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Collectively Exhaustive Hybrid Triboelectric Nanogenerator Based on Flow‐Induced Impacting‐Sliding Cylinder for Ocean Energy Harvesting

Ji‐Seok Kim, Junyoung Kim, Jong‐Nam Kim, Junseong Ahn, Jun‐Ho Jeong, Inkyu Park, Daegyoum Kim, Il‐Kwon Oh

2021Advanced Energy Materials42 citationsDOI

Abstract

Abstract For the sustainable application of remote sensing and monitoring in the ocean environment, energy harvesting technology based on flow‐induced vibration is in the spotlight. Herein, based on the flow‐induced self‐excitation of an impacting‐sliding cylinder, a collectively exhaustive hybrid triboelectric nanogenerator (TENG) is reported, that utilizes both freestanding‐sliding (FS) and contact‐separation (CS) modes. Most importantly, the flow‐induced impacting cylinder (FIC) between two side walls is newly implemented to resolve the critical problem of the lock‐in phenomena occurring in conventional vortex‐induced vibration systems of circular cylinders. Owing to the presence of two side walls, the FIC based TENG (FIC‐TENG) shows a stable electrical power generation in a wide range of flow velocity (0.05–1.02 m s −1 ) without lock‐in phenomena. In addition, the collectively exhaustive FIC‐TENG can be used to continuously produce electric power utilizing both FS and CS hybrid modes. The energy harvesting performance is greatly enhanced by adopting nanopatterns on triboelectric surfaces in the CS mode TENG and a frequency upconversion effect of interdigitated electrodes in the FS mode TENG, resulting in proper remote operation of a wireless fidelity thermometer.

Topics & Concepts

NanogeneratorTriboelectric effectMaterials scienceEnergy harvestingCylinderOptoelectronicsVortex-induced vibrationVibrationVortexPower (physics)AcousticsNanotechnologyPiezoelectricityMechanical engineeringMechanicsComposite materialEngineeringPhysicsQuantum mechanicsAdvanced Sensor and Energy Harvesting MaterialsInnovative Energy Harvesting TechnologiesAdvanced Materials and Mechanics