M.J. Brennan scite author profile

The benefits of using a non-linear stiffness in an energy harvesting device comprising a mass-spring-damper system are investigated. Analysis based on the principle of conservation of energy reveals a fundamental limit of the effectiveness of any non-linear device over a tuned linear device for such an application. Two types of non-linear stiffness are considered. The first system has a non-linear bi-stable snap-through mechanism. This mechanism has the effect of steepening the displacement response of the mass as a function of time, resulting in a higher velocity for a given input excitation. Numerical results show that more power is harvested by the mechanism if the excitation frequency is much less than the natural frequency. The other non-linear system studied has a hardening spring, which has the effect of shifting the resonance frequency. Numerical and analytical studies show that the device with a hardening spring has a larger bandwidth over which the power can be harvested due to the shift in the resonance frequency.

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Finite element prediction of wave motion in structural waveguides

Mace

Duhamel²,

Brennan³

et al. 2005

363

223

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A method is presented by which the wavenumbers for a one-dimensional waveguide can be predicted from a finite element (FE) model. The method involves postprocessing a conventional, but low order, FE model, the mass and stiffness matrices of which are typically found using a conventional FE package. This is in contrast to the most popular previous waveguide/FE approach, sometimes termed the spectral finite element approach, which requires new spectral element matrices to be developed. In the approach described here, a section of the waveguide is modeled using conventional FE software and the dynamic stiffness matrix formed. A periodicity condition is applied, the wavenumbers following from the eigensolution of the resulting transfer matrix. The method is described, estimation of wavenumbers, energy, and group velocity discussed, and numerical examples presented. These concern wave propagation in a beam and a simply supported plate strip, for which analytical solutions exist, and the more complex case of a viscoelastic laminate, which involves postprocessing an ANSYS FE model. The method is seen to yield accurate results for the wavenumbers and group velocities of both propagating and evanescent waves.

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Force and displacement transmissibility of a nonlinear isolator with high-static-low-dynamic-stiffness

Carrella¹,

Brennan²,

Waters³

et al. 2012

International Journal of Mechanical Sciences

421

178

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A study of a nonlinear vibration isolator with a quasi-zero stiffness characteristic

Kovacic

Brennan

Waters

2008

Journal of Sound and Vibration

395

126

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On the design of a high-static–low-dynamic stiffness isolator using linear mechanical springs and magnets

Carrella

Brennan

Waters

et al. 2008

Journal of Sound and Vibration

290

118

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On the jump-up and jump-down frequencies of the Duffing oscillator

Brennan

Kovacic

Carrella

et al. 2008

Journal of Sound and Vibration

213

112

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Background: On Georg Duffing and the Duffing Equation

Kovacic¹,

Brennan²

2011

106

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M.J. Brennan

Static analysis of a passive vibration isolator with quasi-zero-stiffness characteristic

Potential benefits of a non-linear stiffness in an energy harvesting device

Finite element prediction of wave motion in structural waveguides

Force and displacement transmissibility of a nonlinear isolator with high-static-low-dynamic-stiffness

A study of a nonlinear vibration isolator with a quasi-zero stiffness characteristic

On the design of a high-static–low-dynamic stiffness isolator using linear mechanical springs and magnets

On the jump-up and jump-down frequencies of the Duffing oscillator

Background: On Georg Duffing and the Duffing Equation

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