Coil-levitated hybrid generator for mechanical energy harvesting and wireless temperature and vibration monitoring

Coil-levitated hybrid generator for mechanical energy harvesting and wireless temperature and vibration monitoring

The development of wireless monitoring is currently restricted by the short lifetime of batteries, requiring frequent replacement. Utilization of abundant mechanical energy from the surrounding environment has attracted increasing attention in real-time monitoring. Herein, a coil-levitated hybrid ge...

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Bibliographic Details
Published in:Science China. Technological sciences Vol. 64; no. 6; pp. 1325 - 1334
Main Authors: Xue, XiaoBin, Zhang, ZengXing, Wu, Bin, He, ShanShan, Wang, Qiang, Zhang, WenJun, Bi, RuiYu, Cui, Juan, Zheng, YongQiu, Xue, ChenYang
Format: Journal Article
Language:English
Published: Beijing Science China Press 01-06-2021
Springer Nature B.V
Subjects:
Battery chargers
Charging
Coils
Electromagnetic induction
Energy harvesting
Engineering
Lithium-ion batteries
Nanogenerators
Piezoelectricity
Rechargeable batteries
Vibration monitoring
coil levitation
wireless monitoring
hybrid generator
self-powered
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Summary:The development of wireless monitoring is currently restricted by the short lifetime of batteries, requiring frequent replacement. Utilization of abundant mechanical energy from the surrounding environment has attracted increasing attention in real-time monitoring. Herein, a coil-levitated hybrid generator was developed for the efficient harvesting of mechanical energy from mechanical motion. The novel coil-levitated structure adapted to the metal and magnetic environment. The output currents were systematically analyzed at different operation modes based on the unique combination of triboelectrification, electromagnetic induction, and piezoelectric effect. Under the excitation of vibration frequency and amplitude of 8 Hz and 5 mm respectively, the as-constructed triboelectric nanogenerator delivered a peak power density of 11.40 W/m 3 at 10 MΩ. Meanwhile, the middle electromagnetic part and bottom piezoelectric generator provided peak power densities of 6.97 and 79.93 W/m 2 at 10000 Ω, respectively. More importantly, the battery charging experiment was verified, in which a 30 mA h Li-ion battery can be charged from 2.57 to 3.27 V in about 90 min. In sum, a self-powered temperature and vibration monitoring system was successfully developed based on hybrid generator, promising for realizing wireless monitoring of mechanical equipment without any external power supply.
ISSN:1674-7321
1869-1900
DOI:10.1007/s11431-020-1755-4