Piezoelectric Composite Materials for Ultrasonic Transducer Applications. Part II: Evaluation of Ultrasonic Medical Applications

IEEE Transactions on Sonics and Ultrasonics Pub Date : 1985-07-01 DOI:10.1109/T-SU.1985.31624

T. R. Gururaja, Walter A. Schulze, L. E. Cross, R. Newnham

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引用次数: 134

Abstract

Abstmct-The electro-acoustic properties of Lead zirconate titanate (PZT) rod-polymer composites relevant for ultrasonic transducer applications are reported. Acoustic impedance of the composite materials was measured by three different techniques in the frequency range 0.33.5 MHz. Dependence of the acoustic impedance as a function of volume fraction of PZT and frequency was also modeled theoretically. Time-delay spectrometry was employed to calibrate the free-field transmitting and receiving voltage responses of the composite materials. The acoustic impedance of the composite materials was in the range of 3-10 M rayl. The figure of merit in the receiving mode of composite materials was three times that of PZT. The figure of merit for a 20percent PZT composite (2 = 7.3 M rayl) was further enhanced by 50 percent using a single-layer impedance transformer of lucite (2 =3.3 M rayl). These composite materials were molded into curved shapes by simple thermal process to fabricate focused transducers. The axial and lateral beam profiles of focused composite transducers are presented.

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用于超声波换能器的压电复合材料。第二部分:超声医学应用评价

摘要:报道了与超声换能器应用相关的锆钛酸铅(PZT)棒聚合物复合材料的电声性能。在0.33.5 MHz的频率范围内，采用三种不同的技术测量了复合材料的声阻抗。对声阻抗随PZT体积分数和频率的变化关系进行了理论建模。采用延时光谱法对复合材料的自由场发射和接收电压响应进行了标定。复合材料的声阻抗范围为3 ~ 10 M。复合材料接收模式的优值是PZT接收模式的3倍。20% PZT复合材料(2 = 7.3 M rayl)的性能值通过使用单层硅树脂阻抗变压器(2 =3.3 M rayl)进一步提高了50%。这些复合材料通过简单的热加工成型成弯曲的形状来制造聚焦换能器。给出了聚焦复合换能器的轴向和横向光束分布。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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IEEE Transactions on Sonics and Ultrasonics

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