Use of Macro Fibre Composite Transducers as Acoustic Emission Sensors

Eaton, Mark Jonathan; Pullin, Rhys; Holford, Karen Margaret; Evans, Samuel Lewin; Featherston, Carol Ann; Rose, Aleena

doi:10.3390/rs1020068

Cited by 20 publications

(10 citation statements)

References 8 publications

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“…Lee and Kuo [21] design a miniature acoustic transducer with two conical PZT elements to measure the surface wave velocity by using PZT ceramic (PZT-5H) as the sensing element. Other piezoelectric elements reported in literature for AE sensing are polyvinylidene fluoride-trifluonoethylene (PVDF-TrFE) copolymer [22], embedded polyvinylidene fluoride (PVDF) [23], PTCa/PEKK piezo-composites [24,25], piezoelectric polymer-ceramic composites [26], macro-fiber composite (MFC) film [27].…”

Section: Piezoelectric Acoustic Emission (Ae) Sensorsmentioning

confidence: 99%

Numerical approach to absolute calibration of piezoelectric acoustic emission sensors using multiphysics simulations

Zhang

Yalcinkaya

Ozevin

2017

Sensors and Actuators A: Physical

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In this paper, the absolute calibration of piezoelectric Acoustic Emission (AE) sensors is developed using multi-physics numerical and experimental models. In this process, two common excitation approaches including laser and pencil lead break (PLB) are used to generate the simulation sources because of their excellent reproducibility and well-established analytical expressions of their source functions. The numerical models include source function, steel plate and piezoelectric sensor model with the details including adhesive layer, wear plate, piezoelectric ceramic, and backing material. The experimental results of four types of AE sensors (true wideband sensor, low and high frequency conventional sensors and low frequency unpackaged sensor) are compared with the numerical results. The numerically obtained calibration curves show good agreement with the calibration curves provided by the manufacturer. The influences of adhesive layer, backing material and sensor size on the sensor response are studied. The uncoupled piezoelectric sensor models indicate that there is no single displacement history that the sensors can be used for calibration. It is shown that the quantitative AE analysis requires the coupled structural and electrical models of structural medium and piezoelectric sensor.

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Section: Piezoelectric Acoustic Emission (Ae) Sensorsmentioning

confidence: 99%

Numerical approach to absolute calibration of piezoelectric acoustic emission sensors using multiphysics simulations

Zhang

Yalcinkaya

Ozevin

2017

Sensors and Actuators A: Physical

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“…To test the performance of the proposed algorithm, macro fiber composite (model MFC-M2814) sensors manufactured by Smart Material Inc., with an active area of 28 mm x 14 mm and a bandwidth of kHz, were used. The typical physical structure of an MFC sensor is formed by rectangular piezoceramic fibers locked in an epoxy matrix and sandwiched between two arrays of integrated electrodes (see for example (Eaton, et al, 2009) for details). The rectangular piezoceramic fibers are arranged in a regular spacing and precise parallel alignment to form the MFC transducer.…”

Section: Experimental Set Upmentioning

confidence: 99%

“…This value is close to that reported in the literature and indicates that monitoring of the vibrational modes up to a 0.4 m distance (considering the distance among the sensors in the experimental setup) should be feasible. The directionality sensitivity is also a concern with MFC sensors (Eaton, et al, 2009). To characterize the response of a typical MFC sensor, a set of preliminary tests was carried out on a thin aluminum plate with dimensions of 600 x 600 mm 2 and 1.9 mm in thickness.…”

Section: Experimental Set Upmentioning

confidence: 99%

Damage detection using the signal entropy of an ultrasonic sensor network

Rojas

Baltazar

Loh

2015

Smart Mater. Struct.

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Piezoelectric ultrasonic sensors used to propagate guided waves can potentially be implemented to inspect large areas in engineering structures. However, the inherent dispersion and noise of guided acoustic signals, multiple echoes in the structure, as well as a lack of an approximate or exact model, limit their use as a continuous structural health monitoring system. In this work, the implementation of a network of piezoelectric sensors randomly placed on a plate-like structure to detect and locate artificial damage is studied. A network of macro fiber composite (MFC) sensors working in a pitch-catch configuration was set on an aluminum thin plate 1.9 mm in thickness. Signals were analyzed in the timescale domain using the discrete wavelet transform. The objectives of this work were threefold, namely to first develop a damage index based on the entropy distribution using short time wavelet entropy (STWE) of the ultrasonic waves generated by a sensor network, second to determine the performance of an array of spare macro fiber composite (MFC) sensors to detect artificial damage, and third to implement a time-of-arrival (TOA) algorithm on the gathered signals for damage location of an artificial circular discontinuity. Our preliminary test results show that the proposed methodology provides sufficient information for damage detection, which, once combined with the TOA algorithm, allows localization of the damage.

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“…One of the most prominent MFC utilizations is linked to health monitoring systems and the evaluation of damages (Park et al, 2006;Hameed et al, 2009). MFC sensors are capable of recording AE and detecting damages (Eaton et al, 2009). Some vibration tests under optimal running conditions revealed that the monitoring and control can be done with a limited number of actuators, which reduces costs (Sohn et al, 2011).…”

Section: Mfc Is a Composite Technology Originally Developed At The Namentioning

confidence: 99%

Pattern recognition by wavelet transforms using macro fibre composites transducers

González-Carrato

Márquez

Dimlaye³

et al. 2014

Mechanical Systems and Signal Processing

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This paper presents a novel pattern recognition approach for a non-destructive test based on macro fibre composite transducers applied in pipes. A fault detection and diagnosis (FDD) method is employed to extract relevant information from ultrasound signals by wavelet decomposition technique. Wavelet transform is a powerful tool that reveals particular characteristics as trends or breakdown points. The FDD developed for the case study provides information about the temperatures on the surfaces of the pipe, leading to monitor faults associated to cracks, leaks or corrosion. This issue may not be noticeable when temperatures are not subject to sudden changes, but it can cause structural problems in the medium and long-term. Furthermore, the case study is completed by a statistical method based on the coefficient of determination. The main purpose will be to predict future behaviours in order to set alarms levels as part of a structural health monitoring system.

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Use of Macro Fibre Composite Transducers as Acoustic Emission Sensors

Cited by 20 publications

References 8 publications

Numerical approach to absolute calibration of piezoelectric acoustic emission sensors using multiphysics simulations

Numerical approach to absolute calibration of piezoelectric acoustic emission sensors using multiphysics simulations

Damage detection using the signal entropy of an ultrasonic sensor network

Pattern recognition by wavelet transforms using macro fibre composites transducers

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