3D printing of metallic micro-gears for micro-fluidic applications

Q3 Engineering

Journal of Micromechanics and Molecular Physics Pub Date : 2021-10-29 DOI:10.1142/s2424913021410022

C. Wang, S. Chandra, X. Tan, S. Tor

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引用次数: 0

Abstract

Micro-fluidic devices are essential to handle fluids on the micro-meter scale (micro-scale), making them crucial to biomedical applications, where micro-gear is the key component for active fluid mixing. Rapid and direct fabrication of micro-gears is preferred because they are usually custom-made to specific applications and iterative design is needed. However, conventional manufacturing (CM) techniques for micro-fluidic devices are labor-intensive and time-consuming as multiple steps are required. Three-dimensional (3D) printing, or formally known as additive manufacturing (AM) offers a promising alternative over CM techniques in producing near-net shape complex geometries, given the micro-scale fabrication process. In this work, two types of powder-bed fusion (PBF) AM techniques, namely laser-PBF (L-PBF) and electron beam-PBF (EB-PBF) are used to benchmark 3D-printed micro-gears from stainless steel 316L micro-granular powders. Results showcase the preeminence of L-PBF over EB-PBF in generating distinguishable micro-scale features on gear profiles and superior micro-hardness in mechanical property. Overall, PBF metal AM shows significant promise in advancing the otherwise tedious state of CM for micro-gears.

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用于微流体应用的金属微齿轮的3D打印

微流体装置对于处理微米尺度(微尺度)的流体至关重要，这使得它们对生物医学应用至关重要，其中微齿轮是主动流体混合的关键部件。快速和直接制造微齿轮是首选，因为它们通常是针对特定应用定制的，并且需要迭代设计。然而，传统的微流体装置制造技术是劳动密集型和耗时的，因为需要多个步骤。三维(3D)打印，或正式称为增材制造(AM)，在生产近净形状复杂几何形状方面，提供了比CM技术更有前途的替代方案，考虑到微尺度制造过程。在这项工作中，使用两种类型的粉末床熔合(PBF) AM技术，即激光PBF (L-PBF)和电子束PBF (EB-PBF)，对不锈钢316L微颗粒粉末的3d打印微齿轮进行基准测试。结果表明，L-PBF比EB-PBF在产生可区分的齿轮轮廓微尺度特征方面具有优势，并且在力学性能方面具有优越的显微硬度。总体而言，PBF金属AM在推进微齿轮CM的其他繁琐状态方面显示出显着的希望。

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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来源期刊

Journal of Micromechanics and Molecular Physics Materials Science-Polymers and Plastics

CiteScore

3.30

自引率

0.00%

发文量