An electromagnetic wearable 3-DoF resonance human body motion energy harvester using ferrofluid as a lubricant

• Published in: Applied energy Vol. 197; pp. 364 - 374
• Main Authors: Wu, Shuai, Luk, P.C.K., Li, Chunfang, Zhao, Xiangyu, Jiao, Zongxia, Shang, Yaoxing
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 01.07.2017
• Subjects: Electromagnetic; Energy harvester; Ferrofluid; Generator; Wearable; Electromagnetic; Ferrofluid; Wearable; Energy harvester; Generator
• ISSN: 0306-2619; 1872-9118
• DOI: 10.1016/j.apenergy.2017.04.006

•A wearable kinetic energy harvester which has 3-DoF resonance is proposed.•Three different frequencies resonance absorb human motion energy more efficiently.•Ferrofluid is used to make the permanent magnetic vibrator ‘contactless’.•The ferrofluid improves 40% harvesting efficiency via the reduction of friction. Wearable energy harvester offers clean and continuous power for wearable sensors or devices, and plays an important role in a wide range of applications such as the health monitoring and motion track. In this study, we investigate a small electromagnetic resonance wearable kinetic energy harvester. It consists of a permanent magnet (PM) supported by two elastic strings within a rectangular box form a 3-degree-of-freedom (3-DoF) vibrator. Copper windings are attached to the outer surface of the box to generate electrical energy when the PM is forced to vibrate. To minimize any frictional losses, ferrofluid is used such that the poles of PM are cushioned by the ferrofluid, to the effect that the PM will not touch the inner of the box. Simulation results show that the ferrofluid can keep the PM ‘contactless’ from the box even subject to 10 times gravity acceleration. A prototype is built and tested under different loading conditions. Resistance load experimental results indicate the proposed harvester can generate 1.1mW in walking condition and 2.28mW in running condition. An energy storage circuit is employed and the energy storage experimental results show that the average storage power during walking and running conditions are 0.014mW and 0.149mW respectively. It is shown that the developed harvester can be readily attached on a shoe to offer continuous power supply for wearable sensors and devices.