A novel high-power density, low-frequency electromagnetic vibration energy harvester based on anti-phase motion

[Display omitted] •A novel harvester that achieves anti-phase vibration at any frequency.•Achieved a power output and power density of 417.8 mW and 765.3 Wm−3 in experiment.•Experiment results are comparable or better than recent published works.•A 1.0% decrease in friction can increase the power ou...

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Bibliographic Details
Published in:Energy conversion and management 2021-06, Vol.238, p.114175, Article 114175
Main Authors: Foong, Faruq Muhammad, Thein, Chung Ket, Yurchenko, Daniil
Format: Article
Language:English
Subjects:
Anti-phase vibration
Coils
Coulomb friction
Damping
Design optimization
Electromagnetic vibration energy harvesting
Energy
Energy harvesting
Load resistance
Maximum power
Mechanical arms
Mechanical properties
Power density
Resonant frequencies
Vibration
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Summary:[Display omitted] •A novel harvester that achieves anti-phase vibration at any frequency.•Achieved a power output and power density of 417.8 mW and 765.3 Wm−3 in experiment.•Experiment results are comparable or better than recent published works.•A 1.0% decrease in friction can increase the power output by 98.7 mW.•A theoretical power density of 1708.5 Wm−3 can be achieved after optimisation. The paper proposes a novel electromagnetic vibration energy harvester based on the concept of anti-phase vibration. Anti-phase motion is desirable in electromagnetic vibration energy harvesting applications as it results in a higher power output due to the increase in the relative velocity between the coil and the magnet components. The proposed device achieves anti-phase motion at any driving frequency due to a developed new design. The harvester was experimentally tested under a base input of 0.49 g, 0.38 g and 0.36 g, recording a power density of 765.3 Wm−3, 420.8 Wm−3 and 587.2 Wm−3 respectively under a resonant frequency of 11.8 Hz. Although the device has not yet been optimised, these values obtained are already comparable, if not higher than the recent previous works on vibration energy harvesting. In addition, the observed experimental results have well agreed with the results obtained through the mathematical model, derived in this study. The original design was then optimised to determine the optimum load resistance, mechanical arm length and component dimensions that would result in the maximum power output. Considering a base input of 0.36 g and the same friction and damping forces as obtained from the experiment, a power density of 1708.5 Wm−3 could theoretically be achieved under the same natural frequency.
ISSN:0196-8904
1879-2227
DOI:10.1016/j.enconman.2021.114175