Harvesting biomechanical energy from human’s movement is an alternative solution to effectively power the wearable electronics. In this paper, two impact-driven piezoelectric energy harvesters were developed which can be integrated within human shoe-soles and also can be tailored to integrate in commercial carpets or outdoor roadway to harvest the massive mechanical energy from the passing vehicles or people crowds at low frequencies. For a comprehensive study, two buckling types of PVDF harvesters were selected and tested. It has been shown that the mechanical responses of the arch type prototype and the C type prototype are different. In addition, the mechanical response of the C type can be affected by the vertical height of the C type. The peak-peak voltage of the C type increases with the vertical height of the C type decreases. The peak-peak voltage of arch type is almost the same with the C type when the vertical height of which is 25 mm. The stability of the output voltage of the arch type is the worst when compared with that of the three C types. The stability of the output voltage of the C type when the vertical height of which is 25 mm is the worst among the three different vertical heights
Abstract. The conversion of biomechanical energy from human movement into useful electrical energy to power wearable electronics has become a topic of extensive study. This paper studies a model suitable to design and characterize 33-mode energy harvester based on piezoelectric polymers for wearable applications. The aim is to describe adequately the 33-mode energy harvester behavior, with a reasonable number of parameters and based on well-known physical equations. The connection mode is been considered and the corresponding open circuit total voltages are derived, which are verified by the experiments. Moreover, the experiments prove that all the three harvesters can be used to scavenging energy. IntroductionWeareable electronics are becoming smaller and increasingly widely used, resulting in an increasing research on the development of harvesting energy from human motion to provide renewable and clean energy [1][2][3]. According to previous research, it is identified as a feasible way to harvest energy from human foot which can produce great mechanical energy.There are many energy harvesters mounted in shoes based on different mechanisms, such as electromagnetic, electrostatic, thermoelectric, nano-triboelectric, piezoelectric harvesters. Specifically, piezoelectric energy harvester can convert mechanical energy into electric power directly, thus it owns a simpler structure and easier fabrication [1,4]. Hence, it can be especially suitable for wearable sensors.Kymissis, et al.[5]explored an insole which made of eight-layer stacks of PVDF sheets with a flexible plastic substrate, to harness the energy dissipated in bending of the sole and a PZT unimorph to tap the energy from heel strikes. Zhao et al. [1,6] proposed a sandwich structure PVDF energy harvester which is readily compatible with a shoe and works in the 31-mode and studied a series of models. Mateu et al. [7] did a study for different piezoelectric beam structures made of PVDF and found that triangular cantilever generates more energy than the rectangular shape.As discussed above, 31-mode energy harvester for wearable applications has been studied widely. The studies are rarely conducted in 33-mode harvester for it's difficult to implement in a real structure, but with the reduction of power consumption of wearable applications, the 33-mode can meet its needs. In this research, in order to study the 33-mode harvester for wearable applications, the insole is chosen as a good place for the 33-mode harvester to implant. A sandwich structure thin flat harvester is designed for it can be fitted without any sacrifice of comfort or radical alterations in design, which is readily compatible with a shoe. To obtain higher power, parallel and series configurations of the piezoelectric film are taken into consider, so two segmented electrode harvesters consisted of two equal area PVDF
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