An M-shaped buckled beam for enhancing nonlinear energy harvesting

Aiming to achieve the high-performance piezoelectric energy harvester under low excitation, a bistable energy harvester with an M-shaped buckled beam is proposed in this paper. When the M-shaped beam is pre-compressed into a buckling state, motion of the M-shaped beam has changed from monostable oscillation to bistable oscillation. Compared with the original mono-stable M-shaped beam, numerical and experimental results show that the proposed harvester can easily maintain large-amplitude interwell oscillation and offer a wider operation bandwidth in lower frequency range. The harvester can offer an operation bandwidth of 5 Hz or 6 Hz under 3 m/s2 or 5 m/s2 excitation, which is improved by 233.3 % or 140 % in comparison with the monostable configurations. In bistable configurations, the acceleration threshold required for interwell oscillation can be decreased by reducing the buckling level, which can provide higher voltage and wider operation bandwidth in sweep frequency excitation. In monostable configu-rations, it is observed that the M-shaped beam shows a softening behavior or a hardening behavior with different clamping distance. Numerical and experimental results verify that the performance of monostable configuration with a softening behavior is better than that with a hardening behavior.

Automated summary

This paper proposes a bistable energy harvester with an M-shaped buckled beam aiming to achieve high-performance piezoelectric energy harvesting under low excitation. Compared with the original monostable M-shaped beam, the proposed harvester can easily maintain large-amplitude interwell oscillation and offer a wider operation bandwidth in a lower frequency range. Numerical and experimental results show that the acceleration threshold required for interwell oscillation can be decreased by reducing the buckling level in bistable configurations, which provides higher voltage and wider operation bandwidth in sweep frequency excitation. Additionally, the performance of the monostable configuration with a softening behavior is better than that with a hardening behavior.