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Bio-Inspired Soft Proboscis Actuator Driven by Dielectric Elastomer Fluid Transducers

In recent years, dielectric elastomer actuators (DEAs) have attracted lots of attention for providing multiple degree-of-freedom motions, such as axial extensions, torsion, bending, and their combinations. The wide applications include soft robots, artificial muscles, and biomimetic animals. In gene...

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Autores principales: Lin, Po-Wen, Liu, Chien-Hao
Formato: Online Artículo Texto
Lenguaje:English
Publicado: MDPI 2019
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6401884/
https://www.ncbi.nlm.nih.gov/pubmed/30960125
http://dx.doi.org/10.3390/polym11010142
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author Lin, Po-Wen
Liu, Chien-Hao
author_facet Lin, Po-Wen
Liu, Chien-Hao
author_sort Lin, Po-Wen
collection PubMed
description In recent years, dielectric elastomer actuators (DEAs) have attracted lots of attention for providing multiple degree-of-freedom motions, such as axial extensions, torsion, bending, and their combinations. The wide applications include soft robots, artificial muscles, and biomimetic animals. In general, DEAs are composed of stretchable elastomers sandwiched by two compliant electrodes and actuated by applying external electric stimuli. Since most DEAs are limited by the breakdown thresholds and low strain-to-volume ratios, dielectric fluid transducers (DFTs) have been developed by substituting dielectric elastomers with dielectric fluids for high breakdown threshold voltages. In addition, DFTs have large rate of lateral extensions, due to their fluid contents, and are beneficial for soft actuators and pumping applications. In this research, we exploited DFTs to develop a soft spiral proboscis actuator inspired by the proboscises of butterflies for achieving uncoiling and coiling motions under external voltages. The bio-inspired spiral proboscis actuator (BSPA) was composed of a coil-shaped tube, a DFT-based pouch, and a spiral spring for mimicking the tubular part, a mechanism to uncoil the tube, and a mechanism to coil the tube, respectively. When applying external voltages to the pouch, the high dielectric fluid was injected into the empty coiled tube for uncoiling where the tube elongated from a compact volume to a stiff and flexible shape. When removing the exciting voltages, the tube retracted to its original coiled shape via the elastic spring. A prototype was designed, fabricated, and examined with high stimulating voltages. It was demonstrated that the proboscis actuator could achieve uncoiling and coiling motions consistently for several cycles. Compared to convection DEA-based pumps with fixed shapes, the proposed actuator is soft and beneficial for portable applications and coiling/uncoiling motions.
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spelling pubmed-64018842019-04-02 Bio-Inspired Soft Proboscis Actuator Driven by Dielectric Elastomer Fluid Transducers Lin, Po-Wen Liu, Chien-Hao Polymers (Basel) Article In recent years, dielectric elastomer actuators (DEAs) have attracted lots of attention for providing multiple degree-of-freedom motions, such as axial extensions, torsion, bending, and their combinations. The wide applications include soft robots, artificial muscles, and biomimetic animals. In general, DEAs are composed of stretchable elastomers sandwiched by two compliant electrodes and actuated by applying external electric stimuli. Since most DEAs are limited by the breakdown thresholds and low strain-to-volume ratios, dielectric fluid transducers (DFTs) have been developed by substituting dielectric elastomers with dielectric fluids for high breakdown threshold voltages. In addition, DFTs have large rate of lateral extensions, due to their fluid contents, and are beneficial for soft actuators and pumping applications. In this research, we exploited DFTs to develop a soft spiral proboscis actuator inspired by the proboscises of butterflies for achieving uncoiling and coiling motions under external voltages. The bio-inspired spiral proboscis actuator (BSPA) was composed of a coil-shaped tube, a DFT-based pouch, and a spiral spring for mimicking the tubular part, a mechanism to uncoil the tube, and a mechanism to coil the tube, respectively. When applying external voltages to the pouch, the high dielectric fluid was injected into the empty coiled tube for uncoiling where the tube elongated from a compact volume to a stiff and flexible shape. When removing the exciting voltages, the tube retracted to its original coiled shape via the elastic spring. A prototype was designed, fabricated, and examined with high stimulating voltages. It was demonstrated that the proboscis actuator could achieve uncoiling and coiling motions consistently for several cycles. Compared to convection DEA-based pumps with fixed shapes, the proposed actuator is soft and beneficial for portable applications and coiling/uncoiling motions. MDPI 2019-01-15 /pmc/articles/PMC6401884/ /pubmed/30960125 http://dx.doi.org/10.3390/polym11010142 Text en © 2019 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (http://creativecommons.org/licenses/by/4.0/).
spellingShingle Article
Lin, Po-Wen
Liu, Chien-Hao
Bio-Inspired Soft Proboscis Actuator Driven by Dielectric Elastomer Fluid Transducers
title Bio-Inspired Soft Proboscis Actuator Driven by Dielectric Elastomer Fluid Transducers
title_full Bio-Inspired Soft Proboscis Actuator Driven by Dielectric Elastomer Fluid Transducers
title_fullStr Bio-Inspired Soft Proboscis Actuator Driven by Dielectric Elastomer Fluid Transducers
title_full_unstemmed Bio-Inspired Soft Proboscis Actuator Driven by Dielectric Elastomer Fluid Transducers
title_short Bio-Inspired Soft Proboscis Actuator Driven by Dielectric Elastomer Fluid Transducers
title_sort bio-inspired soft proboscis actuator driven by dielectric elastomer fluid transducers
topic Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6401884/
https://www.ncbi.nlm.nih.gov/pubmed/30960125
http://dx.doi.org/10.3390/polym11010142
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