A novel sensor for monitoring acoustic cavitation. Part I: Concept, theory, and prototype development

• Published in: IEEE transactions on ultrasonics, ferroelectrics, and frequency control Vol. 50; no. 10; pp. 1342 - 1350
• Main Authors: Zeqiri, B., Gelat, P.N., Hodnett, M., Lee, N.D.
• Format: Journal Article
• Language: English
• Published: New York, NY IEEE 01.10.2003; Institute of Electrical and Electronics Engineers; The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
• Subjects: Acoustic emission; Acoustic measurements; Acoustic sensors; Acoustical measurements and instrumentation; Acoustics; Bandwidth; Cavitation; Cylinders; Emissions; Exact sciences and technology; Frequency; Fundamental areas of phenomenology (including applications); Microorganisms; Monitoring; Physics; Piezoelectric films; Prototypes; Sensor phenomena and characterization; Sensors; Shape; Shields; Acoustic measurement; Ultrasonic cleaning; Secondary source; Sound source; Acoustic cavitation; Experimental study; Modeling; Monitoring
• ISSN: 0885-3010; 1525-8955
• DOI: 10.1109/TUFFC.2003.1244751

This paper describes a new concept for an ultrasonic cavitation sensor designed specifically for monitoring acoustic emissions generated by small microbubbles when driven by an applied acoustic field. Its novel features include a hollow, open-ended, cylindrical shape, with the sensor being a right circular cylinder of height 32 mm and external diameter 38 mm. The internal diameter of the sensor is 30 mm; its inner surface is fabricated from a 110 /spl mu/m layer of piezoelectrically active film whose measurement bandwidth is sufficient to enable acoustic emissions up to and beyond 10 MHz to be monitored. When in use, the sensor is immersed within the liquid test medium and high frequency (megahertz) acoustic emissions occurring within the hollow body of the sensor are monitored. In order to shield the sensor response from events occurring outside the cylinder, the outer surface of the sensor cylinder is encapsulated within a special 4 mm thick polyurethane-based cavitation shield with acoustic properties specifically developed to be minimally perturbing to the 40 kHz applied acoustic field but attenuating to ultrasound generated at megahertz frequencies (plane-wave transmission loss >30 dB at 1 MHz). This paper introduces the rationale behind the new sensor, describing details of its construction and the materials formulation program undertaken to develop the cavitation shield.