Method for controlling vibration by exploiting piecewise-linear nonlinearity in energy harvesters

Tien, Meng-Hsuan; D’Souza, Kiran

doi:10.1098/rspa.2019.0491

Cited by 10 publications

(9 citation statements)

References 49 publications

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“…With these values determined, the entire vibration cycle for any gap size can be constructed. For a more detailed explanation of the BAA method, refer to previous works on this topic [34,35].…”

Section: (B) System Dynamicsmentioning

confidence: 99%

“…This process is then repeated during the operation of the device. The previous computational study showed that this design performs more effectively than many other VEHs for a number of cases since it can operate efficiently for a wide variety of excitation conditions [34].…”

Section: Introductionmentioning

confidence: 99%

“…In order to overcome these obstacles to effective energy harvesting, a new PWL nonlinear harvester has recently been proposed and numerically investigated [34]. In the proposed design, an actively controlled mechanical stopper is positioned across from the traditional linear VEH.…”

mentioning

confidence: 99%

“…These results are then compared with the computational predictions. Modifications were made to the previous idealized computational model presented in [34] to account for parameters not considered in the previous idealized study. The remainder of this work is organized as follows.…”

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confidence: 99%

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Frequency tunable electromagnetic vibration energy harvester using piecewise linear nonlinearity

Veney,

D’Souza

2023

Proc. R. Soc. A.

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Vibration energy harvesting is increasingly being seen as a viable energy source to provide for our energy-dependent society. There has been great interest in scavenging previously unused or wasted energy in a large variety of systems including vibrating machinery, ocean waves and human motion. In this work, a bench-top system of a piecewise-linear nonlinear vibration energy harvester is studied. A similar idealized model of the system had previously been studied numerically, and in this work the method is adjusted to better account for the physical system. This new design is able to actively tune the system’s resonant frequency to match the current excitation through the adjustment of the gap size between the oscillator and mechanical stopper; thus maximizing the system response over a broad frequency range. This design shows an increased effective frequency bandwidth compared with traditional linear systems and improves upon current nonlinear designs that are less effective than linear harvesters at resonance. In this paper, the physical system is tested at various excitation conditions and gap sizes to showcase the new harvester design’s effectiveness.

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Section: (B) System Dynamicsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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confidence: 99%

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confidence: 99%

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Frequency tunable electromagnetic vibration energy harvester using piecewise linear nonlinearity

Veney,

D’Souza

2023

Proc. R. Soc. A.

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“…Yao et al [23] attached a nonlinear energy sink (NES) with piecewise linear stiffness to suppress the vibration of a forced primary vibration system, and the effectiveness of the NES was proven by experiments. In design of energy harvesters, Tien and D'souza [24] proposed a new vibration harvester composed of a piecewise linear oscillator and an adjustable gap, which has an optimal vibration performance over a broad frequency range and the best performance at resonance. Zhang et al [25] experimentally designed a vibration harvester with piecewise linear stiffness characteristic, which may work in a broadband and low-frequency range.…”

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confidence: 99%

Experimental Modelling and Amplitude-Frequency Response Analysis of a Piecewise Linear Vibration System

Sun

2021

IEEE Access

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The amplitude-frequency response of a nonlinear vibration system with the coexistence of stiffness and viscous damping piecewise linearities are analysed by means of analytical, numerical and experimental investigations. First, a mechanical model of the piecewise linear system under simple harmonic base excitation is established, and the amplitude-frequency response equation is obtained by the averaging method. Second, an experimental device is built to realize the piecewise linear system. The stiffness and damping coefficients are identified by the least square method. Third, case studies are conducted to illustrate the effect of the clearance and base excitation amplitude on the amplitude-frequency response. The experimental results show that the introduction of the piecewise linear stiffness and damping significantly decreases the response amplitude at the primary resonance. The piecewise linear stiffness, damping coefficients, primary resonance frequency and frequency range of the bi-stable state depend on the clearance and excitation amplitude. The experimental results are consistent with the theoretical predictions and numerical simulation results of the method of backward differentiation formulas. This research provides instructive ideas to the design of the nonlinear isolator in practical engineering.

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Improving the performance of a two-sided vibro-impact energy harvester with asymmetric restitution coefficients

Dulin

Lin

Serdukova

et al. 2022

International Journal of Mechanical Sciences

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Method for controlling vibration by exploiting piecewise-linear nonlinearity in energy harvesters

Cited by 10 publications

References 49 publications

Frequency tunable electromagnetic vibration energy harvester using piecewise linear nonlinearity

Frequency tunable electromagnetic vibration energy harvester using piecewise linear nonlinearity

Experimental Modelling and Amplitude-Frequency Response Analysis of a Piecewise Linear Vibration System

Improving the performance of a two-sided vibro-impact energy harvester with asymmetric restitution coefficients

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