Tiny Triboelectric Nanogenerator Can Harvest Energy From the Breeze You Make When You Walk

This illustration shows a triboelectric nanogenerator developed by researchers in China that harvests electricity generated from the wind-blown fluttering plastic strips. The design allows researchers to scavenge wind energy as light as a breeze.
Credit: Xin Chen, Xiaojing Mu, and Ya Yang

Most of the wind available on land is too gentle to push commercial wind turbine blades, but now researchers in China have designed a kind of “tiny wind turbine” that can scavenge wind energy from breezes as little as those created by a brisk walk. The method, presented today (September 23, 2020) in the journal Cell Reports Physical Science, is a low-cost and efficient way of collecting light breezes as a micro-energy source.

The new device is not technically a turbine. It is a nanogenerator made of two plastic strips in a tube that flutter or clap together when there is airflow. Like rubbing a balloon to your hair, the two plastics become electrically charged after being separated from contact, a phenomenon called the triboelectric effect. But instead of making your hair stand up like Einstein’s, the electricity generated by the two plastic strips is captured and stored.

The video shows the two plastic strips from the triboelectric nanogenerator flapping in sync for energy generation in slow motion.
Credit: Chen, Ma, and Ren et al./Cell Reports Physical Science

“You can collect all the breeze in your everyday life,” says senior author Ya Yang of Beijing Institute of Nanoenergy and Nanosystems, Chinese Academy of Sciences. “We once placed our nanogenerator on a person’s arm, and a swinging arm’s airflow was enough to generate power.”

A breeze as gentle as 1.6 m/s (3.6 mph) was enough to power the triboelectric nanogenerator designed by Yang and his colleagues. The nanogenerator performs at its best when wind velocity is between 4 to 8 m/s (8.9 to 17.9 mph), a speed that allows the two plastic strips to flutter in sync. The device also has a high wind-to-energy conversion efficiency of 3.23%, a value that exceeds previously reported performances on wind energy scavenging. Currently, the research team’s device can power up 100 LED lights and temperature sensors.

“Our intention isn’t to replace existing wind power generation technology. Our goal is to solve the issues that the traditional wind turbines can’t solve,” says Yang. “Unlike wind turbines that use coils and magnets, where the costs are fixed, we can pick and choose low-cost materials for our device. Our device can also be safely applied to nature reserves or cities because it doesn’t have the rotating structures.”

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