Curved Origami Offers A Creative Route To Making Robots And Other Mechanical Devices

Curved Origami Offers A Creative Route To Making Robots And Other Mechanical Devices

The big idea

Building robotic grippers that can firmly grasp heavy objects and also gently grasp delicate ones usually requires complicated sets of gears, hinges and motors. But it turns out that it’s also possible to make grippers out of simple sheets of flexible material with the right creases in them.

Our lab at Arizona State University has designed curved fold patterns that can change stiffness and flexibility. Flexible materials shaped with these patterns can be used to make simple, inexpensive robotic grippers, swimming robots and other mechanical devices.

People naturally vary the amount of stiffness needed to handle fragile and sturdy objects appropriately. Robots interact with the environment in the same way. Curved folding is a simple way to give robots the ability to vary the amount of stiffness they use to interact with different objects and environments.

Our team’s idea was inspired by origami, the art of paper folding. Origami can be stiff or flexible depending on its folding pattern, but it is hard to give origami a range of stiffnesses.

To overcome this problem, we replaced straight origami folding lines, or creases, with curved creases. By using multiple curved lines between two points rather than just one straight line, a curved origami structure can take on multiple shapes. We found that each shape has its own unique stiffness. Building a robotic gripper, for example, based on this design allows it to apply different amounts of force to objects depending on which curved crease the robot uses.

Four small plastic sheets with curved folds forming different structures
Examples of curved origami with robotics applications. Zirui Zhai, Arizona State University, CC BY-NC-ND

Compared with other methods for variable stiffness, this method is simple and compact, which means it can be used to make small and light devices.

Why it matters

Changing stiffness is important and ubiquitous in nature, and it’s a key variable in engineering. A heavy-duty robot gripper needs high stiffness, or low flexibility, to lift heavy objects. Other robot grippers need low stiffness, or high flexibility, to protect fragile objects.

Changing between a stiff state and a flexible state is critical in robots, but today’s adjustable stiffness systems are commonly bulky and cannot be used in micro-robots or soft robots. Micro-robots include insect-size robots being developed to monitor infrastructure and the environment. Soft robots under development are made of inflatable or flexible materials, which makes them safer to use alongside people. Our curved origami designs have a simple mechanical structure, making them easy to fabricate and control.

The authors demonstrate curved folds, variable stiffness and how curved folds can be used to make robots.

What other research is being done

Traditional mechanical structures can also be used to vary stiffness: for example, grippers powered by variable pneumatics or electric motors. Our work is the first to achieve a full range of stiffness control with a simple structure.

The curved origami technique builds on our previous origami-inspired work, including origami-based stretchable lithium ion batteries and origami-inspired structures that can be collapsed and expanded on demand.

What’s next

We are adding more remote control functions to the curved origami structures to trigger the folding. We are considering several different methods such as pneumatic, magnetic and electronic control. With on-board control, curved origami can be applied to fields beyond robotics. One possibility is haptic devices that change their stiffness to give people realistic force feedback in virtual reality. The Conversation

A series of six photos of a blue plastic square with pleated folds floating in water
A pneumatic, swimming robot made from plastic sheets with curved folds. Zirui Zhai, Arizona State University, CC BY-NC-ND

Hanqing Jiang, Professor of Mechanical Engineering, Arizona State University and Zirui Zhai, Ph.D. student in Mechanical Engineering, Arizona State University

This article is republished from The Conversation under a Creative Commons license. Read the original article.