Energy harvesting from vibration using flexible floroethylenepropylene piezoelectret films with cross-tunnel structure

Wang, Yujie; Wu, Li‐Ming; Zhang, Xiaoqing

doi:10.1109/tdei.2015.7116321

Cited by 30 publications

(21 citation statements)

References 24 publications

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“…[7][8][9][10][11][12][13][14] Piezoelectrets are charged polymer foams exhibiting strong piezoelectric effects, small bulk density, flexibility or/and stretchability. 15,16 The quasistatic piezoelectric d 33 coefficients of piezoelectrets can be up to a few hundred pC/N in polypropylene (PP) films [17][18][19][20][21][22][23] and are of similar size or larger in some fluorocarbon polymer films, /ε 0 ε r (see also Sect.…”

Section: Introductionmentioning

confidence: 99%

“…Relevant studies show that energy harvesters based on normal cellular PP piezoelectrets or piezoelectrets made of layered fluoroethylenepropylene (FEP), excited in the {3-3} and stretching modes, can generate an output power of up to about 10 µW, referred to the acceleration g (in italics) due to gravity. [7][8][9]12 Our prior studies indicate that, compared with normal cellular PP, electron irradiated polypropylene (IXPP) not only results in piezoelectrets with improved thermal stability of d 33 and better mechanical properties, 28 but also yields enhanced stretchability after proper modifications of the microstructure. 21 Therefore, it is of interest to explore the capability of energy harvesting from vibration by using IXPP piezoelectret films.…”

Section: Introductionmentioning

confidence: 99%

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Energy harvesting from vibration with cross-linked polypropylene piezoelectrets

Zhang

Sessler

2015

AIP Advances

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Piezoelectret films are prepared by modification of the microstructure of polypropylene foam sheets cross-linked by electronic irradiation (IXPP), followed by proper corona charging. Young’s modulus, relative permittivity, and electromechanical coupling coefficient of the fabricated films, determined by dielectric resonance spectra, are about 0.7 MPa, 1.6, and 0.08, respectively. Dynamic piezoelectric d33 coefficients up to 650 pC/N at 200 Hz are achieved. The figure of merit (FOM, d33 ⋅ g33) for a more typical d33 value of 400 pC/N is about 11.2 GPa−1. Vibration-based energy harvesting with one-layer and two-layer stacks of these films is investigated at various frequencies and load resistances. At an optimum load resistance of 9 MΩ and a resonance frequency of 800 Hz, a maximum output power of 120 μW, referred to the acceleration g due to gravity, is obtained for an energy harvester consisting of a one-layer IXPP film with an area of 3.14 cm2 and a seismic mass of 33.7 g. The output power can be further improved by using two-layer stacks of IXPP films in electric series. IXPP energy harvesters could be used to energize low-power electronic devices, such as wireless sensors and LED lights.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Energy harvesting from vibration with cross-linked polypropylene piezoelectrets

Zhang

Sessler

2015

AIP Advances

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“…In the step of Fig. 1 Schematic and SEM image of two-layer laminated FEP film with crosstunnel structure [8,10] .…”

Section: Details Of Experimental Workmentioning

confidence: 99%

“…1(b). Thereafter, the FEP films are piezoelectric and thus called piezoelectrets [10] . The quasi-static d 33 coefficients of the FEP piezoelectret films were determined by measuring the charges induced upon applying a mechanical force to the sample surface.…”

Section: Details Of Experimental Workmentioning

confidence: 99%

Energy scavenging from vibration with two-layer laminated fluoroethylenepropylene piezoelectret films

Zhang

Sessler

2015

2015 Joint IEEE International Symposium on the Applications of Ferroelectric (ISAF), International Symposium on Integrated Func

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Fluoroethylenepropylene (FEP) piezoelectret films with a cross-tunnel structure were prepared using a templatebased process and contact charging. Energy harvesting from the fabricated FEP films was investigated in the {3-3} mode at various seismic masses, load resistances and exciting frequencies.The results show that the output power is dependent on the seismic mass, load resistance and vibration frequency. Around the optimum load resistance, a normalized output power of 73 μW at 130 Hz was obtained for an FEP piezolectret film with a seismic mass of 60 g and an area of 7.1 cm 2 . At a vibration frequency of 150 Hz, the output power from an FEP film sample with an excited area of 3.1 cm 2 and a seismic mass of 54 g, is high enough to light a blue color LED diode, showing such thin, light and flexible FEP piezoelectret films may be applied in environmental vibration energy harvesters for powering lowpower electronic devices.

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“…Studies have also investigated the use of piezoelectret foam in harvesting energy from the human body during walking (Luo et al, 2015) and from arterial forces and throat motion (Wu et al, 2015). While polypropylene is the most common piezoelectret material studied (Wegener and Bauer, 2005), Wang et al (2015) and Zhang et al (2014Zhang et al ( , 2015 have investigated a new class of piezoelectret material, cross-tunnel fluoroethylenepropylene (FEP), for energy harvesting and showed improved thermal stability compared to polypropylene.…”

Section: Introductionmentioning

confidence: 99%

Multilayer piezoelectret foam stack for vibration energy harvesting

Ray

Anton

2016

Journal of Intelligent Material Systems and Structures

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Electronic devices are high-demand commodities in today’s world, and such devices will continue increasing in popularity. Currently, batteries are implemented to provide power to these devices; however, the need for battery replacement, their cost, and the waste associated with battery disposal present a need for advances in self-powered technology. Energy harvesting technology has great potential to alleviate the drawbacks of batteries. In this work, a novel piezoelectret foam material is investigated for low-level vibration energy harvesting. Specifically, piezoelectret foam assembled in a multilayer stack configuration is explored. Modeling and experimentation of the stack when excited in compression at low frequencies are performed to investigate piezoelectret foam for multilayer energy harvesting. An equivalent circuit model derived from the literature is used to model the piezoelectret stack. Two 20-layer prototype devices and one 40-layer prototype device are fabricated and experimentally tested via harmonic base excitation. Electromechanical frequency response functions between input acceleration and output voltage are measured experimentally. Modeling results are compared to experimental measurements to assess the fidelity of the model near resonance. Finally, energy harvesting experimentation in which the device is subject to harmonic base excitation at the fundamental natural frequency is conducted to determine the ability of the stack to successfully charge a capacitor. For a 20-layer stack excited at 0.5 g, a 100-µF capacitor is charged to 1.45 V in 15 min, and produces a peak power of 0.45 µW. A 40-layer stack is found to charge a 100-µF capacitor to 1.7 V in 15 min when excited at 0.5 g, and produce a peak power of 0.89 µW.

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Energy harvesting from vibration using flexible floroethylenepropylene piezoelectret films with cross-tunnel structure

Cited by 30 publications

References 24 publications

Energy harvesting from vibration with cross-linked polypropylene piezoelectrets

Energy harvesting from vibration with cross-linked polypropylene piezoelectrets

Energy scavenging from vibration with two-layer laminated fluoroethylenepropylene piezoelectret films

Multilayer piezoelectret foam stack for vibration energy harvesting

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