Abstract:
Electromagnetic energy conversion, based on Faraday's law, can deliver a relatively large, continuous power to a low impedance load from a vibrating body. However, increa...Show MoreMetadata
Abstract:
Electromagnetic energy conversion, based on Faraday's law, can deliver a relatively large, continuous power to a low impedance load from a vibrating body. However, increasing the energy-conversion efficiency and keeping it high at a relatively large vibration amplitude have been difficult, and no miniature energy harvester has shown more than tens of milliwatt power level from submillimeter vibration amplitude. Here we provide a new energy-conversion technique to convert mechanical vibration into electrical energy with unprecedented power level of more than a quarter watt out of submillimeter vibration amplitude. The technique uses an array of alternating north- and south-orientation magnets to enhance magnetic flux change by more than an order of magnitude. A newly fabricated harvester occupying 51 \times 51 \times 10 mm ^{3} ( = 26 cc) and weighing 90 g generates an electromotive force (EMF) of {V}_{p-p}= 28.8 V with 263 mW power output (into 96- \Omega load) when it is vibrated at 65 Hz with vibration amplitude of 660 \mum. The power level is high enough to light an incandescent light bulb. Also, its microfabricated version occupying 20 \times 5 \times 0.9 mm ^{3} ( = 0.09 cc) and weighing 0.5 g generates an EMF of {V}_{p-p}= 30 mV with 2.6- \muW power output (into 10.8- \Omega load) when it is vibrated at 290 Hz with vibration amplitude of 11 \mum.
Published in: Proceedings of the IEEE ( Volume: 102, Issue: 11, November 2014)