Rotational Multimaterial 3D Printing of Soft Robotic Matter With Embedded Asymmetrical Pneumatics

摘要

The rapid design and fabrication of soft robotic matter is of growing interest for shape morphing, actuation, and wearable devices. Here, we report a facile fabrication method for creating soft robotic materials with embedded pneumatics that exhibit programmable shape morphing behavior. Using rotational multimaterial 3D printing, asymmetrical core-shell filaments composed of elastomeric shells and fugitive channels are patterned in 1D, 2D, and 2.5D motifs. By precisely controlling the nozzle design, rotation rate, extrusion rate, and print path, one can control the local orientation, shape, and cross-sectional area of the patterned fugitive channel along each printed filament. Once the elastomeric matrix is cured, the fugitive ink is removed, leaving behind embedded channels that facilitate pneumatic actuation. Using a connected Fermat spiral pathing approach, one can automatically generate desired print paths required for more complex soft robots, such as hand-inspired grippers. Our integrated design and printing approach enables one to rapidly build soft robotic matter that exhibits myriad shape morphing transitions on demand.