Experimental Validation of Equivalent Circuit Modelling of the Piezo-Stripe Harvester Attached to the SFSF Rectangular Plate

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.Search in Google Scholar

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.Search in Google Scholar

3. Anton Novel SR., (2009), Piezoelectric Energy Harvesting Devices for Unmanned Aerial Vehicles, Smart Material Structures, 1–10.10.1117/12.774990Search in Google Scholar

4. Anton SR., (2011), Multifunctional Piezoelectric Energy Harvesting Concepts, Doctoral Thesis, Virginia Polytechnic Institute and State University.Search in Google Scholar

5. Borowiec M., (2015), Energy harvesting of cantilever beam system with linear and nonlinear piezoelectric model, The European Physical Journal – Special Topics, 224, 2771–2786.10.1140/epjst/e2015-02588-2Search in Google Scholar

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, 04014034.10.1061/(ASCE)BE.1943-5592.0000608Search in Google Scholar

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, 265–28310.1016/j.ymssp.2018.01.007Search in Google Scholar

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.Search in Google Scholar

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.Search in Google Scholar

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, 011003.10.1115/1.4002785Search in Google Scholar

11. Gosiewski Z., (2008), Analysis of Coupling Mechanism in lateral/ torsional Rotor Vibrations, Journal of Theoretical and Applied Mechanics, 46(4), 829–844.Search in Google Scholar

12. Hanre RL., (2012), Concurrent attenuation of and energy harvesting from, surface vibrations: experimental verification, and model validation, Smart Material Structures, 21, 035016.10.1088/0964-1726/21/3/035016Search in Google Scholar

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), 604–617.10.1016/j.ymssp.2012.10.012Search in Google Scholar

14. Hu Y., Zhang Y. (2011), Self-powered system with wireless data transmission, Nano Letters, 11(6), 2572–2577.10.1021/nl201505c21604749Search in Google Scholar

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, 358–36310.1109/CarpathianCC.2016.7501123Search in Google Scholar

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, 133:405.10.1140/epjp/i2018-12201-1Search in Google Scholar

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, 812.10.3390/s19040812Search in Google Scholar

18. Koszewnik A., Gosiewski Z. (2016) Quasi-optimal locations of piezo-elements on a rectangular plate, European Physical Journal Plus, 2016, 131:232.10.1140/epjp/i2016-16232-2Search in Google Scholar

19. Koszewnik A., Wernio K. (2016), Modelling and Testing of the piezoelectric beam as energy harvesting beam, Acta Mechanica et Automatica, 10(4), 291–295.10.1515/ama-2016-0045Search in Google Scholar

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), 208–216.10.1016/j.sna.2009.02.024Search in Google Scholar

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, 2448–2456.10.1016/j.chaos.2007.07.021Search in Google Scholar

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, 2879–2908.10.1140/epjst/e2015-02596-2Search in Google Scholar

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, 1659–1675.10.1140/epjst/e2019-800150-6Search in Google Scholar

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, 1131–1144.10.1016/S0140-3664(02)00248-7Search in Google Scholar

25. Wang L., Yuan F.G., (2008), Vibration energy harvesting by magnetostrictive material, Smart Materials and Structures, 17, 045009.10.1088/0964-1726/17/4/045009Search in Google Scholar