Novel Fast Cure Silicone Inks for Single‐Step, Support‐Free 3D Printing of Tall, Overhanging, and High Aspect Ratio Structures

Silicone elastomers have a broad variety of applications, such as soft robotics, biomedical devices, and structural metamaterials. The extrusion‐based method known as direct ink write (DIW) has enabled the production of additively manufactured silicone structures. However, this method is limited to...

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Published in:Advanced materials technologies 2024-05, Vol.9 (19), p.n/a
Main Authors: Guell Izard, Anna, Pérez Pérez, Lemuel X., Weisgraber, Todd H., Van Meerbeek, Ilse M., Golobic, Alexandra M., Duoss, Eric B., Lenhardt, Jeremy M.
Format: Article
Language:English
Subjects:
3D printing
3D printing, fast cure
Additive Manufacturing
Direct ink write
elastomer
ENGINEERING
fast cure
INORGANIC, ORGANIC, PHYSICAL, AND ANALYTICAL CHEMISTRY
MATERIALS SCIENCE
silicone
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container_end_page n/a
container_issue 19
container_start_page
container_title Advanced materials technologies
container_volume 9
creator Guell Izard, Anna
Pérez Pérez, Lemuel X.
Weisgraber, Todd H.
Van Meerbeek, Ilse M.
Golobic, Alexandra M.
Duoss, Eric B.
Lenhardt, Jeremy M.
description Silicone elastomers have a broad variety of applications, such as soft robotics, biomedical devices, and structural metamaterials. The extrusion‐based method known as direct ink write (DIW) has enabled the production of additively manufactured silicone structures. However, this method is limited to manufacturing mostly planar or pseudo‐3D structures. Due to the low self‐supporting capabilities of extruded strands for traditional silicone‐based “inks,” obtaining tall or overhanging structures, or structures comprised by thin walls is not feasible. Here, a novel Fast Cure silicone‐based ink is demonstrated that enables manufacturing of complex 3D structures. The Fast Cure ink is a two‐part mixture and silicone structures are produced by inline mixing and coextrusion of a part containing a catalyst (part A) and a part containing a crosslinker (part B). By the virtue of crosslinking, the extruded strands rapidly rigidize, increasing their self‐supportive capacity. Hence, structures can be obtained with superior shape retention and previously unobtainable parts are realized that are tall, with aspect ratios higher than 3, and have overhanging features, achieving inclination angles smaller than 35° with respect to the printing plane. These minimal sag parts are achieved without requiring extra curing or mechanisms, support structures, or suspension baths. Fast Cure silicone in direct ink write additive manufacturing enables the obtention of previously unattainable structures, such as tall or overhanging structures, or structures comprised by thin walls. Thanks to the quick gelling process, extruded strands rigidize, enabling the attainment of such structures, without requiring an extra curing mechanism or a suspension bath.
doi_str_mv 10.1002/admt.202400423
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subjects 3D printing
3D printing, fast cure
Additive Manufacturing
Direct ink write
elastomer
ENGINEERING
fast cure
INORGANIC, ORGANIC, PHYSICAL, AND ANALYTICAL CHEMISTRY
MATERIALS SCIENCE
silicone
title Novel Fast Cure Silicone Inks for Single‐Step, Support‐Free 3D Printing of Tall, Overhanging, and High Aspect Ratio Structures
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