Modeling and measurement of piezoelectric fibers and interdigitaded electrodes for the optimization of piezofibre composites

Commercially available PZT-5A composition fibres fabricated using four production methods were incorporated into 1-3 composites with fibre volume fractions ranging from 0.02 to 0.72. Measurements of the piezoelectric induced strain constants (d33 and d31), relative dielectric constants (e33), longitudinal coupling factors (k33) and stiffness' (s33) of the varying volume fraction composites are compared to analytical expressions in order to extract the fibre properties. Results show 1-3 composite data accurately follows the analytical trends. The Viscous Plastic Process (VPP) fibres are found to exhibit optimum material properties, which approach bulk material values. Reduced piezoelectric activity in extruded fibres is thought to be associated with a small grain size and high porosity. A second study, an optimisation of interdigitated electrode design, was performed using the finite element software ANSYS. The effect of the IDE geometry (electrode width and spacing) and PZT substrate thickness on the strain output of bulk PZT substrates was modelled. Results show optimal actuation occurs at electrode widths equal to half the substrate thickness, and for thin substrates the electrode finger spacing can be reduced to enable lower driving voltages.

[1]  Thomas R. Shrout,et al.  Development of ultra-fine scale piezoelectric fibers for use in high frequency 1-3 transducers , 1996, ISAF '96. Proceedings of the Tenth IEEE International Symposium on Applications of Ferroelectrics.

[2]  S. Yoshikawa,et al.  Piezoelectric PZT tubes and fibers for passive vibrational damping , 1992, ISAF '92: Proceedings of the Eighth IEEE International Symposium on Applications of Ferroelectrics.

[3]  W. Kreher,et al.  Smart structures by integrated piezoelectric thin fibres (II): Properties of composites and their physical description , 1999 .

[4]  Nesbitt W. Hagood,et al.  Improving transverse actuation of piezoceramics using interdigitated surface electrodes , 1993, Smart Structures.

[5]  H. Beige,et al.  A New Method for the Determination of Elastic Properties of Thin Piezoelectric PZT Fibers , 2002 .

[6]  H. Beige,et al.  Properties of fine scale piezoelectric PZT fibers with different Zr content , 2001 .

[7]  W. A. Smith,et al.  Modeling 1-3 composite piezoelectrics: hydrostatic response , 1993, IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control.

[8]  Thomas R. Shrout,et al.  Active PZT fibers: a commercial production process , 1999, Smart Structures.

[9]  K. Kendall,et al.  High-strength ceramics through colloidal control to remove defects , 1987, Nature.

[10]  Anindya Ghoshal,et al.  Active fiber composites for structural health monitoring , 2000, Smart Structures.

[11]  L. J. Nelson,et al.  Smart piezoelectric Fibre composites , 2002 .

[12]  Thomas R. Shrout,et al.  Lead Zirconate Titanate Fine Fibers Derived from Alkoxide‐Based Sol‐Gel Technology , 2005 .

[13]  C. Choy,et al.  Nanocrystalline powder and fibres of lead zirconate titanate prepared by the sol-gel process , 1997 .

[14]  David J. Warkentin,et al.  Modeling and electrode optimization for torsional IDE piezoceramics , 2000, Smart Structures.