Experimental characterisation of dual-mass vibration energy harvesters employing velocity amplification

Ronan Frizzell, Gerard Kelly, Francesco Cottone, Elisabetta Boco, Valeria Nico, Declan O'Donoghue, Jeff Punch

Research output: Contribution to journalArticlepeer-review

Abstract

Vibration energy harvesting extracts energy from the environment and can mitigate reliance on battery technology in wireless sensor networks. This article presents the nonlinear responses of two multi-mass vibration energy harvesters that employ a velocity amplification effect. This amplification is achieved by momentum transfer from larger to smaller masses following impact between masses. Two systems are presented that show the evolution of multi-mass vibration energy harvester designs: (1) a simplified prototype that effectively demonstrates the basic principles of the approach and (2) an enhanced design that achieves higher power densities and a wider frequency response. Various configurations are investigated to better understand the nonlinear dynamics and how best to realise future velocity-amplified vibration energy harvesters. The frequency responses of the multi-mass harvesters show that these devices have the potential to reduce risks associated with deploying vibration energy harvester devices in wireless sensor network applications; the wide frequency response reduces the need to re-Tune the harvesters following frequency variations of the source vibrations.

Original languageEnglish
Pages (from-to)2810-2826
Number of pages17
JournalJournal of Intelligent Material Systems and Structures
Volume27
Issue number20
DOIs
Publication statusPublished - Dec 2016

Keywords

  • electromagnetic transduction
  • multiple masses
  • nonlinear oscillator
  • vibration energy harvesting

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