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

Frizzell, Ronan; Kelly, Gerard; Cottone, F.; Boco, Elisabetta; Nico, Valeria; O’Donoghue, Declan; Punch, Jeff

doi:10.1177/1045389x16642030

Cited by 6 publications

(7 citation statements)

References 21 publications

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“…The equivalent dynamic of the whole system can be considered as a second order linear system, see Equation (24). The chosen output is the rotational speed of the cylinder, because the extracted power depends on it.…”

Section: Piezoelectric Power Controlmentioning

confidence: 99%

“…According to Cottone [6], non-linear oscillators can offer the option of broadening the response of vibration energy systems, in that way they can physically respond to changes in driving frequency, Uzun et al [23]. They can also harvest energy from sources where vibrations are present in several frequencies, see Frizzell et al [24] and Cottone et al [25], and [26]. Dong et al [27] developed a new energy harvesting device based on two side-by-side flexible plates.…”

Section: Introductionmentioning

confidence: 99%

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Power Control Optimization of an Underwater Piezoelectric Energy Harvester

et al. 2018

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Abstract:Over the past few years, it has been established that vibration energy harvesters with intentionally designed components can be used for frequency bandwidth enhancement under excitation for sufficiently high vibration amplitudes. Pipelines are often necessary means of transporting important resources such as water, gas, and oil. A self-powered wireless sensor network could be a sustainable alternative for in-pipe monitoring applications. A new control algorithm has been developed and implemented into an underwater energy harvester. Firstly, a computational study of a piezoelectric energy harvester for underwater applications has been studied for using the kinetic energy of water flow at four different Reynolds numbers Re = 3000, 6000, 9000, and 12,000. The device consists of a piezoelectric beam assembled to an oscillating cylinder inside the water of pipes from 2 to 5 inches in diameter. Therefore, unsteady simulations have been performed to study the dynamic forces under different water speeds. Secondly, a new control law strategy based on the computational results has been developed to extract as much energy as possible from the energy harvester. The results show that the harvester can efficiently extract the power from the kinetic energy of the fluid. The maximum power output is 996.25 µW and corresponds to the case with Re = 12,000.

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Section: Piezoelectric Power Controlmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Power Control Optimization of an Underwater Piezoelectric Energy Harvester

et al. 2018

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“…Frizzell et al. 56 achieved velocity amplification through impact-driven momentum transfer to deliver 17 mW of power for 1 g acceleration at 24 Hz. Hadas et al.…”

Section: Resultsmentioning

confidence: 99%

Design and analysis of switchable magnetic polarity bistable energy harvester

Satpute¹,

Jugulkar

Satpute³

et al. 2018

Proceedings of the Institution of Mechanical Engineers, Part C:

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Multistable vibration harvesters that involve repelling magnet force result in improved efficiency over a wider bandwidth in comparison to the conventional resonant devices. However, the dynamic performance of the vibration harvester can be further improved by switching the magnetic force polarity to ensure pull force on the mass as it moves towards the mean position. In the presented work, the design and analysis of a switching polarity bistable harvester has been presented, which changes the magnetic interaction polarity in order to improve power output as well as efficient operational bandwidth. An innovative mechanism has been developed to operate the harvester with switching polarity for higher base acceleration amplitude. The proposed design has integrated switchable polarity magnetic interaction and rotary electric generator which is driven by a compound gear train in the conventional spring-mass harvester. Analytical and numerical simulations have been formulated to illustrate efficient operational characteristics over the operating frequency band and to determine the optimum electrical damping coefficient. Effects of magnetic interaction force, the inertia of the switching mechanism and gears have been considered in the numerical analysis. A prototype delivered the peak power of 1.49 W at the resonance frequency and exhibited 50% increase in power in comparison to fixed polarity design.

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“…There is no doubt that velocity amplification contributes to enhancing the generating performance because the induced voltage is proportional to the relative moving velocity of the magnet to the induction coil. O'Donoghue et al [19,20] demonstrated that the 2DOF system generated the highest output voltage under the forced excitation compared to the 3DOF and 4DOF. This system also presented an absolute advantage over the traditional 2DOF linked system in terms of output power.…”

Section: Introductionmentioning

confidence: 99%

Design and Research on a Nonlinear 2DOF Electromagnetic Energy Harvester With Velocity Amplification

Liu

Jin

et al. 2020

IEEE Access

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In order to power the microelectronic devices of the Internet of Things in the low-frequency broadband vibration environment, a novel nonlinear 2DOF electromagnetic energy harvester was proposed based on the magnetic levitation structure and velocity amplification mechanism. The electromechanical coupling model was established and numerically simulated to analyze the generating characteristics. A prototype was fabricated and tested to verify the theoretical model. The influences of the key parameters, including the gap between the suspended magnet and the lower spring, excitation acceleration, spring stiffness, mass of copper cylinder, on the generating characteristics were studied. When it was subjected to a harmonic excitation with acceleration amplitude of 0.8g, the measured open-circuit voltage reached peaks of 3.13 V at 8 Hz and 2.93 V at 13.5 Hz, respectively. The optimal output power at 8 Hz was 10.18 mW with the matched load resistance of 250 Ω. Both the experimental and theoretical results demonstrated that this novel electromagnetic energy harvester had obvious advantages in increasing the output power and widening the bandwidth. INDEX TERMS Electromagnetic energy harvester, low frequency, velocity amplification, broadband.

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

Cited by 6 publications

References 21 publications

Power Control Optimization of an Underwater Piezoelectric Energy Harvester

Power Control Optimization of an Underwater Piezoelectric Energy Harvester

Design and analysis of switchable magnetic polarity bistable energy harvester

Design and Research on a Nonlinear 2DOF Electromagnetic Energy Harvester With Velocity Amplification

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