High Breakdown Field Dielectric Elastomer Actuators Using Encapsulated Polyaniline as High Dielectric Constant Filler

Jan-Anders Månson, Martin Molberg
Wiley-Blackwell, 2010
Article

A novel method allowing rapid production of reliable composites with increased dielectric constant and high dielectric strength for dielectric elastomer actuators (DEA) is reported. The promising approach using composites of conductive particles and insulating polymers generally suffers from low breakdown fields when applied to DEA devices. The present publication shows how to overcome this deficiency by using conductive polyaniline (PAN I) particles encapsulated into an insulating polymer shell prior to dispersion. PANI particles are encapsulated using miniemulsion polymerization (MP) of divinylbenzene (DVB). The encapsulation process is scaled up to approximately 20 g particles per batch. The resulting particles are used as high dielectric constant (e) fillers. Composites in a polydimethylsiloxane (PDMS) matrix are prepared and the resulting films characterized by dielectric spectroscopy and tensile tests, and evaluated in electromechanical actuators. The composite films show a more than threefold increase in epsilon', breakdown field strengths above 50 V mu m(-1), and increased strain at break. These novel materials allow tuning the actuation strain or stress output and have potential as materials for energy harvesting.

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Jan-Anders Månson, Martin Molberg
Wiley-Blackwell, 2010
Article

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https://infoscience.epfl.ch/record/172285?ln=fr

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Fracture toughness determination of high volume fraction particle reinforced aluminium matrix composites

Andreas Mortensen, Andreas Rossoll, Ludger Weber

The influence of particle size and particle type on the fracture toughness of aluminium matrix composites is investigated using model composites of 99.99% purity aluminium reinforced with particles of alumina and boron carbide. These composites are produced by gas pressure infiltration, and feature a volume fraction of reinforcement near 50 vol pet. The average particle size is varied between 5 and 35 mum. Fracture properties are determined using the single specimen J-integral test method. Observations of crack propagation mechanisms are conducted by optical microscopy using the arrested crack technique. Equivalent initiation fracture toughness values (K-JC) up to 24 MPa .m(1/2) for the toughest composites are measured, a comparatively high value for a material consisting of 50 vol pet ceramic. In both composites systems, it is found that the average particle size exerts a significant influence on fracture initiation and crack propagation resistance. Microscopical investigations of the mode of fracture show that cleavage of angular particles is present, and becomes increasingly dominant in alumina reinforced composites as the average particle size increases. For composites reinforced by rounded alumina or angular boron carbide particles, matrix voiding is dominant. Particle cracking results in a lower fracture initiation roughness, while increasing particle diameter results in increased crack initiation toughness and tearing modulus.

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Thermal conductivity of Al-SiC composites with monomodal and bimodal particle size distribution

Andreas Mortensen, Ludger Weber

The thermal conductivity of aluminum matrix composites having a high volume fraction of SiC particles is investigated by comparing data for composites fabricated by infiltrating liquid aluminum into preforms made either from a single particle size, or by mixing and packing SiC particles of two largely different average sizes (170 and 16 mu m). For composites based on powders with a monomodal size distribution, the thermal conductivity increases steadily from 151 W/m K for particles of average diameter 8 mu m to 216 W/m K for 170 mu m particles. For the bimodal particle mixtures the thermal conductivity increases with increasing volume fraction of coarse particles and reaches a roughly constant value of 220 W/m K for mixtures with 40 or more vol.% of coarse particles. It is shown that all present data can be accounted for by the differential effective medium (DEM) scheme taking into account a finite interfacial thermal resistance. (c) 2007 Elsevier B.V. All rights reserved.

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A simplified model is proposed to quantity the effect of damage in the form of particle cracking on the elastic and plastic behaviour of particle-reinforced metal matrix composites under uniaxial tensile loading: cracked particles are simply replaced, in a mean-field model, with as much matrix. Pure aluminium reinforced with 44 vol.%., alumina particles, tested in tension and unloaded at periodic plastic deformations, is analysed by neutron diffraction during each reloading elastic step, at 30%, 50%, 701% and 90% of the tensile flow stress. The data give the evolution of the elastic matrix strains in the composite and also measure the progress of internal damage by particle cracking. The test gives (i) the evolution of the in situ matrix flow stress, and (ii) the evolution of load partitioning during elastic deformation with increasing composite damage. Predictions of the present model compare favourably with relevant results in the literature, and with results from the present neutron diffraction experiments. (C) 2008 Acta Materialia Inc. Published by Elsevier Ltd. All rights reserved.

2008

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