用于低频能量收集的高效聚偏氟乙烯(PVDF)纳米发电机

E. Ghafari, T. Nantung, Na Lu
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引用次数: 6

摘要

在低频范围内有丰富的机械能,利用压电能量采集器可以直接转化为电能。然而,很少有压电能量采集器在低频范围内具有很高的转换效率。本研究旨在开发一种高效的压电纳米发电机,用于PVDF聚合物的低频能量收集应用。利用机械振动装置对PVDF装置进行能量收集的可行性进行了评估。此外,还研究了幅值和频率对PVDF能量采集器输出电压的影响。结果表明,该装置的最佳频率范围为45 Hz。结果表明,由于PVDF纳米纤维没有足够的时间从诱导应变中恢复,输出电压开始以更高的频率衰减。振幅的变化对压电器件的输出电压有很大的影响。由于诱导应变量的增加,PVDF器件的电压输出随振幅的增加而增强。实际上,感应应变的量是可用机械能的主要来源,可以输入压电装置转换为电能。结果清楚地表明,频率和幅值都会影响压电器件的输出电压。在30 ~ 45hz的频率范围内可以获得最高的电压输出。研究论文
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An Efficient Polyvinylidene Fluoride (PVDF) Nanogenerator for Energy Harvesting in Low Frequency Range
There are abundant mechanical energy available in low frequency range, which can be directly converted into electricity using piezoelectric energy harvester. However, very few piezoelectric energy harvester have high conversion efficiency at low frequency range. This study aims to develop an efficient piezoelectric nanogenerator which can be used in low frequency range for energy harvesting applications using PVDF polymers. The feasibility of using PVDF device for energy harvesting was assessed by using a mechanical vibration setup. In addition, the effect of both amplitude and frequency on the voltage output of the PVDF energy harvester has been studied. According to the results, the optimized frequency range for the device was found to be 45 Hz. The results indicated that the voltage output starts to decay at a higher frequency which can be due to the insufficient time for the PVDF nanofiber to be recovered from the induced strain. The variation of the amplitude has a great influence on the voltage output of the piezoelectric device. The voltage output of the PVDF device is enhanced with increasing the amplitude due to the higher amount of induced strain. In fact, the amount of induced strain is the primary source of the available mechanical energy which can be fed into the piezoelectric device to be converted to the electrical energy. The results clearly show that both frequency and amplitude can affect the voltage output of the piezoelectric device. The highest obtained voltage output can be obtained at the frequency range between 30-45 Hz. RESEARCH PAPER
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