Image typesetting machine scanning process algorithm is suitable for many high-resolution two-dimensional (printing) applications and three-dimensional (printing) applications. Such as engraving RFID gravure roller.
Printed electronic technology is an upcoming new technology. The high precision required by electronic components and circuits will set a new benchmark for the accuracy and uniformity of print output. Most organic and inorganic inks for conductors and semiconductors are pasty and difficult to print.
For uniform, non-porous layering of these inks, precise control of cell geometry and surface texture of gravure plates is critical. An engraving test of an RFID tag antenna is shown, with a contour line width of only 10 microns.
Laser Engraver technology combines digital imaging methods, improves traditional printing and platemaking processes, and improves print output efficiency, screen range, accuracy and quality. Corresponding algorithms can be used to utilize different laser types. Utilizing the modulated laser beam waveform, the single-shot single-hole SHC process is currently the fastest process for gravure, which can be used for various substrates, inks and printing. A new engraving algorithm using a high-power TEM00 source extends the application of laser ablation methods to a range of industrial applications, such as anilox rollers for large-area material transfer, high-precision gravure printing patterns for printing electronics, For 3D printing tools. When both the required laser power and the new engraving mature algorithm are satisfied, the ultra-short pulse Laser Engraver will be able to promote and improve the above method. The challenge ahead will be to use picosecond ultrashort pulse lasers to optimize the ablation process.