Fundamentals of scientific research: Textbook. Moscow: GOU "Educational and methodological center for education in railway transport", 2007. 271 p.
- Matalytsky M. A., Khatskevich G. A. Probability theory and mathematical statistics: textbook. Minsk: Higher School, 2017. 591 p.
- Ivchenko G. I., Medvedev Yu. I. Mathematical statistics: textbook. M.: Knizhny Dom “LIBROKOM”, 2014. 352 p.
- Rudenko V. M. Mathematical statistics: textbook. Kyiv: Center of Educational Literature, 2012. 304 p.
- Ustych P. A., Karpych V. A., Ovechnikov M. N. Reliability of rail non-traction rolling stock. Moscow, 1999. 415 p.
- https://promvest.info/ru/otrasli-i-predpriyatiya/na-uvz-vpervyie-izgotovlen-vagon-hopper-modeli-20-5197-dlya-perevozki-okatyishey-i-aglomerata/
- http://vmz.com.ua/index.php/vagony-menu/khoppery/9-uncategorised/123-vagon-khopper-dlya-okatyshej
- https://vagon.by/model/20-9916-01
- https://vagon.by/model/19-9809
- https://vagon.by/model/19-1241
- Yamshinskyi, M.M., Nazarenko, V.S., and Kravchenko, K.O. (2015). Analysis of brake pads and ways of evaluating their perspective. Structural analysis of brake pads and ways of evaluation. Bulletin of the East Ukrainian National University named after Volodymyr Dahl, pp. 204 – 209.
- Babaev A. M., Dmytriev D. V. Principle of operation, calculations and basics of operation of railway rolling stock brakes: textbook - Kyiv: State Economic and Technological University of Transport, 2007, p.176.
- Lovska A. O., Ravlyuk V. G. Synopsis of lectures on the discipline "Modern brake wagon systems" (part II). Synopsis of lectures. Kharkiv: Ukrainian State University of Railway Transport, 2019, p. 61.
- Gallagher R. (1984). Method of finite elements. Moscow: Mir, p. 428.
- Sham Tyku. Effective work SolidWorks 2005. Official manual. Petersburg, 2006, p. 720.
- Martynov I. E., Ravlyuk V. G., Afanasenko I. M. Methodical instructions for the performance of the control work in the discipline "New brake technology". Kharkiv: Ukrainian State University of Railway Transport, 2014. p. 41.
- Guoshun Wang, Rong Fu. Impact of Brake Pad Structure on Temperature and Stress Fields of Brake Disc // Advances in Materials Science and Engineering. – 2013. – Vol. 2013, Article ID 872972, http://dx.doi.org/10.1155/2013/872972
- Aurelio Somà, Marco Aimar, Nicolò Zampieri. Simulation of the Thermal Behavior of Cast Iron Brake Block during Braking Maneuvers // Applied Science. – 2021. – Vol. 11(11), 5010; https://doi.org/10.3390/app11115010
- Jay Prakash Srivastava, Prabir Kumar Sarkar, Vinayak Ranjan. Effects of thermal load on wheel–rail contacts: A review // Journal of Thermal Stresses. – 2016. – Vol. 39, Issue 11. P. 1389 – 1418. https://doi.org/10.1080/01495739.2016.1216060
- Azadeh Haidari Parisa, Hosseini Tehrani. Thermal load effects on fatigue life of a cracked railway wheel // Latin American Journal of Solids and Structures. – 2015. – Vol.12 (6), June. https://doi.org/10.1590/1679-78251658
- Qing Wu, Colin Cole, Maksym Spiryagin. Preload on draft gear in freight trains // Proceedings of the Institution of Mechanical Engineers, Part F: Journal of Rail and Rapid Transit. – 2018. – Vol. 232, Issue 6. https://doi.org/10.1177/0954409717738849
- Andrew Nikitchenko, Viktor Artiukh, Denis Shevchenko, Vera Murgul. Modeling of Operation of Elastic-frictional Draft Gear by NX Motion Software // Procedia Engineering. – 2017. – Vol. 187, P. 790 – 796.
- Hyun-Ah Lee, Seong-Beom Jung, Hwan-Hak Jang, Dae-Hwan Shin, Jang Uk Lee, Kwang Woo Kim, Gyung-Jin Park. Structural-optimization-based design process for the body of a railway vehicle made from extruded aluminum panels // Proceedings of the Institution of Mechanical Engineers, Part F: Journal of Rail and Rapid Transit. – 2016. – Vol. 230, Issue 4. – P. 1283 – 1296.
- D.Ya. Antipin, D.Yu Racin, S.G. Shorokhov. Justification of a Rational Design of the Pivot Center of the OpenTop Wagon Frame by means of Computer Simulation // Procedia Engineering. – 2016. – Vol. 150. – P. 150 – 154
- Tomasz Kuczek, Bartosz Szachniewicz. Topology Optimization of Railcar Composite Structure // Inderscience Enterprises Ltd. 2014, January.
- Bain D.G. (2019). Analysis of the stress state of the load-bearing floor covering of a four-axle half-car with a hollow body. Bulletin of the Bryansk State Technical University, 1(29), p.47–51.
