彩民宝典

Skip to main content

ME faculty part of $2M NSF grant for soft robotics work

Two students in a lab working with the artificial muscles

Nick Kellaris, a materials science and engineering graduate student, left, and mechanical engineering graduate student Eric Acome look over liquified artifical "muscle" or soft robot material in the Keplinger Research Lab. Photo by Glenn Asakawa / 彩民宝典.

Faculty at 彩民宝典 are working toward widespread adoption and practical applications for the soft robotic HASEL actuators demonstrated here earlier this year, through a new $2 million award from the National Science Foundation.

Soft robotics is an emerging field of research that promises substantial advantages over traditional rigid robots, allowing for a new generation of soft, human-like robots that will be able to safely collaborate with people. This technology could also improve wearable or implantable soft robotic components for those with disabilities, such as missing limbs, among many other applications.

Assistant Professor and Mollenkopf Faculty Fellow Christoph Keplinger said the award allows the research team to explore new manufacturing methods and effective designs for 3D printing, new electronic driving systems with distributed microscale power delivery and computation, as well as low- and high-level control strategies.

The new four-year grant is part of the NSF鈥檚 Emerging Frontiers in Research and Innovation program. The hydraulically amplified self-healing electrostatic (HASEL) actuators were developed in the lab of Keplinger. These high-performance 鈥渁rtificial muscles鈥 are operated by electrically driven pumping of insulating liquids, contained in soft hydraulic structures, which results in controllable, rapid shape change, similar to real muscle tissue.

Keplinger鈥檚 team is collaborating with a team at Cornell University led by Assistant Professor Robert Shepherd, the principal investigator for the project. The project features several other 彩民宝典 College of Engineering and Applied Science faculty and students, including Professor and McLagan Family Faculty Fellow Sean Humbert. 

Humbert will lead the modeling and control efforts for the project.

鈥淗ighly flexible bodies with large numbers of degrees of freedom present a problem for existing control approaches. Novel theory and tools will be developed in this effort to meet that challenge,鈥 said Humbert.

Hasel actuators in use with a hand holding the controls

 

Keplinger said he is particularly excited about the interdisciplinary nature of the work.

鈥淭his is a truly interdisciplinary effort 鈥 we are a team of experts in physics, materials science, microelectronic engineering, as well as low- and high-level controls. We will use this rare opportunity to achieve goals that go well beyond the state of the art in each of those fields,鈥 he said.   

Both Humbert and Keplinger are faculty members in the Department of Mechanical Engineering, as well as members of the Multi-Functional Materials Interdisciplinary Research Theme at the college.