New RoboBee Traverses Air and Water

Hybrid robot flies, dives, swims and propels itself out of water.

Air-water hybrid microrobot uses a tiny, novel sparker inside the chamber ignites the gas to propel the RoboBee out of the water. The robot is designed to passively stabilize in air, so that it always lands on its feet. (Image courtesy of Yufeng Chen/Harvard SEAS.)

Air-water hybrid microrobot uses a tiny, novel sparker inside the chamber ignites the gas to propel the RoboBee out of the water. The robot is designed to passively stabilize in air, so that it always lands on its feet. (Image courtesy of Yufeng Chen/Harvard SEAS.)

We’ve seen RoboBees that can fly, stick to walls and dive into water. Now, get ready for a hybrid RoboBee that can fly, dive into water, swim, propel itself back out of water and safely land.

New floating devices allow this multipurpose air-water microrobot to stabilize on the water’s surface before an internal combustion system ignites to propel it back into the air.

This latest-generation RoboBee, which is 1,000 times lighter than any previous aerial-to-aquatic robot, could be used for numerous applications, from search-and-rescue operations to environmental monitoring and biological studies.

The research is described in Science Robotics. It was led by a team from the Harvard John A. Paulson School of Engineering and Applied Sciences (SEAS) and the Wyss Institute for Biologically-Inspired Engineering at Harvard.

“This is the first microrobot capable of repeatedly moving in and through complex environments,” said Yufeng Chen, who was a graduate student in the Microrobotics Lab at SEAS when the research was conducted and is first author of the paper. “We designed new mechanisms that allow the vehicle to directly transition from water to air, something that is beyond what nature can achieve in the insect world.”

Designing a millimeter-sized robot that moves in and out of water has numerous challenges. First, water is 1,000 times denser than air, so the wing flapping speed must will vary widely between the two mediums. If the flapping frequency is too low, the RoboBee can’t fly. If it’s too high, the wing will snap off in water.

By combining theoretical modeling and experimental data, the researchers found the goldilocks combination of wing size and flapping rate, scaling the design to allow the bee to operate repeatedly in both air and water. Using this multimodal locomotive strategy, the robot to flaps its wings at 220 – 300 Hz in air and 9 – 13 Hz in water.

Another major challenge the team had to address: at the millimeter scale, the water’s surface might as well be a brick wall. Surface tension is more than 10 times the weight of the RoboBee and three times its maximum lift. Previous research demonstrated how impact and sharp edges can break surface tension on a RoboBee’s entry into water but the question remained: How does it get back out again?

To solve that problem, the researchers retrofitted the RoboBee with four buoyant outriggers — essentially robotic floaties — and a central gas collection chamber. Once the RoboBee swims to the surface, an electrolytic plate in the chamber converts water into oxyhydrogen, a combustible gas fuel.

he RoboBee is retrofitted with four buoyant and a central gas collection chamber. Once the RoboBee swims to the surface, an electrolytic plate in the chamber converts water into oxyhydrogen, a combustible gas fuel. (Image courtesy of Yufeng Chen/Harvard SEAS.)

he RoboBee is retrofitted with four buoyant and a central gas collection chamber. Once the RoboBee swims to the surface, an electrolytic plate in the chamber converts water into oxyhydrogen, a combustible gas fuel. (Image courtesy of Yufeng Chen/Harvard SEAS.)

“Because the RoboBee has a limited payload capacity, it cannot carry its own fuel, so we had to come up with a creative solution to exploit resources from the environment,” said Elizabeth Farrell Helbling, graduate student in the Microrobotics Lab and co-author of the paper. “Surface tension is something that we have to overcome to get out of the water, but is also a tool that we can utilize during the gas collection process.”

The gas increases the robot’s buoyancy, pushing the wings out of the water and the floaties stabilize the RoboBee on the water’s surface. From there, a tiny, novel sparker inside the chamber ignites the gas, propelling the RoboBee out of the water. The robot is designed to passively stabilize in air, so that it always lands on its feet.

“By modifying the vehicle design, we are now able to lift more than three times the payload of the previous RoboBee,” said Chen. “This additional payload capacity allowed us to carry the additional devices including the gas chamber, the electrolytic plates, sparker, and buoyant outriggers, bringing the total weight of the hybrid robot to 175 miligrams, about 90mg heavier than previous designs. We hope that our work investigating tradeoffs like weight and surface tension can inspire future multi-functional microrobots – ones that can move on complex terrains and perform a variety of tasks.”

Because of the lack of onboard sensors and limitations in the current motion-tracking system, the RoboBee cannot yet fly immediately upon propulsion out of water but the team hopes to change that in future research.

“The RoboBee represents a platform where forces are different than what we – at human scale – are used to experiencing,” said Robert Wood, a professor of engineering and applied sciences at Harvard and senior author of the paper. “While flying the robot feels as if it is treading water; while swimming it feels like it is surrounded by molasses. The force from surface tension feels like an impenetrable wall. These small robots give us the opportunity to explore these non-intuitive phenomena in a very rich way.”

For more in-depth UAV coverage, check out our feature: Drone Age – Rise of the Flying Robots.

Source: Harvard John A. Paulson School of Engineering and Applied Sciences