Double-speed piezoelectric–electromagnetic hybrid energy harvester driven by cross-moving magnets

Shi, Ge; Hu, Xiangzhan; Xia, Yinshui; Jia, Shengyao; Wang, Xiudeng; Xia, Huakang; Sun, Yanwei; Shi, Mang; Wang, Binrui

doi:10.1088/1361-665x/ad0f37

Smart Mater. Struct.

2023

DOI: 10.1088/1361-665x/ad0f37

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Double-speed piezoelectric–electromagnetic hybrid energy harvester driven by cross-moving magnets

Ge Shi,

Xiangzhan Hu,

Yinshui Xia

et al.

Abstract: Energy harvesters have gained popularity as green energy devices that transform mechanical energy from the environment into electricity. However, traditional piezoelectric energy harvesters are limited by narrowband response, and the output capability of electromagnetic energy harvesters is dependent on the rate of magnetic field changes on the coil, which is constrained by the device’s structure. To address these issues, this paper presents a hybrid energy harvester (HEH) that combines coils and arc magnets, … Show more

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Cited by 3 publications

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Design and characterization of a wind-adaptable piezoelectric energy harvester utilizing a rigid-flexible compound blunt body

Yang,

Zhang,

et al. 2025

Mechanical Systems and Signal Processing

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Design and characterization of a wind-adaptable piezoelectric energy harvester utilizing a rigid-flexible compound blunt body

Yang,

Zhang,

et al. 2025

Mechanical Systems and Signal Processing

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A self-regulated wind energy harvester with automatic mode transition strategy enabled by wind-induced centrifugal force

Wu,

Fan,

Zhu

et al. 2024

Smart Mater. Struct.

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Natural wind energy distributes over a wide speed range, but conventional wind turbines with high electrical damping can only work under relatively high wind speeds, whereas breeze harvesters with low electrical damping suffer from limited electric outputs despite their low start-up wind speeds. To solve this dilemma, we report herein an automatic mode transition (AMT) strategy for rotary wind energy harvesters (WEHs) to realize self-regulation of electrical damping according to ambient wind speeds. The superior performance achieved with the AMT strategy has been demonstrated through an AMT-WEH comprising a low-damping as well as a high-damping power generation units. Theoretical analysis and experimental tests reveal that the AMT-WEH not only can work in low-damping single-unit mode to harvest weak wind (≥ 2.6 m/s), but also can switch spontaneously to high-damping dual-unit mode to efficiently capture strong wind. As connected with matched electrical loads, the AMT-WEH can switch to dual-unit mode and generate high average power of 188.2 mW under 8.2 m/s wind, which is more than 11.5-fold increase as compared with that (16.3 mW) of a conventional WEH without the AMT design. This study demonstrates a distinctive AMT strategy for WEHs to effectively exploit wide-speed-range wind energy toward self-contained sensors and electronics.

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Design and Characteristic Analysis of a Performance-Enhanced Piezoelectric Wind Energy Harvester With a Transformable Y-Type Bluff Body

Yang,

Zhang,

et al. 2024

IEEE Sensors J.

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Double-speed piezoelectric–electromagnetic hybrid energy harvester driven by cross-moving magnets

Cited by 3 publications

References 32 publications

Design and characterization of a wind-adaptable piezoelectric energy harvester utilizing a rigid-flexible compound blunt body

Design and characterization of a wind-adaptable piezoelectric energy harvester utilizing a rigid-flexible compound blunt body

A self-regulated wind energy harvester with automatic mode transition strategy enabled by wind-induced centrifugal force

Design and Characteristic Analysis of a Performance-Enhanced Piezoelectric Wind Energy Harvester With a Transformable Y-Type Bluff Body

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