Title :
A high sensitivity hydrostatic piezoelectric transducer based on transverse piezoelectric mode honeycomb ceramic composites
Author :
Zhang, Q.M. ; Wang, H. ; Zhao, J. ; Fielding, Joseph T., Jr. ; Newnham, Robert E. ; Cross, L. Eric
Author_Institution :
Intercollege Mater. Res. Lab., Pennsylvania State Univ., University Park, PA, USA
Abstract :
A new piezoelectric composite transducer based on the ceramic honeycomb structure is introduced. The transducer is operated in the transverse piezoelectric (TP) d/sub 31/ mode. The ceramic honeycomb configuration enables one to fabricate a TP honeycomb transducer by either embedding a honeycomb ceramic skeleton into a soft polymer matrix to form a composite or by blocking the openings of the honeycomb cells with thin layers of epoxy to form an end-capped honeycomb structure. With the unique honeycomb configuration and TP operation mode, the piezoelectric d/sub 33/ response of the ceramic is nearly eliminated and the piezoelectric responses from the three orthogonal directions add together when the transducer is subjected to a hydrostatic pressure. As a result, the transducer exhibits exceptionally high hydrostatic piezoelectric response.
Keywords :
filled polymers; hydrophones; intelligent materials; intelligent sensors; lead compounds; piezoceramics; piezoelectric transducers; PZT; PZT type; PbZrO3TiO3; end-capped honeycomb structure; high sensitivity; honeycomb ceramic composites; hydrostatic piezoelectric transducer; orthogonal directions; piezoelectric composite transducer; piezoelectric response; smart material; soft polymer matrix; transverse piezoelectric mode; Ceramics; Composite materials; Honeycomb structures; Intelligent actuators; Piezoelectric transducers; Polymers; Shape; Skeleton; Technological innovation; Vibration control;
Journal_Title :
Ultrasonics, Ferroelectrics, and Frequency Control, IEEE Transactions on
