2020
DOI: 10.1109/access.2020.2999783
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Modeling and Measurement Study for Wind Turbine Blade Trailing Edge Cracking Acoustical Detection

Abstract: The rapid deployment of the offshore wind turbine technology has brought more requirements for remote turbine health monitoring especially for blade health conditions. The trailing edge cracking (TEC) is often the early stage blade health issue which leads to more serious problems and even crash of wind turbine. In response to this cracking issue, this paper presents aero-acoustic noise modeling analysis of the blade airfoil section with and without cracking of typical 3 millimeter (mm) gap in the trailing edg… Show more

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Cited by 9 publications
(5 citation statements)
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“…Using distances x 1 = 225 mm, x 2 = 237 mm (frequency range of 22-38 kHz, ∆x/λ = 0.3) and x 1 = 225 mm and x 2 = 231 mm (frequency range of 57-64 kHz, ∆x/λ = 0.3) of the A 0 mode, the two segments of the dispersion curves were reconstructed. The comparison of the results with 2D-FFT algorithm based on peaks of spectrum magnitude was performed, the mean relative error δ c ph = 1.3% for first reconstructed range (22)(23)(24)(25)(26)(27)(28)(29)(30)(31)(32)(33)(34)(35)(36)(37)(38) and δ c ph = 0.3% for second range (57-64 kHz) was determined. The total mean relative error δ c ph = 0.8% was calculated.…”
Section: Discussionmentioning
confidence: 99%
See 1 more Smart Citation
“…Using distances x 1 = 225 mm, x 2 = 237 mm (frequency range of 22-38 kHz, ∆x/λ = 0.3) and x 1 = 225 mm and x 2 = 231 mm (frequency range of 57-64 kHz, ∆x/λ = 0.3) of the A 0 mode, the two segments of the dispersion curves were reconstructed. The comparison of the results with 2D-FFT algorithm based on peaks of spectrum magnitude was performed, the mean relative error δ c ph = 1.3% for first reconstructed range (22)(23)(24)(25)(26)(27)(28)(29)(30)(31)(32)(33)(34)(35)(36)(37)(38) and δ c ph = 0.3% for second range (57-64 kHz) was determined. The total mean relative error δ c ph = 0.8% was calculated.…”
Section: Discussionmentioning
confidence: 99%
“…Wind energy is said to be one of the most basic energy sustainability alternatives, therefore, the world is moving rapidly towards renewable energy, and the number of wind farms is constantly growing [28][29][30]. However, with the increasing number of wind farms, the world is facing an ever-increasing number of turbine blades being ejected [31]. The main reasons for this are various defects that occur in the production of WTBs, and the service life can affect the development of damage under fatigue loads [32,33].…”
Section: Introductionmentioning
confidence: 99%
“…So, we used the octave method to extract the feature information. Octave [24] is a macro signal analysis method that does not consider the amplitude of a specific frequency, but instead focuses on the power spectrum characteristics of the frequency band, which is composed of multiple frequencies. The steps for extracting the feature information using the octave method are as follows:…”
Section: Octave Feature Extractionmentioning
confidence: 99%
“…Wind power blade trailing edge cracking (TEC) is generally an early blade health problem. Zhang et al [129] proposed a prediction method combining computational fluid dynamics (CFD) simulations and semiempirical models. An airfoil cross-sectional analysis of the blade trailing edge with and without a 3 mm gap crack defect successfully explained that blade trailing edge cracking is the cause of the accompanying acoustically sharp "whistling sound".…”
Section: Introduction Of Wind Power Blade Aerodynamic Noisementioning
confidence: 99%