A variable-capacitance vibration-to-electric energy harvester

The work presented here investigates a unique design platform for multi-stable energy harvesting using only interaction between magnets. A solid cylindrical magnet is levitated between two stationary magnets. Peripheral magnets are positioned around the casing of the energy harvester to create multiple stable positions. Upon external vibration, kinetic energy is converted into electric energy that is extracted using a coil wrapped around the casing of the harvester. A prototype of the multi-stable energy harvester is fabricated. Monostable and bistable configurations are demonstrated and fully characterized in static and dynamic modes. Compared to traditional multi-stable designs the harvester introduced in this work is compact, occupies less volume, and does not require complex circuitry normally needed for multi-stable harvesters involving piezoelectric elements. At 2.5g [m/s2], results from experiment show that the bistable harvester does not outperform the monostable harvester. At this level of acceleration, the bistable harvester exhibits intrawell motion away from jump frequency. Chaotic motion is observed in the bistable harvester when excited close to jump frequency. Interwell motion that yields high displacement amplitudes and velocities is absent at this acceleration.

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C8.1 - Thermo-Electric Energy Harvester for Low-Power Sanitary Applications

10.5162/sensor2013/c8.1 ◽

2013 ◽

Author(s):

C. Beisteiner ◽

B. G. Zagar

Keyword(s):

Low Power ◽

Energy Harvester ◽

Electric Energy ◽

Thermo Electric

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Electric energy harvester for microbial fuel cells

Optics and Precision Engineering ◽

10.3788/ope.20132107.1707 ◽

2013 ◽

Vol 21 (7) ◽

pp. 1707-1712 ◽

Cited By ~ 1

Author(s):

莫冰 MO Bing ◽

黄荣海 HUANG Rong-hai ◽

赵峰 ZHAO Feng ◽

凌朝东 LING Chao-dong

Keyword(s):

Fuel Cells ◽

Microbial Fuel Cells ◽

Energy Harvester ◽

Electric Energy

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An Analysis Model Combining Gamma-Type Stirling Engine and Power Converter

Energies ◽

10.3390/en12071322 ◽

2019 ◽

Vol 12 (7) ◽

pp. 1322 ◽

Cited By ~ 1

Author(s):

Hua-Ju Shih

Keyword(s):

Low Temperature ◽

Bias Voltage ◽

Temperature Difference ◽

Energy Harvester ◽

Waste Heat ◽

Power Converter ◽

Stirling Engine ◽

Living Environment ◽

Analysis Model ◽

Variable Capacitance

Waste heat is a potential source for powering our living environment. It can be harvested and transformed into electricity. Ohmic heat is a common type of waste heat. However, waste heat has the following limitations: wide distribution, insufficient temperature difference (ΔT < 70 K) for triggering turbines, and producing voltage below the open voltage of the battery. This paper proposes an energy harvester model that combines a gamma-type Stirling engine and variable capacitance. The energy harvester model is different from Tavakolpour-Saleh’s free-piston-type engine [7.1 W at ΔT = 407 K (273–680 K)]. The gamma-type Stirling engine is a low-temperature-difference engine. It can be triggered by a minimum ΔT value of 12 K (293–305 K). The triggering force in the variable capacitance is almost zero. Furthermore, the gamma-type Stirling engine is suitable for harvesting waste heat at room temperature. This study indicates that 21 mW of energy can be produced at ΔT = 30 K (293–323 K) for a bias voltage of 70 V and volume of 103.25 cc. Because of the given bias voltage, the energy harvester can break through the open voltage of the battery to achieve energy storage at a low temperature difference.

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Wearable Device Oriented Flexible and Stretchable Energy Harvester Based on Embedded Liquid-Metal Electrodes and FEP Electret Film

Sensors ◽

10.3390/s20020458 ◽

2020 ◽

Vol 20 (2) ◽

pp. 458

Author(s):

Jianbing Xie ◽

Yiwei Wang ◽

Rong Dong ◽

Kai Tao

Keyword(s):

Liquid Metal ◽

Energy Harvester ◽

Open Circuit Voltage ◽

Electric Energy ◽

Open Circuit ◽

Metal Electrodes ◽

Conductive Film ◽

Stretchable Electrode ◽

Liquid Metal Alloy ◽

Elbow Motion

In this paper, a flexible and stretchable energy harvester based on liquid-metal and fluorinated ethylene propylene (FEP) electret films is proposed and implemented for the application of wearable devices. A gallium liquid-metal alloy with a melting point of 25.0 °C is used to form the stretchable electrode; therefore, the inducted energy harvester will have excellent flexibility and stretchability. The solid-state electrode is wrapped in a dragon-skin silicone rubber shell and then bonded with FEP electret film and conductive film to form a flexible and stretchable energy harvester. Then, the open-circuit voltage of the designed energy harvester is tested and analyzed. Finally, the fabricated energy harvester is mounted on the elbow of a human body to harvest the energy produced by the bending of the elbow. The experimental results show that the flexible and stretchable energy harvester can adapt well to elbow bending and convert elbow motion into electric energy to light the LED in a wearable watch.

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Analysis of the Wrist-Wearable Energy Harvester With Vibrating Piezoelectric Multiple Bimorph Cantilevers Using FEM and Topology Optimization

Volume 2: Mechanics and Behavior of Active Materials; Integrated System Design and Implementation; Bioinspired Smart Materials and Systems; Energy Harvesting ◽

10.1115/smasis2014-7663 ◽

2014 ◽

Author(s):

Cheol Kim ◽

Young-Geun Song

Keyword(s):

Topology Optimization ◽

Energy Harvester ◽

Piezoelectric Materials ◽

Electric Energy ◽

Optimization Method ◽

Optimum Shape ◽

Element Analysis ◽

Piezoelectric Layers ◽

Tungsten Tip ◽

Tip Mass

A small wrist-watch-like wearable electric energy harvester which can extract electricity from swinging motions of people’s arms while walking has been developed newly. The harvester consists of multiple vibrating piezoelectric cantilevered thin beams attached to a round central hub structure radially with tip masses. The cantilevers are made of a polycarbonate substrate beam, PMN-PT piezoelectric material on its both sides, and a high density tungsten tip mass. The swinging of a human arm with the harvester causes the bending deformations in each blade while walking and then produces electricity from strains in two piezoelectric layers. The swinging motion was formulated mathematically and kinematically in terms of swinging angles, angular velocities and accelerations. Finite element analysis was used to model the cantilevered beams and calculate the voltage output. The optimum shape of piezoelectric layers were calculated on the basis of the topology optimization method specialized for piezoelectric materials.

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