Design and Experimental Investigation of a Piezoelectric Rotation Energy Harvester Using Bistable and Frequency Up-Conversion Mechanisms

Xie, Zhengqiu; Xiong, Jitao; Zhang, Deqi; Wang, Tao; Shao, Yimin; Huang, Wenbin

doi:10.3390/app8091418

Cited by 31 publications

(8 citation statements)

References 37 publications

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“…Regarding the contact excitation mode, the deformation of piezoelectric elements was mostly induced by mechanical plucking (Kuang et al, 2016; Raja et al, 2023; Yi et al, 2021) or impact-based steel balls (Chen et al, 2020; Roundy and Tola, 2014; Yang et al, 2014). Because the direct contact during the mechanical plucking or the impact of steel balls would decrease long-term reliability of the piezoelectric elements and plectra and cause a lot of noise, the contactless magnetic plucking technique was developed to avoid the direct contact between the exciting mechanisms and piezoelectric elements (Dauksevicius et al, 2018; Xie et al, 2018; Xue and Roundy, 2017). The contactless magnetic plucking technique mainly uses the non-contact magnetic coupling force in the process of rotation to bend and deform the piezoelectric elements.…”

Section: Introductionmentioning

confidence: 99%

Development and performance evaluation of a wheel-type cantilevered piezoelectric rotational energy harvester via an unfixed exciting magnet

Kan

Zhang

Wang

et al. 2023

Journal of Intelligent Material Systems and Structures

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A wheel-type cantilevered piezoelectric rotational energy harvester (wheel-type PREH) via an unfixed exciting magnet was presented to harvest energy from rotational motion without or far away from a fixed support. To verify the structural feasibility and figure out the effect of rolling exciting magnet and excited magnet on the dynamic characteristics and power generation performance of the wheel-type PREH, the theoretical analysis, simulation, fabrication and experimental testing were performed. The results showed that the performance of the wheel-type PREH depended on the rotary speeds, proof mass and piezo-cantilever mass, number of exciting magnets, cylindrical sleeve materials and so on. When other parameters were constant, there were multiple optimal rotary speeds for the maximal amplitude-ratio, output voltage, electrical energy and output power to achieve peak. Besides, the total number of voltage crests per second did not change with rotary speed. There was a constant optimal resistance load for the wheel-type PREH at different rotary speeds to achieve maximal power. The PREH prototype could yield a maximum output power of 0.74 mW at 767 r/min with optimal load resistance of 215 kΩ and 40 different color LEDs in parallel and a low power light strip could be lighted by wheel-type PREH.

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Section: Introductionmentioning

confidence: 99%

Development and performance evaluation of a wheel-type cantilevered piezoelectric rotational energy harvester via an unfixed exciting magnet

Kan

Zhang

Wang

et al. 2023

Journal of Intelligent Material Systems and Structures

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“…Technologies of kinetic energy harvesting have achieved rapid progress in recent decades due to their ability to harvest ambient kinetic energy to generate electricity. Among the kinetic motion, rotational motion has been widely used for various applications, including engines [ 1 ], turbines [ 2 , 3 , 4 , 5 ], rotating shafts [ 6 ], human motions [ 7 , 8 , 9 , 10 ] and vehicle wheels [ 11 , 12 , 13 ]. Fu et al [ 14 ] reviewed the state-of-the-art technology in the field of rotational energy harvesting for self-powered sensing.…”

Section: Introductionmentioning

confidence: 99%

Design and Experimental Investigation of a Rotational Piezoelectric Energy Harvester with an Offset Distance from the Rotation Center

et al. 2022

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Rotational energy harvesting technology has attracted more and more attention recently. This paper presents a piezoelectric rotational energy harvester that can be mounted with an offset distance from the rotation center. The piezoelectric energy harvester is designed to be dynamically excited by the force due to gravity, which causes the piezoelectric cantilever beams in the harvester to vibrate periodically as the harvester rotates. A novel design of the harvester structure with a hollow mass is proposed and analyzed in this paper. Experiments were performed to investigate the design and analysis. A power output of 106~2308 μW can be achieved at the rotating frequencies of 0.79~14 Hz with a piezoelectric cantilever beam in the prototyped energy harvester. Results showed that the prototyped harvester can be mounted on a rotating wheel hub and output sufficient power in a wide frequency range for wireless monitoring sensors.

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“…Zou et al explored a magnetically coupled energy harvester using two inverted piezoelectric cantilever beams for rotary motion [28]. Xie et al presented a bistable piezoelectric rotation energy harvester with the frequency up-conversion capability by using a magnetic-coupled buckled beam [29]. A brief survey of literatures shows that the researchers have already conducted lots of work on the I-PREHs to improve the performance and the considerable progress has been made.…”

Section: Introductionmentioning

confidence: 99%

A cantilevered piezoelectric energy harvester excited by an axially pushed wedge cam using repulsive magnets for rotary motion

Kan¹,

Zhang²,

Wang³

et al. 2021

Smart Mater. Struct.

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Harvesting energy from the rotary environment to replace the conventional electrochemical batteries has gained considerable interest. Different from the existing rotation-induced energy harvesters based on the bidirectional deformation of piezoelectric vibrators, a novel cantilevered piezoelectric energy harvester excited by an axially pushed wedge cam using repulsive magnets for rotary motion was presented and fabricated in this paper. The new piezoelectric rotary energy harvester (PREH) was characterized by the simultaneous realization of unidirectional deformation and limited amplitude for piezoelectric vibrators. To verify the feasibility of the proposed principle and design, a theoretical model was established based on Fourier series as well as superposition principle. Meanwhile, the influence of the system parameters on the response characteristic of the presented PREH were obtained by simulation. And then, the experiments of rotating speed response were performed to evaluate the energy harvesting performance in terms of the deformation and open-circuit voltage. Both simulation and experimental results showed that the amplitude of the piezo-cantilever could be limited by using the cam mechanism and there were obvious resonance peaks on the amplitude-rotary speeds curves. Thus, the relatively stable output voltage could be maintained over a broad rotating speed range. Also, the stable voltage increased with the increasing of cam lift, but the effective rotating speed range became narrow. With the increasing of the cam angle, the effective rotating speed bandwidth could be increased, whereas the self-locking phenomenon of the piezo-cantilever would occur when the angle was increased to some extent. Besides, the bandwidth could be adjusted by changing the number of exciting magnets and stiffness of cam system. Under the optimum matching parameters, the maximum power 10.88 mW was reached for the presented PREH.

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Design and Experimental Investigation of a Piezoelectric Rotation Energy Harvester Using Bistable and Frequency Up-Conversion Mechanisms

Cited by 31 publications

References 37 publications

Development and performance evaluation of a wheel-type cantilevered piezoelectric rotational energy harvester via an unfixed exciting magnet

Development and performance evaluation of a wheel-type cantilevered piezoelectric rotational energy harvester via an unfixed exciting magnet

Design and Experimental Investigation of a Rotational Piezoelectric Energy Harvester with an Offset Distance from the Rotation Center

A cantilevered piezoelectric energy harvester excited by an axially pushed wedge cam using repulsive magnets for rotary motion

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