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(Reference retrieved automatically from Web of Science through information on FAPESP grant and its corresponding number as mentioned in the publication by the authors.)

Optimal design of laminated piezocomposite energy harvesting devices considering stress constraints

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Author(s):
Kiyono, C. Y. [1] ; Silva, E. C. N. [1] ; Reddy, J. N. [2]
Total Authors: 3
Affiliation:
[1] Univ Sao Paulo, Escola Politecn, Dept Mechatron & Mech Syst Engn, Ave Prof Mello Moraes 2231, BR-05508900 Sao Paulo, SP - Brazil
[2] Texas A&M Univ, Dept Mech Engn, College Stn, TX 77843 - USA
Total Affiliations: 2
Document type: Journal article
Source: INTERNATIONAL JOURNAL FOR NUMERICAL METHODS IN ENGINEERING; v. 105, n. 12, p. 883-914, MAR 23 2016.
Web of Science Citations: 6
Abstract

Energy harvesting devices are smart structures capable of converting the mechanical energy (generally, in the form of vibrations) that would be wasted otherwise in the environment into usable electrical energy. Laminated piezoelectric plate and shell structures have been largely used in the design of these devices because of their large generation areas. The design of energy harvesting devices is complex, and they can be efficiently designed by using topology optimization methods (TOM). In this work, the design of laminated piezocomposite energy harvesting devices has been studied using TOM. The energy harvesting performance is improved by maximizing the effective electric power generated by the piezoelectric material, measured at a coupled electric resistor, when subjected to a harmonic excitation. However, harmonic vibrations generate mechanical stress distribution that, depending on the frequency and the amplitude of vibration, may lead to piezoceramic failure. This study advocates using a global stress constraint, which accounts for different failure criteria for different types of materials (isotropic, piezoelectric, and orthotropic). Thus, the electric power is maximized by optimally distributing piezoelectric material, by choosing its polarization sign, and by properly choosing the fiber angles of composite materials to satisfy the global stress constraint. In the TOM formulation, the Piezoelectric Material with Penalization and Polarization material model is applied to distribute piezoelectric material and to choose its polarization sign, and the Discrete Material Optimization method is applied to optimize the composite fiber orientation. The finite element method is adopted to model the structure with a piezoelectric multilayered shell element. Numerical examples are presented to illustrate the proposed methodology. Copyright (c) 2015 John Wiley \& Sons, Ltd. (AU)

FAPESP's process: 12/14576-9 - Design of Piezoelectric Energy harvesting Devices Using Topology Optimization Method
Grantee:Cesar Yukishigue Kiyono
Support Opportunities: Scholarships in Brazil - Post-Doctoral