A micromachined low-frequency piezoelectric harvester for vibration and wind energy scavenging

To efficiently scavenge ambient vibration energy and wind energy at the same time, a low-frequency piezoelectric harvester was designed, fabricated and tested. A lumped-parameter model of the cantilevered piezoelectric energy harvester with a proof mass was established and the closed-form expressions of voltage and power on a resistance load under base acceleration excitation were derived. After effects of the lengths of the proof mass and electrodes on output power were analyzed, a MEMS harvester was optimally designed. By using aluminum nitride as piezoelectric layer, a MEMS energy harvester was fabricated with bulk micromachining process. Experimental results show that the open-circuit frequency of the MEMS harvester is about 134.8 Hz and the matched resistance is about 410 k Omega. Under the harmonic acceleration excitation of +/- 0.1 g, the maximum output power is about 1.85 mu W, with the normalized power density of about 6.3 mW cm(-3) g(-2). The critical wind speed of the device is between 12.7 and 13.2 m s(-1) when the wind direction is from the proof mass to the fixed end of the cantilever. The maximum output power under 16.3 m s(-1) wind is about 2.27 mu W.