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Polymer Inkjet Printing: Construction of Three-Dimensional Structures at Micro-Scale by Repeated Lamination  

Yun, Yeon-Hee (Department of Chemical Engineering and Bionanotechnology, Hanyang University)
Kim, Jae-Dong (Department of Chemical Engineering and Bionanotechnology, Hanyang University)
Lee, Byung-Kook (Department of Chemical Engineering and Bionanotechnology, Hanyang University)
Cho, Yong-Woo (Department of Chemical Engineering and Bionanotechnology, Hanyang University)
Lee, Hee-Young (Medikan Inc.)
Publication Information
Macromolecular Research / v.17, no.3, 2009 , pp. 197-202 More about this Journal
Abstract
Solution-based, direct-write patterning by an automated, computer-controlled, inkjet technique is of particular interest in a wide variety of industrial fields. We report the construction of three-dimensional (3D), micro-patterned structures by polymer inkjet printing. A piezoelectric, drop-on-demand (DOD) inkjet printing system and a common polymer, PVA (poly(vinyl alcohol)), were explored for 3D construction. After a systematic preliminary study with different solvent systems, a mixture of water and DMSO was chosen as an appropriate solvent for PVA inks. The use of water as a single solvent resulted in frequent PVA clogging when the nozzles were undisturbed. Among the tested polymer ink compositions, the PVA inks in a water/DMSO mixture (4/1 v/v) with concentrations of 3 to 5 g/dL proved to be appropriate for piezoelectric DOD inkjet printing because they were well within the proper viscosity and surface tension range. When a dot was printed, the so-called 'coffee-ring effect' was significant, but its appearance was not prominent in line printing. The optimal polymer inkjet printing process was repeated slice after slice up to 200 times, which produced a well-defined, 3 D micro-patterned surface. The overall results implied that piezoelectric DOD polymer inkjet printing could be a powerful, solid-freeform, fabrication technology to create a controlled 3D architecture.
Keywords
inkjet printing; direct writing; 3D construction; micro-patterning; viscosity; surface tension;
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