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Researchers have developed a novel device that couples magnetic fields and kirigami design principles to remotely control the movement of a flexible dimpled surface, allowing it to manipulate objects without actually grasping them. This image shows how multimodal manipulation of these magnetic kirigami dome metasheets allows them to lift and spin Petri dishes loaded with multi-colored spheres. Credit: Yinding Chi
A new device utilizing magnetic fields and kirigami design allows for the delicate manipulation of objects without grasping.
Researchers have designed an innovative device that combines magnetic fields with kirigami-inspired design to remotely control a flexible, dimpled surface. This surface can move objects without needing to physically grasp them, making it ideal for lifting and transporting fragile items, gels, or liquids. The technology holds promise for applications in tight or confined spaces where conventional tools, like robotic arms, cannot operate.
“We were trying to address two challenges here,” explains Jie Yin, co-corresponding author of a paper on the work and an associate professor of mechanical and aerospace engineering at North Carolina State University. “The first challenge was how to move objects that you can’t pick up with grippers – such as fragile objects or things in confined spaces. The second challenge was how to use a magnetic field to remotely lift and move objects that are not magnetic.”
Magnetic Metasheet Mechanics
To address those challenges, the researchers created a “metasheet” that consists of an elastic polymer that is embedded with magnetic microparticles. A pattern was then cut into the sheet. The outer edges of the metasheet are attached to a rigid frame.
By moving a magnetic field under the metasheet, you can force sections of the metasheet to bulge upward or sink downward.
Manipulating Objects With Magnetic Waves
“You can actually cause the surface of the metasheet to move like a wave by controlling the direction of the magnetic field,” Yin says. “And adjusting the strength of the magnetic field determines how much the wave rise or fall.”
“Controlling the surface movement of the metasheet makes it possible to move many types of objects resting on the surface – whether they’re drops of liquid or a flat piece of glass,” says Joe Tracy, co-corresponding author of the paper and a professor of materials science and engineering at NC State.
Future Applications and Enhancements
“The design of cuts on the metasheet are an example of kirigami, or paper-cutting,” says Yinding Chi, first author of the paper and a former Ph.D. student at NC State. “This is particularly important for the metasheets, because kirigami enhances the flexibility without sacrificing the fundamental stiffness of the material itself.
“That allows us to amplify the deformation of the material without losing its mechanical strength,” says Chi, who is now a postdoctoral researcher at the University of Pennsylvania. “In addition, the metasheet is very responsive to the magnetic field, with a response time as fast as two milliseconds.”
“There’s been rather little work done on how magnetic actuation can be used in conjunction with kirigami, and what we’ve done here suggests that there’s a tremendous amount of potential for combining these approaches in fields from soft robotics to manufacturing applications,” says Tracy.
“We are interested in scaling this approach down, to allow the metasheets to manipulate smaller objects and smaller volumes of liquid,” says Chi.
“We’re also interested in how this approach could be used to create haptic technologies that may have applications in everything from gaming to accessibility devices,” says Yin.
Reference: “Magnetic kirigami dome metasheet with high deformability and stiffness for adaptive dynamic shape-shifting and multimodal manipulation” 6 December 2024, Science Advances.
The paper was co-authored by Matthew Clary, Fangjie Qi, Haoze Sun and Saarah Niesha Cantú of NC State; and by Emily Evans and Catherine Capodanno of Elon University.
This work was done with support from the National Science Foundation under grants 2005374, 2329674, 1663416 and 1662641.
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