Structures can contract, reshape and grab objects while floating on water
Credit: Sangchul Roh, NC State University
Researchers at North Carolina State University have created 3D-printed flexible mesh structures that can be controlled with applied magnetic fields while floating on water. The structures can grab small objects and carry water droplets, giving them the potential to be useful as soft robots that mimic creatures living on water surfaces or that can serve as tissue scaffolds for cell cultures.
“This research shows capabilities in the emerging field of combining 3D printing and soft robotics,” said Orlin Velev, S. Frank and Doris Culberson Distinguished Professor of Chemical and Biomolecular Engineering at NC State and corresponding author of a paper describing the research.
To create these structures, the researchers made an “ink” from silicone microbeads, bound by liquid silicone and contained in water. The resulting “homocomposite thixotropic paste” resembles common toothpaste, which can easily be squeezed out of a tube but then maintains its shape on your toothbrush without dripping. The researchers used a 3D printer to shape the paste into mesh-like patterns. The patterns are then cured in an oven to create flexible silicone structures that can be controlled – stretched and collapsed – by the application of magnetic fields.
“This self-reinforced paste allows us to create structures that are ultra-soft and flexible,” said Sangchul Roh, an NC State Ph.D. student in Velev’s lab and first author of the paper.
“Embedding of iron carbonyl particles, which are widely available and have a high magnetization, allows us to impart a strong response to magnetic field gradients,” added Joseph Tracy, professor of materials science and engineering and a senior co-investigator on the project.
“The structures are also auxetic, which means that they can expand and contract in all directions,” Velev said. “With 3D printing, we can control the shape before and after the application of the magnetic field.”
The structures’ properties also allow them to be used while floating on water, similar to water striders, or insects that skim or hop across water surfaces.
“Mimicking live tissues in the body is another possible application for these structures,” Roh said.
In the paper, published in a special issue of Advanced Materials Technologies, the researchers showed how they were able to design reconfigurable meshes, a structure that could “grab” a tiny ball of aluminum foil and a structure that can “carry” a single water droplet and then release it on demand through the mesh.
“For now, this is an early stage proof-of-concept for a soft robotic actuator,” Velev said.
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The paper is co-authored by NC State graduate students Lilian B. Okello, Jameson P. Hankwitz and Jessica A.-C. Liu, and undergraduate student Nuran Golbasi.
The research is funded by the National Science Foundation under grants CBET-1604116 and CMMI-1663416.
Note to editors: An abstract of the paper follows.
“3D-Printed Silicone Soft Architectures with Programmed Magneto-Capillary Reconfiguration”
Authors: Sangchul Roh, Lilian B. Okello, Nuran Golbasi, Jameson P. Hankwitz, Jessica A.-C. Liu, Joseph B. Tracy and Orlin D. Velev, North Carolina State University
Published: Jan. 15, 2019, online in Advanced Materials Technologies
DOI: 10.1002/admt.201800528.
Abstract: Soft intelligent structures that are programmed to reshape and reconfigure under magnetic field can find applications such as in soft robotics and biomedical devices. Here, a new class of smart elastomeric architectures that undergo complex reconfiguration and shape change in applied magnetic fields, while floating on the surface of water, is reported. These magnetoactive soft actuators are fabricated by 3D printing with homocomposite silicone capillary ink. The ultrasoft actuators easily deform by the magnetic force exerted on carbonyl iron particles embedded in the silicone, as well as lateral capillary forces. The tensile and compressive moduli of the actuators are easily determined by their topological design through 3D printing. As a result, their responses can be engineered by the interplay of the intensity of the magnetic field gradient and the programmable moduli. 3D printing allows us to fabricate soft architectures with different actuation modes, such as isotropic/anisotropic contraction and multiple shape changes, as well as functional reconfiguration. Meshes that reconfigure in magnetic fields and respond to external stimuli by reshaping could serve as active tissue scaffolds for cell cultures and soft robots mimicking creatures that live on the surface of water.
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