Development of mono-component and tri-component fibres 100% polymer based piezoelectric PVDF to harvest energy

A first study focused on the realization of a 100% Polyvinylidene fluoride woven fabric. The multi-filaments produced by melt spinning and studied by FTIR, X-Ray and DSC, were optimized in the β-phase, 97%, thanks drawing ratio of λ=5, and the processing temperature, 90°C. When the polar β-phase ach...

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Bibliographic Details
Published inIOP conference series. Materials Science and Engineering Vol. 254; no. 7; pp. 72026 - 72031
Main Authors Talbourdet, A, Rault, F, Cayla, A, Cochrane, C, Devaux, E, Gonthier, A, Lemort, G, Campagne, C
Format Journal Article
LanguageEnglish
Published Bristol IOP Publishing 01.10.2017
Subjects
Beta phase
Conducting polymers
Electric potential
Energy harvesting
Filaments
Melt spinning
Piezoelectricity
Polyvinylidene fluorides
Voltage
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Summary:A first study focused on the realization of a 100% Polyvinylidene fluoride woven fabric. The multi-filaments produced by melt spinning and studied by FTIR, X-Ray and DSC, were optimized in the β-phase, 97%, thanks drawing ratio of λ=5, and the processing temperature, 90°C. When the polar β-phase achieves a certain level in PVDF, the woven material is poling with fields up to about 6kV. DMA tests coupled to a Keithley voltmeter allow the solicitation of PVDF fabrics. A variation of voltage is obtained in compression, with a maximum output voltage of up to 2,3V. The other part of the study explains premises of a tricomponent fibre development, PEHD/PVDF/PA12. Two layers of conductive polymers acting as electrodes are placed on either side of the PVDF layer. The interfacial adhesion between the three different layers is analysed by SEM. The maximum stretch on melt spinning was fixed at 2.5 and the β-phase of the PVDF measured by X-Ray.
ISSN:1757-8981
1757-899X
DOI:10.1088/1757-899X/254/7/072026