Smith W A, Auld B A
North American Philips Corp., New York, NY.
IEEE Trans Ultrason Ferroelectr Freq Control. 1991;38(1):40-7. doi: 10.1109/58.67833.
A simple physical model of 1-3 composite piezoelectrics is advanced for the material properties that are relevant to thickness-mode oscillations. This model is valid when the lateral spatial scale of the composite is sufficiently fine that the composite can be treated as an effective homogeneous medium. Expressions for the composite's material parameters in terms of the volume fraction of piezoelectric ceramic and the properties of the constituent piezoelectric ceramic and passive polymer are derived. A number of examples illustrate the implications of using piezocomposites in medical ultrasonic imaging transducers. While most material properties of the composite roughly interpolate between their values for pure polymer and pure ceramic, the composite's thickness-mode electromechanical coupling can exceed that of the component ceramic. This enhanced electromechanical coupling stems from partially freeing the lateral clamping of the ceramic in the composite structure. Their higher coupling and lower acoustic impedance recommend composites for medical ultrasonic imaging transducers. The model also reveals that the composite's material properties cannot be optimized simultaneously; tradeoffs must be made. Of most significance is the tradeoff between the desired lower acoustic impedance and the undesired smaller electromechanical coupling that occurs as the volume fraction of piezoceramic is reduced.
针对与厚度模式振荡相关的材料特性,提出了一种1-3型复合压电材料的简单物理模型。当复合材料的横向空间尺度足够精细,以至于可以将其视为一种有效的均匀介质时,该模型是有效的。推导了复合材料材料参数与压电陶瓷体积分数以及组成压电陶瓷和无源聚合物特性之间的表达式。一些示例说明了在医学超声成像换能器中使用压电复合材料的意义。虽然复合材料的大多数材料特性大致介于纯聚合物和纯陶瓷的值之间,但复合材料的厚度模式机电耦合可能超过组成陶瓷的耦合。这种增强的机电耦合源于在复合结构中部分解除了陶瓷的横向夹持。它们更高的耦合和更低的声阻抗推荐了用于医学超声成像换能器的复合材料。该模型还表明,复合材料的材料特性不能同时优化;必须进行权衡。最重要的权衡是,随着压电陶瓷体积分数的降低,在期望的低声阻抗和不期望的较小机电耦合之间进行权衡。