As an important part of the internal combustion engine, the piston-liner assembly is subjected to high temperature and pressure and prone to failure during operation. Condition monitoring of the piston-liner is crucial for the normal operation and maintenance of the engine. The key parameters of the variational mode decomposition algorithm were determined based on block vibration characteristics, and the algorithm was then used to decompose the block vibration into six intrinsic mode functions (IMFs). Continuous wavelet transform was employed for the time-frequency analysis of block vibration. Time-frequency results indicated that IMF1 and IMF6 were closely associated with combustion and piston slap, respectively. Based on this, multiple evaluation criteria were utilized to confirm the characterization parameters of IMFs linked to combustion and piston slap. The support vector machine model was developed through input vector selection, training and test set construction, and kernel function choice. Subsequently, a genetic algorithm was employed to optimize the key parameters of the penalty factor and the kernel width parameter. The optimized support vector machine model was trained and tested. The diagnosis model achieved a 96.9% classification accuracy and met the piston-liner monitoring requirements.
BoYWuHCheW, et al. Methodology and application of digital twin-driven diesel engine fault diagnosis and virtual fault model acquisition. Eng Appl Artif Intell2024; 131: 107853.
2.
LiSLiuZYanY, et al. Research on diesel engine fault status identification method based on synchro squeezing S-transform and vision transformer. Sensors2023; 23(14): 6447.
3.
DahhamRYWeiHPanJ. Improving thermal efficiency of internal combustion engines: recent progress and remaining challenges. Energies2022; 15: 6222.
4.
ZhangLWangHLiuD, et al. Research on wear detection mechanism of cylinder liner-piston ring based on energy dissipation and AE. Wear2022; 508–509: 204472.
5.
RaoXShengCGuoZ, et al. A review of online condition monitoring and maintenance strategy for cylinder liner-piston rings of diesel engines. Mech Syst Signal Process2022; 165: 108385.
6.
DziubakTDziubakSD. A study on the effect of inlet air pollution on the engine component wear and operation. Energies2022; 15: 1182.
7.
LiuZMengXZhangL, et al. Study on the three-dimensional tribo-dynamic analysis of piston ring pack considering the influence of piston secondary motion. J Tribol2022; 144(11): 111802.
8.
LiuDLiGSunN, et al. Vibration-induced cavitation in cylinder liners caused by piston slaps. Int J Mech Sci2024; 267: 109025.
9.
JiSLiYTianG, et al. Study on the relationship between combustion parameters and cylinder head vibration signal in time domain. Energies2021; 14(19): 6421.
10.
JiSLanXLianJ, et al. Combustion parameter estimation for ICE from surface vibration using frequency spectrum analysis. Measurement2018; 128: 485–494.
11.
MoosavianANajafiGGhobadianB, et al. Piston scuffing fault and its identification in an IC engine by vibration analysis. Appl Acoust2016; 102(15): 40–48.
12.
ChadliMDavoodiMMeskinN. Distributed state estimation, fault detection and isolation filter design for heterogeneous multi-agent linear parameter-varying systems. Inst Eng Technol2017; 11(2): 254–262.
13.
CavalliMLavacchielliGTonelliR, et al. Comparison of analytical and multibody dynamic approaches in the study of a V6 engine piston. J Multi-body Dynam2017; 231(3): 420–438.
14.
DolatabadiNLittlefairBDe la CruzM, et al. A transient tribodynamic approach for the calculation of internal combustion engine piston slap noise. J Sound Vib2015; 352: 192–209.
15.
BuzzoniMMucchiEDalpiazG. A CWT-based methodology for piston slap experimental characterization. Mech Syst Signal Process2017; 86: 16–28.
16.
MohamadSAKamelMA. Optimization of cylinder liner macro-scale surface texturing in marine diesel engines based on teaching–learning-based optimization algorithm. J Eng Tribol2021; 235(2): 329–342.
17.
ChenJRandallRBPeetersB. Advanced diagnostic system for piston slap faults in IC engines, based on the non-stationary characteristics of the vibration signals. Mech Syst Signal Process2016; 75: 434–454.
18.
ÇelebiKUludamarETosunE, et al. Experimental and artificial neural network approach of noise and vibration characteristic of an unmodified diesel engine fueled with conventional diesel, and biodiesel blends with natural gas addition. Fuel2017; 197: 159–173.
19.
KangJLuYLuoH, et al. Wear assessment model for cylinder liner of internal combustion engine under fuzzy uncertainty. Mech Ind2021; 22: 29–9.
20.
ZhaoHHuangJWangJ, et al. Improved SSA-VMD algorithm and its application in fault diagnosis of reciprocating compressor. Lubr Eng2022; 47(7): 147–152.
21.
LiYLiuSWangA, et al. Research on diesel engine bearing fault diagnosis based on vibration signal. Institute of Electrical and Electronics Engineers Inc, 2022.
22.
LiCLiaYLiuY. Fault diagnosis of wheelset bearing of high-speed train based on EEMD and parameter adaptive VMD. J Vib Shock2022; 41(01): 68–77.
23.
JiaNChengYLiuY, et al. Intelligent fault diagnosis of rotating machines based on wavelet time-frequency diagram and optimized stacked denoising auto-encoder. IEEE Sens J2022; 22(17): 17139–17150.
24.
DjaballahSMeftahKKhelilK, et al. Deep transfer learning for bearing fault diagnosis using CWT time–frequency images and convolutional neural networks. J Fail Anal Prev2023; 23(3): 1046–1058.
25.
WeiHShuG. The relationship between piston slap surface vibration and combustion noise in internal combustion engines. Trans Chinese Soc Int Combust Eng2004; 1: 27–32. https://doi.org/10.16236/j.cnki.nrjxb.2004.01.004
26.
LiuSGaoLXingM, et al. Vibration transmission in lubricated piston-liner systems: experimental and multi-physics coupled analysis. Int J Mech Sci2025; 288: 110002.
27.
WeiJJiSHuL, et al. Research on the selection method of state characterization parameters of piston-cylinder liner friction pairs. Chinese Int Combust Engine Eng2024; 45(02): 75–84.
28.
XiaSXiaYXiangJ. Piston wear detection and feature selection based on vibration signals using the improved spare support vector machine for axial piston pumps. Materials2022; 15: 8504.
29.
JiWLiuDMengY, et al. A review of genetic-based evolutionary algorithms in SVM parameters optimization. Evol Intell2021; 14: 1389–1414.
30.
JiSJiangYWangG, et al. Study on the correlation between combustion status and block vibration induced by piston slap. Appl Acoust2022; 199: 109006.
31.
ArmaghaniDMingYMohammedA, et al. Effect of SVM kernel functions on bearing capacity assessment of deep foundations. J Soft Comput Civil Eng2023; 7(3): 111–128.
32.
GuoFJSunWZWangJS, et al. Feature selection and support vector machine classification method for banknote dirtiness recognition based on marine predator algorithm with mathematical functions. J Intell Fuzzy Syst2023; 45(3): 4315–4336.
33.
WangMYuJZhouM, et al. Joint forecasting model for the hourly cooling load and fluctuation range of a large public building based on GA-SVM and IG-SVM. Sustainability2023; 15: 16833.
34.
AlsuwianTTayyebMAminAA, et al. Design of a hybrid fault-tolerant control system for air–fuel ratio control of internal combustion engines using genetic algorithm and higher-order sliding mode control. Energies2022; 15: 5666.
