In a harmonic reducer, the precision flexible thin-walled bearing (FTB), which is the core component, achieves the high reduction ratio requirement through its elastic deformation. The lifespan of a harmonic reducer mainly depends on this FTB. The special load conditions make it easy for the inner and outer rings, as well as the rolling elements, to suffer damage. The outer ring is especially prone to fatigue failure. Therefore, analyzing the dynamic response and fatigue life of FTBs under complex operating conditions is crucial for ensuring their reliability and durability. This paper designs a vibration-based fault diagnosis and lifespan testing machine to study the load conditions and kinematic characteristics of FTB in harmonic reducers. We derive a model for solving the fault characteristic frequencies of the inner and outer rings and rolling elements of FTB with elliptical characteristics. The results show that the fault characteristic frequencies of FTB vary within a range, whereas those of conventional bearings are fixed values. Additionally, normal FTBs contain periodic impact components in their vibration signals. In contrast, conventional bearings only produce such periodic impacts when damaged.
ChaoZShaopingWZimengW, et al. (2015) An accelerated life test model for harmonic drives under a segmental stress history and its parameter optimization. Chinese Journal of Aeronautics28(6): 1758–1765.
2.
FedericoGHugoVMEttoreP (2016) Influence of wave generator profile on the pure kinematic error and centrodes of harmonic drive. Mechanism and Machine Theory104: 100–117.
3.
GuoYZhaoXShangguanW, et al. (2020) Fault characteristic frequency analysis of elliptically shaped bearing. Measurement155: 107544.
4.
HanXJYuanSHZH (1993) Analysis & calculation of flexible bearings. Bearing47(9): 2–5.
5.
HangJJunyangLGuoX, et al. (2021) Modeling and analysis of pure kinematic error in harmonic drive. Mechanism and Machine Theory155: ■■■.
6.
HuQLiuZYangC, et al. (2021) Research on dynamic transmission error of harmonic drive with uncertain parameters by an interval method. Precision Engineering68: 285–300.
7.
HuiminDBoDChuZ, et al. (2022) An equivalent mechanism model for kinematic accuracy analysis of harmonic drive. Mechanism and Machine Theory173: ■■■.
8.
JiangYWangYZZhaoK, et al. (2017) Mechanical property analysis of flexible thin bearing in harmonic drive. Bearing(01): 10–14.
9.
LiWChenL (2022) Study on modeling and degradation law of transmission efficiency for harmonic reducer. Journal of Failure Analysis and Prevention22(5): 1943–1953.
10.
LiWHaoL (2022) Study on the degradation law of harmonic gear drive backlash with wear and assembly errors. Engineering Failure Analysis140: 106614.
11.
LiXSongCYangY, et al. (2020) Optimal design of wave generator profile for harmonic gear drive using support function. Mechanism and Machine Theory152(prepublish): 103941.
12.
LiuLXinHBCuiDQ, et al. (2014) The design of flexible bearing life test device. Applied Mechanics and Materials496: 861–864.
13.
MahantoSBSahooVMaitiR (2018) Effect of cam insertion on stresses in harmonic drive in industrial robotic joints. Procedia Computer Science133: 432–439.
14.
ManiwaKObaraS (2007) Mixed lubrication analysis between wave generator and flexspline in strain wave gearing: numerical analysis under load-torque applying operation. Journal of Japanese Society of Tribologist52(1): 19–36.
15.
ManiwaKObaraS (2007) Study on lubrication mechanisms of strain wave gearing. Jaxa Research & Development Report6: 1–170.
16.
NeerajKRKS (2023) Bearings in aerospace, application, distress, and life: a review. Journal of Failure Analysis and Prevention23(3): 915–947.
17.
OstapskiW (2010) Analysis of the stress state in the harmonic drive generator-flexspline system in relation to selected structural parameters and manufacturing deviations. Bulletin of the Polish Academy of Sciences, Technical Sciences58(4): 683–698.
18.
PhamAAhnH (2018) High precision reducers for industrial robots driving 4th industrial revolution: state of arts, analysis, design, performance evaluation and perspective. International Journal of Precision Engineering and Manufacturing-Green Technology5(4): 519–533.
19.