- Determination of the dynamic load of the carrying structure of the hopper wagon with the actual dimensions of structural elements / Oleksij Fomin, Alyona Lovska, Pavel Skok, Ivan Rogovskii // Technology audit and production reserves. – 2021. – № 1/1(57). – Р. 6 – 11. doi: 10.15587/2706-5448.2021.225458
- Mrzyglod M., Kuczek T. Uniform crashworthiness optimization of car body for high-speed trains // Structural and Multidisciplinary Optimization . 2014, Vol. 49. P. 327–336.
- Avent R. R., Mukai D. J., Robinson P. F. Effect of heat straightening on material properties of steel // Journal of Materials in Civil Engineering. – 2000. – Vol. 12, Issue 3. – P. 188 – 195.
- Alessio Gullino, Paolo Matteis, Fabio D’Aiuto. Review of Aluminum-To-Steel Welding Technologies for Car-Body Applications // Metals. – 2019. – Vol. 9, Issue 315. doi:10.3390/met9030315
- Chandra Prakash Shukla, P. K. Bharti. Study and Analysis of Doors of BCNHL Wagons // International Journal of Engineering Research & Technology (IJERT). 2015. Vol. 4. Issue 04. P. 1195 – 1200.
- Alexandru Ionut Patrascu, Anton Hadar, Stefan Dan Pastrama. Structural Analysis of a Freight Wagon with Composite Walls // Materiale plastic. 2019. Vol. 57(2). P. 140 – 151. doi: 10.37358/MP.20.2.5360
- George Edward Street, Preetum Jayantilal Mistry, Michael Sylvester Johnson. Impact Resistance of Fibre Reinforced Composite Railway Freight Tank Wagons // Journal of Composites Science. 2021. Vol. 5. Issue 152. https://doi.org/10.3390/jcs5060152
- Mariusz Kosobudzki, Krzysztof Jamroziak, Mirosław Bocian, et al. The analysis of structure of the repaired freight wagon // AIP Conference Proceedings. 2018. Vol. 2029. 020030. https://doi.org/10.1063/1.5066492
- Marek Płaczek, Andrzej Wróbel, Maciej Olesiejuk. Modelling and arrangement of composite panels in modernized freight cars // MATEC Web of Conferences. 2017. Vol. 112. 06022. doi: 10.1051/matecconf/201711206022
- Yuansong Liu, Mingjie Guan. Selected physical, mechanical, and insulation properties of carbon fiber fabric-reinforced composite plywood for carriage floors // European Journal of Wood and Wood Products. 2019. Vol. 77(03). doi: 10.1007/s00107-019-01467-y
- Zaynitdinov Olmos Irikovich, Rahimov Rustam Vyacheslavovich, Waail Mahmod Lafta, Ruzmetov Yadgor Ozodovich. Development of new polymer composite materials for the flooring of rail carriage // International Journal of Engineering & Technology. 2020. Vol. 9 (2). P. 378 – 381.
- Antipin D.Ya. (2019). Improvement of the calculation method for the strength of the upper linings of the side walls of gondola cars. Bulletin of the Bryansk State Technical University, 3(76), pp. 58 – 64. DOI: 10.30987/article_5c8b5ceb111c58.12769482
- Domenico Gattuso, Giancarla Cassone, Antonio Lucisano, Maurizio Lucisano, Francesco Lucisano. Automated rail wagon for new freight transport opportunities // IEEE International Conference on Models and Technologies for Intelligent Transportation Systems (MT-ITS). 2017. DOI: 10.1109/MTITS.2017.8005581
- Pavol Šťastniak, Lukáš Smetanka, Marián Moravčík. Structural Analysis of a Main Construction Assemblies of the New Wagon Prototype Type Zans // Manufacturing Technology. 2018. Vol. 18. No. 3. P. 510 – 515.
- S. Slavchev, V. Stoilov, S. Purgic. STATIC Strength Analysis Of The Body Of A Wagon, Series Zans // Journal of the Balkan Tribological Association. 2015. Vol. 21. No 1. P. 38 – 57.
- Wenfei Liu, Yuming Wang, Tianyou Wang. Box Girder Optimization by Orthogonal Experiment Design and GA-BP Algorithm in the Gondola Car Body // Processes. 2022. Vol. 10. Issue 74. https://doi.org/10.3390/pr10010074
- Rúben Silva, Diogo Ribeiro, Cássio Bragança, Cristina Costa, António Arêde, Rui Calçada. Model Updating of a FreightWagon Based on Dynamic Tests under Different Loading Scenarios // Applied Science. 2021. Vol. 11. 10691. https://doi.org/10.3390/app112210691
- Cheng Wei, Cai Kaiwu, Qu Fukang, Xiao Jin. Study on Fatigue Strength and Life of Freight Car Frame after Making Holes // MATEC Web of Conferences. 2018. Vol. 175. 01035. https://doi.org/10.1051/matecconf/2018175
- Andrzej Buchacz, Andrzej Baier, Marek Płaczek, Krzysztof Herbuś, Piotr Ociepka, Michał Majzner. Development and analysis of a new technology of freight cars modernization // Journal Of Vibroengineering. 2018. Vol. 20. Issue 8. P. 2978 – 2997.
