Autonomous crawling soft 'ringbots' can navigate narrow gaps

Autonomous crawling soft 'ringbots' can navigate narrow gaps
(a, b) The ring with equal thickness (t) and height (h) can only snap twice and shrink to the minimum size. (c) The simulated flipping reaction moments of a ring with radius 15 mm through FEA. (d, e) The ring with h = 5t (d) transforms into a static trumpet-like shape when placed on hot surface without snapping (e). Credit: Advanced Materials (2022). DOI: 10.1002/adma.202207372

Researchers at North Carolina State University have created a ring-shaped soft robot capable of crawling across surfaces when exposed to elevated temperatures or infrared light. The researchers have demonstrated that these "ringbots" are capable of pulling a small payload across the surface—in ambient air or under water, as well as passing through a gap that is narrower than its ring size.

The ringbots are made of liquid crystal elastomers in the shape of looped ribbon, resembling a bracelet. When you place the ringbot on a that is at least 55 degrees Celsius (131 degrees Fahrenheit), which is hotter than the ambient air, the portion of the ribbon touching the surface contracts, while the portion of the ribbon exposed to the air does not. This induces a rolling motion in the ribbon.

Similarly, when researchers shine on the ringbot, the portion of the ribbon exposed to the light contracts, while the portion shielded from the light does not. This also induces a rolling motion in the ribbon.

In practical terms, this means that the crawling ringbot moves from the bottom up when placed on a hot surface. But when exposed to infrared light, the movement begins from the top down.

One of the things that drives this continuous motion is the fact that the ringbots are bistable, meaning that there are two shapes when it is at rest. If the ribbon begins to twist, it will either snap back to its original shape, or snap forward into the other bistable state.

Picture a rubber bracelet shaped like a . If you fold two ends of the bracelet forward a little bit, then let go, it will snap back to its original shape. But if you fold the ends over far enough, it will snap over—essentially folding the bracelet inside out.

Credit: North Carolina State University

In the case of the ringbots, the "folding" is done by applying constant heat or infrared light, causing the elastomer to contract and rotate. If the ring robot is symmetrical, this will essentially make it dance in place.

"But by engineering the shape of the loop, so that one side of the loop is permanently twisted, the structure is asymmetrical," says Jie Yin, corresponding author of a paper on the work and an associate professor of mechanical and aerospace engineering at NC State. "This means that the loop is exposed to the heat or infrared light unevenly, which causes the soft robot to move laterally across the surface."

When placed on a hot surface, the end result is that the crawling ringbot pulls itself forward. But when exposed to infrared light, the crawling ringbot pushes itself forward. Think of it as front-wheel drive versus rear-wheel drive.

In demonstrations, the ringbots were capable of pulling a small payload, and worked both in ambient air and underwater.

The researchers also demonstrated that a ringbot could adapt its body shape to squeeze through a confined space that is more than 30% narrower than the ringbot's diameter. And when the gap is too narrow for the to pass through, it redirects itself to move away from the gap.

"This is a fundamental advance, not something designed with a specific application in mind," says Yao Zhao, a postdoctoral researcher in Yin's lab. "We are demonstrating what can be accomplished when 'physical intelligence' is engineered into the material and the design of the structure itself, allowing it to move and navigate space without computational input."

The paper is published in the journal Advanced Materials.

More information: Yao Zhao et al, Self‐sustained Snapping Drives Autonomous Dancing and Motion in Free‐standing Wavy Rings, Advanced Materials (2022). DOI: 10.1002/adma.202207372
Journal information: Advanced Materials

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