Undetected axle cracks in in-service train wheelsets may lead to axle fracture and catastrophic consequences. Vibration components at integer multiples of the rotational frequency (n × Rev components) have been demonstrated as effective indicators for revealing the presence of cracks, since they originate directly from the nonlinear modulation introduced by crack breathing behavior. However, existing studies on these indicators rarely consider the test with health baseline established from long-term wheelset wear, nor do they provide sufficient validation under high-speed operating conditions. In this study, an experimental campaign was conducted to establish a long-mileage health baseline (14,500 km) under full-scale wheelset test bench laboratory conditions, and three-axis acceleration signals were acquired from sensors mounted on axle-box of the wheelset within a wide speed range (100–300 km/h). The effectiveness of n × Rev indicators for crack detection was evaluated. Furthermore, a non-dimensional n × Rev indicator is proposed to mitigate the influence introduced by long-term wear on crack indication. Through a data-driven implementation case, the advantages of joint decision-making based on multiple n × Rev indicators are demonstrated. The results provide both qualitative and quantitative support for the development of wheelset crack monitoring tools based on on-board sensor nodes.
PanAWenCWangH, et al. Premature fatigue failure analysis of axle in permanent magnet direct-drive electric locomotive. Materials (Basel)2025; 18: 3747.
2.
ZouLZengDLiY, et al. Experimental and numerical study on fretting wear and fatigue of full-scale railway axles. Rail Eng Sci2020; 28: 365–381.
3.
ZengDZhangYLuL, et al. Fretting wear and fatigue in press-fitted railway axle: A simulation study of the influence of stress relief groove. Int J Fatigue2019; 118: 225–236.
4.
SchmidováEPaščenkoPCulekB, et al. Premature failures of railway axles after repeated pressing. Eng Fail Anal2021; 123: 105253.
5.
HirakawaKToyamaKKubotaM. The analysis and prevention of failure in railway axles. Int J Fatigue1998; 20: 135–144.
6.
ZhuCHeJPengJ, et al. Failure mechanism analysis on railway wheel shaft of power locomotive. Eng Fail Anal2019; 104: 25–38.
7.
FolettiSBerettaSGurerG. Defect acceptability under full-scale fretting fatigue tests for railway axles. Int J Fatigue2016; 86: 34–43.
8.
EpastoGDistefanoFGuL, et al. Design and optimization of Metallic Foam Shell protective device against flying ballast impact damage in railway axles. Mater Des2020; 196: 109120.
9.
HoddinottDS. Railway axle failure investigations and fatigue crack growth monitoring of an axle. Proc Inst Mech Eng F J Rail Rapid Transit2004; 218: 283–292.
10.
BerettaSCarboniMLo ConteA, et al. An investigation of the effects of corrosion on the fatigue strength of AlN axle steel. Proc Inst Mech Eng F J Rail Rapid Transit2008; 222: 129–143.
11.
HannemannRKösterPSanderM. Fatigue crack growth in wheelset axles under bending and torsional loading. Int J Fatigue2019; 118: 262–270.
12.
HannemannRKösterPSanderM. Investigations on crack propagation in wheelset axles under rotating bending and mixed mode loading. Proc Struct Integr2017; 5: 861–868.
13.
MancaD. New insights into the Viareggio railway accident. Chem Eng Trans2014; 36: 13–18.
14.
LanducciGTugnoliABusiniV, et al. The Viareggio LPG accident: lessons learnt. J Loss Prev Process Ind2011; 24: 466–476.
15.
EvansAW. Rail safety and rail privatisation in Britain. Accid Anal Prev2007; 39: 510–523.
ZerbstUVormwaldMAnderschC, et al. The development of a damage tolerance concept for railway components and its demonstration for a railway axle. Eng Fract Mech2005; 72: 209–239.
19.
CarboniMCantiniS. Advanced ultrasonic “Probability of Detection” curves for designing in-service inspection intervals. Int J Fatigue2016; 86: 77–87.
20.
CavutoAMartarelliMPandareseG, et al. FEM based design of experiment for train wheelset diagnostics by laser ultrasonics. Ultrasonics2021; 113: 106368.
21.
SchiavoneBKleinRM. Magnetic particle inspection of freight car axles and wheel sets. American Society of Mechanical Engineers Digital Collection.
22.
MaTSunZChenQ. Study on crack features in images of fluorescent magnetic particle inspection for railway wheelsets. Insight: Non-Destr Test Cond Monit2018; 60: 519–524.
23.
BernalESpiryaginMColeC. Ultra-low power sensor node for on-board railway wagon monitoring. IEEE Sens J2020; 20: 15185–15192.
24.
CiiSTomasiniGBacciML, et al. Solar wireless sensor nodes for condition monitoring of freight trains. IEEE Trans Intell Transp Syst2022; 23: 3995–4007.
25.
