Design and fabrication of driving microcoil with large tilt-angle for medical scanner application

2014 Symposium on Design, Test, Integration and Packaging of MEMS/MOEMS (DTIP) Pub Date : 2014-04-01 DOI:10.1109/DTIP.2014.7056688

Bin Sun, R. Sawada, Zhuo-qing Yang, Yi Zhang, T. Itoh, R. Maeda

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引用次数: 6

Abstract

This paper presents an electromagnetically-actuated single optical fiber scanner that utilizes its high-order resonance modal and tilt microcoil to realize a larger scanning angle. The device is fabricated on the surface of a thin polymer tube with 1mm diameter by our developed spray coating and cylindrical projection lithography systems, which could be used as ultra-thin medical endoscope. In order to realize the electromagnetically-driven scanning, a cylindrical magnet is fixed at the center of the polyimide pipe by an optical fiber. When an AC power is supplied to the microcoil, the fiber scanner is actuated under a certain frequency. The modal and dynamic response of the designed scanner under high-order vibration has been simulated and analyzed. The microcoil with 60° tilt angle is fabricated by wet etching and maskless electroplating processes. The electromagnetic property and maximum driven displacement of the fabricated device have been also evaluated, which is generally in accordance with that simulated. Finally, the electroplated microcoil of 60° tilt-angle, 40μm line width, 40μm line spacing and 15μm thickness has been obtained successfully.

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医用扫描仪用大倾角驱动微线圈的设计与制造

本文提出了一种利用高阶谐振模态和倾斜微线圈实现更大扫描角度的电磁驱动单光纤扫描器。该装置采用我们研制的喷雾涂层和圆柱投影光刻系统，制作在直径为1mm的薄聚合物管表面，可作为超薄医用内窥镜。为了实现电磁驱动扫描，在聚酰亚胺管的中心用光纤固定一个圆柱形磁铁。当交流电源供电给微线圈时，光纤扫描器在一定频率下被驱动。对所设计的扫描仪在高阶振动下的模态响应和动力响应进行了仿真分析。采用湿法蚀刻和无掩膜电镀工艺制备了倾角为60°的微线圈。对所制备器件的电磁特性和最大驱动位移进行了计算，结果与仿真结果基本一致。最后，成功制备了倾角60°、线宽40μm、线间距40μm、线厚15μm的电镀微线圈。

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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2014 Symposium on Design, Test, Integration and Packaging of MEMS/MOEMS (DTIP)

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