溶胶-凝胶法制备PZT V型阀微执行器的新型设计与制造

C. Qiu, Huijun Zhang, Wei Qu, Hongmei Liu, Dan Bu, M. Cao
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引用次数: 0

摘要

为了对PZT (Pb(Zr,Ti)O3)压电薄膜进行定性研究,设计了一种新型微致动器。新颖的V型阀几何结构使流体泵送。利用PZT薄膜的压电响应特性,制备了微驱动器的多层驱动膜。作为驱动膜的关键技术,在硅衬底上制备Si /SiO2/Ti /Au /PZT/Cr/Au多层膜。该微执行器由硅-硅叠层组成,采用各向异性刻蚀工艺,包括泵腔和V型阀刻蚀步骤。给出了V型阀的SEM(扫描电子显微镜)照片和多层驱动膜的XRD (X射线衍射)分析。结果表明,该方法制备的泵腔平整均匀,很好地解决了硅衬底沉积PZT的问题。V型阀的单层设计降低了制造的复杂性,满足了材料节约的要求。本文对其设计和制作进行了阐述和讨论。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A Novel Design and Fabrication of V Type Valve Microactuator with PZT Prepared by Sol-Gel
A new microactuator design was fabricated to make a qualitative researcher on the PZT (Pb(Zr,Ti)O3) piezoelectric thin film. A novel V type valve geometry structure enables fluid pumping. The PZT thin films were used to fabricate multi-layer driving membrane for microactuator by its piezoelectric response. As the key technology of driving membrane, the Si /SiO2/Ti /Au /PZT/Cr/Au multi-layer film preparation on silicon substrate was developed. The microactuator consists of silicon-silicon stack and is fabricated with anisotropic etching process involving pump chamber and V type valve etching step. The SEM (scanning electron microscope) photographs of V type valve and XRD (X- ray diffraction) analysis for the multi-layer driving membrane were presented. The results show that the method of pump chamber fabricated is flat and uniform and the problem of PZT deposited on silicon substrate solved well. The single layer design of V type valve reduced the fabrication complexity and it satisfied the desires for materials retrenchment. Design and fabricated are described and discussed in this paper.
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