Battery-free ‘smart’ toys move closer to commercial reality
Rubber duckies could soon be at the forefront of an electronic revolution. In ACS Sustainable Chemistry & Engineering, scientists report they have used specialized nanogenerators that gather energy from mechanical vibrations to transform squeaky bathtub companions and other conventional children’s toys into ‘smart’ electronics. They say the finding could have broad commercial applications, leading to the development of battery-free, self-powered toys, medical sensors and other devices.
Watch a video of prototype toys: www.youtube.com/watch?v=zL2LR-iqE5Y
By age 4, virtually every child has had contact with an electronic toy or mobile device, according to the American Academy of Pediatrics. Keeping these devices blinking and beeping is tedious, often requiring frequent charging or battery changes. Researchers have explored alternative ways to produce and store energy for these devices without using batteries. One promising approach involves the use of triboelectric nanogenerators, or TENGs. TENGs gather electrical charges from friction, similar to the static that builds up on a balloon when it is rubbed against someone’s head. TENGs amplify and convert this biomechanical energy into a usable form. However, ramping up these devices for commercial applications has been challenging, possibly because of low energy storage and conversion efficiencies. To address some of these issues, Sang-Jae Kim and colleagues at Jeju National University in South Korea sought to more effectively harness the energy from TENGs and use it to transform traditional toys into commercially viable, self-powered ‘smart’ toys.
The researchers designed and incorporated TENGs — made with aluminum electrodes and an eco-friendly silicone-like film between them — into rubber ducks and clapping toys. Squeezing or shaking the toys alternatively separated and brought the electrodes into contact with film, creating an electrical charge. Once activated, the TENGs harvested enough biomechanical energy to illuminate several LED lights attached to each toy. The TENGs were durable, suggesting they could operate for substantial periods. The researchers conclude their unique approach can transform traditional toys into battery-free interactive ones, and raises the prospect of successfully using TENGs commercially in other “smart” gadgets including medical devices and wearable electronics.
The authors acknowledge funding from the Basic Science Research Program through the National Research Foundation of Korea.
Materials provided by American Chemical Society. Note: Content may be edited for style and length.