Abstract
The aim of this paper is studied the Elements that affect the circuit SECE for piezoelectric energy harvesting and the influences on piezoelectric energy harvesting performance. In addition, the energy harvesting system based on piezoelectric energy plays an important role in the conversion of vibration energy from the environment into electrical energy, which can be used by low-power electronic devices. Concerning the interface circuit, the SECER (Synchronized Electrical Charge Extraction Regulator) circuit is usually required to rectify the alternating current (AC) signal into a direct current (DC) signal. In this paper, the properties of the SECER circuit and the influences on the energy recovery performance are analyzed and presented by power visualization simulation in the case of low load and high source frequency, as well as in the case of high load and low frequency. and whose characteristics can significantly influence the energy harvesting. It can be seen that the harvesting energy has a close relationship with the characteristics of the SECER circuit components. This study discloses the SECE influences on piezoelectric energy harvesting performance. In addition, the results show that the nonlinear SECER technique is 20% more efficient than the standard circuit, in terms of maximum power and bandwidth, for generators characterized by a moderate electromechanical coupling coefficient.
Access this chapter
Tax calculation will be finalised at checkout
Purchases are for personal use only
Similar content being viewed by others
References
Zhang Y, Bowen CR, Ghosh SK, Mandal D, Khanbareh H, Arafa M, Wan C (2019) Ferroelectret materials and devices for energy harvesting applications. Nano Energy 57:118–140
Ennawaoui C, Lifi H, Hajjaji A, Elballouti A, Laasri S, Azim A (2019) Mathematical modeling of mass spring’s system: hybrid speed bumps application for mechanical energy harvesting. Eng Solid Mechanics 7(1):47–58
Ennawaoui C, Lifi H, Hajjaji A, Samuel C, Rguiti M, Touhtouh S, Courtois C (2019) Dielectric and mechanical optimization properties of porous poly (ethylene-co-vinyl acetate) copolymer films for pseudo-piezoelectric effect. Polym Eng Sci 59(7):1455–1461
Cao Y, Li W, Figueroa J, Wang T, Torres D, Wang C, Sepúlveda N (2018) Impact-activated programming of electro-mechanical resonators through ferroelectret nanogenerator (FENG) and vanadium dioxide. Nano Energy 43:278–284
Wilson SA, Jourdain RP, Zhang Q, Dorey RA, Bowen CR, Willander M, Johansson C (2007) New materials for micro-scale sensors and actuators: an engineering review. Mater Sci Eng R Rep 56(1–6):1–129
Malki Z, Ennawaoui C, Hajjaji A, Najihi I, Eljouad M, Boughaleb Y (2020) Pedestrian crossing system for the mechanical energy harvesting using piezoelectric materials. In: IOP conference series: materials science and engineering, vol 948, no 1, p 012030. IOP Publishing, November
Zhukov S, von Seggern H, Zhang X, Xue Y, Ben Dali O, Pondrom P, Kupnik M (2020) Microenergy harvesters based on fluorinated ethylene propylene piezotubes. Adv Eng Mater 1901399
Hajjaji A, Guyomar D, Pruvost S, Touhtouh S, Yuse K, Boughaleb Y (2010) Temperature/electric field scaling in Ferroelectrics. Physica B 405(13):2757–2761
Rjafallah A, Hajjaji A, Guyomar D, Kandoussi K, Belhora F, Boughaleb Y (2019) Modeling of polyurethane/lead zirconate titanate composites for vibration energy harvesting. J Compos Mater 53(5):613–623
Hajjaji A, Guyomar D, Touhtouh S, Pruvost S, Boughaleb Y, Rguiti M, Benkhouja K (2010) Nonlinearity and scaling behavior in a soft lead zirconate titanate piezoceramic. J Appl Phys 108(6):
