一种激光可调压电能量采集器

2015 Symposium on Piezoelectricity, Acoustic Waves, and Device Applications (SPAWDA) Pub Date : 2015-10-01 DOI:10.1109/SPAWDA.2015.7364444

D. Guo, Huiyu Li, H. Tzou

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引用次数: 1

摘要

在这项研究中，提出了一种由光激活形状记忆聚合物(LaSMP)操纵的可调谐压电能量收集器。叠层悬臂梁由弹性衬底、光激活形状记忆聚合物层和用作能量收集器的压电片组成。LaSMP层在紫外光照射下可以改变杨氏模量，通过LaSMP的模量变化函数调节收割机的固有频率。调谐后的收割机固有频率可以与外部基极激励频率相匹配，从而实现宽带共振能量收集响应。对于第一种模式，当固有频率从6.12Hz增加到5.94Hz时，有效功率从1.18×10-4μW增加到1.3×10-3μW。对于第二种模式，有效功率从0.003μW增加到0.0304μW;对于第三种模式，有效功率从0.0086μW增加到0.0879μW。

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A laser tunable piezoelectric energy harvester

In this study, a tunable piezoelectric energy harvester manipulated by the light-activated shape memory polymer (LaSMP) is presented. A laminated cantilever beam consists of an elastic substrate, a light-activated shape memory polymer layer and piezoelectric patches is used as energy harvester. LaSMP layer could change its Young's modulus under the exposure of UV lights and harvester's natural frequency is regulated through the modulus change function of LaSMP. The tuned natural frequency of the harvester could match the external base excitation frequency and thus to achieve broadband resonance energy harvesting responses. For the first mode, the effective power increases from 1.18×10-4μW to 1.3×10-3μW when the natural frequency changes from 6.12Hz to 5.94Hz. For the second mode, the effective power increases from 0.003μW to 0.0304μW and for the third mode, it increases from 0.0086μW to 0.0879μW.

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2015 Symposium on Piezoelectricity, Acoustic Waves, and Device Applications (SPAWDA)

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