Determining patterns of vertical load on the prototype of a removable module for long-size cargoes

Authors

DOI:

https://doi.org/10.15587/1729-4061.2022.266855

Keywords:

transport mechanics, removable module, supporting structure, structural strength, structural adaptation

Abstract

The object of this study is the processes of occurrence, exposure to, and redistribution of loads in the supporting structure of a removable module for the transportation of long cargoes.

To adapt platform cars to the transportation of long loads, it is proposed to introduce a removable module with elastic-friction connections in the structure.

In order to select the optimal profiles for the removable module, in terms of minimal material consumption, the calculation was carried out in the Lira software package. Based on the calculation results, a spatial model of the concept of the removable module was built.

To determine the dynamic loads that act on the platform car loaded with a removable module, a mathematical simulation was carried out. It was established that the use of elastic-friction links in the structure of the removable module helps reduce its dynamic load, as well as the platform car, by 4.6 %. The resulting acceleration was taken into account when calculating the strength of the removable module. The calculation results showed that the strength of the removable module under operational loads is ensured.

A feature of the reported results is that the proposed design of a removable module makes it possible not only to adapt the platform car to the transportation of long loads but also to reduce its load in operation.

The scope of practical application of the results includes the engineering industry, in particular, railroad transport. Worth noting is that the conditions for the practical use of the results imply the introduction of elastic-friction links in the structure of the removable module.

The reported research will contribute to compiling recommendations for the design of modern vehicle structures, in particular removable type, as well as for improving the efficiency of rail transportation.

Author Biographies

Glib Vatulia, Ukrainian State University of Railway Transport

Doctor of Technical Sciences, Professor, Vice-Rector for Research

Alyona Lovska, Ukrainian State University of Railway Transport

Doctor of Technical Sciences, Associate Professor

Department of Wagon Engineering and Product Quality

Mykhailo Pavliuchenkov, Ukrainian State University of Railway Transport

PhD, Associate Professor

Department of Structural Mechanics and Hydraulics

Volodymyr Nerubatskyi, Ukrainian State University of Railway Transport

PhD, Associate Professor

Department of Electrical Power Engineering, Electrical Engineering and Electromechanics

Andrii Okorokov, Ukrainian State University of Science and Technologies

PhD, Associate Professor

Department of Management of Operational Work

Denys Hordiienko, ELAKS PJSC

Senior Engineer

Roman Vernigora, Ukrainian State University of Science and Technologies

Department of Railway Stations and Units

Ukrainian State University of Science and Technologies

Irina Zhuravel, Ukrainian State University of Science and Technologies

PhD

Department of Management of Operational Work

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Determining patterns of vertical load on the prototype of a removable module for long-size cargoes

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Published

2022-12-30

How to Cite

Vatulia, G., Lovska, A., Pavliuchenkov, M., Nerubatskyi, V., Okorokov, A., Hordiienko, D., Vernigora, R., & Zhuravel, I. (2022). Determining patterns of vertical load on the prototype of a removable module for long-size cargoes . Eastern-European Journal of Enterprise Technologies, 6(7 (120), 21–29. https://doi.org/10.15587/1729-4061.2022.266855

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Section

Applied mechanics