- Fomin Oleksij, Lovska Alyona. Determination of dynamic loading of bearing structures of freight wagons with actual dimensions // Eastern-European Journal of Enterprise Technologies. 2021. Vol. 2/7 (110). P. 6 – 15. doi: https://doi.org/10.15587/1729-4061.2021.220534
- Fomin Oleksij, Lovska Alyona. Establishing patterns in determining the dynamics and strength of a covered freight car, which exhausted its resource // Eastern-European Journal of Enterprise Technologies. 2020. Vol. 6. Issue 7 (108). P. 21 – 29. doi: 10.15587/1729-4061.2020.217162
- Putyato A.V., Konovalov E.N., Afanaskov P.M. (2016). Forecasting the final resource of a hopper-doser car after long-term operation taking into account the actual physical and mechanical characteristics of the material of the supporting structure. Mechanics of machines, mechanisms and materials, 1(34), pp. 26 - 35.
- Improvement of the design of the hopper car for grain transportation / Kebal Y. V., Shatov V. A., Tyokotev O. M., Murashova N. G. // Collection of scientific papers State Economic and Technological University of Transport. "Transport systems and technologies" series, 2017, Issue. 30, pp.113 – 122.
- Substantiating the optimization of the loadbearing structure of a hopper car for transporting pellets and hot agglomerate / O. Fomin, A. Lovska, I. Skliarenko, Yu . Klochkov // Eastern-European Journal of Enterprise Technologies. – 2020. – № 1/7 (103) – P. 65 – 74. doi: 10.15587/1729-4061.2020.193408
- George Edward Street, Preetum Jayantilal Mistry, Michael Sylvester Johnson. Impact Resistance of Fibre Reinforced Composite Railway Freight Tank Wagons // Journal of Composites Science. – 2021, Vol. 5 (6), Issue 152, https://doi.org/10.3390/jcs5060152
- Zaynitdinov Olmos Irikovich, Ruzmetov Yadgor Ozodovich, Rustam Rahimov, Waail Mahmod Lafta. Development of new polymer composite materials for the flooring of rail carriage // International Journal of Engineering and Technology. – 2020. – Vol. 9(2). P. 378 – 381.
- Alexandru Ionut Patrascu, Anton Hadar, Stefan Dan Pastrama. Structural Analysis of a Freight Wagon with Composite Walls // MATERIALE PLASTICE. – 2020. – Vol. 57 (2). P. 140 – 151. https://doi.org/10.37358/MP.20.2.5360
- Nicholas Fantuzzia, Michele Bacciocchiab, David Benedettic, Jacopo Agnelli. The use of sustainable composites for the manufacturing of electric cars // Composites Part C. – 2021. – Vol. 4. 100096. https://doi.org/10.1016/j.jcomc.2020.100096
- Tautvydas Pravilonis, Edgar Sokolovskij. Analysis of composite material properties and their possibilities to use them in bus frame construction // Transport. – 2020. – Vol. 35, Issue 4. P. 368 – 378. https://doi.org/10.3846/transport.2020.13018
- I. D. Ibrahima, T. Jamirua, E. R. Sadikub, W. K. Kupolatic, K. Mpofud, A. A. Ezea, C. A. Uwa. Production and Application of Advanced Composite Materials in Rail Cars Development: Prospect in South African Industry // Procedia Manufacturing. – 2019. – Vol. 35. P. 471 – 476.
- Kondratiev А. Improving the mass efficiency of a composite launch vehicle head fairing with a sandwich structure // Eastern-European Journal of Enterprise Technologies. 2019. Vol. 6. No. 7 (102). P. 6 – 18. https://doi.org/10.15587/1729-4061.2019.184551
- A. Kondratiev, V. Gaidachuk, T. Nabokina, V. Kovalenko. Determination of the influence of deflections in the thickness of a composite material on its physical and mechanical properties with a local damage to its wholeness // Eastern-European Journal of Enterprise Technologies. 2019. Vol. 4. No. 1 (100). P. 6 – 13. https://doi.org/10.15587/1729-4061.2019.174025.
- Parunakyan V. E., Jenchako V. G. (2010). Investigation of the defrosting process of iron-containing raw materials in wagons with the use of computer technology "Data mining". Bulletin of the Azov State Technical University, 20, p. 267 - 274.
- Oleksij Fomin, Alyona Lovska, Vadym Dzhenchako, Olexandr Zhylinkov, Anna Fomina, Andrii Lytvynenko. (2022). Determining the features of temperature influence on the load-bearing structure of a hopper car with a composite cladding when transporting pellets to metallurgical enterprises. Eastern-European Journal of Enterprise Technologies, Vol. 1/7 (115), pp. 32 – 41.
- Krylov V.I., Klykov V.Ye., and Yasentsev V.F. (1980). Rolling stock brakes: textbook. Moscow: Transport, p. 271.
- Karyagina N.S., Medvedev V.V. (1978). Occupational safety in the wagon industry. Moscow: Transport, p. 222.