Abstract
This paper presents the optimal modeling and finite element analysis of strong-coupled, high-power and low-loss flux-pipe resonant coils for bidirectional wireless power transfer (WPT), applicable to electric vehicles (EVs) using series-series compensation topology. The initial design involves the modeling of strong-coupled flux-pipe coils with a fixed number of wire-turns. The ohmic and core loss reduction for the optimized coil model was implemented by creating two separate coils that are electrically parallel but magnetically coupled in order to achieve maximum flux linkage between the secondary and primary coils. Reduction in the magnitude of eddy current losses was realized by design modification of the ferrite core geometry and optimized selection of shielding material. The ferrite core geometry was modified to create a C-shape that enabled the boosting and linkage of useful magnetic flux. In addition, an alternative copper shielding methodology was selected with the advantage of having fewer eddy current power losses per unit mass when compared with aluminum of the same physical dimension. From the simulation results obtained, the proposed flux-pipe model offers higher coil-to-coil efficiency and a significant increase in power level when compared with equivalent circular, rectangular and traditional flux-pipe models over a range of load resistance. The proposed model design is capable of transferring over 11 kW of power across an airgap of 200 mm with a coil-to-coil efficiency of over 99% at a load resistance of 60 Ω.
Highlights
Wireless power transfer (WPT) technology involves the use of electromagnetic waves to transmit electrical power through space [1]
Electromagnetic radiation-based WPT is denoted as microwave power transfer, inductive coupling-based WPT is often denoted as uncompensated inductive power transfer, and magnetic resonant coupling-based WPT is denoted as compensated inductive coupled power transfer [8,9]
For typical flux-pipe resonant coils, there are three areas of optimization—the coil winding, the ferrite core geometry and the selection of appropriate shield material based on Equations (1)–(3)—to achieve stronger coupled, lower loss, higher power and higher power transfer efficiency (PTE) of the resonant coils
Summary
Wireless power transfer (WPT) technology involves the use of electromagnetic waves to transmit electrical power through space [1]. For the commercial deployment of WPT, the major areas available for improvement are transmission distance, transmission efficiency and transmitted power level. 2019, 12, 3534 deployment of WPT, the major areas available for improvement ofare transmission distance, transmission efficiency and transmitted power level. Four major factors significantly affect the optimal design and technological drive towards achieving high transmission significantly affect the optimal design technological drive towardsdesign, achieving transmission distance, efficiency, and power. Flat [5], circular coils, rectangular geometry significantly impacts level of transmission efficiency. In this design, the fundamental flux path is reduced thereby thecoil overall size of the reducing resonant coil in addition bettercoil longitudinal and to aboutreducing.
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