Abstract
Contactless power transfer (CPT) technology development has been driven rapidly over the past decade by the world-wide trends towards new energy explorations, and numerous reports have been presented in this area. This paper focuses on passive magnetic shielding, which acts as one of the major factors mainly determining the overall CPT system performance when discussing electromagnetic field flux distribution and its real-time effects on magnetic resonant coupling. As a well performance conductive metallic material, aluminium has been adopted to be a passive shielding material in the designed novel H-shape coupler CPT system in this paper, in order to evaluate and find out the optimal inner shielding distance in between the coil and the inner shielding shell. Three inner shielding distances are applied and analyzed across a critical range of system operating frequency, by which the actual CPT system performance differences from perspectives of electromagnetics and power electronics have been illustrated and compared. As a result, it can be noticed that the 15-mm inner shielding gap CPT model is able to yield an optimal system performance with a maximum system efficiency, peak system output RMS power of over 36% and 22 kW, respectively, which also shows an optimal capability to address major concerns over electric vehicle contactless charging. Besides, along with the electromagnetic field parameters generated in the model, such as actual real-time values of flux linkage, magnetic flux density and field strength, it can be found that the 15-mm inner shielding gap prototype is able to achieve better overall magnetic field performance than 5-mm and 25-mm inner shielding distance CPT models.
Highlights
Inductive coupling based technologies have been gaining considerable attentions in consumer electronics, factory automations, medical implants, lightings, defense systems and electric vehicles [1]-[4]
This paper focuses on passive magnetic shielding, which acts as one of the major factors mainly determining the overall Contactless power transfer (CPT) system performance when discussing electromagnetic field flux distribution and its real-time effects on magnetic resonant coupling
It can be noticed that the 15-mm inner shielding gap CPT model is able to yield an optimal system performance with a maximum system efficiency, peak system output RMS power of over 36% and 22 kW, respectively, which shows an optimal capability to address major concerns over electric vehicle contactless charging
Summary
Inductive coupling based technologies have been gaining considerable attentions in consumer electronics, factory automations, medical implants, lightings, defense systems and electric vehicles [1]-[4]. 2. CPT system design Based on the effectiveness of high permeability and low core loss of soft ferromagnetic materials, the geometrically improved H-shape soft magnetic core coupler is proposed to form magnetic flux line trajectories and enhance flux distributions within the inductive coupling space in and between the cores and coils, which can lead to optimal CPT system coupling performance especially at electromagnetic resonant coupling status [6]. Due to contributions of minimizing reactance magnitude, the S-S compensation topology has been adopted in the designed CPT system in this paper, as shown in figure 2
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