El hmamsy Y, Ennawaoui C, Hajjaji A, Boughaleb Y (2020) Theoretical study and Simulation method for optimizing the performance of advanced Energy Harvesting techniques. In: IOP conference series: materials science and engineering, vol 948, no 1, p 012014. IOP Publishing, November
Guyomar D, Lallart M (2011) Recent progress in piezoelectric conversion and energy harvesting using nonlinear electronic interfaces and issues in small scale implementation. Micromachines 2(2):274–294
Lallart M, Garbuio L, Petit L, Richard C, Guyomar D (2008) Double synchronized switch harvesting (DSSH): A new energy harvesting scheme for efficient energy extraction. IEEE Trans Ultrason Ferroelectr Freq Control 55(10):2119–2130
Nechibvute A, Chawanda A, Luhanga P, Akande AR (2012) Piezoelectric energy harvesting using synchronized switching techniques. Int J Eng Technol 2(6):936–946
Garbuio L, Lallart M, Guyomar D, Richard C, Audigier D (2009) Mechanical energy harvester with ultralow threshold rectification based on SSHI nonlinear technique. IEEE Trans Industr Electron 56(4):1048–1056
Erturk A, Inman DJ (2008) Issues in mathematical modeling of piezoelectric energy harvesters. Smart Mater Struct 17(6):065016
Lallart M, Anton SR, Inman DJ (2010) Frequency self-tuning scheme for broadband vibration energy harvesting. J Intell Mater Syst Struct 21(9):897–906
Lallart M, Guyomar D (2008) An optimized self-powered switching circuit for non-linear energy harvesting with low voltage output. Smart Mater Struct 17(3):035030
Ennawaoui C, Hajjaji A, Azim A, Boughaleb Y (2016) Theoretical modeling of power harvested by piezo-cellular polymers. Mol Cryst Liq Cryst 628(1):49–54
Rjafallah A, Hajjaji A, Belhora F, El Ballouti A, Touhtouh S, Guyomar D, Boughaleb Y (2020) PZT ceramic particles/polyurethane composites formalism for mechanical energy harvesting. Eur Phys J Appl Phys 89(3):30901
Belhora F, Cottinet PJ, Hajjaji A, Guyomar D, Mazroui MH, Lebrun L, Boughaleb Y (2013) Mechano-electrical conversion for harvesting energy with hybridization of electrostrictive polymers and electrets. Sens Actuators A 201:58–65
Lefeuvre E, Audigier D, Richard C, Guyomar D (2007) Buck-boost converter for sensorless power optimization of piezoelectric energy harvester. IEEE Trans Power Electron 22(5):2018–2025
Belhora F, Hajjaji A, Mazroui MH, El Fatnani FZ, Rjafallah A, Guyomar D (2015) Energy harvesting using hybridization of dielectric nanocomposites and electrets. Polym Adv Technol 26(6):569–573
El hmamsy Y, Ennawaoui C, Hajjaji A (2021) Study and design the circuit for piezoelectric vibration energy harvester to charge a datalogger. Int J Eng Appl Phys 1(1):18–25
Author information
Authors and Affiliations
Editor information
Editors and Affiliations
Rights and permissions
Copyright information
© 2021 The Author(s), under exclusive license to Springer Nature Switzerland AG
About this paper
Cite this paper
El Hmamsy, Y., Ennawaoui, C., Najihi, I., Hajjaji, A. (2021). The Synchronized Electrical Charge Extraction Regulator for Harvesting Energy Using Piezoelectric Materials. In: Motahhir, S., Bossoufi, B. (eds) Digital Technologies and Applications. ICDTA 2021. Lecture Notes in Networks and Systems, vol 211. Springer, Cham. https://doi.org/10.1007/978-3-030-73882-2_138
Download citation
DOI: https://doi.org/10.1007/978-3-030-73882-2_138
Published:
Publisher Name: Springer, Cham
Print ISBN: 978-3-030-73881-5
Online ISBN: 978-3-030-73882-2
eBook Packages: Intelligent Technologies and RoboticsIntelligent Technologies and Robotics (R0)