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Processing line for stacked DE-actuator modules

Poster presented at EuroEAP 2016, International Conference on Electromechanically Active Polymer (EAP) transducers & artificial muscles, Helsingor (Copenhagen), 14-15 June 2016
: Wegener, Michael; Biedermann, Miriam; Seidel, Sven-Oliver; Krüger, Hartmut

Poster urn:nbn:de:0011-n-4351481 (462 KByte PDF)
MD5 Fingerprint: 641977c00bc58225f05c343eda8fcfc8
Created on: 16.2.2017

2016, 1 Folie
International Conference on Electromechanically Active Polymer (EAP) Transducers & Artificial Muscles (EuroEAP) <2016, Helsingor>
Bundesministerium für Bildung und Forschung BMBF
03ZZ1004A; SmartProcesses
Poster, Electronic Publication
Fraunhofer IAP ()

Dielectric elastomer actuators (DEAs) are widely studied due to their extraordinary properties. Research and development on DEAs is conducted in order to generate and optimize the elastomeric materials, flexible electrodes, preparation processes of films and layers as well as to build up film, roll and stacked actuators. A broad variety of applications is developed for different kind of actuators. Recently, huge developments were performed in stacked actuators. Such actuators consist of several tens or hundreds of single elastomer layers with flexible electrodes which are processed or aligned on top of each other. Actuator modules with heights of e. g. some millimeters to centimeters are fabricated which provide a deflection in transversal direction in the range of some hundred micrometers to e. g. some millimeters. Here, we present the manufacturing of stacked actuator modules which is performed in a semi-automatic processing line. The elastomeric layers are processed from the liquid phase by doctor-blading which allows the deposition of a homogeneous layer on a substrate with the size of 20 cm x 20 cm. In the next step the elastomer is cured by thermal or UV treatment. Carbon-particle electrodes are deposited by an air-brush technique. This procedure is repeated in order to process stacked actuator modules with e. g. 10 layers which can be combined to larger stacked actuators. Finally, stacked actuators were characterized regarding their geometrical and electrical properties.