Venting in the comparative study of flexural ultrasonic transducers to improve resilience at elevated environmental pressure levels

Andrew Feeney, Lei Kang, William E. Somerset, Steve DIxon

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    Abstract

    The classical form of a flexural ultrasonic transducer is a piezoelectric ceramic disc bonded to a circular metallic membrane. This ceramic induces vibration modes of the membrane for the generation and detection of ultrasound. The transducer has been popular for proximity sensing and metrology, particularly for industrial applications at ambient pressures around 1 bar. The classical flexural ultrasonic transducer is not designed for operation at elevated pressures, such as those associated with natural gas transportation or petrochemical processes. It is reliant on a rear seal which forms an internal air cavity, making the transducer susceptible to deformation through pressure imbalance. The application potential of the classical transducer is therefore severely limited. In this study, a venting strategy which balances the pressure between the internal transducer structure and the external environment is studied through experimental methods including electrical impedance analysis and pitch-catch ultrasound measurement. The vented transducer is compared with a commercial equivalent in air towards 90 bar. Venting is shown to be viable for a new generation of low cost and robust industrial ultrasonic transducers, suitable for operation at high environmental pressure levels.

    Original languageEnglish
    Article number9006815
    Pages (from-to)5776-5784
    Number of pages9
    JournalIEEE Sensors Journal
    Volume20
    Issue number11
    Early online date21 Feb 2020
    DOIs
    Publication statusPublished - 1 Jun 2020

    Keywords

    • air-coupled ultrasound
    • elevated Pressure
    • Flexural ultrasonic transducer
    • unimorph

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