Pittsburgh engineers create insect-inspired robots that can monitor hard-to-reach spots
From: University of Pittsburgh
March 3, 2022 -- The
ancient insect creatures can squeeze through the tiniest cracks, fit snugly
into tight spaces and survive in harsh environments: There aren’t many spaces
that are off-limits to an insect. That’s
why researchers at the University of Pittsburgh have created tiny bug-inspired
robots that can carry out tasks in hard-to-reach spaces and inhospitable
environments.
“These robots could be
used to access confined areas for imaging or environmental evaluation, take
water samples, or perform structural evaluations,” said Junfeng Gao, who led
the work as a PhD student in industrial engineering at the Swanson School of
Engineering. “Anywhere you want to access confined places—where a bug could go
but a person could not—these machines could be useful.”
For many creatures
under a certain size—like trap-jaw ants, mantis shrimp, and fleas—jumping
across a surface is more energy-efficient than crawling. Those impulsive
movements were replicated in the robots, which are made of a polymeric
artificial muscle.
“It’s akin to loading
an arrow into a bow and shooting it—the robots latch on to build up energy and
then release it in an impulsive burst to spring forward,” explained M. Ravi
Shankar, professor of industrial engineering at Pitt whose lab led the
research. “Usually, actuation in the artificial muscles we work with is fairly
slow. We were drawn to the question, ‘How do we take this artificial muscle and
use it to generate a jumping actuation rather than slow actuation?’”
The answer lay in the
interplay of molecular order and geometry.
“The curved composite
shape of the polymer muscle allows it to build energy when it is powered. The
way the molecules are aligned in the muscle draws inspiration from the natural
world, where their combined actuation builds energy into the structure,” said
Mohsen Tabrizi, co-author of the study and PhD student in industrial
engineering at the Swanson School. “This is accomplished using no more than a
few volts of electricity.”
The versatile movement
and lightweight structure enables the robots—which are about the size of a
cricket—to move along moving surfaces like sand as easily as hard surfaces, and
even to hop across water.
The paper, “Molecularly
Directed, Geometrically Latched, Impulsive Actuation Powers Sub-Gram Scale
Motility,” (DOI: 10.1002/admt.202100979) was published in the journal Advanced
Materials Technologies and was coauthored by Junfeng Gao, Arul
Clement, Mohsen Tabrizi, and M. Ravi Shankar.
https://www.sciencedaily.com/releases/2022/03/220303191454.htm
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