Experimental investigations of dynamic loads in the process of operating the crane running wheel with an elastic insert

N. Fidrovska Kharkiv National Automobile and Road University https://orcid.org/0000-0002-5248-273X
E. Slepugnikov National University of Civil Defense of Ukraine https://orcid.org/0000-0002-5449-3512
I. Perevoznik Kharkiv State Automobile and Road College

Keywords: running wheel, dynamic loads, movement mechanism, elastic insert, load truck, experimental studies

Abstract

The article considers an experimental investigation of dynamic loads which occur while moving the travelling crane truck. Crane wheels are the elements which are mostly prone to wear off. Decrease in their durability leads to the increase of expenditures on maintenance and downtime. Therefore, the increase in durability of crane wheels is a topical issue of contemporary cranebuilding. All running wheels constructions are rigid enough to resist shocks and distortions caused by deviations of the rail track from the recommended values and lead to significant wear and tear of the flanges and rails.
For comparison, we chose solid two-ribbed running wheels with a cylindrical rim, which are used on almost all travelling cranes and wheels of the new design, consisting of three layers and having an elastic insert, which is made of special rubber.
To check the theoretical data obtained earlier, an experiment was carried out on an overhead travelling crane with a capacity of 5 tons, span of 22.5 m, lifting height of 8 m, and operating mode 7 K. The study of the vibration state was carried out on a beam in the middle of the span, on the axle of the driven wheel of the crane truck and on the axle of the drive wheel of the crane of conventional design.
The analysis of the received results showed that when using a running wheel with an elastic insert the dynamic factors when moving a load truck decrease. The analysis of the regularities of vibration signs formation in different points of the travelling crane construction was conducted. The proposed design and calculation procedure of the running wheel with an elastic insert allows increasing its operational reliability.

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References

Haniszewski, T., 2017. Modeling the dynamics of cargo lifting process by overhead crane for dynamic overload factor estimation. Journal of vibroengineering. Vol. 19, Issue 1, pp. 75–86. DOI https://doi.org/10.21595/ jve.2016.17310.

Slepugnikov E. 2015. Vyznachenna dynamichnyh navantaqen pre peresuvany vantaqnogo vizka mostovogo krana. Mashinobuduvanny. №16, pp.34-37.

Romacevych , Y., Loveikin, V. , Stekhno, O., 2019. CLOSED-LOOP OPTIMAL CONTROL OF A SYSTEM „TROLLEY - PAYLOAD”. UPB Scientific Bulletin, Series D: Mechanical Engineering. Vol. 81, Issue 2, pp. 5–12.

Franchuk, V.P., Ziborov, K.A., Krivda, V.V., Fedoriachenko, S.O., 2017. On wheel rolling along the rail regime with longitudinal load. Naukovyi Visnyk NHU, № 3, pp. 62–67.

Markine, V., Mashal, A , Ren, M., 2018. Effect of wheel–rail terface parameters on contact stability in explicit finite element analysis. Proc IMechE, Part F: J Rail and Rapid Transit. Vol. 232 (6), рр. 1879-1894. DOI: 10.1177/0954409718754941.

Konowrocki, R., Chojnacki, A. 2020. Analysis of rail vehicles’ operational reliability in the aspect of safety against derailment based on various methods of determining the assessment criterion. Eksploatacja i Niezawodnosc – Maintenance and Reliability Vol. 22, No.1, pp. 73–85. http://dx.doi.org/10.17531/ein.2020.1.9.

Ma, Y., Markine, V., Mashal A., et al., 2017. Improving performance of finite element simulations on wheel-rail interaction using a coupling strategy. Proc IMechE, Part F: J Rail and Rapid Transit. doi: 10.1177/ 0954409717745983.

Raksha, S.V., Anofriev, P.G., Bohomaz, V.M., Kuropiatnyk, O.S., 2019. Mathematical and S-models of cargo oscillations during movement of bridge crane. Naukovyi Visnyk NHU, № 2, pp. 108–115.

Artamonov D. 2017. Modernizaziya mehanizma peredviqeniya teleqki mostovogo krana. Molodoy issledovatel.V,5(8), pp.12-16.

Fidrovska N., Slepuzhnikov E., Perevoznik I., 2019. A contact problem solution with taking into account shear deformations. Science and Education a New Dimension. Natural and Technical Sciences, VII(23), Issue 193, pp. 80–81. https://doi.org/10.31174/SEND-NT2019-193VII23-20.

Slepuzhnikov E., 2016. Raschet trehsloynoy zilindricheskoy konstrukzii. Gornaya mehanika I mashinobuduvannya . №1. pp. 62–65.

Fidrovska N., Slepugnikov E., Chernishenko A. 2015. Dinamichni navantaqennya hodovih kolis s gumovimi vstavkami. Mashinobuduvannya, №15, с. 87–91.