Maximum power, optimal load, and impedance analysis of piezoelectric vibration energy harvesters

Liao, Yabin; Liang, Junrui

doi:10.1088/1361-665x/aaca56

Cited by 53 publications

(58 citation statements)

References 32 publications

(56 reference statements)

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“…The result is depicted in Figure 5. One of the 3-stage topologies, based on a FB rectifier, has been studied in plenty articles, under various denominations : AC-DC power harvesting circuit [70], Standard Energy Harvesting (SEH) interface [65,66,40], Linear Load Adaptation (LLA) [48] or even MPPT-DC [49]. Interestingly, another proposition of 3-stage topology has been published by Lallart et al [52] and makes use of a voltage inversion stage, a rectifier stage and a synchronized charge extraction stage (see Figure 5).…”

Section: -Stage Topologiesmentioning

confidence: 99%

Maximum power point of piezoelectric energy harvesters: a review of optimality condition for electrical tuning

Brenes

Morel

Jerome

et al. 2020

Smart Mater. Struct.

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This paper is a review and synthetic overlook of existing energy harvesting circuits and techniques for piezoelectric energy scavengers. We provide a hierarchical presentation based on functional analysis to distinguish between existing solutions which may look superficially similar but prove to perform very differently in practice. Based on this hierarchical presentation, definitions of topologies, architectures and techniques are given in order to avoid redundancy among existing and future solutions. Then, after a thorough and unified mathematical analysis of the general problem to address, we present a comparison of the conditions for each technique to maximize the power flow from an external vibration source to an electrical load. This analysis is meant to help researchers and engineers make optimal choices for effective implementation of Maximum Power Point Tracking (MPPT).

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Section: -Stage Topologiesmentioning

confidence: 99%

Maximum power point of piezoelectric energy harvesters: a review of optimality condition for electrical tuning

Brenes

Morel

Jerome

et al. 2020

Smart Mater. Struct.

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show abstract

“…Recent advances in internet of things (IoT) and wireless sensing networks provide new insights into sustainability and availability of new types of micro-energy storage and conversion devices, including MEMS-based micro/nano generators, thermoelectrics and solar cells [1][2][3]. Conventional MEMS-based vibration energy harvesters are capable of transforming mechanical energy into electrical energy through piezoelectric [4][5][6], electromagnetic [7][8][9], electrostatic [10][11][12] and triboelectric mechanisms [13][14][15]. Piezoelectric materials possess a unique merit of direct electromechanical coupling which can efficiently convert mechanical strain into electrical energy and vice versa.…”

Section: Introductionmentioning

confidence: 99%

Piezoelectric ZnO thin films for 2DOF MEMS vibrational energy harvesting

Tao

Tang

et al. 2019

Surface and Coatings Technology

114

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Zinc oxide (ZnO) is an environmental-friendly semiconducting, piezoelectric and nonferroelectric material, and plays an essential role for applications in microelectromechanical systems (MEMS). In this work, a fully integrated two-degree-of-freedom (2DOF) MEMS piezoelectric vibration energy harvester (p-VEH) was designed and fabricated using ZnO thin films for converting kinetic energy into electrical energy. The 2DOF energy harvesting system comprises two subsystems: the primary one for energy conversion and the auxiliary one for frequency adjustment. Piezoelectric ZnO thin film was deposited using a radio-frequency magnetron sputtering method onto the primary subsystem for energy conversion from mechanical vibration to electricity. Dynamic performance of the 2DOF resonant system was analyzed and optimized using a lumped parameter model. Two closely located but separated peaks were achieved by precisely adjusting mass ratio and frequency ratio of the resonant systems. The 2DOF MEMS p-VEH chip was fabricated through a combination of laminated surface micromachining process, double-side alignment and bulk micromachining process. When the fabricated prototype was subjected to an excitation acceleration of 0.5 g, two close resonant peaks at 403.8 and 489.9 Hz with comparable voltages of 10 and 15 mV were obtained, respectively.

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“…Recently, some researchers have explored the strong and weak coupling effects based on galloping energy harvesting. Liao et al [51] analyzed the maximum output power of a piezoelectric energy harvester. They proposed that the total power limit could be obtained by tuning the energy harvesting circuit, and they defined three different types of coupling strength by analyzing the closed expression between the mechanical damping and the effective electromechanical coupling coefficient.…”

Section: Introductionmentioning

confidence: 99%

“…In order to analyze the performance of the harvester under the condition of strong and weak couplings, the dimensionless quantity k should be defined (k represents the electromechanical coupling strength). In the load circuit interface, Liao et al [51] expressed the electromechanical coupling strength as , and three different coupling strengths are respectively defined as follows:…”

mentioning

confidence: 99%

Enhancing Wind Energy Harvesting Using Passive Turbulence Control Devices

Wang

Zhou

et al. 2019

Applied Sciences

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Aiming to predict the performance of galloping piezoelectric energy harvesters, a theoretical model is established and verified by experiments. The relative error between the model and experimental results is 5.3%. In addition, the present model is used to study the AC output characteristics of the piezoelectric energy harvesting system under passive turbulence control (PTC), and the influence of load resistance on the critical wind speed, displacement, and output power under both strong and weak coupling are analyzed from the perspective of electromechanical coupling strength, respectively. The results show that the critical wind speed initially increases and then decreases with increasing load resistance. For weak and critical coupling cases, the output power firstly increases and then decreases with the increase of the load resistance, and reaches the maximum value at the optimal load. For the weak, critical, and strong coupling cases, the critical optimal load is 1.1 MΩ, 1.1 MΩ, and 3.0 MΩ, respectively. Overall, the response mechanism of the presented harvester is revealed.

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Maximum power, optimal load, and impedance analysis of piezoelectric vibration energy harvesters

Cited by 53 publications

References 32 publications

Maximum power point of piezoelectric energy harvesters: a review of optimality condition for electrical tuning

Maximum power point of piezoelectric energy harvesters: a review of optimality condition for electrical tuning

Piezoelectric ZnO thin films for 2DOF MEMS vibrational energy harvesting

Enhancing Wind Energy Harvesting Using Passive Turbulence Control Devices

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