Title :
Tunable acoustic energy harvester using Helmholtz resonator and dual piezoelectric cantilever beams
Author :
Aichao Yang ; Ping Li ; Yumei Wen ; Caijiang Lu ; Xiao Peng ; Wei He ; Jitao Zhang ; Decai Wang ; Feng Yang
Author_Institution :
Res. Center of Sensors & Instrum., Chongqing Univ., Chongqing, China
Abstract :
A tunable acoustic energy harvester consisting of dual piezoelectric cantilever beams and a Helmholtz resonator with a perforated backplate is proposed. The tunability of the operation frequency band can be achieved not only via simply adjusting the radius (r) of the aperture due to the strong dependence of resonance frequencies of the Helmholtz resonator on the acoustic impedance affected by r, but also by changing the distance (d) between piezoelectric cantilever beams because of their magnetic force interaction. Experimental results show that as r (or d) increases from 0 (or 1.4) to 1.0 (or 3.4) cm, the frequency band is broadened and varies from 175.5~198 (or 175.5~213) Hz to 170.5~221 (or 161~203) Hz. The average ratio of the adjusted frequency bandwidth to r (or d) can reach 28 (or 2.25) Hz/cm over the range of 125~250 Hz.
Keywords :
acoustic resonators; acoustic transducers; crystal resonators; energy harvesting; Helmholtz resonator; acoustic impedance; distance 1.4 cm to 3.4 cm; dual piezoelectric cantilever beams; frequency 125 Hz to 250 Hz; magnetic force interaction; operation frequency band; perforated backplate; size 0 cm to 1.0 cm; tunable acoustic energy harvester; Acoustic beams; Acoustics; Cavity resonators; Energy harvesting; Optical resonators; Resonant frequency; Structural beams; Helmholtz resonator; dual piezoelectric cantilever beams; tunable acoustic energy harvester;
Conference_Titel :
Ultrasonics Symposium (IUS), 2014 IEEE International
Conference_Location :
Chicago, IL
DOI :
10.1109/ULTSYM.2014.0622
