The Current State of Silicone-Based Dielectric Elastomer Transducers

Madsen, Frederikke Bahrt; Daugaard, Anders Egede; Hvilsted, Søren; Skov, Anne Ladegaard

doi:10.1002/marc.201500576

Cited by 350 publications

(400 citation statements)

References 241 publications

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“…The indisputable need for materials improvement leads to many unconventional approaches for reaching a breakthrough in the development of dielectric elastomer actuators. [20] In our recent paper high-dielectric-constant liquids were suggested as fillers that are potentially capable of enhancing a material's dielectric constant. [21,22] It was reported that water (ε=80) incorporated and uniformly distributed within hydrophobic PDMS in the form of encapsulated discrete water droplets is capable of enhancing the dielectric constant of a given elastomer.…”

Section: Introductionmentioning

confidence: 99%

Glycerol as high‐permittivity liquid filler in dielectric silicone elastomers

Mazurek

Gerhard

et al. 2016

J of Applied Polymer Sci

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A recently reported novel class of elastomers was tested with respect to its dielectric properties.The new elastomer material is based on a commercially available polydimethylsiloxane (PDMS) composition, which has been modified by embedding glycerol droplets into its matrix. The approach has two major advantages that make the material useful in a dielectric actuator. First, the glycerol droplets efficiently enhance the dielectric constant which can reach astonishingly high values in the composite. Second, the liquid filler also acts as a softener that effectively decreases the elastic modulus of the composite. In combination with very low cost and easy preparation, the two property enhancements lead to an extremely attractive dielectric elastomer material. Experimental permittivity data are compared to various theoretical models that predict relative-permittivity changes as a function of filler loading, and the applicability of the models is discussed.

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Section: Introductionmentioning

confidence: 99%

Glycerol as high‐permittivity liquid filler in dielectric silicone elastomers

Mazurek

Gerhard

et al. 2016

J of Applied Polymer Sci

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“…We use dielectric elastomer actuators (DEAs) [6]- [8] for biomimetic underwater robots because they combine many appealing features. DEAs exhibit high compliance (∼1 MPa of elastic modulus), large actuation strokes (e.g., 85 % of linear strain [9]), fast response time (less than 200 µs [10]), and theoretically high electromechanical efficiency (max.…”

Section: Introductionmentioning

confidence: 99%

Biomimetic underwater robots based on dielectric elastomer actuators

Shintake

Shea

Floreano

2016

2016 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS)

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Abstract-Dielectric elastomer actuators (DEAs), a soft actuator technology, hold great promise for biomimetic underwater robots. The high-voltages required to drive DEAs can however make them challenging to use in water. This paper demonstrates a method to create DEA-based biomimetic swimming robots that operate reliably even in conductive liquids. We ensure the insulation of the high-voltage DEA electrodes without degrading actuation performance by laminating silicone layers. A fish and a jellyfish were fabricated and tested in water. The fish robot has a length of 120 mm and a mass of 3.8 g. The jellyfish robot has a 61 mm diameter for a mass of 2.6 g. The measured swimming speeds for a periodic 3 kV drive voltage were ∼8 mm/s for the fish robot, and ∼1.5 mm/s for the jellyfish robot.

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“…For example, over 400 million actuation cycles have been demonstrated for silicone-based DEAs [224], and their change in electromechanical properties for a time period of several months has been studied recently [225]. The suitability of PVDF and its most important copolymer PVDF-TrFE for low earth orbit applications has been demonstrated in [226], which consequently qualifies the material also for the use in microfluidic devices.…”

Section: Discussionmentioning

confidence: 99%

Stimulus-active polymer actuators for next-generation microfluidic devices

Hilber

2016

Appl. Phys. A

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Microfluidic devices have not yet evolved into commercial off-the-shelf products. Although highly integrated microfluidic structures, also known as lab-on-a-chip (LOC) and micrototal-analysis-system (lTAS) devices, have consistently been predicted to revolutionize biomedical assays and chemical synthesis, they have not entered the market as expected. Studies have identified a lack of standardization and integration as the main obstacles to commercial breakthrough. Soft microfluidics, the utilization of a broad spectrum of soft materials (i.e., polymers) for realization of microfluidic components, will make a significant contribution to the proclaimed growth of the LOC market. Recent advances in polymer science developing novel stimulus-active soft-matter materials may further increase the popularity and spreading of soft microfluidics. Stimulus-active polymers and composite materials change shape or exert mechanical force on surrounding fluids in response to electric, magnetic, light, thermal, or water/solvent stimuli. Specifically devised actuators based on these materials may have the potential to facilitate integration significantly and hence increase the operational advantage for the end-user while retaining costeffectiveness and ease of fabrication. This review gives an overview of available actuation concepts that are based on functional polymers and points out promising concepts and trends that may have the potential to promote the commercial success of microfluidics.

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The Current State of Silicone-Based Dielectric Elastomer Transducers

Cited by 350 publications

References 241 publications

Glycerol as high‐permittivity liquid filler in dielectric silicone elastomers

Glycerol as high‐permittivity liquid filler in dielectric silicone elastomers

Biomimetic underwater robots based on dielectric elastomer actuators

Stimulus-active polymer actuators for next-generation microfluidic devices

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