Numerical analysis of the harvester having toroidal structure and examination of the application results

Year 2020, Volume: 4 Issue: 2, 134 - 141, 15.08.2020

Mahmut Kabakulak , Serdal Arslan

https://doi.org/10.35860/iarej.694834

Cited By: 1

Abstract

In most places with energy transmission, data of the line can be obtained with sensors. However, in recent years, the energy requirement of sensors has been met through harvesters. The electrical power required for sensor systems can be provided through electromagnetic fields around the line, especially through the electrical power transmission line or energy-carrying cable systems. In this study, numerical analysis of the harvester with toroidal coil, which was intended to be used for sensor feeds, was performed using Ansys Maxwell. In addition, experimental studies of the harvesters with toroidal core were carried out. The results were compared with some studies in the literature. Considering line current and saturation effects, it was seen that the studied toroid models were appropriate for home sensor applications.

Keywords

Ansys Maxwell, Energy harvesting, Electromagnetic field, Toroidal core

References

• 1. Yilmaz, C., and M. Kanoglu, Investigation of hydrogen production cost by geothermal energy. International Advanced Researches and Engineering Journal, 2017. 1(1): p. 5-10.
• 2. Sen, O., and C. Yilmaz, Thermodynamic performance analysis of geothermal and solar energy assisted power generation and residential cooling system. International Advanced Researches and Engineering Journal, 2020. 4(1): p. 41-47.
• 3. Boles, J.D., et al. Inductive power harvesting for a touchless transmission line inspection system. in IEEE Power and Energy Society General Meeting (PESGM) 2016: Boston, USA. p.1-5.
• 4. Liu, Y., et al., A novel high-density power energy harvesting methodology for transmission line online monitoring devices. Review of Scientific Instruments, 2016. 87(7): p. 075119.
• 5. Moser, M.J., et al., Strong and weak electric field interfering: Capacitive icing detection and capacitive energy harvesting on a 220-kV high-voltage overhead power line. IEEE transactions on industrial electronics, 2010. 58(7): p. 2597-2604.
• 6. Yang, F., et al., A novel self-powered lightning current measurement system. IEEE Transactions on Industrial Electronics, 2017. 65(3): p. 2745-2754.
• 7. Yuan, S., et al., A high-efficiency helical core for magnetic field energy harvesting. IEEE Transactions on Power Electronics, 2016. 32(7): p. 5365-5376.
• 8. White, R.M., et al., Atmospheric sensors and energy harvesters on overhead power lines. Sensors, 2018. 18(1): p. 114.
• 9. Wang, W., et al., Optimization design of an inductive energy harvesting device for wireless power supply system overhead high-voltage power lines. Energies, 2016. 9(4): p. 242.
• 10. Dos Santos, M.P., et al. Energy harvesting using magnetic induction considering different core materials. in 2014 IEEE International Instrumentation and Measurement Technology Conference (I2MTC)2014:Montevideo, Uruguay. p.1-3.
• 11. Zhuang, Y., et al. An improved energy harvesting system on power transmission lines. in IEEE Wireless Power Transfer Conference (WPTC)2017: Taipei, Taiwan. p.1-3.
• 12. Zhao, X., et al. Energy harvesting for overhead power line monitoring. in International Multi-Conference on Systems, Signals & Devices 2012: Chemnitz, Germany. p.1-5.
• 13. Çelik, K., E. Kurt, and Y. Uzun, Experimental and theoretical explorations on the buckling piezoelectric layer under magnetic excitation. Journal of Electronic Materials, 2017. 46(7): p. 4003-4016.
• 14. Kabakulak, M., M.T. Güllüoğlu, and S. Arslan. A wireless energy harvesting system design and numerical analysis. in 3rd International Congress of Professional and Technical Sciences 2018: Gaziantep, Turkey. p.418-425.
• 15. Kabakulak, M., M.T. Güllüoğlu, and S. Arslan. Energy harvester analysis in common simulation platform. in 1st International GAP Mathematics - Engineering - Science and Health Sciences Congress2018: Sanliurfa, Turkey. p. 26-32.
• 16. Kabakulak, M., M.T. Güllüoğlu, and S. Arslan. Comparison of energy harvesters according to change of conductor form. in 1st International Mersin Symposium 2018: Mersin, Turkey. p.16-26.
• 17. Kabakulak, M., M.T. Güllüoğlu, and S. Arslan. Energy Harvesting from Busbar. in 1st International Mersin Symposium2018: Mersin, Turkey. p.27-36
• 18. METGLAS® 2605-SA1 core datasheet. 2018 [01 January 2020]; Available from: https://www.netl.doe.gov/sites/default/files/netl-file/METGLAS-2605-SA1-Core-Datasheet_approved%5B1%5D.pdf.
• 19. Fenercioğlu, A., and Tarimer, I., Solution Processes of a Magnetic System’s Magnetostatic Analysis wıth Maxwell 3D Field Simulator. Selçuk Teknik Dergisi, 2007. 6(3): p. 221-240.
• 20. Arslan S., Medium frequency spot welding transformer and machine design. MSc Thesis, 2011, Turkey: Gazi University, Graduate School of Natural and Applied Sciences.
• 21. Park, B., Kim, et al. Optimization design of toroidal core for magnetic energy harvesting near power line by considering saturation effect. AIP Advances, 2018. 8(5): p. 1-7.
• 22. Kabakulak M., Energy harvesting from electromagnetic fields around overhead power lines. MSc Thesis, 2020, Turkey: Harran University, Graduate School of Natural and Applied Sciences.
• 23. ANSYS, Ansys Maxwell 2019 version Help File, p.1-2955.