Litcius/Paper detail

Cantilever-based ferroelectret energy harvesting

Omar Ben Dali, Perceval Pondrom, G. M. Sessler, Sergey Zhukov, Heinz von Seggern, Xiaoqing Zhang, Mario Kupnik

2020Applied Physics Letters30 citationsDOI

Abstract

We present a vibrational energy harvester with fluorinated ethylene propylene (FEP)-ferroelectrets working in d31 mode. The ferroelectret film consists of two FEP films, fused together to form a parallel tunnel structure with well-defined air gaps. Its dynamic piezoelectric g31 coefficient is 0.7 V m N−1. The energy-harvesting device is an air-spaced cantilever arrangement that was produced by the additive manufacturing technique. The device was tested by exposing it to sinusoidal vibrations with an acceleration a, generated by a shaker. The measurement shows a resonance at about 35 Hz and a normalized output power of 320 μW for a seismic mass of 4.5 g at an acceleration of 0.1 g (g is the gravity of the earth). This demonstrates a significant improvement of air-spaced vibrational energy harvesting with ferroelectrets and greatly exceeds previous performance data for polymer cantilever devices.

Topics & Concepts

CantileverEnergy harvestingMaterials sciencePiezoelectricityAccelerationShakerVibrationComposite materialAcousticsResonatorPower (physics)OptoelectronicsPhysicsClassical mechanicsThermodynamicsInnovative Energy Harvesting TechnologiesAdvanced Sensor and Energy Harvesting MaterialsDielectric materials and actuators