Title

Printing transparent grid patterns with conductive silver ink with flexography

Author Info

Colleen Twomey, California Polytechnic State University - San Luis ObispoFollow
Xiaoying Rong, California Polytechnic State University, San Luis ObispoFollow
Liam O'Hara, Clemson University
Charles Tonkin, Clemson University
Malcolm Keif, California Polytechnic State University - San Luis ObispoFollow

Recommended Citation

Published in TAGA 2015 Technical Association of the Graphic Arts Proceedings: Albequerque, NM, March 22, 2015, pages 62-76.

Abstract

The printed electronics market, according to market research firm IDTechEx, is slated to grow from $16.04 billion in 2013 to $76.79 billion in 2023. Printing transparent grids with a known printing process such as flexography is attractive to this market because transparent grids are part of the fast-growing touch screen market (amongst others , and flexography offers a lowcost/high-volume print platform that can handle a variety of substrates, high press speeds, roll-toroll (R2R) printing, and the ability to handle different ink rheologies. However, flexography has print characteristics that can be problematic for printed electronics such as high image (feature) gain and the ability to hold fine images (features) in the (relief) printing plate.

This study used a “banded” anilox roll, which has multiple volumes and cell counts separated into bands, conductive nano-silver, water-based ink, and a PET substrate and printed on a commercial flexo narrow- web press. The process parameters studied included types of sticky back, anilox cell count/volume, plate imaging, and plate surface morphology. The printed transparent grid patterns were evaluated for conductivity, which was measured with a Digital Multimeter; and transparency, which was measured with a transmission densitometer.

The results of the study showed that when the photopolymer plates were imaged at a resolution of 000dpi and with a “flat top dot” (1:1 file - image) exposure technique, the flexo plate was able to hold a minimum of 6.35 microns line width. The 6.35 microns lines were successfully printed on the press and produced the conductive lines. Types of sticky back and different anilox cell volumes have an impact on measured resistance of the grid pattern. $ high modulus, or “¿rm” sticky back tape with a low screen count/high-volume anilox (800 cpi/2.85bcm) resulted in the lowest (<15 ohms) resistance. In addition, the introduction of plate surface texture during the platemaking lowered resistance. The grid pattern shapes of diamond/square and hexagon yielded the best transmissivity (above 92%).

The study proved that commercially available flexographic materials and optimized process parameters could improve the printability and performance of transparent grid patterns with conductive inks.

Disciplines

Graphic Communications

Copyright

2015 Printing Industries of America