Effect of core material on induced voltage in electromagnetic harvester
DOI:
https://doi.org/10.5281/zenodo.10473102Keywords:
Electromagnetic harvesters, Energy harvesting, Toroidal coreAbstract
With the increasing demand for energy today, diversification of resources and meeting this demand has become crucial. Environmentally friendly alternative solutions have been the subject of research. Especially investments in renewable energy sources have increased in this regard. The power required by low-power sensor technologies can be met by harvesters. For this purpose, the design and Finite Element Analysis (FEA) of the toroid core electromagnetic harvester have been carried out in the study. The material of the toroidal core is determined by selecting Nickel-steel, M19, and nanocrystalline, and the effect of induced voltage and mutual inductance on the core material has been identified. In addition, the line current was determined as a variable and its effect on both flux density and voltage was determined.
References
Seyman M. N., Saçaklı B., "A Novel Subcarrier Allocation Algorithm for MC-CDMA Systems", Journal of Electrical Engineering, 67(5), 371-376, 2016.
Seyman M. N., Demiral B., "An Efficient Approach for Sub-Carrier Allocation in MIMO MC-CDMA Systems”, Journal of Electrical Engineering, 73(3), 221-225, 2022.
Monagle, D., Ponce, E., and Leeb, S.D., "Generalized analysis method for magnetic energy harvesters", IEEE Transactions on Power Electronics, 37(12), 15764-15773, 2022.
Zhang, J., Ge, B., Zhang, Q., Wu, J., Tao, J., Chen, J., Jiang, L., and Cao, L., “A Dual-Output Magnetoelectric Energy Harvester in Ferrite/Piezoelectric Toroidal Magnetoelectric Composites”, IEEE Transactions on Magnetics, 58(2), 1-4, 2022.
Park, B., Kim, D., Park, J., Kim, K., Koo, J., Park, H., & Ahn, S., “Optimization design of toroidal core for magnetic energy harvesting near power line by considering saturation effect”, AIP Advances, 8, 056728, 2018.
Balcı, M.Ş., Sakar, S., and Dalcalı, A., "Electromagnetic Energy Harvester Design for Power Transmission Line", Transdisciplinary Journal of Engineering & Science, Vol. SP-2, pp. 111-123, 2022.
Balcı, M.Ş., and Dalcalı, “Power Analysis of Toroidal Core Electromagnetic Energy Harvesters for Transmission Lines”, Engineering Technologies and Systems, 33(4), 599-611, 2023.
Xu, C., Wang, W., Su, W., Duan, M., & Hu, M., “Sensitivity Analysis of Free-Standing Columnar Magnetic Field Energy Harvester for Powering Wireless Monitoring Sensors”, IEEE Transactions on Circuits and Systems I: Regular Papers, Vol. 70(11), 4650-4659, 2023.
Gaikwad, A.A., and Kulkarni, S.B., "Evaluation of dimensional effect on electromagnetic energy harvesting", Procedia Computer Science, 143, 58-65, 2018.
Paul, S., Bashir, S., and Chang, J., “Design of a Novel Electromagnetic Energy Harvester with Dual Core for Deicing Device of Transmission Lines”, IEEE Transactions on Magnetics, Vol. 55(2), 2019.
Park, Bumjin, et al., "The magnetic energy harvester with improved power density using saturable magnetizing inductance model for maintenance applications near high voltage power line", IEEE access, Vol. 9, 82661-82674, 2021.
Zhuang, Y., Xu, C., Yuan, S., He, C., Chen, A., Lee, W.W., Zhou, J., and Huang, Y., “An Improved Energy Harvesting System on Power Transmission Lines”, IEEE Wireless Power Transfer Conference, Taiwan, 2017.
Zhuang, Y., Xu, C., Song, C., Chen, A., Lee, W., Huang, Y., and Zhou, J, "Improving Current Transformer-Based Energy Extraction From AC Power Lines by Manipulating Magnetic Field", IEEE Transactions on Industrial Electronics, 67(11), 9471-9479, 2020.
Ye, K., Liu, Z., Liu, C., Yang, A., Yuan, H., Rong, M., Wang, X., “A Novel Method of Maximum Power Point Reaching for Magnetic Field Energy Harvesting Based on a Low-Power Analog Control Circuit”, IEEE Transactions on Power Electronics, Vol. 39(1), 2024.
Gao, M., Yi, L., Moon, J., "Mathematical Modeling and Validation of Saturating and Clampable Cascaded Magnetics for Magnetic Energy Harvesting", IEEE Transactions on Power Electronics, 38(3), 3455-3468, 2023.
Gao, M., Herrera, H. L., and Moon, J., “Optimization of Core Size and Harvested Power for Magnetic Energy Harvesters based on Cascaded Magnetics”, IEEE Applied Power Electronics Conference and Exposition, Orlando, FL, USA, 2926-2932, 2023.
Balcı, M.Ş., “Electromagnetic energy harvester design, optimization and application for unmanned aerial vehicles”, M. Sc. Thesis, Bandırma Onyedi Eylül University, 2023.
Muhammad, A., Khan, F., Ullah, B., Milyani, A.H., Azhari, A.A., “Design and FEM analysis of high-power density C-core permanent magnet transverse flux generator with reduced PM volume”, IET Renewable Power Generation, Vol. 17, 885-893, 2023.
Oladapo, B.I., Bowoto, O.K., Adebiyi, V.A., Ikumapayi, O.M., “Energy harvesting analysis of hip implantin achieving sustainable development goals”, Structures, Vol. 55, 28-38, 2023.
Olhan, S., Antil, B., Khatkar, V., Behera, B.K., “Mechanical, thermal, and viscoelastic behavior of sisal fibre-based structural composites for automotive applications: Experimental and FEM analysis”, Composite Structures, Vol. 322, 117427, 2023.
Dalcalı, A., “Influence of Rotor Magnet Material and Stator Winding Geometry on Output Torque in Spherical Actuator”, Journal of Engineering Sciences and Design, Vol. 7(1), 145-151, 2019.
Published
Issue
Section
License
Copyright (c) 2023 AINTELIA Science Notes
This work is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.
