[en] A monolithic approach is proposed that provides simultaneous modelling and analysis of the harvester, which involves surface- coupled fluid-structure interaction, volume-coupled electro- mechanics and a controlling energy harvesting circuit for applica- tions in energy harvesting. A space-time finite element approximation is used for numerical solution of the weighted residual form of the governing equations of the flow-driven piezoelectric energy harvesting device. This method enables time-domain investigation of different types of structures (plate, shells) subject to exterior/interior flow with varying cross sections, material compositions, and attached electrical circuits with respect to the electrical power output generated.
Disciplines :
Engineering, computing & technology: Multidisciplinary, general & others
Author, co-author :
Zilian, Andreas ; University of Luxembourg > Faculty of Science, Technology and Communication (FSTC) > Engineering Research Unit
Ravi, Srivathsan ; University of Luxembourg > Faculty of Science, Technology and Communication (FSTC) > Engineering Research Unit
External co-authors :
no
Language :
English
Title :
Strongly-coupled modelling and analysis of energy harvesting devices
Publication date :
2016
Journal title :
Applied Mathematics and Mechanics
ISSN :
0032-8235
Publisher :
U.S. Dept. of Commerce, Office of Technical Services
Volume :
16
Pages :
505-506
Peer reviewed :
Peer reviewed
Focus Area :
Computational Sciences
European Projects :
FP7 - 322151 - FSI-HARVEST - Numerical modelling of smart energy harvesting devices driven by flow-induced vibrations
FnR Project :
FNR3996097 - Numerical Modelling Of Smart Energy Harvesting Devices Driven By Flow-induced Vibrations, 2012 (01/02/2013-31/01/2017) - Srivathsan Ravi