IJEM Vol. 13, No. 3, 8 Jun. 2023
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Piezoelectric transducers, footstep energy, power management system, street lighting system
To meet the ever-growing demand of this power hungry world, wasted energy can play a significant role. Wasted energy is the one which is not used in any part of a transferred or transformed process. Footstep energy is such a type that can be utilized properly in potential areas like crowded places. Every time people walk, a system captures this energy as pressure or stress and then converts it into electrical energy. This paper presents the design of a prototype of pressure transduced intelligent power management system for the street lighting system that can be self-enabled automatically from dawn to dusk. A way of avoiding the risk of battery damage is introduced in this design. A priority based power connection scheme is also shown to make an effective power management system for this system. The output results are also in accord with the design scheme that indicate almost linear relationships between stress in piezo transducers and voltage or power produced from it.
Md. Atik-Uz-Zaman Atik, Niaz Mostakim, Nazmus Sarwar, "Design and Implementation of a Prototype of Piezo Transduced Intelligent Power Management System for Efficient Street Lighting", International Journal of Engineering and Manufacturing (IJEM), Vol.13, No.3, pp. 25-33, 2023. DOI:10.5815/ijem.2023.03.03
[1]M. R. H. D. S. &. P. A. T. Gholikhani, "A critical review of roadway energy harvesting technologies," Applied Energy, 261, 114388, 2020.
[2]S. C. M. S. A. T. Dr. Meena Chavan, "Footstep Power Generation using Piezoelectric Sensor and Distribution using RFID," International Research Journal of Engineering and Technology (IRJET), vol. 7, no. 9, 2020.
[3]Y. C. J. L. X. L. Y. Z. S. &. C. Z. Sun, "Flexible piezoelectric energy harvester/sensor with high voltage output over wide temperature range," Nano Energy, , no. 61, pp. 337-345, 2019.
[4]D. Y. M. F. Y. M. C. F. M. &. L. M. Hu, "Strategies to achieve high performance piezoelectric nanogenerators.," Nano Energy, no. 55, pp. 288-304, 2019.
[5]X. Wang, "Piezoelectric nanogenerators-Harvesting ambient mechanical energy at the nanometer scale," Nano Energy , vol. 1 , no. 1 , pp. 13-24, 2012.
[6]J. L. M. H. &. S. L. M. Siang, "Review of vibrationābased energy harvesting technology: Mechanism and architectural approach.," International Journal of Energy Research, vol. 5, no. 42, pp. 1866-1893, 2018.
[7]P. S. a. A. N. Chaiyan Jettanasen, "Development of Micro-Mobility Based on Piezoelectric Energy Harvesting for Smart City Applications," vol. 7, no. 12, 2020.
[8]M. K. Nurettin Sezer, "A comprehensive review on the state-of-the-art of piezoelectric energy harvesting,," Nano energy, no. 80, 2021.
[9]H. S. K. J. H. &. K. J. Kim, "A review of piezoelectric energy harvesting based on vibration.," International journal of precision engineering and manufacturing, , vol. 12(6), pp. 1129-1141., 2011.
[10]A. Kamboj, A. Haque, A. Kumar, V. K. Sharma and A. Kumar, "Design of footstep power generator using piezoelectric sensors," in IEEE, 2017.
[11]D. C. S. a. H. A. B. Gadgay, "Foot Step Power Generation Using Piezoelectric Materials," in IEEE International Conference on Computation System and Information Technology for Sustainable Solutions (CSITSS), , 2021.
[12]F. M. S. Y. S. M. I. A. M. Anis Maisarah Mohd Asry, "Study on footstep power generation using piezoelectric tile," Indonesian Journal of Electrical Engineering and Computer Science, vol. 15, no. 2, pp. 593-599, 2019.
[13]R. J. S. D. B. M. S. &. K. T. Ganesh, "Experimental study on footstep power generation system using piezoelectric sensor," Materials Today: Proceedings, vol. 45, pp. 1633-1637, 2021.
[14]D. Sathisha, "A Novel Method for Electricity Generation from Footsteps Using Piezoelectric Transducers," Turkish Journal of Computer and Mathematics Education (TURCOMAT), vol. 12(2), pp. 810-817, 2021.
[15]J. LI, "Design of Active Vibration Control System for Piezoelectric Intelligent Structures," IJEME, vol. 2, no. 7, pp. 22-28, 2012.
[16]A. K. U. A. M. A. A. &. N. N. Ali, "Footstep Power Generation Using Piezoelectric Sensor," in 2nd International Conference on ICT for Digital, Smart, and Sustainable Development, ICIDSSD, 2021.
[17]B. B. T. &. C. R. N. P. Tiwari, "Piezoelectric lead zirconate titanate as an energy material: A review study.," Materials Today: Proceedings, vol. 43, pp. 407-412., 2021.
[18]"Datasheet: Materials Technical Data (Typical Values)," 15 Novemver 2020. [Online]. Available: https://info.piezo.com/hubfs/Data-Sheets/piezo-material-properties-data-sheet-20201112.pdf. [Accessed 2022].
[19]"Datasheet: Piezo Design: Forces & Stiffness in Piezoelectric Actuation," 2020. [Online]. Available: https://www.piezo.ws/piezoelectric_actuator_tutorial/Piezo_Design_part3.php. [Accessed 2022].
[20]H. Z. J. L. C. L. S. W. &. L. L. Liu, "A comprehensive review on piezoelectric energy harvesting technology: Materials, mechanisms, and applications.," Applied Physics Reviews, Vols. 5(4), 041306, 2018.
[21]B. X. ,. B. L. ,. L. C. ,. Y. L. ,. W. Z. ,. H. W. ,. W. W. a. M. w. Ruifeng Zhang, "A Study on the Open Circuit Voltage and State of Charge Characterization of High Capacity Lithium-Ion Battery Under Different Temperature," MDPI, 2018.