The investigation of the energy harvesting performance using electrospun PTFE/PVDF based on a triboelectric assembly
The investigation of the energy harvesting performance using electrospun PTFE/PVDF based on a triboelectric assembly
This work presents an investigation into the energy harvesting performance of a combination of polytetrafluoroethylene (PTFE) and polyvinylidene fluoride (PVDF) materials prepared using a one-step electrospinning technique. Before electrospinning, different percentages of the 1 micron PTFE powder were added to a PVDF precursor. The surface morphology of the electrospun PTFE/PVDF fibre was investigated using a scanning electron microscope and tunnelling electron microscope. The structure was investigated using Fourier-transform infrared spectroscopy and x-ray diffraction analysis (XRD). A highly porous structure was observed with a mix of the α- and β-phase PVDF. The amount of β-phase was found to reduce when increasing the percentage of PTFE. The maximum amount of PTFE that could be added and still be successfully electrospun was 20%. This percentage showed the highest energy harvesting performance of the different PTFE/PVDF combinations. Electrospun fibres with different percentages of PTFE were deployed in a triboelectric energy harvester operating in the contact separation mode and the open circuit voltage and short circuit current were obtained at frequencies of 4–9 Hz. The 20% PTFE fibre showed 4 (51–202 V) and 7 times (1.3–9.04 µA) the voltage and current output respectively when compared with the 100% PVDF fibre. The Voc and Isc were measured for different load resistances from 1 kΩ to 6 GΩ and achieved a maximum power density of 348.5 mW m−2 with a 10 MΩ resistance. The energy stored in capacitors 0.1, 0.47, 1, and 10 µF from a book shaped PTFE/PVDF energy harvester were 1.0, 16.7, 41.2 and 136.8 µJ, respectively. The electrospun fibre is compatible with wearable and e-textile applications as it is breathable and flexible. The electrospun PTFE/PVDF was assembled into shoe insoles to demonstrate energy harvesting performance in a practical application.
White, Pattarinee
ef6aec5f-d14a-469b-bd91-51156aad9c0c
Pankaew, Piyapong
53d6495d-dddb-4b82-a9db-43ad67193fc5
Bavykin, Dmitry
1e9fabfc-d078-4585-876f-85ff33b7eed5
Moshrefi-Torbati, M.
65b351dc-7c2e-4a9a-83a4-df797973913b
Beeby, Stephen
ba565001-2812-4300-89f1-fe5a437ecb0d
6 June 2024
White, Pattarinee
ef6aec5f-d14a-469b-bd91-51156aad9c0c
Pankaew, Piyapong
53d6495d-dddb-4b82-a9db-43ad67193fc5
Bavykin, Dmitry
1e9fabfc-d078-4585-876f-85ff33b7eed5
Moshrefi-Torbati, M.
65b351dc-7c2e-4a9a-83a4-df797973913b
Beeby, Stephen
ba565001-2812-4300-89f1-fe5a437ecb0d
White, Pattarinee, Pankaew, Piyapong, Bavykin, Dmitry, Moshrefi-Torbati, M. and Beeby, Stephen
(2024)
The investigation of the energy harvesting performance using electrospun PTFE/PVDF based on a triboelectric assembly.
Smart Materials and Structures, 33 (7), [075010].
(doi:10.1088/1361-665X/ad508d).
Abstract
This work presents an investigation into the energy harvesting performance of a combination of polytetrafluoroethylene (PTFE) and polyvinylidene fluoride (PVDF) materials prepared using a one-step electrospinning technique. Before electrospinning, different percentages of the 1 micron PTFE powder were added to a PVDF precursor. The surface morphology of the electrospun PTFE/PVDF fibre was investigated using a scanning electron microscope and tunnelling electron microscope. The structure was investigated using Fourier-transform infrared spectroscopy and x-ray diffraction analysis (XRD). A highly porous structure was observed with a mix of the α- and β-phase PVDF. The amount of β-phase was found to reduce when increasing the percentage of PTFE. The maximum amount of PTFE that could be added and still be successfully electrospun was 20%. This percentage showed the highest energy harvesting performance of the different PTFE/PVDF combinations. Electrospun fibres with different percentages of PTFE were deployed in a triboelectric energy harvester operating in the contact separation mode and the open circuit voltage and short circuit current were obtained at frequencies of 4–9 Hz. The 20% PTFE fibre showed 4 (51–202 V) and 7 times (1.3–9.04 µA) the voltage and current output respectively when compared with the 100% PVDF fibre. The Voc and Isc were measured for different load resistances from 1 kΩ to 6 GΩ and achieved a maximum power density of 348.5 mW m−2 with a 10 MΩ resistance. The energy stored in capacitors 0.1, 0.47, 1, and 10 µF from a book shaped PTFE/PVDF energy harvester were 1.0, 16.7, 41.2 and 136.8 µJ, respectively. The electrospun fibre is compatible with wearable and e-textile applications as it is breathable and flexible. The electrospun PTFE/PVDF was assembled into shoe insoles to demonstrate energy harvesting performance in a practical application.
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White_2024_Smart_Mater._Struct._33_075010
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Accepted/In Press date: 24 May 2024
Published date: 6 June 2024
Identifiers
Local EPrints ID: 501727
URI: http://eprints.soton.ac.uk/id/eprint/501727
ISSN: 0964-1726
PURE UUID: f6c59592-86b0-4325-82a9-037beb73eb5e
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Date deposited: 09 Jun 2025 17:25
Last modified: 22 Aug 2025 02:26
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Author:
Pattarinee White
Author:
Piyapong Pankaew
Author:
Stephen Beeby
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