Acoustic emission source location in composite structure by Voronoi construction using geodesic curve evolution

Gangadharan, R.; Prasanna, G; Bhat, M.R.; Murthy, C. Siva Ram; Gopalakrishnan, S.

doi:10.1121/1.3224736

Cited by 13 publications

(8 citation statements)

References 24 publications

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“…To trace the active region within a large structure of wind turbine blade (i.e., in twodimensional position), AE wireless units can be spaced apart on the blade and AE sources can be assumed to be within a region and less than halfway between the wireless units. In this case, methods explained in [21] can be applied to trace the AE source. In this paper, the zonal localization is used to specify the active blade, and the results of this localization are presented in Section 5.…”

Section: Source Localization On Wind Turbine Bladesmentioning

confidence: 99%

Structural Health Monitoring of Wind Turbine Blades: Acoustic Source Localization Using Wireless Sensor Networks

et al. 2015

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Structural health monitoring (SHM) is important for reducing the maintenance and operation cost of safety-critical components and systems in offshore wind turbines. This paper proposes anin situwireless SHM system based on an acoustic emission (AE) technique. By using this technique a number of challenges are introduced due to high sampling rate requirements, limitations in the communication bandwidth, memory space, and power resources. To overcome these challenges, this paper focused on two elements: (1) the use of anin situwireless SHM technique in conjunction with the utilization of low sampling rates; (2) localization of acoustic sources which could emulate impact damage or audible cracks caused by different objects, such as tools, bird strikes, or strong hail, all of which represent abrupt AE events and could affect the structural health of a monitored wind turbine blade. The localization process is performed using features extracted from aliased AE signals based on a developed constraint localization model. To validate the performance of these elements, the proposed system was tested by testing the localization of the emulated AE sources acquired in the field.

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Section: Source Localization On Wind Turbine Bladesmentioning

confidence: 99%

Structural Health Monitoring of Wind Turbine Blades: Acoustic Source Localization Using Wireless Sensor Networks

et al. 2015

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“…The incorporation of direction-dependent velocity in source location calculations for composites has been demonstrated by Gangadharan et al 20 and Kundu et al 21 Ciampa and Mia 22 further improved the localization method of manually simulated AE sources in composites of unknown lay-up and thickness. The method identifies the time of arrival of the first flexural Lamb mode and the source location is identified with a back-tracking approach using redundant measurements.…”

Section: Acoustic Emission Source Location In Compositesmentioning

confidence: 99%

Detecting and locating damage initiation and progression in full-scale sandwich composite fuselage panels using acoustic emission

Leone

Ozevin

Awerbuch

et al. 2012

Journal of Composite Materials

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In this study, acoustic emission was evaluated as a supplementary nondestructive testing method for detecting damage initiation and progression, identifying the site of damage, and anticipating ultimate fracture in notched full-scale honeycomb sandwich composite fuselage panels using redundant arrays of different acoustic emission sensor models. Each panel contained different damage scenarios and was subjected to combinations of quasi-static hoop and longitudinal loads. Damage progression and location were characterized with various inspection techniques, and the acoustic emission results were correlated with photogrammetric strain fields. Applying post-test signal processing, acoustic emission accurately detected notch tip damage initiation and tracked its progression to ultimate failure.

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“…Spatial selection requires localization of acoustic emission sources with an acceptable error, which in the case of composite materials has proven to be a rather complex problem [14][15][16][17]. Parametric selection is effective when the maximum amplitude of the acoustic emission pulses is, on average, at least 5 dB higher than the amplitude of the noise component.…”

Section: Introductionmentioning

confidence: 99%

Strategies for Extracting Damage Induced AE Signals from Different Type Noise-Like Backgrounds for Carbon-Fibre Reinforced Polymers

2021

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This paper presents an algorithm for isolating a useful acoustic signal (corresponding to damage accumulation) against the background of a signal used to model the performance of an industrial rotary equipment. Acoustic emission signals induced by deformation and fracture were studied using a uniaxial tensile test on woven laminate samples cut along the fiber and weft directions. The background signal is a random composition of acoustic pulses used to model the performance of an industrial rotary equipment. A comparison of useful and noise signals enables us to develop two algorithms based on frequency filtering of a signal and its decomposition into empirical modes. These algorithms can be used to isolate useful AE pulses against the background of all signal intensities under consideration.

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Acoustic emission source location in composite structure by Voronoi construction using geodesic curve evolution

Cited by 13 publications

References 24 publications

Structural Health Monitoring of Wind Turbine Blades: Acoustic Source Localization Using Wireless Sensor Networks

Structural Health Monitoring of Wind Turbine Blades: Acoustic Source Localization Using Wireless Sensor Networks

Detecting and locating damage initiation and progression in full-scale sandwich composite fuselage panels using acoustic emission

Strategies for Extracting Damage Induced AE Signals from Different Type Noise-Like Backgrounds for Carbon-Fibre Reinforced Polymers

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