Application of the Multifractal Spectrum to the Analysis of Vibration Signals Generated During Testing of Selected Composite Materials

被引：0

作者：

Figlus, Tomasz ^{[1
]}

Koziol, Mateusz ^{[2
]}

机构：

[1] Silesian Tech Univ, Fac Transport & Aviat Engn, Krasinskiego 8, PL-40019 Katowice, Poland

[2] Silesian Tech Univ, Fac Mat Engn, Krasinskiego 8, PL-40019 Katowice, Poland

来源：

ADVANCES IN SCIENCE AND TECHNOLOGY-RESEARCH JOURNAL | 2024年 / 18卷 / 07期

关键词：

vibration; multifractal spectrum; signal analysis; fibre reinforced polymer; FAILURE PROGRESS; GLASS; DIAGNOSIS; LAMINATE; POLYMER; SYSTEM; DAMAGE;

D O I：

10.12913/22998624/192616

中图分类号：

T [工业技术];

学科分类号：

08 ;

摘要：

This paper presents a procedure for the application of a multifractal spectrum to analyse vibration signals obtained during static bending tests of selected fibre reinforced polymer matrix composite materials. The analyses were designed to determine the failure course of the composites tested under bending conditions. Non-stationary changes occurring in the signals include low- and high-energy symptoms of progressive damage in materials, which are difficult to identify and interpret, especially in the early stages. Determined using fractal leaders, the multifractal spectra of the vibration signals calculated for the different stages of the bending test allowed qualitative identification of the changes caused by progressive damage with different energy responses. In addition, the quantitative measures of change in the characteristics of the multifractal spectrum determined clearly indicated the changes occurring in the recorded signals. It can be concluded from the research that the proposed signal processing method based on a multifractal spectrum determined from non-stationary vibration signals is sensitive to changes occurring in these signals.

引用

页码：123 / 137

页数：15

共 45 条

[1]

Kuczaj M., Wieczorek A.N., Konieczny L., Burdzik R., Wojnar G., Filipowicz K., Gluszek G., Research on vibroactivity of toothed gears with highly flexible metal clutch under variable load conditions, Sensors, 23, (2023)

[2]

Yang C., Zhang L., Han Y., Cai D., Wei S., Study on the transmission and evolution characteristics of vibration wave from vibratory roller to filling materials based on the field test, Appl. Sci, 10, (2020)

[3]

Jirova R., Pesik L., Pneumatic vibroisolation system of the base desk with natural frequency regulation, Scientific Journal of Silesian University of Technology. Series Transport, 113, pp. 91-100, (2021)

[4]

Figlus T., Koziol M., Kuczynski L., Impact of application of selected composite materials on the weight and vibroactivity of the upper gearbox housing, Materials, 12, 16, (2019)

[5]

Figlus T., Koziol M., Kuczynski L., The effect of selected operational factors on the vibroactivity of upper gearbox housings made of composite materials, Sensors (Switzerland), 19, 19, (2019)

[6]

Isaac C.W., Wrona S., Pawelczyk M., Karimi H.R., Modelling vibro–acoustic response of lightweight square aluminium panel influenced by sound source locations for active control, Sci Rep, 12, (2022)

[7]

Tong Q., Liu Z., Lu F., Feng Z., Wan Q., A New de-noising method based on enhanced time-frequency manifold and kurtosis-wavelet dictionary for rolling bearing fault vibration signal, Sensors, 22, (2022)

[8]

Teng Z., Teng S., Zhang J., Chen G., Cui F., Structural damage detection based on real-time vibration signal and convolutional neural network, Appl. Sci, 10, (2020)

[9]

Waszczuk-Mlynska A., Galezia A., Radkowski S., Fault identification in membrane structures using the hilbert transforms, Sensors, 22, (2022)

[10]

Perez-Sanjines F., Peeters C., Verstraeten T., Antoni J., Nowe A., Helsen J., Fleet-based early fault detection of wind turbine gearboxes using-informed based on coherence, Mechanical Systems and Signal Processing, 185, (2023)

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