Simulation and Experimental Research on a New Symmetrical Hydraulic Piezoelectric Energy Harvester

This study introduces a new symmetrical hydraulic piezoelectric energy harvester. By integrating theoretical analysis, simulation, and empirical testing, the research delves into the energy-harvesting potential of monolithic single-side output, monolithic two-side parallel-connected output, stacked one-side parallel-connected output, and stacked two-side parallel-connected output under varying parameter configurations. Additionally, it elucidates the energy dissipation occurring during the energy-harvesting process of stacked piezoelectric disks. It has been observed that the primary determinant of voltage is the amplitude of pulsation, not the static pressure. Concurrently, the study also addresses the consistency of power generation between multiple channels. A study is made on whether there is a proportional relationship between single-channel power generation and multi-channel power generation. The root mean square (RMS) voltage of each connection sharply rises with resistance from 2 to 100 K Omega. It is found that the performance of parallel connection of monolithic piezoelectric disk is better than that of other connection methods. At 3 MPa and 100 Hz, the optimal resistance is 16 K Omega, yielding a maximum average power of 1155.63 mu W and an optimal power density of 1.774 mu W (bar mm3)-1. Consequently, the research offers a novel approach to addressing the issue of sustainable energy supply for low-power electronic devices and sensors. This research presents a novel symmetrical hydraulic piezoelectric energy harvester (SHPEH). The correlation between single-channel and multi-channel power generation is examined, revealing that the parallel performance of a monolithic piezoelectric disk surpasses alternative connection configurations. Consequently, this investigation offers an innovative solution to address the sustainable energy demands of low-power electronic devices and sensors.image (c) 2024 WILEY-VCH GmbH