Low-frequency, broadband vibration energy harvester using coupled oscillators and frequency up-conversion by mechanical stoppers

• Published in: Smart materials and structures Vol. 26; no. 6; pp. 65021 - 65031
• Main Authors: Dechant, Eduard, Fedulov, Feodor, Chashin, Dmitrii V, Fetisov, Leonid Y, Fetisov, Yuri K, Shamonin, Mikhail
• Format: Journal Article
• Language: English
• Published: IOP Publishing 01.06.2017
• Subjects: broadband; frequency up-conversion; low frequency; mechanical stoppers; modeling; piezoelectric transducer; vibration energy harvesting
• ISSN: 0964-1726; 1361-665X
• DOI: 10.1088/1361-665X/aa6e92

The frequencies of ambient vibrations are often low (below 30 Hz). A broadband (3 dB bandwidth is larger than 10 Hz at an acceleration amplitude of 9.81 m s−2) vibration based energy harvester is proposed for transducing mechanical energy at such low frequencies into electrical energy. The mechanical setup converts low frequency mechanical vibrations into high frequency resonance oscillations of the transducer. This conversion is done by mechanical impacts on two mechanical stoppers. The originality of the presented design is that both low-frequency and high-frequency oscillators are permanently mechanically coupled. In the equivalent mechanical circuit, this coupling is achieved by connecting the ends of the stiff spring to both seismic masses, whereas one seismic mass (collison member) is also attached to the soft spring used as the constitutive element of a low-frequency oscillator. Further, both mechanical oscillators are not realized as conventional cantilever beams. In particular, the high frequency oscillator with the natural frequency of 340 Hz is a disc-shaped diaphragm with attached piezoelectric elements and a seismic mass. It is shown that it is possible to convert mechanical vibrations with acceleration amplitude of 9.81 m s−2 in the region between approximately 7 and 25 Hz into electrical power larger than 0.1 mW with the maximum value of 0.8 mW. A simplified mathematical model based on piecewise linear coupled oscillators shows good agreement with experimental results. The ways to enhance the performance of the harvester and improve agreement with experiments are discussed.