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conferenceseries

.com

March 20-22, 2017 Orlando, USA

3

rd

International Conference on

Smart Materials & Structures

Volume 6, Issue 2 (Suppl)

J Material Sci Eng

ISSN: 2169-0022 JME, an open access journal

Smart Materials 2017

March 20-22, 2017

Investigation on electromechanical harvesting schemes to improve the performance of viscoelastic dielectric

elastomer generators

Liying Jiang, Jianyou Zhou

and

Roger Khayat

University of Western Ontario, Canada

A

s a category of electroactive polymers, dielectric elastomers (DEs) exhibit physical response to electrical stimuli and transduce

electrical energy to mechanical energy. On the other hand, when acting in a generator mode, they can also convert mechanical

energy from different sources, such as winds, ocean waves and human movement into electrical energy. Due to their flexibility and

high energy density, dielectric elastomer generators (DEGs) have recently attracted much attention from the research community. It

has been demonstrated in experiments that DEGs can achieve energy densities more than 10 times higher than those of piezoelectric

and electromagnetic generators. Although some DEGs have shown very promising results, their performance is in fact affected by

multiple failure modes and the material viscoelasticity. Particularly, the material viscoelasticity of the DE membrane embedded in

a DEG could cause high energy dissipation of the generator and exert a strong influence on the design of its harvesting scheme. To

uncover possible approaches to improve the performance of DEGs, this work presents a framework to comprehensively evaluate the

harvested energy and conversion efficiency of DEGs with the consideration of the finite-deformation viscoelasticity of the material.

Also, different possible energy harvesting schemes are explored in this work. From our simulation results, it is found that choosing a

suitable voltage level of the power supply (or a suitable bias voltage) could markedly raise both the harvested energy and conversion

efficiency of DEGs. The general framework and results in this work are expected to provide insight into optimizing the design of

dielectric elastomer generators.

Biography

Liying Jiang is an Associate Professor at the Department of Mechanical and Materials Engineering, University of Western Ontario, Canada. She has received her

PhD from the University of Alberta in 2005. Her research interests and activities cover a wide range of applied mechanics. Her expertise is theoretical and numerical

simulation to develop mechanics and physics models for challenging problems related to material’s behavior ranging from traditional composites to smart materials

and to nanostructured materials.

lyjiang@uwo.ca

Liying Jiang et al., J Material Sci Eng 2017, 6:2 (Suppl)

http://dx.doi.org/10.4172/2169-0022.C1.061