Endurance limit of the axial-piston hydraulic machine cylinder block

Khomiak, Yuriy; Kibakov, Oleksandr; Medvedev, Stanislav; Nikolenko, Ilya; Zheglova, Victoria

doi:10.29354/diag/116691

Artykuł - szczegóły

Tytuł artykułu

Endurance limit of the axial-piston hydraulic machine cylinder block

Autorzy

Khomiak Yuriy , Kibakov Oleksandr , Medvedev Stanislav , Nikolenko Ilya , Zheglova Victoria

Treść / Zawartość

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DOI

10.29354/diag/116691

Warianty tytułu

Języki publikacji

Abstrakty

The fatigue resistance of the cylinder block (CB) of an axial-piston hydraulic machine (APHM) made of tin bronze CuSn12 has been investigated. Fatigue tests of smooth and notched standard samples were performed and fatigue curves were constructed. The stress state of the CB is investigated by the finite element method. It is established that the maximum stresses are localized on a small part of the partition between axial cylinders holes loaded by internal pressure. A method for recalculating the established length of this zone of partition with an uneven distribution of dangerous stresses by an equivalent length with a constant stress equal to the maximum is proposed. The use of the statistical theory of the similarity of the fatigue failure of Serensen-Kogayev, the results of the fatigue tests of the samples and the calculation of the equivalent length made it possible to determine the endurance limit of the CB considered. The acceptability of the proposed method estimating the endurance limit by the known results of resource tests of the CB APHM 210.25 is confirmed.

Słowa kluczowe

complex stress state finite element method fatigue fracture similarity criterion fatigue curves of tin bronze CuSn12

złożony stan naprężeń maszyna hydrauliczna metoda elementów skończonych krzywe zmęczeniowe wytrzymałość

Wydawca

Polskie Towarzystwo Diagnostyki Technicznej

Czasopismo

Diagnostyka

Rocznik

2020

Tom

Vol. 21, No. 1

Strony

71--79

Opis fizyczny

Bibliogr. 25 poz., rys., tab.

Twórcy

autor

Khomiak Yuriy

Odessa National Polytechnic University, Ukraine

autor

Kibakov Oleksandr

kibakov60@gmail.com

Odessa National Maritime University, Ukraine

autor

Medvedev Stanislav

Odessa National Maritime University, Ukraine

autor

Nikolenko Ilya

Academy of Construction and Architecture, "V.I. Vernadsky Crimean Federal University"

