Theoretical and experimental investigation of magnet and coil arrays optimization for power density improvement in electromagnetic vibration energy harvesters

Li, Yong; Li, Jianwen; Liu, Zhaowei; Hu, Haitao; Hu, Jiefeng; Wang, Junlei; He, Zhengyou

Title: Theoretical and experimental investigation of magnet and coil arrays optimization for power density improvement in electromagnetic vibration energy harvesters
Creator: Li, Yong; Li, Jianwen; Liu, Zhaowei; Hu, Haitao; Hu, Jiefeng; Wang, Junlei; He, Zhengyou
Date: 2023
Type: Text; Journal article
Identifier: http://researchonline.federation.edu.au/vital/access/HandleResolver/1959.17/198382
Identifier: vital:19042
Identifier: https://doi.org/10.1016/j.enconman.2023.117411
Identifier: ISSN:0196-8904 (ISSN)
Abstract: Power density is a critical evaluation indicator of electromagnetic vibration energy harvesters and has become one of the research hotspots. Therefore, it is of great significance to establish a simple and accurate theory to optimize and guide the design of an energy harvester for power density enhancement. Indeed, an alternating magnet array has a high flux gradient, which is one of the key factors for power enhancement. Under volume constraints, the coil output power is highly related to the magnet configuration, as the latter determines the magnitude of the flux gradient as well as the total flux mutation. Motivated by this, in this paper, an electromagnetic vibration energy harvester based on a coil array and a magnet array is proposed. The magnetic field distribution of rectangular magnets is analyzed. Then, a theoretical model based on Faraday's law of electromagnetic induction is derived to efficiently calculate the open-circuit voltage of coils with different numbers of magnets. After that, the optimal magnetic configuration is obtained based on the developed model without the need of measuring the parasitic damping of the energy harvester. Simulations and experiments verify the correctness of the theory. The results show that at an acceleration of 1 g and frequency of 41.2 Hz, the output power and power density reach a maximum of 3.71 mW and 106.68
Publisher: Elsevier Ltd
Relation: Energy Conversion and Management Vol. 293, no. (2023), p.
Rights: All metadata describing materials held in, or linked to, the repository is freely available under a CC0 licence
Subject: 4004 Chemical engineering; 4008 Electrical engineering; 4017 Mechanical engineering; Electromagnetic vibration energy harvesting; Induced electromotive force model; Magnet array; Power density enhancement
Reviewed
Funder: This work was supported by the Young Elite Scientist Sponsorship Program by the China Association for Science and Technology, the Cutting-edge Science and Technology Cultivation Project of Southwest Jiaotong University (Grant number: 2682022KJ005), the Fundamental Research Funds for the Central Universities (Grant number: 2682023ZTPV026), and the Young Eagle Program in Southwest Jiaotong University.

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