Electro-mechanical characterization of a piezoelectric energy harvester

•A pavement piezoelectric (PZT) energy harvester design is proposed.•An electromechanical model of the PZT for low frequencies is introduced.•A methodology for characterizing PZT transducers is clearly described.•The estimated power and voltage from the model matches well with experimental data.•The...

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Bibliographic Details
Published in:Applied energy Vol. 253; p. 113585
Main Authors: Khalili, Mohamadreza, Biten, Ayetullah B., Vishwakarma, Gopal, Ahmed, Sara, Papagiannakis, A.T.
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-11-2019
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Summary:•A pavement piezoelectric (PZT) energy harvester design is proposed.•An electromechanical model of the PZT for low frequencies is introduced.•A methodology for characterizing PZT transducers is clearly described.•The estimated power and voltage from the model matches well with experimental data.•The verified model used in Simulink® provides energy harvesting circuit design tool. Energy harvesting consists of capturing untapped ambient energy of various forms, such as mechanical, thermal or solar, and converting it into electrical energy. A significant unexploited source of mechanical energy is from vehicle movement on roadways. This paper presents the development of a piezoelectric energy harvester (PEH) capable of converting mechanical energy from roadways into electricity and uses an electro-mechanical model for characterizing it. The PEH consists of a stack of piezoelectric (PZT) elements connected in parallel. Its electro-mechanical properties were characterized by subjecting it to dynamic loads with peaks ranging from 1.1 to 11 kN and loading frequencies ranging from 2.5 to 62 Hz. The model constants were estimated by fitting a model to experimental data through an error minimization routine. This model is capable of converting load input (N) to voltage output (V) and vice-versa. Its quality of fit was successfully tested in the laboratory using different load amplitudes and frequencies. For an external resistance of 500 kΩ and sinusoidal loads with peaks of 1.1 and 11 kN applied at 66 Hz, the maximum voltage output of one of the PZT stacks was 95 V and 1190 V and the corresponding root mean square power output was 9 mW and 1400 mW, respectively. This model provides the background for the development of a self-powered axle load sensing system for roadway vehicles.
ISSN:0306-2619
1872-9118
DOI:10.1016/j.apenergy.2019.113585