Підвищення ефективності машин і механізмів агропромислового комплексу застосуванням підшипників ковзання з криволінійними твірними внутрішньої циліндричної поверхні

Олексій Садовий; Олег Савенков; Ігор Сидорика; Юрій Щербак; Анна Кондратьєва

[1] Borysiuk, D.V., Tverdokhlib, I.V., Kupchuk, I.M., & Polievoda, Yu.A. (2023). Mathematical model of diagnosing the bearing assembly of the hub of steered bridges of wheeled tractors of traction class 1,4. Engineering, Energy, Transport AIC, 1(120), 14-20. doi: 10.37128/2520-6168-2023-1-2.

[2] Guo, A., Wang, X., Jin, J., Hua, D.Y., & Hua, Z. (2015). Experimental test of static and dynamic characteristics of tilting-pad thrust bearings. Advances in Mechanical Engineering, 7(7). doi: 10.1177/1687814015593878.

[3] Henry, Y., Bouyer, J., & Fillon, M. (2015). An experimental analysis of the hydrodynamic contribution of textured thrust bearings during steady-state operation: A comparison with the untextured parallel surface configuration. Proceedings of the Institution of Mechanical Engineers, Part J: Journal of Engineering Tribology, 229(4), 362-375. doi: 10.1177/1350650114537484.

[4] Kindrachuk, M., Kharchenko, V., Humeniuk, I., & Leusenko, D. (2023). Influence of alloying the metal matrix on the anti-friction properties of eutectic coatings. Problems of Friction and Wear, 1(98), 63-69. doi: 10.18372/0370-2197.1(98).17360.

[5] Marchuk, R., & Mnatsakanov, R. (2023). Analysis of polymer composite materials for sliding bearings. Problems of Friction and Wear, 1(98), 55-62. doi: 10.18372/0370-2197.1(98).17359.

[6] Martins, D.H.C.S.S., de Lima, A.A., Pinto, M.F., Hemerly, D.D.O., Prego, T.D.M., e Silva, F. L., ... Haddad, D.B. (2023). Hybrid data augmentation method for combined failure recognition in rotating machines. Journal of Intelligent Manufacturing, 34(4), 1795-1813. doi: 10.1007/s10845-021-01873-1.

[7] Matviychuk, V.A., Gaidamak, O.L., & Karpiichuk, M.F. (2022). Prospects for creating surface layers of deta-leu with increased tribological characteristics using gas-dynamic filling. Engineering, Energy, Transport AIC, 1(116), 83-95. doi: 10.37128/2520-6168-2022-1-10.

[8] Mitra, M., Singha, N.R., & Chattopadhyay, P.K. (2023). Review on renewable energy potential and capacities of South Asian countries influencing sustainable environment: A comparative assessment. Sustainable Energy Technologies and Assessments, 57, 103295. doi: 10.1016/j.seta.2023.103295.

[9] Papadopoulos, C.I., Kaiktsis, L., & Fillon, M. (2014). Computational fluid dynamics thermohydrodynamic analysis of three-dimensional sector-pad thrust bearings with rectangular dimples. Journal of Tribology, 136(1), 011702. doi: 10.1115/1.4025245.

[10] Phiri, R., Rangappa, S.M., Siengchin, S., Oladijo, O.P., & Dhakal, H.N. (2023). Development of sustainable biopolymer-based composites for lightweight applications from agricultural waste biomass: A Review. Advanced Industrial and Engineering Polymer Research, 6(4), 436-450. doi: 10.1016/j.aiepr.2023.04.004.

[11] Pichler, J., Nothnangel, R.M., Besser, C., Pisarova, L., Dörr, N., Marchetti-Deschmann, M., & Frauscher, M. (2023). A comprehensive review of sustainable approaches for synthetic lubricant components. Green Chemistry Letters and Reviews, 16(1), 2185547. doi: 10.1080/17518253.2023.2185547.

[12] Soni, A., Das, P. K., Yusuf, M., Ridha, S., Kamyab, H., Chelliapan, S., ... Mussa, Z.H. (2023). Valorization of post-consumers plastics and agro-waste in sustainable polymeric composites for tribological applications. Waste and Biomass Valorization. doi: 10.1007/s12649-023-02103-w.

[13] Syrovatka, V. (2023). Obtaining composite powder materials and coatings based on titanium diboride. International Science Journal of Engineering & Agriculture, 2(3), 10-17. doi: 10.46299/j.isjea.20230203.02.

[14] Terra, I.C.D.C., Batista, F.G., Silva, D.W., Scatolino, M.V., Júnior, F.T.A., Martins, M.A., & Mendes, L.M. (2023). Mining waste and coconut fibers as an eco-friendly reinforcement for the production of concrete blocks. Environmental Science and Pollution Research, 30, 62641-62652. doi: 10.1007/s11356-023-26493-5.

[15] Vinod, B., Suresh, S., Reddy, S.S.K., & Sujith, K.S. (2023). Tribological and mechanical characteristics of Mg-Zn6.0-Y1.2-Zr0.2 alloy by SPS technique: Natural and agro-waste utilization. Journal of Bio-and Tribo-Corrosion, 9, 5. doi: 10.1007/s40735-022-00728-3.

[16] Wadhwa, A.S., & Chauhan, A. (2023). An overview of the mechanical and tribological characteristics of non-ferrous metal matrix composites for advanced engineering applications. Tribology in Industry, 45(1), 51-80. doi: 10.24874/ti.1359.08.22.12.

[17] Woo, S., O’Neal, D.L., Hassen, Y.M., & Mebrahtu, G. (2023). Enhancing the fatigue design of mechanical systems such as refrigerator to reserve food in agroindustry for the circular economy. Sustainability, 15(8), 7010. doi: 10.3390/su15087010.

[18] Xu, A., Darbandi, M., Javaheri, D., Navimipour, N.J., Yalcin, S., & Salameh, A.A. (2023). The management of IoT-based organizational and industrial digitalization using machine learning methods. Sustainability, 15(7), 5932. doi: 10.3390/su15075932.

[19] Yeromenko, O.V., Yeriomina, Ye.A., & Tomina, A.-M. (2023). Supply of operation modes on tribological power to basaltoplastics based on polytetafluororetylene. Mathematical Modeling, 1(48), 48-55. doi: 10.31319/2519-8106.1(48)2023.280072.

[20] Zhang, W., & Zhu, B. (2023). Optimization design for slip/no-slip configuration of hydrophobic sliding bearings using Monte Carlo search. Tribology International, 178(A), 108034. doi: 10.1016/j.triboint.2022.108034.

Sadovoy, О., Savenkov, O., Sydoryka, I., Shcherbak, Yu., & Kondratieva, А. (2023). Increasing the efficiency of machines and mechanisms of the agro-industrial complex using sliding bearings with curvilinear generators of the internal cylindrical surface. Ukrainian Black Sea Region Agrarian Science, 27(4), 60-70. https://doi.org/10.56407/bs.agrarian/4.2023.60

Вісник аграрної науки Причорномор'я

Стаття

Вісник аграрної науки Причорномор'я

Стаття

ЦИТУВАТИ

Використані джерела