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Production method inspired by children's pop-up books enables rapid fabrication of tiny, complex devices

17 February 2012

A new technique inspired by elegant pop-up books and origami will soon allow clones of robotic insects to be mass-produced by the sheet. Devised by engineers at Harvard, the ingenious layering and folding process enables the rapid fabrication of not just microrobots, but a broad range of electromechanical devices.

In prototypes, 18 layers of carbon fibre, Kapton (a plastic film), titanium, brass, ceramic, and adhesive sheets have been laminated together in a complex, laser-cut design. The structure incorporates flexible hinges that allow the three-dimensional product, which is just 2.4mm tall, to assemble in one movement, like a pop-up book.

The Harvard Monolithic Bee (or "Mobee") pops up within an assembly scaffold, which performs more than 20 origami assembly folds. Dozens of these microrobots could be fabricated in parallel on a single sheet.

"This takes what is a craft, an artisanal process, and transforms it for automated mass production," says Pratheev Sreetharan, who co-developed the technique with J. Peter Whitney. Both are doctoral candidates at the Harvard School of Engineering and Applied Sciences.

Sreetharan, Whitney, and their colleagues in the Harvard Microrobotics Laboratory have been working for years to build bio-inspired, bee-sized robots that can fly and behave autonomously as a colony. Appropriate materials, hardware, control systems, and fabrication techniques did not exist prior to the RoboBees project, so each must be invented, developed, and integrated by a diverse team of researchers.

Less than a year ago, the group was using a painstaking and error-prone method to fold, align, and secure each of the minuscule parts and joints. "You'd take a very fine tungsten wire and dip it in a little bit of superglue," explains Sreetharan. "Then, with that tiny ball of glue, you'd go in under a microscope like an arthroscopic surgeon and try to stick it in the right place. Until recently, the manual assembly process was the state of the art in this field,"

The same result can now be achieved—without human error—through locking mechanisms and dip soldering. The new process also enables the use of cured carbon fibre, which is rigid and easy to align, rather than uncured carbon fibre, which Sreetharan compares to "wet tissue paper."
"Our new techniques allow us to use any material including polymers, metals, ceramics, and composites," says principal investigator Rob Wood, an Associate Professor of Electrical Engineering at Harvard EAS and a Core Faculty Member at the Wyss Institute for Biologically Inspired Engineering at Harvard.

"The ability to incorporate any type and number of material layers, along with integrated electronics, means that we can generate full systems in any three-dimensional shape," Wood says. "We've also demonstrated that we can create self-assembling devices by including pre-stressed materials."

The implications of this novel fabrication strategy go far beyond these micro-air vehicles. The same mass-production technique could be used for high-power switching, optical systems, and other tightly integrated electromechanical devices that have parts on the scale of micrometers to centimeters.

Moreover, the layering process builds on the manufacturing process currently used to make printed circuit boards, which means that the tools for creating large sheets of pop-up devices are common and abundant. It also means that the integration of electrical components is a natural extension of the fabrication process—particularly important for the size- and weight-constrained RoboBees project.

"In a larger device, you can take a robot leg, for example, open it up, and just bolt in circuit boards. We're so small that we don't get to do that. I can't put a structural mechanism in here and have it serve no electrical function."

Pointing to the carbon-fibre box truss that constitutes the pop-up bee's body frame, Sreetharan says, "Now, I can put chips all over that. I can build in sensors and control actuators."

Harvard Microrobotics Lab

 


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