J. Davies scite author profile

This paper deals with quantifying the performance of a technique for detection, location, and sizing of circumferential crack-like defects in pipelines using synthetically focused guided waves. The system employs a circumferential array of piezoelectric transducer elements. A torsional probing guided wave is excited using the array, which subsequently interacts with the reflecting features of the pipe, such as defects or weld caps. The recorded backscattered signals are synthetically focused to every point of interest in the pipe wall, to form an image of the reflecting features of the pipe. The defect image amplitude is used to estimate the defect depth, and the full width at half maximum of the defect image circumferential profile is used to estimate the circumferential extent of the defect. The imaging system is tested with data from finite element simulations and from laboratory experiments. It is found that reliable sizing of circumferential cracks in finite element simulations and experiments can be achieved if the circumferential extent of the defect is greater than 1.5 lambda(S), where lambda(S) is the shear wavelength at the frequency of inspection. This result is theoretically valid for any pipe size, any axial defect location, and any inspection frequency. Amplitude gains of around 18 dB over an unfocused system have been observed experimentally in an 8-inch pipe with a 9 dB SNR improvement.

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High-temperature (>500°c) wall thickness monitoring using dry-coupled ultrasonic waveguide transducers

Cegla

Cawley

Allin³

et al. 2011

IEEE Trans. Ultrason., Ferroelect., Freq. Contr.

122

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A microfluidic chip based model for the study of full thickness human intestinal tissue using dual flow

Dawson

Dyer

MacFie

et al. 2016

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The study of inflammatory bowel disease, including Ulcerative Colitis and Crohn's Disease, has relied largely upon the use of animal or cell culture models; neither of which can represent all aspects of the human pathophysiology. Presented herein is a dual flow microfluidic device which holds full thickness human intestinal tissue in a known orientation. The luminal and serosal sides are independently perfused ex vivo with nutrients with simultaneous waste removal for up to 72 h. The microfluidic device maintains the viability and integrity of the tissue as demonstrated through Haematoxylin & Eosin staining, immunohistochemistry and release of lactate dehydrogenase. In addition, the inflammatory state remains in the tissue after perfusion on the device as determined by measuring calprotectin levels. It is anticipated that this human model will be extremely useful for studying the biology and testing novel interventions in diseased tissue.

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Cavity-enhanced optical methods for online microfluidic analysis

Rushworth

Davies

Cabral

et al. 2012

Chemical Physics Letters

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The Application of Synthetically Focused Imaging Techniques for High Resolution Guided Wave Pipe Inspection

Davies

Cawley

2007

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J. Davies

The application of synthetic focusing for imaging crack-like defects in pipelines using guided waves

High-temperature (>500°c) wall thickness monitoring using dry-coupled ultrasonic waveguide transducers

A microfluidic chip based model for the study of full thickness human intestinal tissue using dual flow

Cavity-enhanced optical methods for online microfluidic analysis

The Application of Synthetically Focused Imaging Techniques for High Resolution Guided Wave Pipe Inspection

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