Performance analysis of electromagnetic vibration energy harvester under square excitation

• Published in: International journal of mechanical sciences Vol. 271; p. 109127
• Main Authors: Wang, Yuan, Gao, Yanyan, Chen, Zhiwei, Zong, Ruisi, Li, Yubao, Guo, Ruixue, Azam, Ali, Qi, Lingfei, Zhang, Zutao
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 01.06.2024
• Subjects: Electromagnetic; Motion rectification; Parameter adjustment; Square wave excitation; Vibration energy harvesting; Motion rectification; Electromagnetic; Parameter adjustment; Square wave excitation; Vibration energy harvesting
• ISSN: 0020-7403; 1879-2162
• DOI: 10.1016/j.ijmecsci.2024.109127

•Vibro-electric coupling model of the VEH under square wave excitation is established.•The parameter adjusting priority of the VEH system is proposed.•The maximum output power of the proposed system is 2.7 W.•The proposed VEH is suitable for multi-vibration scenarios. Harvesting energy from surrounding vibrations is an effective method for powering various low-power electronic devices. The energy output performance of vibration energy harvesters under some special excitations remains to be investigated. In this paper, a vibration energy harvester (VEH) system based on a rack and pinion mechanism and a bevel gear set is proposed, and a detailed electromechanical coupling modeling of the system under general excitation and square wave excitation is carried out. The energy output characteristics of the proposed system under square wave excitation are explored through simulation and experiment. When the energy output is the target, the priority of adjusting the constituent parameters in the equivalent mass parameter, equivalent damping parameter and equivalent stiffness parameter of the system can be obtained based on the simulation results. The experimental results under periodic square wave excitation force show that the maximum output power of the proposed system is 2.7 W at an amplitude of 4 kN and a frequency of 3 Hz. This is a 55 % increase in the maximum power compared to the sinusoidal excitation under the same conditions. It is demonstrated that the proposed system has great potential to power various low-power electronic devices. [Display omitted]