Experimental validation of equivalent circuit modelling of the piezo-stripe harvester attached to the sfsf rectangular plate

• Autorzy: Koszewnik Andrzej

Identyfikatory

DOI

10.2478/ama-2020-0002

• Języki publikacji: EN

Abstrakty

EN

Plate-like structures with attached piezo-patch elements are widely used in marine, aerospace and civil infrastructure applications to power small devices with low power demand or used for monitoring of vibration structures. In order to assess the feasibility of an energy harvesting system to generate power output from a harvester, an accurate electromechanical model of the piezo-patch harvester attached to a 2D structure in modal coordinates is required. Taking into account this fact, this study is focused on the analysis of the piezoharvester orientations on the SFSF (Simply Supported-Free-Simply Supported-Free) plate undergoing forced dynamic excitation. The results obtained from the numerical analysis of a smart structure led to determining quasi-optimal piezo-harvester location on the structure, and next, to determining a multi-mode representation of the equivalent circuit model. The experimental set-up carried out on the lab stand properly verified the parameters of the ECM model. Finally, the proposed approach can be used for the structural health monitoring of vibration of some 2D mechanical structures like the front wall of a dishwasher.

Słowa kluczowe

EN

aluminium plate; piezo - harvester; energy harvesting system; modal analysis; Equivalent Circuit Model; ECM

• Wydawca: Oficyna Wydawnicza Politechniki Białostockiej
• Czasopismo: Acta Mechanica et Automatica
• Rocznik: 2020
• Tom: Vol. 14, no. 1
• Strony: 8--15
• Opis fizyczny: Bibliogr. 25 poz., rys., tab., wykr.

Twórcy

autor

Koszewnik Andrzej

• Faculty of Mechanical Engineering, Department of Robotics Systems and Mechatronics, Wiejska 45C, 15-351 Białystok, Poland

Bibliografia

• 1. Aboulfotoh N., Wallscheck J., Twiefel J., Bergman L., (2017), Toward understanding the self-adaptive dynamics of a harmonically forced beam with a sliding mass, Archive of Applied Mechanics, 87(4), 699–720.
• 2. Ambrożkiewicz B., Litak G., Wolszczak P., (2020), Modelling of Electromagnetic Energy Harvester with Rotational Pendulum using Mechanical Vibrations to Scavenge Electrical Energy, Applied Sciences, 10(2), 671.
• 3. Anton Novel SR., (2009), Piezoelectric Energy Harvesting Devices for Unmanned Aerial Vehicles, Smart Material Structures, 1–10.
• 4. Anton SR., (2011), Multifunctional Piezoelectric Energy Harvesting Concepts, Doctoral Thesis, Virginia Polytechnic Institute and State University.
• 5. Borowiec M., (2015), Energy harvesting of cantilever beam system with linear and nonlinear piezoelectric model, The European Physical Journal – Special Topics, 224, 2771–2786.
• 6. Cahill P., Nuallian N., Jackson N., Mathewson A., Karoumi R., Pakrashi V., (2014), Energy Harvesting from Train-Induced Response in Bridges, ASCE Journal of Bridge Engineering, 04014034.
• 7. Cahill P., Nuallian N., Jackson N., Mathewson A., Karoumi R., Pakrashi V., (2018), Vibration energy harvesting based monitoring of an operational bridge undergoing forced vibration and train passage, Mechanical System and Signal Processing, 106, 265–283
• 8. Chiu Y., Tseng V., (2008), A capacitive vibration-to-electricity energy converter with integrated mechanical switches, Journal of Micromechanics and Microengineering, 18(10), 104004.
• 9. Cook-Chennault K., Thambi N., Sastry S., (2007), Powering MEMS portable devices – a review of non-regenerative and regenerative power supply systems with special emphasis on piezoelectric energy harvesting systems, Smart Material and Structures, 16(3), 043001.
• 10. De Marqui C., (2011), Modelling and analysis of piezoelectric energy harvesting from aeroelastic vibrations using the doublet-lattice method, Trans. ASME Journal of Vibration Acoustic, 133, 011003.
• 11. Gosiewski Z., (2008), Analysis of Coupling Mechanism in lateral/torsional Rotor Vibrations, Journal of Theoretical and Applied Mechanics, 46(4), 829–844.
• 12. Hanre RL., (2012), Concurrent attenuation of and energy harvesting from, surface vibrations: experimental verification, and model validation, Smart Material Structures, 21, 035016.
• 13. Hanre RL., (2013), Development and testing of a dynamic absorber with corrugated piezoelectric spring for vibration control and energy harvesting applications, Mechanical System and Signal Processing, 36(2), 604–617.
• 14. Hu Y. , Zhang Y. (2011), Self-powered system with wireless data transmission, Nano Letters, 11(6), 2572–2577.
• 15. Koszewnik A. (2016), The optimal vibration Control of the Plate Structure by using piezo-actuators, Proceedings of the 17th IEEE International Carpathian Control Conference (ICCC), Tatrzanska Lomnica, Slovakia, 358–363
• 16. Koszewnik A. (2018), The Design of Vibration Control System for Aluminum Plate with Piezo-stripes based on residues analysis of model, European Physical Journal Plus, 133:405.
• 17. Koszewnik A. (2019), Analytical Modelling and Experimental Validation of an Energy Harvesting System for the Smart Plate with an Integrated Piezo-Harvester, Sensors, 19, 812.
• 18. Koszewnik A., Gosiewski Z. (2016) Quasi-optimal locations of piezo-elements on a rectangular plate, European Physical Journal Plus, 2016, 131:232.
• 19. Koszewnik A., Wernio K. (2016), Modelling and Testing of the piezoelectric beam as energy harvesting beam, Acta Mechanica et Automatica, 10(4), 291–295.
• 20. Lee Ch., Lim Y.M., Yang B. (2009), Theoretical comparison of the energy harvesting capability among various electrostatic mechanisms from structure aspect, Sensor Actuator A, 156(1), 208–216.
• 21. Litak G., Borowiec M., Fischer M., Przystupa W., (2009), Chaotic response of a quarter car model forced by a road profile with a stochastic component, Chaos, Solutions and Fractals, 9, 2448–2456.
• 22. Naifar S., Bradai S., Viehweger C., Kanoun O., (2015), Response analysis of a nonlinear magnetoelectric energy harvester under harmonic excitation, The European Physical Journal – Special Topics, 224, 2879–2908.
• 23. Okosun F., Cahill P.,Hazra B., Pakrashi V., (2019), Vibration-based leak detection and monitoring of water pipes using output–only Piezoelectric Sensors, European Physical Journal – Special Topics, 228, 1659–1675.
• 24. Roundy W., Wright P., Rabaey J., (2003), A study of low level vibrations as a power source for wireless sensor nodes, Computer Communications, 26, 1131–1144.
• 25. Wang L., Yuan F.G., (2008), Vibration energy harvesting by magnetostrictive material, Smart Materials and Structures, 17, 045009.

Uwagi

1. This work is supported with University Work number WZ/WM-IIM/1/2019 of Faculty of Mechanical Engineering, Bialystok University of Technology.

2. Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2021).