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Performance-aware design for piezoelectric energy harvesting optimisation via finite element analysis

Performance-aware design for piezoelectric energy harvesting optimisation via finite element analysis
Performance-aware design for piezoelectric energy harvesting optimisation via finite element analysis

Most of the optimisation studies of Vibration Energy Harvesters (VEHs) account for a single output quantity, e.g. frequency bandwidth or maximum power output, but this approach does not necessarily maximise the system efficiency. In those applications where VEHs are suitable sources of energy, to achieve optimal design it is important to consider all these performance indexes simultaneously. This paper proposes a robust and straightforward multi-objective optimisation framework for Vibration Piezoelectric Energy Harvesters (VPEHs), considering simultaneously the most crucial performance indexes, i.e., the maximum power output, efficiency, and frequency bandwidth. For the first time, a rigorous formulation of efficiency for Multi-Degree of Freedom (MDOF) VPEHs is here proposed, representing an extension of previous definitions. This formulation lends itself to the optimisation of FE and MDOF harvesters models. The optimisation procedure is demonstrated using a planar-shape harvester and validated against numerical results. The effects of changing some structural parameters on the harvester performance are investigated via sensitivity analysis. The results show that the proposed methodology can effectively optimise the global performance of the harvester, although this does not correspond to an improvement of every single index. Furthermore, the optimisation of each performance index individually results in a variety of design configurations that greatly differs from one another. It is here demonstrated that the design obtained with the multi-objective function here proposed is similar to the design obtained when optimising the efficiency.

Finite element analysis, Optimisation, Piezoelectric energy harvesting, Structural dynamics
1569-1713
121-136
Martinelli, Cristiano
2f6f6785-db85-4835-8ef2-aff8211fef4d
Coraddu, Andrea
eb41a72b-88f2-43f2-b685-ed948f2aa818
Cammarano, Andrea
c0c85f55-3dfc-4b97-9b79-e2554406a12b
Martinelli, Cristiano
2f6f6785-db85-4835-8ef2-aff8211fef4d
Coraddu, Andrea
eb41a72b-88f2-43f2-b685-ed948f2aa818
Cammarano, Andrea
c0c85f55-3dfc-4b97-9b79-e2554406a12b

Martinelli, Cristiano, Coraddu, Andrea and Cammarano, Andrea (2023) Performance-aware design for piezoelectric energy harvesting optimisation via finite element analysis. International Journal of Mechanics and Materials in Design, 19 (1), 121-136. (doi:10.1007/s10999-022-09619-4).

Record type: Article

Abstract

Most of the optimisation studies of Vibration Energy Harvesters (VEHs) account for a single output quantity, e.g. frequency bandwidth or maximum power output, but this approach does not necessarily maximise the system efficiency. In those applications where VEHs are suitable sources of energy, to achieve optimal design it is important to consider all these performance indexes simultaneously. This paper proposes a robust and straightforward multi-objective optimisation framework for Vibration Piezoelectric Energy Harvesters (VPEHs), considering simultaneously the most crucial performance indexes, i.e., the maximum power output, efficiency, and frequency bandwidth. For the first time, a rigorous formulation of efficiency for Multi-Degree of Freedom (MDOF) VPEHs is here proposed, representing an extension of previous definitions. This formulation lends itself to the optimisation of FE and MDOF harvesters models. The optimisation procedure is demonstrated using a planar-shape harvester and validated against numerical results. The effects of changing some structural parameters on the harvester performance are investigated via sensitivity analysis. The results show that the proposed methodology can effectively optimise the global performance of the harvester, although this does not correspond to an improvement of every single index. Furthermore, the optimisation of each performance index individually results in a variety of design configurations that greatly differs from one another. It is here demonstrated that the design obtained with the multi-objective function here proposed is similar to the design obtained when optimising the efficiency.

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s10999-022-09619-4 - Version of Record
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More information

Accepted/In Press date: 27 September 2022
e-pub ahead of print date: 25 October 2022
Published date: March 2023
Additional Information: Publisher Copyright: © 2022, The Author(s).
Keywords: Finite element analysis, Optimisation, Piezoelectric energy harvesting, Structural dynamics

Identifiers

Local EPrints ID: 491096
URI: http://eprints.soton.ac.uk/id/eprint/491096
DOI: doi:10.1007/s10999-022-09619-4
ISSN: 1569-1713
PURE UUID: 88af0556-bd5b-4c0c-ab6e-42bb5a95c5d5
ORCID for Andrea Cammarano: ORCID iD orcid.org/0000-0002-8222-8150

Catalogue record

Date deposited: 11 Jun 2024 23:57
Last modified: 12 Jun 2024 02:11

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Contributors

Author: Cristiano Martinelli
Author: Andrea Coraddu
Author: Andrea Cammarano ORCID iD

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