Abstract

The use of multilayer piezoelectric ceramics in ultrasonic transducers is common and multilayer 2-2 connectivity piezocomposites have also been reported but multilayer 1-3 connectivity piezocomposite transducers have not yet been fully documented and issues such as pillar misalignment still have to be clarified. This paper reports 2-layer piezocomposite elements for high-density arrays operating in the 1 – 5 MHz range. Investigation in air without any ancillary acoustic components highlighted undesirable effects, showing that pillar misalignment led to extraneous twisting modes. In practical use, such elements include matching and backing layers, and the effects of acoustic loading must also be considered. Therefore, we report here on work to quantify the influence of pillar misalignment for a complete transducer operating in water. To evaluate performance, our analysis includes electrical impedance data and measurements of the transmit-receive transfer function which relates to device performance in practical situations. We present results from finite element analysis incorporating unidirectional and bidirectional pillar misalignments from 0% to the maximum possible. These results are validated with data from a prototype two-layer 1-3 piezocomposite transducer tested in air and underwater. We comment on the degree of acceptable pillar misalignment compared with previous studies.