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Advances in Manufacturing
Erschienen in: Advances in Manufacturing 4/2023

17.12.2022

Multi-dimensional controllability analysis of precision ball bearing integrity

verfasst von: Lai Hu, Jun Zha, Wei-Hua Zhao, Xiao-Fei Peng, Yao-Long Chen

Erschienen in: Advances in Manufacturing | Ausgabe 4/2023

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Abstract

Many factors affect the integrity of precision ball bearings. In this study, the multi-dimensional controllability of precision ball bearings produced in different company brands (bearing A and bearing B) were studied and compared. The geometric errors (flatness, parallelism, roundness and cylindricity of inner and outer rings, roundness, groove and roughness of inner and outer rings) and vibration errors of bearings were analyzed. Concurrently, the residual stress, residual austenite content, element content ratio, metamorphic layer and temperature-vibration displacement coupling test were also analyzed. Based on the above analysis conclusion, the bearing fatigue life test was carried out for 2 150 h. The reliability of the conclusion is proved again as follows. When the residual austenite content in the raceway of precision ball bearing is 10%, the axial residual stress is 877.4 MPa; the tangential residual stress is 488.1 MPa; the carbon content is 6%; the test temperature of bearing is the lowest; and the service life is prolonged.
Vorheriger Artikel Coupling effect of micro-textured tools and cooling conditions on the turning performance of aluminum alloy 6061
Nächster Artikel Identification of nonlinear process described by neural fuzzy Hammerstein-Wiener model using multi-signal processing

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Literatur
1.
Weck M, Koch A (1993) Spindle bearing systems for high-speed applications in machine tools. CIRP Ann Manuf Technol 42:445–448CrossRef
2.
Nilsson R, Dwyer-Joyce R, Olofsson U (2006) Abrasive wear of rolling bearings by lubricant borne particles. Proc Inst Mech Eng Part J J Eng Tribol 220:429–439CrossRef
3.
Shao Y, Kang R, Liu J (2020) Rolling bearing fault diagnosis based on the coherent demodulation model. IEEE Access 8:207659–207671CrossRef
4.
Harris TA, Kotzalas MN (2006) Advanced concepts of bearing technology: rolling bearing analysis. CRC Press, Boca RatonCrossRef
5.
Harris TA, Barnsby RM, Kotzalas MN (2001) A method to calculate frictional effects in oil-lubricated ball bearings. Tribol Trans 44(4):704–708CrossRef
6.
Harris T, Mindel M (1973) Rolling element bearing dynamics. Wear 23(3):311–337CrossRef
7.
Jones A (1960) A general theory for elastically constrained ball and radial roller bearings under arbitrary load and speed conditions. J Basic Eng 82(2):309–320CrossRef
8.
Poplawski J (1972) Slip and cage forces in a high-speed roller bearing. J Lubr Technol 94(2):143–150CrossRef
9.
Rumbarger J, Filetti E, Gubernick D (1973) Gas turbine engine mainshaft roller bearing-system analysis. J Lubr Technol 95(4):401–416CrossRef
10.
Sun J, Wood R, Ling W et al (2005) Wear monitoring of bearing steel using electrostatic and acoustic emission techniques. Wear 259(7):1482–1489CrossRef
11.
Yu ZQ, Yang ZG (2007) Failure analysis on excess wear of rolling bearing of motors for supply blower. Lubr Eng 32(5):90–93
12.
Zhang Q, Luo J, Chen C et al (2019) Experimental study on skid damage of rolling bearing. Lubr Eng 44(9):64–69
13.
Walters CT (1971) The dynamics of ball bearings. J Lubr Technol 93(1):1–10CrossRef
14.
Geer TE, Kannel JW, Stockwell RD et al (1969) Study of high-speed angular-contact ball bearings under dynamic load. NASA Tech Brief 69:10367
15.
Gupta PK (1975) Transient ball motion and skid in ball bearings. J Lubr Technol 97(2):261–269CrossRef
16.
Gupta PK (1983) Some dynamic effects in high-speed solid-lubricated ball bearings. Tribol Trans 26(3):393–400
17.
Gupta PK (1986) Advanced dynamics of rolling elements. J Appl Mech 53(3):731–732CrossRef
18.
Gupta P, Winn L, Wilcock D (1977) Vibrational characteristics of ball bearings. J Lubr Technol 99(2):284–287CrossRef
19.
Zhang FY (2019) Study on microstructure and wear resistance of the metamorphic layer of GCr15 bearing steel in hard cutting. Dissertation, Dalian University of Technology
20.
Mao C, Huang XM, Li YL et al (2010) Characteristics of affected layer in surface grinding of hardened bearing steel. Nanotechnol Precis Eng 8(4):356–361
21.
Fang MW (2017) Failure analysis of skidding damage of rear bearing aero-engine main shaft. Dissertation, Guizhou University
22.
Hu CY, Liu XL, Li Y (2011) Failure analysis on main fuel pump bearing of engine. Heat Treat Met s1:64–67
23.
Chen X, Rowe W, Mccormack D (2000) Analysis of the transitional temperature for tensile residual stress in grinding. J Mater Process Technol 107(1/3):216–221CrossRef
24.
Fergani O, Shao Y, Lazoglu I (2014) Temperature effects on grinding residual stress. Procedia CIRP 14:2–6CrossRef
25.
Kruszyński BW, Wójcik R (2001) Residual stress in grinding. J Mater Process Technol 109(3):254–257CrossRef
26.
Mahdi M, Zhang L (1999) Applied mechanics in grinding: part 7: residual stresses induced by the full coupling of mechanical deformation, thermal deformation and phase transformation. Int J Mach Tools Manuf 39(8):1285–1298CrossRef
27.
Paul S, Chattopadhyay A (1995) Effects of cryogenic cooling by liquid nitrogen jet on forces, temperature and surface residual stresses in grinding steels. Cryogenics 35(8):515–523CrossRef
28.
Trausmuth A, Godor I, Grun F (2019) Damage models of different hardness layers subjected to point contact. Wear 430/431:157–168CrossRef
29.
Gu JG, Zhang YM, Liu HY (2019) Influences of wear on dynamic characteristics of angular contact ball bearings. Meccanica 54(7):945–965MathSciNetCrossRef
30.
31.
Wood PD, EvansHE PCB (2011) Investigation into the wear behaviour of stellite 6 during rotation as an unlubricated bearing at 600 °C. Tribol Int 44(12):1589–1597CrossRef
32.
Qian K, Li JH, Wu XB (2009) Experimental study on retained austenite and fatigue life of GCr15 steel bearings. Mech Mater 47(6):78–80
33.
Xu HQ (2017) Internal load sequence and life analysis of rolling bearing. Dissertation, Zhejiang University
34.
Zhou C, Qian J, Xing Y et al (2017) Main failure mode of oil-air lubricated rolling bearing installed in high speed machining. Tribol Int 112:68–74CrossRef
Metadaten
Titel
Multi-dimensional controllability analysis of precision ball bearing integrity
verfasst von
Lai Hu
Jun Zha
Wei-Hua Zhao
Xiao-Fei Peng
Yao-Long Chen
Publikationsdatum
17.12.2022
Verlag
Shanghai University
Erschienen in
Advances in Manufacturing / Ausgabe 4/2023
Print ISSN: 2095-3127
Elektronische ISSN: 2195-3597
DOI
https://doi.org/10.1007/s40436-022-00424-y

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