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2019 | OriginalPaper | Buchkapitel

14. Dielectric Elastomers

verfasst von : Seiki Chiba

Erschienen in: Soft Actuators

Verlag: Springer Singapore

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Abstract

Electroactive polymer (EAP) is a new actuation technology with exceptional performance. An especially attractive type of electroactive polymer is dielectric elastomer (DE).

DE, based on the field-induced deformation of elastomeric polymers with compliant electrodes, can produce a large strain response, a fast response time, and high electromechanical efficiency. This unique performance, combined with other factors such as low cost, suggests many potential applications, a wide range of which are under investigation. Applications that effectively exploit the properties of DEs include artificial muscle actuators for robots (especially mobile and biomimetic robots on land, sea, and air); low-cost, lightweight linear actuators; inchworms, micro light scanners, and microfluidics, solid-state optical devices; diaphragm actuators for pumps, displays, and smart skins; acoustic actuators; and rotary motors. Dielectric elastomers may also be used to generate electrical power from mechanical deformation.

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Vorheriges Kapitel Dielectric Gels

Nächstes Kapitel Piezoelectric Polymers

Pelrine R, Chiba S (1992) Review of artificial muscle approaches. In: Proceedings of third international symposium on micromachine and human science, Nagoya, Japan

Pelrine R, Kornbluh R, Chiba S et al (1999) High-field deformation of elastomeric dielectrics for actuators. In: Proceedings 6th SPIE symposium on smart structure and materials, vol 3669, pp 149–161

Oguro K., Fujiwara N, Asaka K, Onishi K, Sewa S (1999) Polymer electrolyte actuator with gold electrodes. In: Proceedings of the SPIE’s 6th annual international symposium on smart structures and materials, SPIE of proceedings, vol 3669, pp 64–71

Otero TF, Sansiñena JM (1998) Soft and wet conducting polymers for artificial muscles. Adv Mater 10(6):491–494CrossRef

Osada Y, Okuzaki H, Hori H (1992) A polymer gel with electrically driven motility. Nature 355:242–244CrossRef

Tomori H et al (2011) Theoretical comparison of McKibben-type artificial muscle and novel straight-fiber-type artificial muscle. Int J Autom Technol 5(4):544CrossRef

Chiba S (2010) Application development of artificial muscle actuators. Electron Mater 49(7):34–41

Kornbluh R, Pelrine R, Chiba S (2004) Silicon to silicon: stretching the capabilities of micromachines with electroactive polymers. IEEJ Trans SM 124(8):266–271CrossRef

Chiba S, Waki M, Kormbluh R, Pelrine R (2008) Innovative power generators for energy harvesting using electroactive polymer artificial muscles. In Bar-Cohen Y (ed) Electroactive polymer actuators and devices (EAPAD) 2008, Proceedings of SPIE, vol 6927, 692715 (1–9)

10.

Chiba S, Stanford S, Pelrine R, Kornbluh R, Prahlad H (2006) Electroactive polymer artificial muscle. JRSJ 24(4):38–42CrossRef

11.

Chiba S et al (2016) Elastomer transducers. In: Advances in science and technology. Trans Tech Publication, Switzerland, vol 97, pp 61–74. https://doi.org/10.4028/wwwscienctific.net/AST.97.61. ISSN: 1662-0356

12.

Chiba S (2002) MEMS and NEMS applications of dielecric elastomer and future trends. Electron Packag Technol 18(1):32–38

13.

Chiba S (2017) Chapter 1: Dielectric elastomer actuators. In: Development of soft actuators and application, control technology for practical application, CMC Press, Japan, pp 9–21

14.

Kornbluh R, Bashkin J, Pelrine R, Prahlad H, Chiba S (2004) Medical applications of new electroactive polymer artificial muscles. Seikei-Kakou 16(10):631–637

15.

Chiba S (2014) Chapter 13: Dielectric elastomers. In: Soft actuators, Springer, Japan

16.

Zhou J, Jiang L, Khayat R (2016) Dynamic analysis of a tunable viscoelastic dielectric elastomer oscillator under external excitation. Smart Mater Struct 25(2):025005CrossRef

17.

Ashida K, Ichiki M, Tanaka M, Kitahara T (2000) Power generation using piezo element: energy conversion efficiency of piezo element. In: Proceedings of JAME annual meeting, pp 139–40

18.

Zurkinden A, Campanile F, Martinelli L (2007) Wave energy converter through piezoelectric polymers. In: Proceedings COMSOL user conference 2007, Grenoble, France

19.

Jean-Mistral C, Basrour S, Chaillout J (2010) Comparison of electroactive polymer for energy scavenging applications. Smart Mater Struct 19(19):085012CrossRef

20.

Chiba S, Waki M, Wada T, Hirakawa Y, Masuda K, Ikoma T (2013) Consistent Ocean wave energy harvesting using electroactive polymer (dielectric elastomer) artificial muscle generators. Appl Energy 104:497–502. ISSN 0306-2619CrossRef

21.

Waki M, Chiba S, Song Z, Ohyama K, Shijie Z (2017) Experimental investigation on the power generation performance of dielectric elastomer water power generation mounted on a square type floating body. J Mater Sci Eng B 7(9–10):179–186. https://doi.org/10.17265/2161-6221/2017.9-10.001CrossRef

22.

Chiba S, Hasegawa K, Waki M, Kurita S (2017) Experimental study on the motion of floating bodies arranged in series for wave power generation. J Mater Sci Eng A 7(11–12):281–289. https://doi.org/10.17265/2161-6213/2017.11-12.001CrossRef

23.

Chiba S et al (2007) Extending applications of dielectric elastomer artificial muscle. In: Proceedings of SPIE, San Diego, March 18–22

24.

Chiba S, Pelrine R, Kornbluh R, Prahlad H, Stanford S, Eckerle J (2007) New opportunities in electric power generation using electroactive polymers (EPAM). J Jpn Inst Energy 86(9):743–737CrossRef

25.

Chiba S, Hasegawa K, Waki M, Fujita K, Ohyama K, Shijie Z (2017) Innovative elastomer transducer driven by karman vortices in water flow. J Mater Sci Eng A 7(5–6):121–135. https://doi.org/10.17265/2161-6213/2017.5-6.002CrossRef

26.

Chiba S, Kornbluh R, Pelrine R, Waki M (2008) Low-cost hydrogen production from electroactive polymer artificial muscle wave power generators. In: Proceedings of world hydrogen energy conference 2008, Brisbane, Australia, June 16–20, 2008

27.

Chiba S et al (2007) Electroactive polymer artificial muscles. Eco design 2007, Japan, 2007–12

28.

Chiba S, Waki M, Fujita K, Masuda K, Ikoma T (2017) Simple and robust direct drive water power generation system using dielectric elastomers. J Mater Sci Eng B7(1–2):39–47. https://doi.org/10.17265/2161-6213/2017.1-2.005CrossRef

Titel: Dielectric Elastomers
verfasst von: Seiki Chiba
Verlag: Springer Singapore
Buch: Soft Actuators
Print ISBN: 978-981-13-6849-3

Electronic ISBN: 978-981-13-6850-9

Copyright-Jahr: 2019
DOI: https://doi.org/10.1007/978-981-13-6850-9_14

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