Curved origami provides new range of stiffness-to-flexibility in robots


ASU_Origami_Robots
|

New research that employs curved origami structures has dramatic implications in the development of robotics going forward, providing tunable flexibility — the ability to adjust stiffness based on function — that historically has been difficult to achieve using simple design.

“The incorporation of curved origami structures into robotic design provides a remarkable possibility in tunable flexibility, or stiffness, as its complementary concept,” explained Hanqing Jiang, a mechanical engineering professor at Arizona State University.

“High flexibility, or low stiffness, is comparable to the soft landing navigated by a cat. Low flexibility, or high stiffness, is similar to executing of a hard jump in a pair of stiff boots,” he said.

Jiang is the lead author of a paper, “In Situ Stiffness Manipulation Using Elegant Curved Origami,” published this week in Science Advances. “Curved Origami can add both strength and catlike flexibility to robotic actions,” he said.

Jiang also compared employing curved origami to the operational differences between sporty cars sought by drivers who want to feel the rigidity of the road and vehicles desired by those who seek a comfortable ride that alleviates jarring movements.

“Similar to switching between a sporty-car mode to a comfortable-ride mode, these curved origami structures will simultaneously offer a capability to on-demand switch between soft and hard modes depending on how the robots interact with the environment,” he said.

Robotics requires a variety of stiffness modes: high rigidity is necessary for lifting weights; high flexibility is needed for impact absorption; and negative stiffness, or the ability to quickly release stored energy like a spring, is needed for sprint.

Origami_Provides_Flexible_Robot_Stiffness
A video explaining the research is available on YouTube.

Traditionally, the mechanics of accommodating rigidity variances can be bulky with nominal range, whereas curved origami can compactly support an expanded stiffness scale with on-demand flexibility. The structures covered in Jiang and team’s research combine the folding energy at the origami creases with the bending of the panel, tuned by switching among multiple curved creases between two points.

Curved origami enables a single robot to accomplish a variety of movements. A pneumatic, swimming robot developed by the team can accomplish a range of nine different movements, including fast, medium, slow, linear and rotational movements, by simply adjusting which creases are used.

In addition to applications for robotics, the curved origami research principles are also relevant for the design of mechanical metamaterials in the fields of electromagnetics, automobile and aerospace components, and biomedical devices.

“The beauty of this work is that the design of curved origami is very similar, just by changing the straight creases to curved creases, and each curved crease corresponds to a particular flexibility,” Jiang said. 

Curved_Origami_Robot_Example)_ASU
A video explaining how origami creases are formed is available on YouTube.

The research was funded by the Mechanics of Materials and Structures program of the National Science Foundation. Authors contributing to the paper are Jiang, Zirui Zhai and Lingling Wu from ASU's School for Engineering, Matter, Transport and Energy, and Yong Wang and Ken Lin from the Department of Engineering Mechanics at Zhejiang University, China.

Images and videos by Zirui Zhai/Arizona State University

More Science and technology

 

A graphic announcing the "cool" products of TOMNET with people working in the foreground and computer screens with data in the background.

ASU travel behavior research center provides insights on the future of transportation

The Center for Teaching Old Models New Tricks, known as TOMNET, has spent the past seven years conducting research and developing tools to improve transportation systems planning methods and data.As…

Illustration of a line up with four black silhouettes and one maroon silhouette

When suspect lineups go wrong

It is one of the most famous cases of eyewitness misidentification.In 1984, Jennifer Thompson was raped at knifepoint by a man who broke into her apartment. During the assault, she tried to make a…

Adam Doupé and the Shellphish team cheer from their seats in the Las Vegas Convention Center.

Jackpot! ASU hackers win $2M at Vegas AI competition

This August, a motley assortment of approximately 30,000 attendees, including some of the best cybersecurity professionals, expert programmers and officials from top government agencies packed the…