Abstract
Low-flow air has been attracted many researchers which can be transformed into electric energy by the piezoelectric materials. A flow amplifier device can be used to increase the performance of piezoelectric energy harvester excited by low-flow air. The Coanda effect theory has been analyzed based on the fast-moving air. To analyze the effect of the amplifier device and verify the feasibility of the proposed cantilevered PVDF energy harvester, we employed finite element simulation to analyze the flow distribution of the amplified flow air. Then the stress and potential distribution of PVDF film have been analyzed. A prototype of the cantilevered PVDF energy harvester is tested with different variables such as input air flow, pressure and cycle time. The test results show that the output voltage increases with increasing input air flow. The output voltage decreases slightly with increasing input cycle time. The peak voltage decreases as the distance between the prototype and the excitation source increases. Importantly, the output voltage for the amplified airflow is about three-times that of the non-amplified air flow. The maximal output voltage and power are 12.80 V and 19.89 μW at the pressure of 0.2 MPa and a flow rate of 200 L/min, respectively.
Highlights
Harvesting energy from the ambient environment has always been a hot issue and a possible solution against the energy crisis [1], [2]
The aim of this paper is to enhance the generation performance of a cantilevered Polyvinylidene fluoride (PVDF) energy harvester which is impacted by amplified air flow
The cycle time is set at 1.5 s and the distance is set at 1.0 cm
Summary
Harvesting energy from the ambient environment has always been a hot issue and a possible solution against the energy crisis [1], [2]. A kind of new energy harvesting device has attracted more and more attention owing to its simple design, low cost, reliable robustness, environmentally friendliness and abundant friction energy sources [3], [4]. Some of this research has been devoted to improving energy harvesting efficiency, to provide stable energy for self-powered wireless electronic devices [11]–[13]. This would eliminate the issue of battery replacement and disposal [14]–[16].
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