Artificial piezoelectric grass for energy harvesting from turbulence-induced vibration

• Published in: Smart materials and structures Vol. 21; no. 10; pp. 105024 - 1-10
• Main Authors: Hobeck, J D, Inman, D J
• Format: Journal Article
• Language: English
• Published: Bristol IOP Publishing 01.10.2012; Institute of Physics
• Subjects: Computational fluid dynamics; Exact sciences and technology; Fluid flow; General equipment and techniques; Grasses; Harvesting; Instruments, apparatus, components and techniques common to several branches of physics and astronomy; Physics; Piezoelectricity; Transducers; Turbulence; Turbulent flow; Vibration; Turbulence; Statistical analysis; Turbulent flow; Wind tunnels; Unimorph transducer; Fluid flow; Energy recovery; PZT; Velocity; Cantilever beam; High pressure; Vibrations; Piezoelectric transducers; Analytical method; Mathematical models; Fluidics
• ISSN: 0964-1726; 1361-665X
• DOI: 10.1088/0964-1726/21/10/105024

The primary objective of this research is to develop a deploy-and-forget energy harvesting device for use in low-velocity, highly turbulent fluid flow environments i.e. streams or ventilation systems. The work presented here focuses on a novel, lightweight, highly robust, energy harvester design referred to as piezoelectric grass. This biologically inspired design consists of an array of cantilevers, each constructed with piezoelectric material. When exposed to proper turbulent flow conditions, these cantilevers experience vigorous vibrations. Preliminary results have shown that a small array of piezoelectric grass was able to produce up to 1.0 mW per cantilever in high-intensity turbulent flow having a mean velocity of 11.5 m s−1. According to the literature, this is among the highest output achieved using similar harvesting methods. A distributed parameter model for energy harvesting from turbulence-induced vibration will be introduced and experimentally validated. This model is generalized for the case of a single cantilever in turbulent cross-flow. Two high-sensitivity pressure probes were needed to perform spectral measurements within various turbulent flows. The design and performance of these probes along with calibration and measurement techniques will be discussed.