Power amplification via compliant layer interdigitation and dielectrophoretic structuring of PZT particle composites

The evolution of portable electronics has led to recent popularity of piezoelectric materials for energy harvesting, especially for devices deployed remotely or in vivo. The efficiency of piezoelectric generators harvesting energy from the human body is lacking due to off-resonance loading. Piezoele...

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Bibliographic Details
Published in:Smart materials and structures 2020-07, Vol.29 (7), p.75004
Main Authors: Pessia, Zachary R, Cunningham, Craig A, Krech, E D, Friis, E A
Format: Article
Language:English
Subjects:
composite
dielectrophoresis
energy harvesting
particles
piezoelectric
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Summary:The evolution of portable electronics has led to recent popularity of piezoelectric materials for energy harvesting, especially for devices deployed remotely or in vivo. The efficiency of piezoelectric generators harvesting energy from the human body is lacking due to off-resonance loading. Piezoelectric ceramics are expensive to manufacture and are dense, brittle, and difficult to use in high strain environments. Piezoelectric composites composed of ferroelectric particles distributed in a polymer matrix are desirable due to low cost and tunable properties. In this study, Compliant Layer Adaptive Composite Stacks (CLACS) made with thin piezoelectric composite layers structured by dielectrophoresis (DEP) were investigated to increase the energy harvesting efficiency at low frequency loading. To predict power generation capabilities, a theoretical model was developed by using established particle composite models in conjunction with a shear lag structural mechanics model for CLACS. Granular composite discs of lead zirconate titanate particles in an epoxy matrix were manufactured at a 50% volume fraction and structured by DEP, if applicable. CLACS were manufactured using composite discs and two compliant layer thicknesses. The stacks were electromechanically tested by varying load, frequency, and resistance. Experimental results showed a significant increase in power amplification with DEP structured discs and compliant layer interdigitation. In addition, the theoretical model accurately predicts power production for both 0-3 and 1-3 CLACS at low frequencies. DEP structured particle composite CLACS can provide a method of energy harvesting for devices in remote locations, especially in low frequency high strain environments.
ISSN:0964-1726
1361-665X
DOI:10.1088/1361-665X/ab85a5