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Abstract

The electro-active performance of ionic polymer-metal composite has been widely reported to be related to the strain caused by the unbalance of local water content. In this paper, the anisotropic strain under electrode constraint in ionic polymer-metal composite during water uptake was investigated. A model was proposed to claim that existence of electrode would lead to anisotropic swelling in ionic polymer-metal composite, and the strain state was significantly affected by the electrode volume proportion as well as the elasticity ratio of the electrode and polymer. Based on Nafion-Pd ionic polymer-metal composite, experiments were carried out to measure the swelling strain during saturation process. Evaluation by the proposed model showed great agreement with the experimental observation, both of which gave the conclusion that, under the surface electrode constraint, strain in the thickness direction was much larger than that in plane directions. At last, based on a formerly-established multi-physical model, it was predicted that for ionic polymer-metal composite, the anisotropy of local swelling can lead to a 10%–15% decrease of the tip displacement.

Keywords

Ionic polymer-metal composites Young’s modulus anisotropy electrode morphology

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References

Krishen

. Space applications for ionic polymer-metal composite sensors, actuators, and artificial muscles. Acta Astronautica 2009; 64: 1160–1166.

Colozza A, Smith C, Shahinpoor M, et al. Solid state aircraft concept overview. Proceedings of the NASA/DoD Conference on Evolvable Hardware (EH’04), 24–26 June 2004, pp.318–324. New York: IEEE.

Sung-Weon

Il-Kwon

. A biomimetic jellyfish robot based on ionic polymer metal composite actuators. Smart Mater Struct 2009; 18: 085002–085002.

Hyung-Kun L, Nak-Jin C, Sunkyung J, et al. Application of ionic polymer-metal composites for auto-focusing compact camera modules. In: Proceedings of the SPIE: EAPAD, San Diego, California, USA, 09 March, 2008, paper no. 69271N. SPIE.

Banik MS. Electroactive polymer based artificial sphincters and artificial muscles patches, Patent US007566297, USA, 2009.

Nikhil DB, Anant VH, Charisse MY, et al. Systems and methods for detecting and treating an obstructive sleep apnea event. Patent WO2010033926, USA, 2010.

Nemat-Nasser

. Micromechanics of actuation of ionic polymer-metal composites. J Appl Phys 2002; 92: 2899–2915.

De Gennes

Okumura

Shahinpoor

. Mechanoelectric effects in ionic gels. Europhys Lett 2000; 50: 513–518.

Asaka

Oguro

. Bending of polyelectrolyte membrane platinum composites by electric stimuli Part II. Response kinetics. J Electroanal Chem 2000; 480: 186–198.

10.

Yamaue

Mukai

Asaka

. Electrostress Diffusion Coupling Model for Polyelectrolyte Gels. Macromolecules 2005; 38: 1349–1356.

11.

Enikov

Seo

. Analysis of water and proton fluxes in ion-exchange polymer-metal composite (IPMC) actuators subjected to large external potentials. Sensor Actuat A Phys 2005; 122: 264–272.

12.

Chang

Chen

Zhu

. Manufacturing process and electrode properties of palladium electroded ionic polymer-metal composite. Smart Mater Struct 2012; 21: 065018–065018.

13.

Murthy M, Proton conducting membrane fuel cells III. In: Proceedings of the international symposium, Pennington: Electrochemical Society, 2005, p.132.

14.

Chang L, Chen H, Zhu Z, et al. A structure model for ionic polymer-metal composite (IPMC). In: Proceedings of the SPIE: EAPAD, San Diego, California, USA, 12 March, 2012, paper no. 83402K. SPIE.

15.

Winter M. The periodic table on the web, http://www.webelements.com/ (2005, accessed 6 July).

16.

Weng

. Some elastic properties of reinforced solids, with special reference to isotropic ones containing spherical inclusions. Int J Eng Sci 1984; 22: 845–856.

17.

Jiang

Nemat-Nasser

. Micromechanical analysis of ionic clustering in Nafion perfluorinated membrane. Mech Mater 2000; 32: 303–314.

18.

Lee

Kim

. Design of IPMC actuator-driven valve-less micropump and its flow rate estimation at low Reynolds numbers. Smart Mater Struct 2006; 15: 1103–1109.

19.

Majsztrik PW. Mechanical and transport properties of nafion-for pem fuel cells; temperature and hydration effects. PhD thesis, Princeton University, USA, 2008.

20.

Zhao

Majsztrik

Benziger

. Diffusion and interfacial transport of water in Nafion. J Phys Chem C 2011; 115: 2717–2727.

21.

Zhu

Asaka

Chang

. Multiphysics of ionic polymer-metal composite actuator. J Appl Phys 2013; 114: 084902–084902.

22.

Zhu

Chen

Chang

. Dynamic model of ionic polymer-metal composites. Aip Adv 2011; 1: 040702–040702.

23.

Chang

Asaka

Zhu

. Effects of surface roughening on the mass transport and mechanical properties of ionic polymer-metal composite. J Appl Phys 2014; 115: 244901–244901.

Electromechanical performance of ionic polymer-metal composite under electrode constraint

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