DebattistiNZanelliFGiuliettiN, et al. Anomaly detection of high-speed train braking system based on wireless sensors network. Measurement2025; 253: 117774.
26.
BruniSCarboniMCrivelliD, et al. A preliminary analysis about the application of acoustic emission and low frequency vibration methods to the structural health monitoring of railway axles. Chem Eng Trans2013; 33: 697–702.
27.
CavaliniJr AASanchesLBachschmidN, et al. Crack identification for rotating machines based on a nonlinear approach. Mech Syst Signal Process2016; 79: 72–85.
28.
LiZMolodovaMNunezA, et al. Improvements in axle box acceleration measurements for the detection of light squats in railway infrastructure. IEEE Trans Ind Electron2015; 62: 4385–4397.
29.
SabbioniECarboniMTarsitanoD, et al. Crack detection in railway axles using continuous monitoring and periodic non-destructive inspection: experimental investigation on a freight wagon using a full-scale roller rig. Struct Health Monit2025; 24(6): 3487–3502.
30.
GuanTDengXWangJ. Dynamic response of axle box bearing for high-speed train considering wheelset flexibility and polygonal wear. Sci Rep2023; 13: 22680.
31.
SunQChenCKempAH, et al. An on-board detection framework for polygon wear of railway wheel based on vibration acceleration of axle-box. Mech Syst Signal Process2021; 153: 107540.
32.
LiuPYangSLiuY. Full-scale test and numerical simulation of wheelset-gear box vibration excited by wheel polygon wear and track irregularity. Mech Syst Signal Process2022; 167: 108515.
33.
KushwahaNPatelVN. Modelling and analysis of a cracked rotor: a review of the literature and its implications. Arch Appl Mech2020; 90: 1215–1245.
34.
RolekPBruniSCarboniM. Condition monitoring of railway axles based on low frequency vibrations. Int J Fatigue2016; 86: 88–97.
35.
DimarogonasAD. Vibration of cracked structures: a state of the art review. Eng Fract Mech1996; 55: 831–857.
36.
XuWSuZRadzieńskiM, et al. Nonlinear pseudo-force in a breathing crack to generate harmonics. J Sound Vib2021; 492: 115734.
37.
GiannopoulosGIGeorgantzinosSKAnifantisNK. Coupled vibration response of a shaft with a breathing crack. J Sound Vib2015; 336: 191–206.
38.
GeorgantzinosSKAnifantisNK. An insight into the breathing mechanism of a crack in a rotating shaft. J Sound Vib2008; 318: 279–295.
39.
El AremS. Nonlinear analysis, instability and routes to chaos of a cracked rotating shaft. Nonlinear Dyn2019; 96: 667–683.
40.
DarpeAKGuptaKChawlaA. Transient response and breathing behaviour of a cracked Jeffcott rotor. J Sound Vib2004; 272: 207–243.
41.
DarpeAKGuptaKChawlaA. Dynamics of a bowed rotor with a transverse surface crack. J Sound Vib2006; 296: 888–907.
42.
JarilloJMMorenoJAlfiS, et al. Novel technology concepts and architecture for on-board condition-based monitoring of railway running gear: the RUN2Rail vision. Proc Inst Mech Eng F J Rail Rapid Transit2021; 235: 616–630.
43.
HassanMBruniSCarboniM. Crack detection in railway axle using horizontal and vertical vibration measurements. In: 7th IET Conference on Railway Condition Monitoring 2016 (RCM 2016), Birmingham, UK, 27–28 September 2016, pp.1–6. IET.
44.
HassanMBruniS. Experimental and numerical investigation of the possibilities for the structural health monitoring of railway axles based on acceleration measurements. Struct Health Monit2019; 18: 902–919.
45.
SabbioniETarsitanoDHassanM, et al. Crack detection in railway axles using axle-box vibration measurements: experimental investigation using a full-scale roller rig. In: HuangWAhmadianM (eds) Advances in dynamics of vehicles on roads and tracks III. Springer Nature Switzerland, 2025, pp.1134–1142.
46.
ZhangWHuangYDongD, et al. A fast identification method of train axle crack parameters based on semi-inverse Kriging method. Proc Inst Mech Eng F J Rail Rapid Transit2023; 237: 835–847.
47.
GómezMJCastejónCGarcía-PradaJC. Crack detection in rotating shafts based on 3 × energy: analytical and experimental analyses. Mech Mach Theory2016; 96: 94–106.
48.
ZhangMCavalloATomasiniG. Data-driven diagnosis of railway wheel flat based on multi-channel vibration data fusion. Measurement2026; 264: 120191.
49.
BraghinFLewisRDwyer-JoyceRS, et al. A mathematical model to predict railway wheel profile evolution due to wear. Wear2006; 261: 1253–1264.
50.
BraghinFBruniSGiorgioD. Experimental and numerical investigation on the derailment of a railway wheelset with solid axle. Veh Syst Dyn2006; 44: 305–325.
