Huatong Cai scite author profile

This paper investigates the influence of the electromechanical coupling effect on the performances of a hybrid piezoelectric and electromagnetic energy harvester. For a common hybrid energy harvester, we derive an accurate analytical solution and get expressions for the resonant frequency shift, output power, amplitude and conversion efficiency. Then, based on various degrees of coupling effect, the performance of the harvester is studied with different load and excitation frequency, and compared with piezoelectric-only and electromagnetic-only energy harvesters. The results show that the bigger the coupling coefficient, the greater the resonant frequency shift, output power and conversion efficiency. In the weak coupling and medium coupling, the performances of the hybrid energy harvester are better than those of the two separate energy harvesting techniques; however, the hybrid energy harvester does not increase the power and conversion efficiency in contrast with the piezoelectric-only and electromagnetic-only energy harvester in strong coupling. In addition, the optimal load resistance of the hybrid energy harvester is related to the strength of the coupling effect; moreover, the optimal load resistance of the electromagnetic harvesting element for the hybrid harvester is bigger than that of the electromagnetic-only harvester in the medium and strong coupling. Through analysis of the results, ways of boosting the performances of the hybrid energy harvester are found.

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Design, fabrication and performances of MEMS piezoelectric energy harvester

Gao

Cai

et al. 2015

JAE

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MEMS piezoelectric energy harvester is optimally designed and fabricated, and its vibration characteristics, output voltage, power, power spectral density (SD) and frequency response function under harmonic and random excitation is studied by theory analysis, simulation and experimental test. For the designed MEMS piezoelectric energy harvester, the accurate solutions and expressions of amplitude, voltage, power and power spectral density are derived. Then, vibration characteristic, voltage, power and power SD with different load resistance, sinusoidal acceleration and random acceleration SD are simulated and tested; moreover, frequency response function of MEMS piezoelectric energy harvester is obtained by experimental test, and the results are consistent with theoretical model. When sinusoidal acceleration is 0.6 g, the maximal amplitude of mass is 116 µm and the power density is 0.1 mW/cm 3 . By testing results, output voltage of piezoelectric energy harvester is proportional to the amplitude, and the amplitude at optimal load is smaller than of at open circuit because of the feedback effect of load resistance. In addition, output power SD linearly increases with acceleration SD increasing. When acceleration SD is 5 × 10 −4 (m/s 2 ) 2 /Hz, power SD is 1.24 µW 2 /Hz.

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Coupling effect analysis for hybrid piezoelectric and electromagnetic energy harvesting from random vibrations

Gao

Cai

et al. 2014

Int. J. Precis. Eng. Manuf.

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Huatong Cai

Modeling and analysis of hybrid piezoelectric and electromagnetic energy harvesting from random vibrations

Theoretical analysis and experimental study for nonlinear hybrid piezoelectric and electromagnetic energy harvester

An analysis of the coupling effect for a hybrid piezoelectric and electromagnetic energy harvester

Design, fabrication and performances of MEMS piezoelectric energy harvester

Coupling effect analysis for hybrid piezoelectric and electromagnetic energy harvesting from random vibrations

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