Optimised Vibration Energy Harvesting for Aerospace Applications

O.J. Wood; C.A. Featherston; D. Kennedy; Mark J. Eaton; Rhys Pullin

doi:10.4028/www.scientific.net/KEM.518.246

Paper Titles

Monimost - Integrated SHM System for Railway Truss Bridges
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Monitoring System for Determination of Vibrations of Different Building Structures during Driving in Reinforced Concrete Pre-Cast Piles and Sheet Piles
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Non-Destructive Testing of Building Objects Positioned in the Area of Coal Exploitation
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Non-Invasive Methods of Delamination Monitoring in Multi-Layer Structures
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Optimised Vibration Energy Harvesting for Aerospace Applications
p.246

Practical Application of Monitoring System Based on Optical Sensors for Marine Constructions
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Practical Solution of Rail Vehicle and Track Dynamics Monitoring System
p.271

Rail Vehicle's Suspension Monitoring System - Analysis of Results Obtained in Tests of the Prototype
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SHM System Based on Modal Filtration
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HomeKey Engineering MaterialsKey Engineering Materials Vol. 518Optimised Vibration Energy Harvesting for...

Optimised Vibration Energy Harvesting for Aerospace Applications

Abstract:

Accurate knowledge regarding the ongoing condition of an aircraft’s structural condition together with future life predictions enable optimal use of material, hence reducing mass, cost and environmental effects. Previous work by the authors has demonstrated the potential for using energy harvested from vibrating aircraft panels to power a self contained health monitoring system based on the use of wireless sensor nodes for an aircraft structure. However the system proposed was far from optimal. Research is being undertaken to investigate the various factors affecting the power output of such a system, including the design of the harvesters used (length, width, number of layers), their positioning and their orientation. The work presented in this paper enables the determination of the optimised positions for a series of harvesters on a representative aircraft panel, based on the use of shape functions for the various modes of vibration over the expected frequency range, to derive a function related to power output which is then optimised. A series of recommendations are made.

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Periodical:

Key Engineering Materials (Volume 518)

Pages:

246-260

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.518.246

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Online since:

July 2012

Authors:

O.J. Wood, C.A. Featherston, D. Kennedy, Mark J. Eaton, Rhys Pullin

Keywords:

Energy Harvesting, Optimization, Piezoelectric, Vibration

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