Performance boost of an electromagnetic energy harvester using vibrational resonance
K.A. Omoteso, T. O. Roy-Layinde, Uchenna Diala
Abstract
Inherent nonlinearities, present in dynamical systems are employed to solve various engineering problems. Nonlinear dynamics involve responses that are not directly proportional to inputs, allowing for more effective system management. The beneficial characteristics of nonlinear systems and its growing associated literature have contributed to mitigating industrial and environmental energy-related challenges. Several recommendations have been provided for increasing the efficiency of a vibration energy harvesting (VEH) system. In this study, we investigated the occurrence of vibrational resonance (VR) in a Duffing-type energy harvester with electromagnetic transduction structure. We explored the impact of system nonlinearities on the occurrence of VR and system performance. We employed both analytical and numerical approaches to show the impact of the system parameters, especially the nonlinear stiffness parameter on the response amplitude at low-frequency excitations. Furthermore, the estimated average power absorbed by the VEH system is selected as the system performance metric, which can be optimized using the system’s parameters of interest. The VEH system demonstrated an improved performance as a significant amount of energy was harvested based on the nonlinear parameters of interest. Our investigation points to a new approach for the design and optimization of electromagnetic energy harvester. • Vibrational resonance (VR) is employed in a Duffing-type electromagnetic energy harvester. • The oscillator is a vibration energy harvester with SDOF, driven by a dual-frequency force. • The stiffness parameters influence the potential structure and resonance dynamics of the system. • The average power extracted was selected as the system’s performance metric. • A new approach is shown for the optimization of an electromagnetic energy harvester.