Mechanical Pre-Stressing a Transducer through a Negative DC Biasing Field

Abstract

This report provides a qualitative study with regards to the feasibility of using a negative DC biasing approach to apply a mechanical compressive stress to a transducers piezoelectric ceramic stack instead of using a stress bolt. A typical underwater Tonpilz longitudinal-type transducer is made up of four major parts: a piezoelectric ceramic drive element that is sandwiched between two masses, a tail mass, a radiating head mass, and a stress bolt. The stress bolt that passes through the ceramic stack (and connects the head mass to the tail mass)keeps the transducer parts together and keeps the ceramic element under a constant compressional stress. The compressive stress prevents the ceramic from going into tension and fracturing when driven under high AC drive conditions that exceed its low tensile strength. The typical compressive stresses applied by the stress bolt are 3000 to 6000 psi. When the transducer element lateral dimensions are small, compared with acoustic wavelength, there is little or no room for a stress bolt. An alternative method of applying a compressive preload without the stress bolt is achieved by applying a negative DC electric field across the piezoelectric ceramic stack, which in turn causes the piezoelectric ceramic element to contract and results in an internal compressive stress. The plausibility of this method will be discussed.

Document Details

Document Type

Technical Report

Publication Date

Apr 21, 2017

Accession Number

AD1033453

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