51.
BraghinFBruniSRestaF. Wear of railway wheel profiles: a comparison between experimental results and a mathematical model. Veh Syst Dyn2002; 37: 478–489.
52.
LiuBBruniS. A method for testing railway wheel sets on a full-scale roller rig. Veh Syst Dyn2015; 53: 1331–1348.
53.
CantiniSCervelloS. The competitive role of wear and RCF: full scale experimental assessment of artificial and natural defects in railway wheel treads. Wear2016; 366–367: 325–337.
54.
CavalloACiiSTomasiniG, et al. Study and testing of wheelset wheel-flat identification features through axle-box vibration measurements. Transp Saf Environ2025; 7(4): tdaf060. https://doi.org/10.1093/tse/tdaf060
55.
BruniSCheliFRestaF. A model of an actively controlled roller rig for tests on full-size railway wheelsets. Proc Inst Mech Eng F J Rail Rapid Transit2001; 215: 277–288.
56.
AlemiACormanFLodewijksG. Condition monitoring approaches for the detection of railway wheel defects. Proc Inst Mech Eng F J Rail Rapid Transit2017; 231: 961–981.
FyfeKRMunckEDS. Analysis of computed order tracking. Mech Syst Signal Process1997; 11: 187–205.
59.
LuSYanRLiuY, et al. Tacholess speed estimation in order tracking: a review with application to rotating machine fault diagnosis. IEEE Trans Instrum Meas2019; 68: 2315–2332.
60.
ZhaoMLinJWangX, et al. A tacho-less order tracking technique for large speed variations. Mech Syst Signal Process2013; 40: 76–90.
RandallRB. A history of cepstrum analysis and its application to mechanical problems. Mech Syst Signal Process2017; 97: 3–19.
64.
OppenheimAVSchaferRW. From frequency to quefrency: a history of the cepstrum. IEEE Signal Process Mag2004; 21: 95–106.
65.
ChildersDGSkinnerDPKemeraitRC. The cepstrum: a guide to processing. Proc IEEE1977; 65: 1428–1443.
66.
BogertBP. The quefrency alanysis of time series for echoes: cepstrum, pseudoautocovariance, cross-cepstrum and saphe cracking. In: Proceedings of the Symposium Time Series Analysis. 1963, pp.209–243. John Wiley & Sons.
67.
IliopoulosIASakellariouJS. Remaining useful life estimation of hollow worn railway vehicle wheels via on-board random vibration-based wheel tread depth estimation. Sensors2024; 24: 375.
68.
XuPYaoWZhaoY, et al. Condition monitoring of wheel wear for high-speed trains: a data-driven approach. In: 2018 IEEE International Conference on Prognostics and Health Management (ICPHM), Seattle, WA, USA, 11–13 June 2018, pp.1–8. IEEE.
69.
HeXDingJShiT, et al. An intelligent onboard condition monitoring method of wheelset bearings under time-varying speed. IEEE Trans Instrum Meas2025; 74: 1–15.
70.
GasparettoLAlfiSBruniS. Data-driven condition-based monitoring of high-speed railway bogies. Int J Rail Transp2013; 1: 42–56.
71.
YeYShiDKrauseP, et al. A data-driven method for estimating wheel flat length. Veh Syst Dyn2019; 58: 1329–1347.
72.
LiCLuoSColeC, et al. An overview: modern techniques for railway vehicle on-board health monitoring systems. Veh Syst Dyn2017; 55: 1045–1070.
73.
Lo SchiavoA. Fully autonomous wireless sensor network for freight wagon monitoring. IEEE Sens J2016; 16: 9053–9063.
74.
StojčevMKKosanovićMRGolubovićLR. Power management and energy harvesting techniques for wireless sensor nodes. In: 2009 9th International Conference on Telecommunication in Modern Satellite, Cable, and Broadcasting Services, Nis, Serbia, 7–9 October 2009, pp.65–72. IEEE.
75.
KanounOBradaiSKhrijiS, et al. Energy-aware system design for autonomous wireless sensor nodes: a comprehensive review. Sensors2021; 21: 548.
ZhangS. Challenges in KNN classification. IEEE Trans Knowl Data Eng2022; 34: 4663–4675.
78.
GoutteCGaussierE. A probabilistic interpretation of precision, recall and F-score, with implication for evaluation. In: LosadaDEFernández-LunaJM (eds) Advances in information retrieval. Berlin, Heidelberg: Springer, 2005, pp.345–359.
79.
GómezMJCorralECastejónC, et al. Effective crack detection in railway axles using vibration signals and WPT energy. Sensors2018; 18: 1603.
80.
SánchezR-VLuceroPMacancelaJ-C, et al. Evaluation of time and frequency condition indicators from vibration signals for crack detection in railway axles. Appl Sci2020; 10: 4367.
