Nonlinear Modeling and Analysis of a Vertical Springless Energy Harvester

Bendame, Mohamed; Abdel‐Rahman, Eihab

doi:10.1051/matecconf/20120101004

Cited by 7 publications

(11 citation statements)

References 7 publications

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“…Several configurations are possible, with levitation systems [ 21 , 22 ], damping springs [ 23 , 24 ] or high-frequency vibrations [ 25 , 26 ]. Some configurations use springs on top and magnets on the bottom to amplify the damping effect [ 27 ].…”

Section: Introductionmentioning

confidence: 99%

Underwater Energy Harvesting to Extend Operation Time of Submersible Sensors

Faria

Martins

Matos

et al. 2022

Sensors

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A linear electromagnetic energy harvesting device for underwater applications, fabricated with a simple manufacturing process, was developed to operate with movement frequencies from 0.1 to 0.4 Hz. The generator has two coils, and the effect of the combination of the two coils was investigated. The experimental study has shown that the energy capture system was able to supply energy to several ocean sensors, producing 7.77 mJ per second with wave movements at 0.4 Hz. This study shows that this energy is enough to restore the energy used by the battery or the capacitor and continue supplying energy to the sensors used in the experimental work. For an ocean wave frequency of 0.4 Hz, the generator can supply power to 8 sensors or 48 sensors, depending on the energy consumed and its optimization.

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Section: Introductionmentioning

confidence: 99%

Underwater Energy Harvesting to Extend Operation Time of Submersible Sensors

Faria

Martins

Matos

et al. 2022

Sensors

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“…Recent years have shown a substantial increase in computational power and a subsequent decrease in power consumption of small-scale electronics. This has led to increased usage of batterybased mobile electronic devices [1][2][3][4]. However, limited energy densities in batteries hamper widespread adoption of these devices when applications require long lifetimes.…”

Section: Introductionmentioning

confidence: 99%

“…Harvesters, with linear mechanical oscillators, suffer inherent limitations in terms of narrow bandwidth around the fundamental frequency and limited scalability to match the fundamental frequency to ambient vibration frequency upon device integration [14]. Bandwidth enhancements have been achieved through either smooth nonlinear harvesting [15,16], piecewise (non)linear harvesting [3,17], parametric excitation [18], multimodal harvesting [19,20], or frequency up-conversion [8,21] techniques, resulting in increased robustness to nonstationary vibrations. However, strong dependency on vibration magnitudes [17], aperiodicity of solutions [22] and limited low-frequency power generation [14] still limit the practical application of VEHs.…”

Section: Introductionmentioning

confidence: 99%

Design and Numerical Analysis of an Electrostatic Energy Harvester With Impact for Frequency Up-Conversion

Lensvelt

Fey

Mestrom

et al. 2020

Journal of Computational and Nonlinear Dynamics

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Integration of vibration energy harvesters (VEHs) with small-scale electronic devices may form an attractive alternative for relatively large batteries and can, potentially, increase their lifespan. However, the inherent mismatch between a harvester's high-frequency resonance, typically in the range 100−1000 Hz, relative to the available low-frequency ambient vibrations, typically in the range 10–100 Hz, means that low-frequency power generation in microscale VEHs remains a persistent challenge. In this work, we model a novel electret-based, electrostatic energy harvester (EEH) design. In this design, we combine an out-of-plane gap-closing comb (OPGC) configuration for the low-frequency oscillator with an in-plane overlap comb configuration for the high-frequency oscillator and employ impact for frequency up-conversion. An important design feature is the tunability of the resonance frequency through the electrostatic nonlinearity of the low-frequency oscillator. Impulsive normal forces due to impact are included in numerical simulation of the EEH through Moreau's time-stepping scheme which has, to the best of our knowledge, not been used before in VEH design and analysis. The original scheme is extended with time-step adjustments around impact events to reduce computational time. Using frequency sweeps, we numerically investigate power generation under harmonic, ambient vibrations. Results show improved low-frequency power generation in this EEH compared to a reference EEH. The EEH design shows peak power generation improvement of up to a relative factor 3.2 at low frequencies due to the occurrence of superharmonic resonances.

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“…In [El Aroudi et al, 2013a], this system was reconsidered and its dynamical behavior was studied by time-domain and frequency-domain numerical simulations using long-time integration performed on a continuoustime PWL model. Other studies dealing with PWL systems that can be used as energy harvesters can be found in [Bendame and Abdel-Rahman, 2012], [Soliman et al, 2008] where a prototype of an electromagnetic micro generator is designed and analyzed both numerically and experimentally. PWL switched systems constitute a special class of hybrid systems [Liberzon, 2003] and arise often in practical control systems when some nonlinear components such as switching, dead-zone, saturation, relays, and hysteresis are encountered.…”

Section: Introductionmentioning

confidence: 99%

Analysis of Bifurcation Behavior of a Piecewise Linear Vibrator with Electromagnetic Coupling for Energy Harvesting Applications

Aroudi

Ouakad

Benadero

et al. 2014

Int. J. Bifurcation Chaos

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Recently, nonlinearities have been shown to play an important role in increasing the extracted energy of vibration-based energy harvesting systems. In this paper, we study the dynamical behavior of a piecewise linear (PWL) spring-mass-damper system for vibration-based energy harvesting applications. First, we present a continuous time single degree of freedom PWL dynamical model of the system. Different configurations of the PWL model and their corresponding state-space regions are derived. Then, from this PWL model, extensive numerical simulations are carried out by computing time-domain waveforms, state-space trajectories and frequency responses under a deterministic harmonic excitation for different sets of system parameter values. Stability analysis is performed using Floquet theory combined with Fillipov method, Poincaré map modeling and finite difference method (FDM). The Floquet multipliers are calculated using these three approaches and a good concordance is obtained among them. The performance of the system in terms of the harvested energy is studied by considering both purely harmonic excitation and a noisy vibrational source. A frequency-domain analysis shows that the harvested energy could be larger at low frequencies as compared to an equivalent linear system, in particular for relatively low excitation intensities. This could be an advantage for potential use of this system in low frequency ambient vibrational-based energy harvesting applications.

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Nonlinear Modeling and Analysis of a Vertical Springless Energy Harvester

Cited by 7 publications

References 7 publications

Underwater Energy Harvesting to Extend Operation Time of Submersible Sensors

Underwater Energy Harvesting to Extend Operation Time of Submersible Sensors

Design and Numerical Analysis of an Electrostatic Energy Harvester With Impact for Frequency Up-Conversion

Analysis of Bifurcation Behavior of a Piecewise Linear Vibrator with Electromagnetic Coupling for Energy Harvesting Applications

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