Professor Larry Howell demonstrates the motion on a developable mechanism. Credit: BYU

It took just over 10 years, but real science has finally caught up to the science fiction of Iron Man's transforming exoskeleton suit.

In a paper published today in Science Robotics, engineers at Brigham Young University detail that allows them to build complex mechanisms into the exterior of a structure without taking up any actual space below the .

This new class of mechanisms, called "developable mechanisms," get their name from developable surfaces, or materials that can take on 3-D shapes from flat conformations without tearing or stretching, like a sheet of paper or metal. They reside in a curved surface (like, say, the arms of Iron Man's suit) and can transform or morph when deployed to serve unique functions. When not in use, they can fold back into the surface of the structure seamlessly.

"These make it possible to build complex machines that integrate with surfaces to be very compact, but can deploy and do ," said researcher Larry Howell, professor of mechanical engineering at BYU. "It opens up a whole new world of potential devices that have more functions, but are still very compact."

  • This image shows how developable mechanisms reside in the surface of an object. Credit: BYU

  • Motorized cylindrical-developable mechanism. A motorized, fully revolving linkage emerging from a cylinder that results in a walking motion. Credit: Nelson et al., Sci. Robot. 4, eaau5171 (2019)

Making hyper-compact mechanisms is something increasingly important as manufacturers across medical, space and military industries are constantly working to get more complex functionality in less space. Potential applications of developable mechanisms include:

  • Medical: Surgical instruments that can both cut materials and deploy lights simultaneously during minimally-invasive surgery
  • Vehicles and airplanes: Storage components that could deploy from the inner surface of the fuselage and be completely out of the way when not in use
  • Military: Quad-rotor drones that have adjustable wing spans for fitting in tight spaces
  • Space: Wheels that could deploy claws for rock crawling, which could be especially useful to an interplanetary rover.

This new class of mechanical structures evolved from Howell and colleague Spencer Magleby's work on origami-based engineering, done in collaboration with origami artist Robert Lang. From for NASA to bulletproof barriers for police officers, their work has generated national and international coverage. As the group of researchers moved to curved principles, the mathematics revealed a new way of doing more complex machines.

Video demonstrating movement of a conical developable mechanism conforming to a cone. Credit: Nelson et al., Sci. Robot. 4, eaau5171 (2019)

"Origami was a stepping stone to this," Magleby said. "The art of Origami has inspired us to do things that don't even look like Origami, yet it is the core of much of this new engineering."

Video of movement of a Chebyshev straight-line mechanism embedded in a cylinder. Credit: Nelson et al., Sci. Robot. 4, eaau5171 (2019)

The new line of research is sponsored by the National Science Foundation and includes researchers at BYU, the University of Southern Indiana and Lang Origami.

"It's pretty cool to accomplish things that have merely been science fiction in the past," Howell said. "These are discoveries that will enable us to do things that no one has ever been able to do before. And we hope that other engineers, as they build on these discoveries, will apply them in ways that will help make the world a better place.

More information: T.G. Nelson at University of Southern Indiana in Evansville, IN el al., "Developable mechanisms on developable surfaces," Science Robotics (2019). robotics.sciencemag.org/lookup … /scirobotics.aau5171

Journal information: Science Robotics