A Miniaturization Strategy for Harvesting Vibration Energy Utilizing Helmholtz Resonance and Vortex Shedding Effect

Author

Chengliang Sun ; Xiaojing Mu ; Li Yan Siow ; Wei Mong Tsang ; Hongmiao Ji ; Hyun Kee Chang ; Qingxin Zhang ; Yuandong Gu ; Dim-Lee Kwong

Author_Institution

Inst. of Microelectron., Agency for Sci., Technol. & Res., Singapore, Singapore

Volume

35

Issue

2

fYear

2014

fDate

Feb. 2014

Firstpage

271

Lastpage

273

Abstract

In this letter, we report a miniaturization strategy for harvesting a low-frequency random vibration energy with a piezoelectric energy harvesting (EH) system utilizing coupled Helmholtz resonance and vortex shedding effect. This is made possible by transferring the low-frequency vibration energy into a pressurized fluid, which is in turn converted into predefined, pressure-independent high-frequency energy harvested by the device. The vibration-pressurized fluid conversion extends the device sampling frequency band; enables efficient harvesting of broadband low vibration frequencies with small form factor. Proof of concept of the proposed strategy has been demonstrated with an AlN-based MEMS EH, which delivered an output power density of 95.5 mW/cm³ under a constant input airflow at 4.2 lbf/in² pressure.

Keywords

Helmholtz equations; aluminium compounds; energy harvesting; micromechanical devices; piezoelectric transducers; AlN; AlN-based MEMS EH; coupled Helmholtz resonance; low-frequency random vibration; miniaturization strategy; piezoelectric energy harvesting; vibration-pressurized fluid conversion; vortex shedding effect; Cavity resonators; Energy harvesting; Micromechanical devices; Power generation; Resonant frequency; Vibrations; Voltage measurement; Helmholtz resonating; Piezoelectric energy harvester; flow induced vibration; vortex shedding;

fLanguage

English

Journal_Title

Electron Device Letters, IEEE

Publisher

ieee

ISSN

0741-3106

Type

jour

DOI

10.1109/LED.2013.2295922

Filename

6701147