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Optimisation-driven design of sliding mode triboelectric energy harvesters

Optimisation-driven design of sliding mode triboelectric energy harvesters
Optimisation-driven design of sliding mode triboelectric energy harvesters
With the increasing demand of emerging technologies for autonomous sensing, the modelling and optimisation of complete energy harvesting systems are essential to achieve efficient power output. To date, most of the optimisation efforts in enhancing the performance of triboelectric energy harvesters have been focused on the improvement of material properties and on the establishment of figures of merit to assist in the definition of parameters. However, these efforts do not consider the complex relationship between the device structure and power output, physical constraints in place, and varying excitation conditions. This paper fills that gap for the first time by applying an optimisation algorithm to establish mechanisms for optimisation-driven design of sliding-mode triboelectric energy harvesters. A global optimisation methodology is developed to improve its performance, having experimentally validated the numerical model adopted. This work highlights the need for a more robust design framework for applications of triboelectric energy harvesting and proposes a hybrid approach combining the finite element method with analytical models to consider different energy harvesting parameters including the degradation of the charge transfer efficiency due to the edge effect. A novel high-power output sliding-mode triboelectric energy harvesting concept is proposed and its performance is optimised, using the proposed methodology.
Energy harvesting, Global optimisation, Triboelectricity
2211-2855
Machado, Lucas Q.
333de39d-3cad-4576-99f0-6b5888cbda1e
Zhao, Huai
aee13537-a4cc-4b7e-8e74-876eb2b4c0f2
Amjadi, Morteza
7b9ab878-ffff-4bae-81b6-db13f32e48db
Ouyang, Huajiang
996c9b4a-69a8-4ae2-9a09-94b36e70c73f
Basset, Philippe
718ae6a5-a5b7-4908-b65c-b559f567ec68
Yurchenko, Daniil
51a2896b-281e-4977-bb72-5f96e891fbf8
Machado, Lucas Q.
333de39d-3cad-4576-99f0-6b5888cbda1e
Zhao, Huai
aee13537-a4cc-4b7e-8e74-876eb2b4c0f2
Amjadi, Morteza
7b9ab878-ffff-4bae-81b6-db13f32e48db
Ouyang, Huajiang
996c9b4a-69a8-4ae2-9a09-94b36e70c73f
Basset, Philippe
718ae6a5-a5b7-4908-b65c-b559f567ec68
Yurchenko, Daniil
51a2896b-281e-4977-bb72-5f96e891fbf8

Machado, Lucas Q., Zhao, Huai, Amjadi, Morteza, Ouyang, Huajiang, Basset, Philippe and Yurchenko, Daniil (2023) Optimisation-driven design of sliding mode triboelectric energy harvesters. Nano Energy, 115, [108735]. (doi:10.1016/j.nanoen.2023.108735).

Record type: Article

Abstract

With the increasing demand of emerging technologies for autonomous sensing, the modelling and optimisation of complete energy harvesting systems are essential to achieve efficient power output. To date, most of the optimisation efforts in enhancing the performance of triboelectric energy harvesters have been focused on the improvement of material properties and on the establishment of figures of merit to assist in the definition of parameters. However, these efforts do not consider the complex relationship between the device structure and power output, physical constraints in place, and varying excitation conditions. This paper fills that gap for the first time by applying an optimisation algorithm to establish mechanisms for optimisation-driven design of sliding-mode triboelectric energy harvesters. A global optimisation methodology is developed to improve its performance, having experimentally validated the numerical model adopted. This work highlights the need for a more robust design framework for applications of triboelectric energy harvesting and proposes a hybrid approach combining the finite element method with analytical models to consider different energy harvesting parameters including the degradation of the charge transfer efficiency due to the edge effect. A novel high-power output sliding-mode triboelectric energy harvesting concept is proposed and its performance is optimised, using the proposed methodology.

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Accepted/In Press date: 20 July 2023
e-pub ahead of print date: 22 July 2023
Published date: October 2023
Additional Information: Funding Information: The authors would like to acknowledge and are thankful for the support received from the Brazilian National Council for Scientific and Technological Development—CNPq , grant 202615/2019-7 . The authors would also like to acknowledge and thank the Ph.D. student Tom Jacquin for his support in providing some of the materials used in the experiments and the technician James Maxwell-Smith for his help in building the experimental rig. Publisher Copyright: © 2023 The Authors
Keywords: Energy harvesting, Global optimisation, Triboelectricity

Identifiers

Local EPrints ID: 484896
URI: http://eprints.soton.ac.uk/id/eprint/484896
ISSN: 2211-2855
PURE UUID: c9016104-20da-4983-a39b-9283c91a07aa
ORCID for Lucas Q. Machado: ORCID iD orcid.org/0000-0002-7397-9737
ORCID for Daniil Yurchenko: ORCID iD orcid.org/0000-0002-4989-3634

Catalogue record

Date deposited: 24 Nov 2023 17:31
Last modified: 10 Oct 2024 02:06

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Contributors

Author: Lucas Q. Machado ORCID iD
Author: Huai Zhao
Author: Morteza Amjadi
Author: Huajiang Ouyang
Author: Philippe Basset
Author: Daniil Yurchenko ORCID iD

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