To maximize the electromechanical transduction of vibratory energy harvesters, the resonance frequency of the harvesting device is usually tuned to the excitation frequency. To achieve this goal, some concepts call for utilizing an axial static preload to soften or stiffen the structure (Leland and Wright, 2006, “Resonance Tuning of Piezoelectric Vibration Energy Scavenging Generators Using Compressive Axial Preload,” Smart Mater. Struct., 15, pp. 1413–1420; Morris et al., 2008, “A Resonant Frequency Tunable, Extensional Mode Piezoelectric Vibration Harvesting Mechanism,” Smart Mater. Struct., 17, p. 065021). For the most part, however, models used to describe the effect of the axial preload on the harvester’s response are linear lumped-parameter models that can hide some of the essential features of the dynamics and, sometimes, oppose the experimental trends. To resolve this issue, this study aims to develop a comprehensive understanding of energy harvesting using axially loaded beams. Specifically, using nonlinear Euler–Bernoulli beam theory, an electromechanical model of a clamped-clamped energy harvester subjected to transversal excitations and static axial loading is developed and discretized using a Galerkin expansion. Using the method of multiple scales, the general nonlinear physics of the system is investigated by obtaining analytical expressions for the steady-state response amplitude, the voltage drop across a resistive load, and the output power. These theoretical expressions are then validated against experimental data. It is demonstrated that in addition to the ability of tuning the harvester to the excitation frequency via axial load variations, the axial load aids in (i) increasing the electric damping in the system, thereby enhancing the energy transfer from the beam to the electric load, (ii) amplifying the effect of the external excitation on the structure, and (iii) enhancing the effective nonlinearity of the device. These factors combined can increase the steady-state response amplitude, output power, and bandwidth of the harvester.
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February 2011
Research Papers
Electromechanical Modeling and Nonlinear Analysis of Axially Loaded Energy Harvesters
Ravindra Masana,
Ravindra Masana
Department of Mechanical Engineering, Nonlinear Vibrations and Energy Harvesting Laboratory (NoVEHL),
Clemson University
, Clemson, SC 29634
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Mohammed F. Daqaq
Mohammed F. Daqaq
Department of Mechanical Engineering, Nonlinear Vibrations and Energy Harvesting Laboratory (NoVEHL),
e-mail: mdaqaq@clemson.edu
Clemson University
, Clemson, SC 29634
Search for other works by this author on:
Ravindra Masana
Department of Mechanical Engineering, Nonlinear Vibrations and Energy Harvesting Laboratory (NoVEHL),
Clemson University
, Clemson, SC 29634
Mohammed F. Daqaq
Department of Mechanical Engineering, Nonlinear Vibrations and Energy Harvesting Laboratory (NoVEHL),
Clemson University
, Clemson, SC 29634e-mail: mdaqaq@clemson.edu
J. Vib. Acoust. Feb 2011, 133(1): 011007 (10 pages)
Published Online: December 17, 2010
Article history
Received:
January 29, 2010
Revised:
May 30, 2010
Online:
December 17, 2010
Published:
December 17, 2010
Citation
Masana, R., and Daqaq, M. F. (December 17, 2010). "Electromechanical Modeling and Nonlinear Analysis of Axially Loaded Energy Harvesters." ASME. J. Vib. Acoust. February 2011; 133(1): 011007. https://doi.org/10.1115/1.4002786
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