3D printing of flexible piezoelectric composite with integrated sensing and actuation applications

Advanced Powder Materials Pub Date : 2024-08-02 DOI:10.1016/j.apmate.2024.100226

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Abstract

3D printing of flexible piezoelectric composites (3D-FPCs) is increasingly attracting the attention due to its unique advantage for customized smart applications. However, current research mainly focuses on the 0–3 piezoelectric composites, in which the piezoelectric ceramics are embedded in polymer matrix in the form of particles. The poor connectivity between particles much reduces the conduction of strain and charge in the composites, seriously limiting its application in actuation. In this work, a continuous lead zirconate titanate (PZT) double-layer ceramic scaffold was prepared by 3D printing and assembled with epoxy resin and interdigital electrodes together to manufacture a multifunctional device. The 3D-FPCs exhibit a free strain of 1830 ppm in actuating and are able to actuate a stainless-steel cantilever beam to produce a tip displacement of 5.71 mm. Additionally, the devices exhibit a sensitivity of 26.81V/g in sensing applications. Furthermore, 3D-FPCs are demonstrated as actuators for mobile small robots and wearable sensors for sensing joint activities.

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具有集成传感和致动应用的柔性压电复合材料的 3D 打印

柔性压电复合材料（3D-FPC）的三维打印因其在定制化智能应用方面的独特优势而日益受到关注。然而，目前的研究主要集中在 0-3 压电复合材料上，即压电陶瓷以颗粒的形式嵌入聚合物基体中。颗粒之间的连接性较差，大大降低了复合材料中应变和电荷的传导性，严重限制了其在致动方面的应用。在这项研究中，通过三维打印技术制备了一种连续的锆钛酸铅（PZT）双层陶瓷支架，并将其与环氧树脂和数字间电极组装在一起，制造出了一种多功能装置。3D-FPC 在致动过程中表现出 1830 ppm 的自由应变，能够致动不锈钢悬臂梁，产生 5.71 mm 的顶端位移。此外，该器件在传感应用中的灵敏度为 26.81V/g。此外，3D-FPC 还可用作移动小型机器人的致动器和用于感知关节活动的可穿戴传感器。

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来源期刊

Advanced Powder Materials

CiteScore

33.30

自引率

0.00%

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