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Optimization design and experimental investigation of piezoelectric energy harvesting devices for pavement

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  • Wang, Chaohui
  • Zhao, Jianxiong
  • Li, Qiang
  • Li, Yanwei

Abstract

This study designs a compression-based pavement energy harvesting device with a group of piezoelectric transducers and investigates the selection of the component materials based on four technical device requirements for enhanced the electric energy output of power-generation pavements. The external dimensions of the proposed devices are optimized based on vehicle wheelpath distribution, tire trace patterns, and vehicle roller compaction conditions. The array pattern of the piezoelectric device is designed based on the driving characteristics. Various device material configurations are examined using different cover plates, rubber pad thicknesses, protective pads, and transducer specifications for optimal mechanic-electric response characteristics. A 150 mm × 150 mm type device is tested as an example and its electrical output performance is evaluated under typical road loading environments. Subsequently, a comparative analysis of various disclosed piezoelectric harvesting device technology were conducted and further research plan was developed. The selected modified polypropylene or aluminum plate, steel plate, modified polypropylene bar, and fiber heat insulation plate are suitable for the device which meets the application demands. The optimum device dimensions under light and heavy traffic conditions are 100 mm × 100 mm and 150 mm × 150 mm, respectively. The optimum configuration of the device includes a modified polypropylene upper cover plate, 1 mm rubber pad, ball-type protective pad, and eight laminated transducers. In addition, parallel connection of stacked transducers is more suitable for energy collection and reuse from traffic-induced pavement vibrations. Under the loading of 0.7 MPa and 15 Hz, the 150 mm × 150 mm device with nine parallel transducers achieves a maximum output power of 50.41 mW, and the corresponding optimum loading is 4 kΩ. Under the loading of 0.2 MPa and 10 Hz, the device achieves a maximum output power of 2.92 mW, and the corresponding optimum load is 10 kΩ. The performance of piezoelectric device designed in this paper excels that of many other available devices.

Suggested Citation

  • Wang, Chaohui & Zhao, Jianxiong & Li, Qiang & Li, Yanwei, 2018. "Optimization design and experimental investigation of piezoelectric energy harvesting devices for pavement," Applied Energy, Elsevier, vol. 229(C), pages 18-30.
    • Handle: RePEc:eee:appene:v:229:y:2018:i:c:p:18-30
    DOI: 10.1016/j.apenergy.2018.07.036
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    Cited by:

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    4. Hong, Seong Do & Ahn, Jung Hwan & Kim, Kyung-Bum & Kim, Jeong Hun & Cho, Jae Yong & Woo, Min Sik & Song, Yewon & Hwang, Wonseop & Jeon, Deok Hwan & Kim, Jihoon & Jeong, Se Yeong & Woo, Sang Bum & Ryu,, 2022. "Uniform stress distribution road piezoelectric generator with free-fixed-end type central strike mechanism," Energy, Elsevier, vol. 239(PA).
    5. Wang, Jun & Liu, Zhiming & Ding, Guangya & Fu, Hongtao & Cai, Guojun, 2021. "Watt-level road-compatible piezoelectric energy harvester for LED-induced lamp system," Energy, Elsevier, vol. 229(C).
    6. Guo, Lukai & Lu, Qing, 2019. "Numerical analysis of a new piezoelectric-based energy harvesting pavement system: Lessons from laboratory-based and field-based simulations," Applied Energy, Elsevier, vol. 235(C), pages 963-977.
    7. Wang, Chaohui & Wang, Shuai & Gao, Zhiwei & Wang, Xingju, 2019. "Applicability evaluation of embedded piezoelectric energy harvester applied in pavement structures," Applied Energy, Elsevier, vol. 251(C), pages 1-1.
    8. Song, Gyeong Ju & Cho, Jae Yong & Kim, Kyung-Bum & Ahn, Jung Hwan & Song, Yewon & Hwang, Wonseop & Hong, Seong Do & Sung, Tae Hyun, 2019. "Development of a pavement block piezoelectric energy harvester for self-powered walkway applications," Applied Energy, Elsevier, vol. 256(C).
    9. Pan, Hongye & Qi, Lingfei & Zhang, Zutao & Yan, Jinyue, 2021. "Kinetic energy harvesting technologies for applications in land transportation: A comprehensive review," Applied Energy, Elsevier, vol. 286(C).
    10. Mohammadreza Gholikhani & Seyed Amid Tahami & Mohammadreza Khalili & Samer Dessouky, 2019. "Electromagnetic Energy Harvesting Technology: Key to Sustainability in Transportation Systems," Sustainability, MDPI, vol. 11(18), pages 1-18, September.
    11. Yangyang Zhang & Qi Lai & Ji Wang & Chaofeng Lü, 2022. "Piezoelectric Energy Harvesting from Roadways under Open-Traffic Conditions: Analysis and Optimization with Scaling Law Method," Energies, MDPI, vol. 15(9), pages 1-12, May.
    12. Jeon, Deok Hwan & Cho, Jae Yong & Jhun, Jeong Pil & Ahn, Jung Hwan & Jeong, Sinwoo & Jeong, Se Yeong & Kumar, Anuruddh & Ryu, Chul Hee & Hwang, Wonseop & Park, Hansun & Chang, Cheulho & Lee, Hyoungjin, 2021. "A lever-type piezoelectric energy harvester with deformation-guiding mechanism for electric vehicle charging station on smart road," Energy, Elsevier, vol. 218(C).
    13. Yuan, Huazhi & Wang, Shuai & Wang, Chaohui & Song, Zhi & Li, Yanwei, 2022. "Design of piezoelectric device compatible with pavement considering traffic: Simulation, laboratory and on-site," Applied Energy, Elsevier, vol. 306(PB).
    14. Bruno C. Mota & Bruno Albuquerque Neto & Suelly H. A. Barroso & Francisco T. S. Aragão & Adelino J. L. Ferreira & Jorge B. Soares & Lélio A. T. Brito, 2022. "Characterization of Piezoelectric Energy Production from Asphalt Pavements Using a Numerical-Experimental Framework," Sustainability, MDPI, vol. 14(15), pages 1-22, August.
    15. Wang, Shuai & Wang, Chaohui & Yuan, Huazhi & Ji, Xiaoping, 2022. "Design and performance of piezoelectric energy output promotion system for road," Renewable Energy, Elsevier, vol. 197(C), pages 443-451.
    16. Wang, Chaohui & Wang, Shuai & Gao, Zhiwei & Song, Zhi, 2021. "Effect evaluation of road piezoelectric micro-energy collection-storage system based on laboratory and on-site tests," Applied Energy, Elsevier, vol. 287(C).

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