RenDQ (1990) Life calculation of flexible bearing used in harmonic gear transmission. Bearing63(3): 9–12.
20.
SahooVMaitiR (2018) Load sharing by tooth pairs in involute toothed harmonic drive with conventional wave generator cam. Meccanica53(1): 373–394.
21.
ShaoFCWenSZH (1991) Analysis of internal loads in flexible rolling bearings of harmonic gear drives. Machinery Design & Manufacture(1): 34–37.
22.
SumithSAbhayG (2022) Design and parametric study of flexible ball bearings: a finite element approach. Materials Today: Proceedings56(P1): 257–262.
23.
TjahjowidodoTAl-BenderFBrusselVH (2013) Theoretical modelling and experimental identification of nonlinear torsional behaviour in harmonic drives. Mechatronics23(5): 497–504.
24.
TuttleTDSeeringWP (1996) A nonlinear model of a harmonic drive gear transmission. IEEE Transactions on Robotics and Automation12(3): 368–374.
25.
WangYChenY (2022) Experimental study on the influence of flexible bearing clearance on natural frequency of harmonic reducer. Journal of Advanced Mechanical Design, Systems, and Manufacturing16(1): ■■■.
26.
WangTMTaoY (2014) Research status and industrialization development strategy of Chinese industrial robot. Journal of Mechanical Engineering50(9): 1–13.
27.
WangXHeZZiY (2010) Adaptive construction of multiwavelet and research on composite fault diagnosis of rolling bearing. Journal of Vibration Engineering23(04): 438–444.
28.
WangYYuYJiangW, et al. (2023) Static analysis of thin-walled flexible components in a harmonic reducer. Journal of Mechanical Science and Technology37(7): 3631–3642.
29.
XinziLChaoshengSCaichaoZ, et al. (2023) Load analysis of thin-walled flexible bearing in harmonic reducer considering assembly with flexspline and cam. Mechanism and Machine Theory180: ■■■.
30.
Yague-SpaudeEGonzalez-PerezIFuentes-AznarA (2020) Stress analysis of strain wave gear drives with four different geometries of wave generator. Meccanica55(prepublish): 2285–2304.
31.
YeNHDengXHeY, et al. (2018) Study on mechanical analysis and fatigue life of harmonic flexspline. Journal of Hunan University45(2): 18–25.
32.
Yi-ChengCYun-HaoCJui-TangT, et al. (2017) Study of a harmonic drive with involute profile flexspline by two-dimensional finite element analysis. Engineering Computations34(7): 2107–2130.
33.
YuYZhaoX (2024) Separation of fault characteristic impulses of flexible thin-wall bearing based on wavelet transform and correlated Gini index. Mechanical Systems and Signal Processing209: 111118.
34.
ZhangDLLiuF (2015) Dynamic and contact characteristic analysis of flexible bearing of harmonic gear drive based on finite element. Journal of Mechanical Transmission39(05): 50–53.
35.
ZhaoXYeB (2024) Elliptical periodic shock of flexible thin-walled elliptical bearing and its separation using singular value decomposition of adding additional signal. Digital Signal Processing153: 104641.
36.
ZhaoBHLiuZSSongCL, et al. (2002) Mechanics analysis on flexible thin wall bearing in harmonic transmission. Bearing10: 1–3.
37.
ZhaoDWangYZhaoK (2019) Fatigue life prediction of flexible bearings based on ABAQUS and nCode-DesignLife. IOP Conference Series: Materials Science and Engineering474(1): 012058.
38.
ZhaoXZHGuoYYLiZH, et al. (2020) Injury characteristic frequency analysis of flexible thin-wall bearing. Journal of Vibration Engineering33(6): 11.
39.
ZhaoXGuoYYeB (2021) Kinematic characteristics and fault feature frequency of flexible thin-wall ellipse bearing. Mechanical Systems and Signal Processing149: 107222.
40.
ZhaoZSunSXuW, et al. (2024) Dynamics modeling and fault diagnosis of flexible thin-walled elliptical bearings in harmonic reducers. Measurement238: 115378.
41.
ZhenLQingshanWBinQ, et al. (2022) Vibration characteristic analysis of flexible rotor-bearing system subjected to external combined loads. European Journal of Mechanics / A Solids96: ■■■.
