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Dielectric breakdown strength of PDMS elastomers after mechanical cycling

Dielectric breakdown strength of PDMS elastomers after mechanical cycling
Dielectric breakdown strength of PDMS elastomers after mechanical cycling
PDMS-based composites such as silicone elastomers are commonly found in high-voltage engineering, especially in outdoor insulation as coatings or structural elements or at interfaces between network elements, such as cable sealing ends (CSE). They are also promising prospects for dielectric elastomer generators (DEG), which are retrieving electrostatic energy from large strain amplitudes. The upper limit of energy conversion from these transducers is determined by the dielectric breakdown strength (DBS). Therefore, developing reliable systems that operate under high electric fields and variable repeated strains requires a thorough understanding of the mechanisms behind electrical breakdown and its coupling to mechanical cycling. In this study, the effect of Mullins damage and mechanical fatigue on silicone elastomers has been investigated. An electro-mechanical instability model that considers cyclic softening allows for predicting the evolution of the breakdown strength depending on the loading history. The results highlight the importance of the “first cycle,” where up to a 30% reduction in the mean DBS was measured. However, subsequent mechanical fatigue only marginally contributes to the degradation, which is a promising perspective for the long-term performance of any silicone elastomer as long as the precise impact of the first cycle is known.
breakdown test, dielectric elastomer, electro-mechanical instability, low-cycle fatigue, Mullins effect, PDMS
1996-1073
Taine, Emmanuel
27a0e305-1b8d-4cb2-aa1c-726680149b2f
Andritsch, Thomas
8681e640-e584-424e-a1f1-0d8b713de01c
Saeedi, Istebreq A.
6df4dfcf-9bb8-4edc-952e-ccc4841f7b54
Morshuis, Peter H.F.
af303056-cf5a-4e71-8a85-4aacf69c9bb2
Taine, Emmanuel
27a0e305-1b8d-4cb2-aa1c-726680149b2f
Andritsch, Thomas
8681e640-e584-424e-a1f1-0d8b713de01c
Saeedi, Istebreq A.
6df4dfcf-9bb8-4edc-952e-ccc4841f7b54
Morshuis, Peter H.F.
af303056-cf5a-4e71-8a85-4aacf69c9bb2

Taine, Emmanuel, Andritsch, Thomas, Saeedi, Istebreq A. and Morshuis, Peter H.F. (2023) Dielectric breakdown strength of PDMS elastomers after mechanical cycling. Energies, 16 (21), [7424]. (doi:10.3390/en16217424).

Record type: Article

Abstract

PDMS-based composites such as silicone elastomers are commonly found in high-voltage engineering, especially in outdoor insulation as coatings or structural elements or at interfaces between network elements, such as cable sealing ends (CSE). They are also promising prospects for dielectric elastomer generators (DEG), which are retrieving electrostatic energy from large strain amplitudes. The upper limit of energy conversion from these transducers is determined by the dielectric breakdown strength (DBS). Therefore, developing reliable systems that operate under high electric fields and variable repeated strains requires a thorough understanding of the mechanisms behind electrical breakdown and its coupling to mechanical cycling. In this study, the effect of Mullins damage and mechanical fatigue on silicone elastomers has been investigated. An electro-mechanical instability model that considers cyclic softening allows for predicting the evolution of the breakdown strength depending on the loading history. The results highlight the importance of the “first cycle,” where up to a 30% reduction in the mean DBS was measured. However, subsequent mechanical fatigue only marginally contributes to the degradation, which is a promising perspective for the long-term performance of any silicone elastomer as long as the precise impact of the first cycle is known.

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Accepted/In Press date: 31 October 2023
e-pub ahead of print date: 3 November 2023
Published date: November 2023
Additional Information: Funding Information: This research was funded by SBM Offshore in the frame of the S3 Wave Energy Converter. Publisher Copyright: © 2023 by the authors.
Keywords: breakdown test, dielectric elastomer, electro-mechanical instability, low-cycle fatigue, Mullins effect, PDMS
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Identifiers

Local EPrints ID: 483670
URI: http://eprints.soton.ac.uk/id/eprint/483670
DOI: doi:10.3390/en16217424
ISSN: 1996-1073
PURE UUID: fcdd30ac-10ad-4543-b62f-8d9d97084070
ORCID for Thomas Andritsch: ORCID iD orcid.org/0000-0002-3462-022X
ORCID for Istebreq A. Saeedi: ORCID iD orcid.org/0000-0002-1254-748X

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Date deposited: 03 Nov 2023 17:48
Last modified: 18 Mar 2024 04:01

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Contributors

Author: Emmanuel Taine
Author: Thomas Andritsch ORCID iD
Author: Istebreq A. Saeedi ORCID iD
Author: Peter H.F. Morshuis

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