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"Ceramic fiber"

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"Ceramic fiber"

Mechanical Properties and Wind Energy Harvesting Characteristics of PZT-Based Piezoelectric Ceramic Fiber Composites
Min-seon Lee, Jin-woo Park, Young-hun Jeong
J Electr Electron Mater 2021;34(2):90-98.   Published online March 1, 2021
DOI: https://doi.org/10.4313/JKEM.2021.34.2.2
Piezoelectric ceramic fiber composite (PCFC) was fabricated using a planar electrode printed piezoelectric ceramic fiber driven in transverse mode for small-scale wind energy harvester applications. The PCFC consisted of an epoxy matrix material and piezoelectric ceramic fibers sandwiched by interdigitated electrode (IDE) patterned polyimide films. The PCFC showed an excellent mechanical performance under a continuous stress. For the fabrication of PCB cantilever harvester, five -PCFCs were vertically attached onto a flexible printed circuit board (PCB) substrate, and then PCFCs were serially connected through a printed Cu circuit. The energy harvesting performance was evaluated applying an inverted structure, which imples its free leading edge located at an open end but the trailing edge at a clamped end, to enhance strain energy in a wind tunnel. The output voltage of the PCB cantilever harvester was increased as the wind speed increased. The maximum output power was 17.2 μW at a resistance load of 200 kΩ and wind speed of 9 m/s. It is considered that the PCB cantilever energy harvester reveals a potential use for wind energy harvester applications.
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Small-Scale Wind Energy Harvester Using PZT Based Piezoelectric Ceramic Fiber Composite Array
Min-seon Lee, Yong-hyeon Na, Jin-woo Park, Young-hun Jeong
J Electr Electron Mater 2019;32(5):418-425.   Published online September 1, 2019
A piezoelectric ceramic fiber composite (PCFC) was successfully fabricated using 0.69Pb(Zr0.47Ti0.53)O3-0.31[Pb(Zn0.4Ni0.6)1/3Nb2/3]O3 (PZT-PZNN) for use in small-scale wind energy harvesters. The PCFC was formed using an epoxy matrix material and an array of Ag/Pd-coated PZT-PZNN piezo-ceramic fibers sandwiched by Cu interdigitated electrode patterned polyethylene terephthalate film. The energy harvesting performance was evaluated in a custom-made wind tunnel while varying the wind speed and resistive load with two types of flutter wind energy harvesters. One had a five-PCFC array vertically clamped with a supporting acrylic rod while the other used the same structure but with a five-PCFC cantilever array. Stainless steel (thickness: 50 ㎛) was attached onto one side of the PCFC to form the PZT-PZNN cantilever. The output power, in general, increased with an increase in the wind speed from 2 m/s to 10 m/s for both energy harvesters. The highest output power of 15.1 ㎼ at 14 kΩ was obtained at a wind speed of 10 m/s for the flutter wind energy harvester with the PZT-PZNN cantilever array. The results presented here reveal the strong potential for wind energy harvester applications to supply sustainable power to various IoT micro-devices.
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