부산대학교 도서관

In an inductive power transfer (IPT) system, the magnetic core is usually used to improve the coefficient between the primary and secondary coils. However, considering the iron losses on magnetic materials, the addition of magnetic core may affect the system efficiency, at the same time, increase the weight of the IPT system significantly. Therefore, in this study, the aggregate influence of thickness, permeability and iron losses of magnetic core on IPT system performance is comprehensively investigated. Firstly, the equivalent circuit model of IPT system is established, and the formulas for different types of losses are analyzed. Then, 3-D models of the IPT system with magnetic core in different shapes are established to simulate the aggregate influence of core thickness, permeability and iron losses. The simulation results reveal that reducing the core thickness requires a larger saturation flux density of magnetic materials. In addition, only if the material losses below a certain value and an appropriate core shape are adopted, the addition of magnetic material can improve the system efficiency. Finally, experimental validation on a 3-kW IPT system are performed under the conditions of no magnetic core, using ferrite core in radial pattern and hollow square shapes, using nanocrystalline core with thickness of 22μm and 16μm in radial pattern and hollow square shapes, respectively. The results show that the high efficiency and the lower overall weight of the IPT system can be achieved when nanocrystalline core with suitable permeability and shape is used.