R. J. Song scite author profile

R. J. Song

2Publications

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33Citation Statements Given

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Electromechanical modeling and experimental verification of nonlinear hybrid vibration energy harvester

Xu¹,

Shan²,

Song³

et al. 2014

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This paper presents a novel nonlinear hybrid energy harvester (NHEH) combining the piezoelectric and electromagnetic harvesting mechanisms. It consists of a piezoelectric cantilever beam with a moving magnet as a part of proof mass and an opposing magnet attached on the frame. In addition, an electromagnetic generator was attached on the beam tip. An electromechanical coupling model of the hybrid energy harvester was established based on energy method. An experimental system was built up to verify the theoretical analysis. Both experiments and simulation show significant improvements in bandwidth and output power from the nonlinear vibration generator. The prototype shows nearly 83.3% increase than the optimized piezoelectric energy harvester in the operating bandwidth at the 1g m/s 2 excitation level.

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Dynamic energy harvesting performance of two Polyvinylidene Fluoride piezoelectric flags in parallel arrangement in an axial flow

Shan¹,

Song²,

Xu³

et al. 2014

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The dynamic performance and output power of two piezoelectric flags are greatly different from those of a single piezoelectric flag due to the coupling effect of each other. In this paper, the dynamic performance and energy harvesting ability of two piezoelectric flags in parallel arrangement in an axial flow are investigated using immersed boundary-lattice Boltzmann method coupled with Euler-Bernoulli beam and piezoelectric theory, which is fully coupled fluid-structure-electric. A 2D simulation model is presented and a resistance is connected to the piezoelectric flag which is made of Polyvinylidene Fluoride (PVDF). The simulation results show that different vibration phases and coupling modes of two piezoelectric flags are identified, including the in-phase mode, the transition mode and the out-phase mode. When the separation distance of two flags is small, the vibration appears to be the in-phase coupling mode. While the separation distance is large enough, two piezoelectric flags decouple and vibrate individually. Between the in-phase mode and the out-phase mode, the transition mode is found. There is strong interference between each other and the output electric energy seems to be disorders. However, the output power of the piezoelectric flags is nearly identical during the in-phase and the out-phase mode. It means that multi-piezoelectric flags can generate multiple times electric energy in reasonable arrangement compared with a single piezoelectric flag.

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R. J. Song

Electromechanical modeling and experimental verification of nonlinear hybrid vibration energy harvester

Dynamic energy harvesting performance of two Polyvinylidene Fluoride piezoelectric flags in parallel arrangement in an axial flow

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