autor

Zheglova Victoria

Odessa National Polytechnic University, Ukraine

Bibliografia

1. Kutuzov VK, Voronov SA, Sergeev YV. Investigation of the influence of loading regimes of axial-piston (in Russian). Hydraulic Machines on the Duration of their Tests. Assembling in Mechanical Engineering. Instrument-Making.2015; 95(6): 38-41.
2. Larchikov I, Yurov A, Stazhkov S et al. Analysis of an axial piston hydraulic machine of power intensive hydraulic drive system. Procedia Engineering. 2014; 69: 512-517. https://doi.org/10.1016/j.proeng.2014.03.020
3. Puzanov AV. Experience in using modern multiphysical software in the development of electrohydraulic actuators. (in Russian). CAD and Graphics.2008; 4: 75-79.
4. Schuhler G, Jourani A, Bouvier S, Perrochat JM. Multi Technical Analysis of Wear Mechanisms in Axial Piston Pumps. Journal of Physics.2017; Conf. Ser. 843 012077: 15 p.
5. Avrunin GA, Samorodov VB, Moroz II. The study of power losses in axial piston hydraulic machines (in Russian). Bulletin of National Technical University "KhPI".2017; 1264(42): 56-59. http://repository.kpi.kharkov.ua/handle/KhPIPress/33695
6. Bergada JM, Kumar S, Davies DL, Watton J. A complete analysis of axial piston pump leakage and output flow ripples. Applied Mathematical Modelling.2012; 36 (4): 1731-1751.
7. Ebara R. Some influencing variables on internal fatigue crack initiation in structural materials. Procedia Engineering.2016; 160: 21-28. https://doi.org/10.1016/j.proeng.2016.08.858
8. Erny C, Thevenet D, Cognard JY, Körner M. Fatigue assessment of naval welded assemblies. Procedia Engineering.2010; 2: 603-612.
9. Van Wittenberghe J, De Pauw J, De Baets P. Experimental determination of the fatigue life of modified threaded pipe couplings. Procedia Engineering.2010; 2 (1): 1849-1858.
10. Sandu N, Zaharia NL. Static and dynamic tests performed on a flat wagon. Problemy Kolejnictwa. 2014; 163: 67-77.
11. Vira V, Kulyk V, Chepil R, Kharchenko Y, Duriagina Z. The diagnostics and ways heat treatment optimization of a railway wheels steel. Diagnostyka. 2019;20(2):105-111. https://doi.org/10.29354/diag/109605
12. Kazuhiko Kasai, Hiroshi Ito, Shojiro Motoyui et al. Full-Scale shake table tests of 5-story steel building with various dampers. Joint conference proceedings 7th International Conference on Urban Earthquake Engineering (7CUEE) & 5th International Conference on Earthquake Engineering (5ICEE). 2010; 11-22.
13. Będkowski W. Аssessment of the fatigue life of machine components under service loading - a review of selected problems. Journal of Theoretical and Applied Mechanics, Warsaw.2014; 52 (2): 443-458.
14. Wang H, Meng FL. Simulation and optimal design of cylinder block of axial piston pump based on ANSYS, J. Advan. Mat. Res.2011; 186: 368-372. https://doi.org/10.4028/www.scientific.net/AMR.186. 368
15. DIN 743-2:2012-12. Tragfähigkeitsberechnung von Wellen und Achsen.- Teil 2: Formzahlen und Kerbwirkungszahlen (in German)
16. GOSТ 25.504-82 Calculations and strength tests. methods for calculating fatigue resistance characteristics (in Russian).
17. Stepnov MN. Calculational methods for constructing curves of multi-cyclic fatigue taking into account structural factors (in Russian). Bulletin of Machine Building.2012; 9: 17-24.
18. Cera A, Mancini G, Leonardi V, Bertini L. Analysis of methodologies for fatigue calculation for railway bogie frames. 8th World Congress on Railway Research R.1.1.3.2, Seoul. 2008; 13 p.
19. Zheglova V, Khomyak Y, Medvedev S, Nikolenko I. Numerical and analytical evaluation of service life of the details axial piston hydraulic machines with complicated configuration under cyclic loading. Procedia Engineering.2017; 176: 557-566.
20. Quan Ling-Xiao, Cao Yuan, Luo Hong-liang, Guo Rui, Guo Haixin. Fatigue analysis of the cylinder in the axial piston pump. Conference Paper. August 2015: 1-8. https://doi. 10.1109/FPM.2015.7337096
21. Oleynik NV, Medvedev SA. The method of rectifying the hyperbolic profile of the groove on fatigue specimens (in Russian). Machine Elements: The Republican Interdepartmental Scientific and Technical Proceedings.1974; 18: 99-105.
22. Kogaev VP, Makhutov NA, Gusenkov AP. Calculations of machine elements and structures for strength and durability: Handbook (in Russian). Moscow, Mashinostroyeniye Publ.1985; 224.
23. Dodin LG. Methods of testing axial-piston hydraulic machines (in Russian). Proceedings of VNIIStroydormash.1981; 92: 23-29.
24. Nikolenko IV, Khomyak YM, Kibakov AG. Calculation of the durability the cylinder block of hydraulic machines (in Russian). Bulletin of Machine Building.1988; 2: 26-29.
25. Gutyrya SS, Medvedev SA, Khomiak YM, Chanchin AV. Probabilistic analysis of fatigue durability of an epicycle of a wheel gearbox of the trolleybus. Bulletin of NTU "KhPI". Series: Problem of mechanical drive. - Kharkiv: NTU "KhPI", 2017; 25(1247):37-43.

Uwagi

Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2021).

Typ dokumentu

Bibliografia

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