5-axis CNC micro-milling machine for three-dimensional microfluidics
5-axis CNC micro-milling machine for three-dimensional microfluidics
Modarelli, M.; Kot-Thompson, D.; Hoshino, K.
AbstractThe gold standard of microfluidic fabrication techniques, SU-8 patterning, requires photolithography equipment and facilities and is not suitable for 3D microfluidics. A 3D printer is more convenient and may achieve high resolutions comparable to conventional photolithography, but only with select materials. Alternatively, 5-axis CNC micro-milling machines can efficiently prototype structures with high resolutions, high aspect ratios, and non-planar geometries from a variety of materials. These machines, however, have not been catered for laboratory-based, small-batch microfluidics development and are largely inaccessible to researchers. In this paper, we present a new 5-axis CNC micro-milling machine specifically designed for prototyping 3D microfluidic channels, made affordable for research and laboratories. The machine is assembled from commercially available products and custom-build parts, occupying 0.72 cubic meters, and operating entirely from computer aided design (CAD) and manufacturing (CAM) software. The 5-axis CNC micro-milling machine achieves sub-m bidirectional repeatability ([≤]0.23 m), machinable features <20 m, and a work volume of 50 x 50 x 68 mm. The tool compatibility and milling parameters were designed to enable fabrication of virtually any mill-able material including metals like aluminum, brass, stainless steel, and titanium alloys. To demonstrate milling high resolution and high aspect ratios, we milled a thin wall from 360 brass with a width of 18.1 m and an aspect ratio of ~50:1. We also demonstrated fabricating molds from 360 brass with non-planar geometries to create PDMS microfluidic channels. These included a channel on a 90{degrees} edge and a channel on a rounded edge with a 250-m radius of curvature. Our 5-axis CNC micro milling machine offers the most versatility in prototyping microfluidics by enabling high resolutions, geometric complexity, a large work volume, and broad material compatibility, all within a user-friendly benchtop system.