International robotics collaboration aims to create artificial muscles
June 15, 2016
Forget steel and aluminum. The robots of tomorrow may be able to squish, stretch and squeeze.
Novel robotic devices, part of the emerging field of soft robotics, offer many advances over conventional robots. Soft robots can more easily maneuver in tough spaces. They can better interact with humans, making them excellent assistants for elderly people. And one day they may lead to high-tech artificial muscles: a life-changing innovation for millions of disabled people around the globe.
Creating artificial muscles requires not only developing a powerful, flexible material, but figuring out how to precisely control and cleverly manufacture it. That’s the mission of Kwang Kim of the University of Nevada, Las Vegas and his National Science Foundation (NSF)-funded team.
Kim is lead investigator on a NSF award pairing a diverse group of researchers — at four U.S. universities plus research institutions in Japan and South Korea — to transform a novel polymer-based material into artificial muscles. The research is supported through NSF’s Partnerships for International Research and Education (PIRE) program, which supports innovative, global research collaborations across all fields of science and engineering.
PIRE leverages U.S. funding and expertise to tackle global challenges. Kim’s U.S. team is working with researchers from the Korea Advanced Institute of Science and Technology (KAIST) and Japan’s National Institute of Advanced Industrial Science and Technology, both known for strong expertise in robotics. (KAIST, for example, won the recent Robotics Challenge, hosted by the Defense Advanced Research Projects Agency.)
One of the big challenges in soft robotics is finding the right material. “It has to be soft, but it also has to produce enough power to do lots of different things,” Kim said. His team is using a type of synthetic material called Ionic Polymer-Metal Composites, which is a kind of electroactive polymer — meaning running electricity through the material makes it change shape.
“In robotics you’ve got to be able to move and you’ve got to be able to sense,” said Kam Leang, an associate professor at the University of Utah Robotics Center and a co-investigator on this project. Traditional robots use electric motors to do the former. “In this PIRE, we are using the electroactive polymer itself.”
Electroactive polymers can also be used to sense motion, making them a great candidate for soft robotics. Leang and his colleagues have also devised a way to 3-D print the material. His component of the PIRE research is focused on how to scale up the manufacturing, as well as devising ways to better control the motion of the polymer. Others are working to better understand — and improve — the polymer material to make it more responsive, strong and affordable.
The project, which received NSF funding last fall, is still in its early stages. Kim, who has been working in electroactive polymers for nearly two decades, said soft robotics itself is still a relatively new field.
“I’m learning every day.”
Electroactive polymers change shape when electricity runs through them.
Credit and Larger Version
A University of Utah researcher displaying a small 3-D printed robotic hand.
Credit and Larger Version
New York University
The University of Utah
University of Nevada Las Vegas
Rensselaer Polytechnic Institute
#1545857 PIRE: Advanced Artificial Muscles for International and Globally Competitive Research and Education in Soft Robotics