Energy harvesting is a promising technology that powers the electronic devices via scavenging the ambient energy. Piezoelectric energy harvesters have attracted considerable interest for their high conversion efficiency and easy fabrication in minimized sensors and transducers. To improve the output capability of energy harvesters, properties of piezoelectric materials is an influential factor, but the potential of the material is less likely to be fully exploited without an optimized configuration. In this paper, an optimization strategy for PVDF-based cantilever-type energy harvesters is proposed to achieve the highest output power density with the given frequency and acceleration of the vibration source. It is shown that the maximum power output density only depends on the maximum allowable stress of the beam and the working frequency of the device, and these two factors can be obtained by adjusting the geometry of piezoelectric layers. The strategy is validated by coupled finite-element-circuit simulation and a practical device. The fabricated device within a volume of 13.1 mm3 shows an output power of 112.8 μW which is comparable to that of the best-performing piezoceramic-based energy harvesters within the similar volume reported so far.
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机译:能量收集是一种有前途的技术,可通过清除环境能量为电子设备供电。压电能量采集器以其高转换效率和易于制造的最小化传感器和换能器引起了人们的极大兴趣。为了提高能量收集器的输出能力,压电材料的性能是一个影响因素,但是如果没有优化的配置,则很难充分利用材料的潜力。本文提出了一种基于PVDF的悬臂式能量收集器的优化策略,以在给定的频率和振动源加速度下实现最高的输出功率密度。结果表明,最大功率输出密度仅取决于梁的最大允许应力和装置的工作频率,这两个因素可以通过调整压电层的几何形状来获得。该策略通过耦合有限元电路仿真和实际设备进行了验证。在体积为13.1 mm 3 的情况下制造的设备显示出112.8μW的输出功率,与迄今为止报道的相似体积中性能最佳的基于压电陶瓷的能量采集器相当。
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