Abstract
In the past decade, vibration energy harvesting has emerged as a potential alternative solution to power wireless sensor nodes. In real-world implementations, external excitation can be very noisy and includes noise signals in a wide frequency band. In order to accommodate operation under noisy excitation, arrays of energy harvesters with different resonance frequencies are often employed to improve responsibility. Due to the nature of noisy excitation and the difference in resonance frequencies, the response voltage signals from each harvester can be very different in amplitude, frequency and phase. In this paper, an array with two cantilevered energy harvesters is studied to analyze the rectified output power with different configurations using full-bridge rectifiers (FBR). The experiments show that connecting the two harvesters in parallel or in series before connecting with a FBR results in significant voltage cancellation due to phase mismatch. The most efficient way to extract energy is to use two FBRs for the two cantilevered energy harvesters, individually, and charge to one single storage capacitor connected at the outputs of the two FBRs.
Highlights
Related content- The fabrication of vibration energy harvester arrays based on AlN piezoelectric film Shang Zhengguo, Li Dongling, Wen Zhiyu et al
Among different vibration energy harvesting topologies, piezoelectric materials are widely adopted due to their high power density in mm[2] scale miniaturized energy harvesting systems [1]
The results show that each cantilever requires an individual full-bridge rectifiers (FBR) to extract and rectify the energy
Summary
- The fabrication of vibration energy harvester arrays based on AlN piezoelectric film Shang Zhengguo, Li Dongling, Wen Zhiyu et al. - A low-frequency hybrid energy harvester with high output performance Y Xia, W Liu, T Chen et al. - A Low-Frequency Three-Dimensional Hybrid Energy Harvester J Zhang, T Chen, H Liu et al. This content was downloaded from IP address 134.151.16.168 on 13/11/2019 at 10:12
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