In-House Fabrication of Solenoid Inductor and Multilayer Metal Core Using 3D Printing, Selective Electroless Plating, Electroplating, and Pressing

Jun Ying Tan, A. Ahmed, J. Kim
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Abstract

This paper presents a simple in-house fabrication of a solenoid inductor using 3D printing, selective electroless plating, and electroplating for the inductor, and pressing for a highly laminated metal core. The frame of the solenoid inductor was 3D printed, where the design of the frame has a solenoid trench and ridge for wiring and insulator, respectively. The ridge of the frame was selectively coated with a novolac resin by dipping and rolling. The unique selective electroless plating showed the direct patterning to form a solenoid conductive path that came from the different surface activation. Electroplating to thicken the solenoid wire completes the inductor fabrication. A pressing and stacking of a nickel film form the highly laminated magnetic core for the inductor. A 10-turn solenoid inductor with a wire thickness of was successfully fabricated. An average inductance of 133 nH was measured in air-core condition. A 120 nickel layer cores were integrated into the inductor and showed the boosted inductance of 252 nH. The proposed simple fabrication has a great potential for various RF passive 3D devices including antennas, filters, and waveguides.
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内部制造电磁电感和多层金属芯使用3D打印,选择性化学镀,电镀和压制
本文介绍了一个简单的内部制造螺线管电感使用3D打印,选择性化学镀,和电镀的电感,并压制高度层压金属芯。电磁电感器的框架进行了3D打印,其中框架的设计具有电磁沟槽和脊线,分别用于布线和绝缘体。通过浸渍和轧制的方法,在框架的脊上选择性地涂上了一层新伏拉克树脂。独特的选择性化学镀表现出直接的图案,形成电磁传导路径,来自不同的表面活化。电镀加厚螺线管导线完成电感的制作。对镍薄膜的压制和堆叠形成用于电感器的高度层压磁芯。成功地制作了导线厚度为的10匝电磁电感器。在空芯条件下测得平均电感为133 nH。将120镍层铁芯集成到电感器中,显示出252 nH的升压电感。提出的简单制造对于各种RF无源3D器件,包括天线,滤波器和波导具有巨大的潜力。
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