Litcius/Paper detail

Time Code for multifunctional 3D printhead controls

Sarah Propst, J. Howard Mueller

2025Nature Communications15 citationsDOIOpen Access PDF

Abstract

Direct Ink Writing, an extrusion-based 3D printing technique, has attracted growing interest due to its ability to process a broad range of materials and integrate multifunctional printheads with features such as shape-changing nozzles, in-situ curing, material switching, and material mixing. Despite these advancements, incorporating auxiliary controls into Geometry Code (G-Code), the standard programming language for these printers, remains challenging. G-Code’s line-by-line execution requires auxiliary control commands to interrupt the print path motion, causing defects in the printed structure. We propose a generalizable time-based synchronization approach called Time Code (T-Code), which decouples auxiliary control from G-Code, enabling uninterrupted print path enrichment. We demonstrate the method’s effectiveness with both high-end and affordable 3D printers by fabricating functional gradients and parallelizing printhead auxiliary devices for mass customization. Our method reduces defects, enhances print speed, and minimizes the mechanical burden on 3D printers, enabling the rapid creation of complex multimaterial structures. Modern 3D printers are still controlled using Geometry Code, a programming language that dates back nearly a century. In this work, the authors present a time-based synchronization method—Time Code—which decouples printhead controls from motion planning, allowing for seamless functionalization of print paths.

Topics & Concepts

Computer scienceCode (set theory)Programming languageSet (abstract data type)Additive Manufacturing and 3D Printing TechnologiesManufacturing Process and OptimizationInteractive and Immersive Displays