Energy harvesting from moving harmonic and moving continuous mass traversing on a simply supported beam

[Display omitted] •Energy harvesting from moving harmonic and continuous mass on simply supported beam.•Theoretical and experimental study of energy harvesting from moving mass.•Increase in the harvested power by adding the mass and the speed of the moving part.•Decrease in the harvested power by in...

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Bibliographic Details
Published in:Measurement : journal of the International Measurement Confederation 2020-01, Vol.150, p.107080, Article 107080
Main Authors: Dehghan Hamani, I., Tikani, R., Assadi, H., Ziaei-Rad, S.
Format: Article
Language:English
Subjects:
Beamforming
Energy harvesting
Energy management
Entrances
Mathematical models
Molecular beam epitaxy
Moving distributed mass
Moving harmonic mass
Numerical analysis
Piezoelectric
Piezoelectricity
Structural health monitoring
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Summary:[Display omitted] •Energy harvesting from moving harmonic and continuous mass on simply supported beam.•Theoretical and experimental study of energy harvesting from moving mass.•Increase in the harvested power by adding the mass and the speed of the moving part.•Decrease in the harvested power by increasing the length of moving continuous mass. In this paper, energy harvesting from a simply supported beam using piezoelectric materials has been performed. Two different models for the moving objects were considered. First, the passing object was modeled as a concentrated mass with some amount of unbalances. The coupled governing equations of the beam, the piezoelectric patch, and the moving mass were obtained and discretized using assumed mode method. The beam response and the output voltage were calculated for different values of moving mass and unbalances. In the second model, the passing object was studied as a distributed mass. The governing equations of the system were extracted at three stages, namely entrance, main, and exit of the object from the beam. To validate the numerical findings, two test setups were erected, and the beam midpoint deflection and the piezoelectric power were measured experimentally. A good degree of correlation was found between numerical and measured values.
ISSN:0263-2241
1873-412X
DOI:10.1016/j.measurement.2019.107080