The development of the Internet of Things infrastructure requires the deployment of millions of heterogeneous sensors embedded in the environment. The powering of these sensors cannot be done with wired connections, and the use of batteries is often impracticable. Energy harvesting is the common proposed solution, and many devices have been developed for this purpose, using light, mechanical vibrations, and temperature differences as energetic sources. In this paper we present a novel energy-harvester device able to capture the kinetic energy from a fluid in motion and transform it in electrical energy. This device, named FLEHAP ( FLuttering Energy Harvester for Autonomous Powering ), is based on an aeroelastic effect, named fluttering, in which a totally passive airfoil shows large and regular self-sustained motions (limit cycle oscillations) even in extreme conditions (low Reynolds numbers), thanks to its peculiar mechanical configuration. This system shows, in some centimeter-sized configurations, an electrical conversion efficiency that exceeds 8% at low wind speed (3.5 m/s). By using a specialized electronic circuit, it is possible to store the electrical energy in a super capacitor, and so guarantee self-powering in such environmental conditions.
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机译:物联网基础设施的发展需要在环境中部署数百万个异构传感器。这些传感器的供电无法通过有线连接完成,并且电池的使用通常是不可行的。能量收集是普遍提出的解决方案,为此目的,已经开发了许多设备,它们利用光,机械振动和温差作为能量源。在本文中,我们提出了一种新型的能量收集装置,该装置能够捕获运动中的流体的动能并将其转化为电能。该设备名为FLEHAP(用于自主发电的扑动能量收集器),基于一种称为扑动的气动弹性效应,其中,即使在极端条件(低雷诺数)下,完全被动的机翼也会显示出大而规则的自持运动(极限循环振荡)数字),这要归功于其独特的机械配置。在一些厘米大小的配置中,该系统显示出在低风速(3.5 m / s)时的电转换效率超过8%。通过使用专用的电子电路,可以将电能存储在超级电容器中,从而保证在这种环境条件下的自供电。
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