Analysis and application of the piezoelectric energy harvester on light electric logistics vehicle suspension systems

Zhao, Zhen; Wang, Tie; Shi, Jinhong; Zhang, Baifu; Zhang, Ruiliang; Li, Meng; Wen, Yonggang

doi:10.1002/ese3.456

Cited by 30 publications

(13 citation statements)

References 30 publications

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“…The harvested energy from the vehicles could be directly utilized or stored in a car battery [50][51][52]. The batteries will be self-charged as the car moves and excited by road irregularities.…”

Section: Figure 10 the Variation Of The Average Dissipated Power By mentioning

confidence: 99%

Energy harvesting from car suspension system: Mathematical approach for half car model

Darabseh¹,

Al-Yafeai²,

Mourad³

2021

JMES

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A significant contribution of this paper is developing a half car model with a built-in piezoelectric stack to evaluate the potential of harvesting power from the car suspension system. The regenerative car suspension system is modelled mathematically using Laplace transformation and simulated using MATLAB/Simulink. Two piezoelectric stacks are installed in series with the front and rear suspension springs to maintain the performance of the original suspension system in ride quality and comfortability. Half car model is subjected under harmonic excitation with acceleration of 0.5 g and velocity of 9.17 rad/s. The harvested voltage and power are tested in both time, and frequency domain approaches. The influence of the different parameters of the piezoelectric stack (number of stack layers and area to thickness) and car suspension (sprung and unsprung stiffness and damping coefficients) are examined. Also, the effect of road amplitude unevenness is considered. The results illustrate that the maximum generated voltage and power at the excitation frequency of 1.46 Hz are 33.51 V and 56.25 mW, respectively.

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Section: Figure 10 the Variation Of The Average Dissipated Power By mentioning

confidence: 99%

Energy harvesting from car suspension system: Mathematical approach for half car model

Darabseh¹,

Al-Yafeai²,

Mourad³

2021

JMES

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“…Furthermore, the vibrations generated from a vehicle's travel can be converted into electricity in order to be either utilized or stored in a battery [53,[162][163][164]. The utilization of the harvested energy would be more beneficial to electric vehicles as they use a battery to cause their movement.…”

Section: Utilization Of the Harvested Energymentioning

confidence: 99%

A State-Of-The-Art Review of Car Suspension-Based Piezoelectric Energy Harvesting Systems

2020

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One of the most important techniques for energy harvesting is the clean energy collection from the ambient vibration. Piezoelectric energy harvesting systems became a hot topic in the literature and attracted most researchers. The reason behind this attraction is that piezoelectric materials are a simple structure and provide a higher power density among other mechanisms (electromagnetic and electrostatic). The aim of this manuscript is to succinctly review and present the state of the art of different existing vibrational applications utilizing piezoelectric energy harvesting technique. Meanwhile, the main concentration is harvesting energy from a vehicle suspension system. There is a significant amount of dissipated energy from the suspension dampers that is worthy of being harvested. Different mathematical car models with their experimental setup are presented, discussed, and compared. The piezoelectric material can be mounted in different locations such as suspension springs, dampers, and tires. The technique of implementing the harvester and the amount of power harvested from each location are analyzed. The evaluation of the electrical harvesting circuits and different storage devices for the harvested power are also discussed. The paper will also shed light on the variety of potential applications of the harvested energy.

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“…Daily human activities show possible energy harvesting examples such as talking, walking, running, heart pumping, knee bending, driving vehicles, etc. [14][15][16][17] A promising way to harvest this wasted Ratanak Lay holds a Bachelor of Chemical & Materials Engineering from the University of Auckland. For his fourth-year project, he undertook research to investigate the effect of teeth's exposure to coke on its mechanical properties.…”

Section: Introductionmentioning

confidence: 99%

The intrinsic piezoelectric properties of materials – a review with a focus on biological materials

2021

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Analysis and application of the piezoelectric energy harvester on light electric logistics vehicle suspension systems

Cited by 30 publications

References 30 publications

Energy harvesting from car suspension system: Mathematical approach for half car model

Energy harvesting from car suspension system: Mathematical approach for half car model

A State-Of-The-Art Review of Car Suspension-Based Piezoelectric Energy Harvesting Systems

The intrinsic piezoelectric properties of materials – a review with a focus on biological materials

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