Simulation of piezoelectric energy device in the pavement of urban crossroad

Authors

DOI:

https://doi.org/10.5902/2236117045212

Keywords:

Energy Harvesting, Piezoelectric devices, Urban pavement

Abstract

Energy Harvesting is a concept that aims to transform the weight of the vehicle traveling on a track into electrical energy, converting mechanical pressure into electricity, it is the principle of piezoelectric technology currently being tested on highways and urban roads around the world. This type of energy varies depending on the load quantity of the vehicle and the number of times it passes, consequently, this form of energy is discontinuous, being the best use when used on roads with a high flow of vehicles. In this context, a study based on the implementation of piezoelectric devices at an urban intersection with traffic lights in three Brazilian cities with different ports is presented: Marau, Erechim and Passo Fundo. Piezoelectric energy still shows the initial phase of technological and experimental development, but it shows the potential for use in the urban environment, mainly due to the concentration of light vehicles, speeds and as a complementary alternative existing in the existing electrical network.

Downloads

Download data is not yet available.

Author Biography

Paulo César Pinto, Universidade do Contestado, Concórdia, SC

Profesor of Program in Masters in civil engineering, sanitary and environmental, Universidade do Contestado, Concórdia, SC, Brazil

References

BENARROCH, W.L. - Harvesting Energy from Asphalt Pavement by Piezoelectric Generator – Israel Symphosium of Energy, 3, 2017.

BROIZAT, J.C. – Wattway: La Route Solaire – Solar Impulse Foundation: Technical Datashet, 2016, 18 pg.

BUITENHUIS, T. – Watt: Sustainable Dance Club – American Sustainable Review, 2, Vol.1, 2010, 4 pg.

COLAROSSI, F; SARACINO, G; SARACINO, L. – Building a Bridge to Renewable Energy - Energy Conversion and Management, 50, 2011, pg. 2029-2034.

COOK, C. A. – Foot Powering Tokyo Train Station – Innow Presentation, 2014.

HADDAD, J; YAMACHITA, R.A. – Os Avanços Tecnológicos em Sistemas de Iluminação e o Correspondente Impacto na Eficiência Energética de Edificações – XVIII SNPTEE, Curitiba, 2015.

IBGE – Instituto Brasileiro de Geografia e Estatística. Cidades e Estados - Erechim. Disponível em: <https://www.ibge.gov.br/cidades-e-estados/rs/erechim.html>. Acesso em: 18 de março de 2020.

IBGE – Instituto Brasileiro de Geografia e Estatística. Cidades e Estados - Marau. Disponível em: <https://www.ibge.gov.br/cidades-e-estados/rs/marau.html>. Acesso em: 18 de março de 2020.

IBGE – Instituto Brasileiro de Geografia e Estatística. Cidades e Estados – Passo Fundo. Disponível em: <https://www.ibge.gov.br/cidades-e-estados/rs/passo-fundo.html>. Acesso em: 18 de março de 2020.

MALMONGE, J.A. – Piezo and Dielectric Properties of PHB-PZT Composite – Polymer Composites. v. 30, n. 9, 2008, pg. 1.333-1337.

McALPINE, - Innowattech, energy harvesting systems – Iroads TN-35, 2014, pg 43-49.

MEHTA, A; AGGRAWAL, N; TIWARI, A. – Solar Rodways: The Future of Roadways – International Advanced Research Journal In Science, Engineering and Technology: Vol.2, Special Issue 1, Ghaziabad, 2017, pg. 167-182.

PAVEGEN – Eletric Footprint: Application Programming Interface Technology Review – Startup Pavegen, 2014, 67 pg.

PEREIRA, A.H.A. – Cerâmicas Piezoelétricas: Funcionamento e Propriedades – Application Note RT-ATCP-01, 2010, 7 pg.

RANJAN, E.R. – Solar Power Roads: Revitalising Solar Highways, Eletrical Power and Smart Grids – International Journal of Engineering Research and General Science, Vol.3, Issue 1, India, pg. 2015, 361-385.

ROSHANI, H. – Energy Harvesting from Asphalt Pavement Roadways Vehicle-Induced Stresses: A Feasisbility Study – Applied Energym V.182, 2016, pg. 210-218.

SHULZ, W. – Science of the Future: Perfect City, WMAD Editors, 2015, 167 pg.

TOMAZINI, D; DOERING, D, HIRSCH, F. BRITO, L. – Estratégias de Eficiência Energética em Praças de Pedágio Rodoviários – Pesquisa RDT Triunfo-Concepa, ANTT, 2018, 110 pg.

WANG, H. – Energy Harvesting Technologies in Roadway and Bridge for Different Applications: A comprehensive review – Applied Science, v.212, 2018, pg. 1083-1094.

YESNER, G. – Evaluation of a Novel Piezoeletric Bridge Transducer – European Conference on Application of Polar Dielectricts and Piezoelectric Force Microscopy, Atlanta, 2017, pg. 1-17.

ZHAO, H; LING, J; YU, J. – A Comparative Analysis of Piezoelectric Transducers for Harvesting Energy from Asphalt Pavement – Journal of the Ceramic Society of Japan, 120, n. 8, 2012, pg. 317-323.

Downloads

Published

2020-05-25 — Updated on 2022-08-01

Versions

How to Cite

Pinto, P. C. (2022). Simulation of piezoelectric energy device in the pavement of urban crossroad. Revista Eletrônica Em Gestão, Educação E Tecnologia Ambiental, 24, e39. https://doi.org/10.5902/2236117045212 (Original work published May 25, 2020)

Issue

REGET 2020-1

Section

ENVIRONMENTAL THECNOLOGY

License

Copyright (c) 2020 Revista Eletrônica em Gestão, Educação e Tecnologia Ambiental

Creative Commons License

This work is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License.

DECLARATION