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Nonlinear Energy Harvesting by Piezoelectric Bionic ‘M’ Shape Generating Beam Featured in Reducing Stress Concentration

Chao Xiong, Nan Wu, Yuncheng He, Yuan Cai, Xianming Zeng, Peichen Jin, Minyi Lai

2023Micromachines14 citationsDOIOpen Access PDF

Abstract

Inspired by the flapping wings of seagulls during flight, a new low-cost, magnet-free, bistable piezoelectric energy harvester is proposed to obtain energy from low-frequency vibration and convert it into electrical energy and reduce fatigue damage caused by stress concentration. In order to optimize the power generation efficiency of this energy harvesting, finite element analysis and experimental tests were carried out. The results of finite element analysis and experimental results are in good agreement, and the superior performance in improving stress concentration of the energy harvester compared to the previous parabolic (bow-shaped) one using bistable technology was quantitatively analyzed using finite element simulation, with a maximum stress reduction of 32.34%. The experimental results showed that under optimal operating conditions, the maximum open-circuit voltage of the harvester was 11.5 V, and the maximum output power was 73 μW. These results indicate that this is a promising strategy, which provides a reference for collecting vibrational energy in low-frequency environments.

Topics & Concepts

Energy harvestingFinite element methodBistabilityStress (linguistics)VibrationMagnetVoltageMaterials scienceBeam (structure)PiezoelectricityPower (physics)Maximum power principleReduction (mathematics)Energy (signal processing)Nonlinear systemEnergy transformationAcousticsStructural engineeringEngineeringElectrical engineeringComposite materialOptoelectronicsPhysicsMathematicsLinguisticsThermodynamicsGeometryPhilosophyQuantum mechanicsInnovative Energy Harvesting TechnologiesAdvanced Sensor and Energy Harvesting MaterialsEnergy Harvesting in Wireless Networks