Improving the Quality of Internal Surfaces of Cylindrical Parts by Plastic Deformation
DOI:
https://doi.org/10.37547/ijasr-06-06-05Keywords:
Cylindrical parts, internal surface, roller burnishingAbstract
The quality of internal cylindrical surfaces is of considerable importance in mechanical engineering, as it directly affects the functional performance, wear resistance, contact behaviour and service life of machine components. Conventional finishing operations, such as boring, reaming, grinding and honing, can improve geometrical accuracy; however, they do not always ensure the required improvement in the surface layer properties. In this study, the improvement of internal surfaces of cylindrical parts by roller plastic deformation was investigated. The main objective of the research was to evaluate the effect of roller burnishing on surface roughness and Brinell hardness as the principal indicators of surface quality. The internal surface of a cylindrical specimen was treated by a roller plastic deformation process, and the resulting surface condition was assessed in terms of the roughness parameter Ra and hardness HB. The preliminary results showed that the treated surface achieved a surface roughness of Ra = 0.8 µm and a Brinell hardness of HB = 205. These findings indicate that roller plastic deformation can be used as an effective chipless finishing method for improving the quality of internal cylindrical surfaces. The improvement is mainly associated with the plastic flattening of surface asperities, densification of the surface layer and work hardening caused by local contact pressure. The proposed method may be recommended for finishing bushings, sleeves, hydraulic cylinder elements and other cylindrical parts with functional internal surfaces.
References
1. ISO 21920-2:2021. Geometrical product specifications (GPS) — Surface texture: Profile — Part 2: Terms, definitions and surface texture parameters. International Organization for Standardization, Geneva, 2021.
2. ISO 6506-1:2014. Metallic materials — Brinell hardness test — Part 1: Test method. International Organization for Standardization, Geneva, 2014.
3. El-Axir, M.H. An investigation into roller burnishing. International Journal of Machine Tools and Manufacture, 2000, 40(11), 1603–1617.
4. Hassan, A.M. The effects of ball- and roller-burnishing on the surface roughness and hardness of some non-ferrous metals. Journal of Materials Processing Technology, 1997, 72(3), 385–391.
5. Yen, Y.C., Sartkulvanich, P., Altan, T. Finite element modelling of roller burnishing process. CIRP Annals, 2005, 54(1), 237–240.
6. Revankar, G.D., Shetty, R., Rao, S.S., Gaitonde, V.N. Analysis of surface roughness and hardness in ball burnishing of titanium alloy. Measurement, 2014, 58, 256–268.
7. Loh, N.H., Tam, S.C. Effects of ball burnishing parameters on surface finish — A literature survey and discussion. Precision Engineering, 1988, 10(4), 215–220.
8. Maximov, J., Duncheva, G. Effect of roller burnishing and slide roller burnishing on surface integrity of AISI 316 steel: theoretical and experimental comparative analysis. Machines, 2024, 12(1), 51.
9. Duncheva, G., Maximov, J. Effect of roller burnishing and slide burnishing on the surface integrity of metallic components. Metals, 2024, 14(6), 710.
10. Celik, M. Effect of roller burnishing on the mechanical behaviour and surface quality of Ti6Al4V alloy. Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, 2023.
11. Babu, P.R., Prasad, T.S., Raju, A.V.S. Effect of internal roller burnishing on surface roughness and surface hardness of mild steel. International Journal of Applied Engineering Research, 2010, 1(4), 777–785.
12. Murthy, R.L., Kotiveerachary, B. Burnishing of metallic surfaces — A review. Precision Engineering, 1981, 3(3), 172–179.
13. Klocke, F., Bäcker, V., Wegner, H., Zimmermann, M. Finite element analysis of the roller burnishing process for fatigue resistance increase of engine components. Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, 2009.
14. Одинцов, Л.Г. Упрочнение и отделка деталей поверхностным пластическим деформированием: справочник. Москва: Машиностроение, 1987.
15. Суслов, А.Г. Качество поверхностного слоя деталей машин. Москва: Машиностроение, 2000.
16. Зайдес, С.А., Забродин, В.А., Мураткин, В.Г. Поверхностное пластическое деформирование. Иркутск: Издательство ИрГТУ, 2002.
17. ГОСТ Р 70117–2022. Шероховатость поверхности. Рекомендации по выбору. Москва: Росстандарт, 2022.
18. Holiqberdiyev, T.U. Mashinasozlik texnologiyasi asoslari. Toshkent: Noshir, 2012, 416 p. ISBN 978-9943-353-84-8.
19. Pyatayev, A.V., Muhamedjanov, B.K. Mashina detallari. Toshkent: IQTISOD-MOLIYA, 2007, 228 p.
20. Hasanov, O.A., Shoazimova, U.X. Mashinasozlik texnologiyasi asoslari: kurs ishi uchun o‘quv-uslubiy ko‘rsatmalar. Toshkent: Toshkent davlat texnika universiteti, 2022, 40 p.
21. Cobanoglu, T., Ozturk, S. Effect of burnishing parameters on the surface quality and hardness. Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, 2015, 229(2). doi: 10.1177/0954405414527962.
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