Self-charging smartwatches and health trackers could be a step closer following the development of tiny mechanical devices powered by movement, a study suggests.
The new mechanisms – which are twice as powerful as similar existing devices – could offer an energy-efficient and sustainable alternative to batteries used in wearable technologies, researchers say.
PhD students in the School of Engineering have developed a technique to create versatile materials that generate electricity by harnessing energy produced by movement of the human body.
The method – devised by a team of three PhD students – creates so-called piezoelectric materials more quickly and efficiently than previous techniques, potentially making it easier to scale up production.
The team devised this new approach by tweaking the chemistry used in the production of ultrafine fibers of a material called PVDF, a versatile substance that generates electricity when pressure is applied to it.
By using a high-voltage power supply the researchers can make 3D sponge-like materials from the fibres, which are then cut into 1cm2 pieces, fitted with electrodes and wires, and encased in silicon.
Twice as powerful
Tests of the devices' power output show they can produce 40 microwatts of electricity per square centimetre – twice as much as the most powerful type of existing piezoelectric generator.
Further development of the structures could extend the life of – or even replace – conventional batteries in wearable technologies, helping to reduce electronic waste and energy consumption, researchers say.
The materials could also have applications in the next generation of smart textiles and be woven into products such as motion-sensing clothes and t-shirts that monitor breathing and heart rate.
"One step closer"
School of Engineering PhD student Francisco Diaz Sanchez, who led the research, said: