A piezoelectric vibration energy harvester based on the reverse-rhombus double-bridge force amplification frame

Zhang, Jiantao; Yu, Xiangfu; Zhao, Wei; Qu, Dong

doi:10.1088/1361-6463/ac0842

Cited by 7 publications

(2 citation statements)

References 36 publications

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“…The present work aims at clean and free power generation at macro-scale using piezoelectric harvesters. The various sources for piezoelectric power generation are human motion , Song et al 2019, Zhang et al 2021, Sirigireddy and Eladi 2022a, vehicular movement (Ansari and Karami 2015, Yang et al 2017, Khalili et al 2022, mechanical vibrations (Roundy andWright 2004, Grzybek andMicek 2019), flow-induced vibrations (Wang et al 2021, Zhang et al 2023, bridge oscillations (Zhang et al 2022) etc. The mechanical energy from these sources are converted into electrical energy using a PEH.…”

Section: Introductionmentioning

confidence: 99%

Analytical model of z-piezoelectric energy harvester for power generation from human physical activities

Sirigireddy,

Eladi

2023

Phys. Scr.

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Human physical activities, viz., walking, jogging, jumping, etc. on piezoelectric energy harvesters (PEH) have a great potential for the generation of free and clean energy. In the present work, an analytical model is developed to study the performance of a z-PEH, and the results were validated with numerical and experimental results. The distinctive features of the z-PEH are (a) it can be installed in a very small pavement/road surface area, (b) it results in very less damage to the road during installation, and (c) the repair and maintenance works can be carried out relatively easily. The power generation of the harvester can be enormously increased by increasing the number of unimorphs in the vertical (z) direction without increasing in the surface (x-y) directions, hence termed z-PEH. The harvester studied has four unimorphs. Each unimorph has a PZT-5A plate and an Aluminum substrate. The analytical and numerical studies resulted in a harvester with optimum dimensions for the PZT plate and Aluminum substrate of 20 × 20 × 0.4 mm3 and 65.1 × 20 × 1 mm3 respectively. Experiments were carried out on the optimum structure. The z-PEH, for an input deflection of 1 mm generated a maximum power of 0.84 mW, 0.88 mW and 0.80 mW from the proposed analytical model, numerical work and experiments respectively. The percentage of error between analytical and numerical results is 4.55% and between analytical and experimental results is 4.76%. An average human can generate a force of 490 N while walking, thereby allowing the use of 88 unimorphs in the z-PEH. The DC power generated from the harvester using the analytical model is 18.39 mW and the power density is 10.09 W/m3.

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Section: Introductionmentioning

confidence: 99%

Analytical model of z-piezoelectric energy harvester for power generation from human physical activities

Sirigireddy,

Eladi

2023

Phys. Scr.

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“…Energy harvesters (EH) are devices that convert ambient energy sources into electrical energy using various energy transduction mechanisms [9][10][11]. Siang et al [12] provides a taxonomy of potential energy harvesting sources where vibration sources fall under both ambient environment and external sources category.…”

Section: Introductionmentioning

confidence: 99%

A bistable rotary-translational energy harvester from ultra-low-frequency motions for self-powered wireless sensing

Masabi

Theodossiades

2022

J. Phys. D: Appl. Phys.

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This paper presents the design, theoretical modelling and experimental study of a bi-stable energy harvester using rotary-translational motion for ultra-low frequency and low excitation amplitude energy sources. A spherical magnet is adopted to produce the rotary-translational motion to convert ultralow-frequency kinetic energy into electricity over a wide frequency range. The bi-stable mechanism is realized by introducing two tethering magnets underneath the sphere magnet’s oscillating path, significantly enhancing the operating range of the harvester. A theoretical model including the impact dynamics, magnetic interaction and electromagnetic conversion has been established to explore the electromechanical behaviours of the harvester under different operating conditions. The results illustrate that the energy harvester operates in intra-well or inter-well motion depending on whether the input excitation is adequate to conquer the potential barrier depth. A prototype is developed to illustrate the design and to validate the theoretical model. The prototype generates sufficient power (mW) at frequencies lower than 2 Hz with excitation amplitudes as low as 0.1g. A peak output power of 9 mW (1.53 mW RMS) is obtained at 2 Hz and 0.7g with 750 Ω external load. The developed energy harvester is integrated with an off-the-shelf power management solution to power a wireless sensing system to successfully record real-time temperature variation in the environment.

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A compliant mechanism based piezoelectric beam energy harvester with multi-mode frequency up conversion

Yan

2023

Energy Reports

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A piezoelectric vibration energy harvester based on the reverse-rhombus double-bridge force amplification frame

Cited by 7 publications

References 36 publications

Analytical model of z-piezoelectric energy harvester for power generation from human physical activities

Analytical model of z-piezoelectric energy harvester for power generation from human physical activities

A bistable rotary-translational energy harvester from ultra-low-frequency motions for self-powered wireless sensing

A compliant mechanism based piezoelectric beam energy harvester with multi-mode frequency up conversion

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