Improved energy harvesting from wideband vibrations by nonlinear piezoelectric converters

Ferrari, Maurizio; Ferrari, Vittorio; Guizzetti, M.; Andò, B.; Baglio, Salvatore; Trigona, Carlo

doi:10.1016/j.sna.2010.05.022

Cited by 450 publications

(230 citation statements)

References 29 publications

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“…Vibration energy harvesting, through the use of linear and nonlinear piezoelectric systems, has been studied in recent years and proved experimentally by [22][23]. Very low values of the overall efficiency need to be improved by reducing energy loss mechanisms and hysteresis losses.Indeed, hysteresis, and stress softening are all phenomena that have been observed [14].…”

Section: State Of the Art And Discussionmentioning

confidence: 99%

Benefits and Challenges of Mechanical Spring Systems for Energy Storage Applications

2015

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Storing the excess mechanical or electrical energy to use it at high demand time has great importance for applications at every scale because of irregularities of demand and supply. Energy storage in elastic deformations in the mechanical domain offers an alternative to the electrical, electrochemical, chemical, and thermal energy storage approaches studied in the recent years. The present paper aims at giving an overview of mechanical spring systems' potential for energy storage applications. Part of the appeal of elastic energy storage is its ability to discharge quickly, enabling high power densities. This available amount of stored energy may be delivered not only to mechanical loads, but also to systems that convert it to drive an electrical load. Mechanical spring systems' benefits and limits for storing macroscopic amounts of energy will be assessed and their integration with mechanical and electrical power devices will be discussed.

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Section: State Of the Art And Discussionmentioning

confidence: 99%

Benefits and Challenges of Mechanical Spring Systems for Energy Storage Applications

2015

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“…The relatively high natural frequencies and narrow bandwidth of the linear resonant VEHs make them inefficient in scavenging ambient broadband and low-frequency vibration energy [5,6]. Therefore, non-resonant VEHs have received increasing attention in recent years [7][8][9][10].…”

Section: Introductionmentioning

confidence: 99%

Impact-Based Electromagnetic Energy Harvester with High Output Voltage under Low-Level Excitations

Luo

Jiang

et al. 2017

Energies

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Abstract:To expand the applications of vibrational energy harvesters (VEHs) as power sources of wireless sensor nodes, it is of significance to improve the scavenging efficiency for the broadband, low-frequency, and low-level vibrational energy. The output voltages of electromagnetic vibrational energy harvesters (EMVEHs) are usually low, which complicates the power management circuit by an indispensable voltage boosting element. To this end, an impact-based non-resonant EMVEH mainly composed of an outer frame and an inner frame on rollers is proposed. Numerical simulations based on a mathematical model of the harvester are conducted to analyze the effects of structural parameters on the output performance. Under base excitation of 0.1 and 0.3 (where g is the gravitational acceleration, 1 g = 9.8 m·s −2 ), the experimental maximum root mean square voltages of a harvester prototype across a resistor of 11 kΩ are as high as 7.6 and 16.5 V at 6.0 and 8.5 Hz, respectively, with the maximum output powers of 5.3 and 24.8 mW, or the power densities of 54.6 and 256 µW cm −3 . By using a management circuit without a voltage boosting element, a wireless sensor node driven by the prototype can measure and transmit the temperature and humidity every 20 s under base excitation of 0.1 g at 5.4 Hz.

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“…Among them an application of a double well potential was proposed [8][9][10][11][12][13]. Gammaitoni et al [9] and Masana and Daqaq [14] discussed the conditions of inter-well hopping.…”

Section: Introductionmentioning

confidence: 99%

Regular and chaotic vibration in a piezoelectric energy harvester with fractional damping

et al. 2015

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Abstract. We examine a vibrational energy harvester consisting of a mechanical resonator with a fractional damping and electrical circuit coupled by a piezoelectric converter. By comparing the bifurcation diagrams and the power output we show that the fractional order of damping changes the system response considerably and affects the power output. Various dynamic responses of the energy harvester are examined using phase trajectory, Fourier spectrum, Multi-scale entropy and 0-1 test. The numerical analysis shows that the fractionally damped energy harvesting system exhibits chaos, and periodic motion, as the fractional order changes. The observed bifurcations strongly influence the power output.

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Improved energy harvesting from wideband vibrations by nonlinear piezoelectric converters

Cited by 450 publications

References 29 publications

Benefits and Challenges of Mechanical Spring Systems for Energy Storage Applications

Benefits and Challenges of Mechanical Spring Systems for Energy Storage Applications

Impact-Based Electromagnetic Energy Harvester with High Output Voltage under Low-Level Excitations

Regular and chaotic vibration in a piezoelectric energy harvester with fractional damping

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