期刊
IEEE TRANSACTIONS ON POWER ELECTRONICS
卷 38, 期 6, 页码 7910-7919出版社
IEEE-INST ELECTRICAL ELECTRONICS ENGINEERS INC
DOI: 10.1109/TPEL.2023.3257372
关键词
Clamps; Batteries; Voltage; Battery chargers; Couplers; Voltage control; Topology; Battery charger; clamp coil; configurable output; inductive power transfer (IPT); self-sustained constant current (CC) to constant voltage (CV) transition
This article proposes a wireless charger with a proper second-order compensation network to reduce the size of the clamp coil and cost. The charger features automatic and smooth CC-to-CV transition, near unity power factor, soft switching, and open-circuit protection during CC charging.
To self-sustain the constant current (CC) output to constant voltage (CV) output transition for inductive power transfer (IPT) chargers, the clamp coil-assisted IPT battery chargers are better than the existing solutions due to the merits of no additional switching components, sensors, and control circuits. However, the clamp coil of these IPT chargers is bulky and hard to design, as the mutual inductances between the clamp coil and the main coupler coils are significant to the output performances. To facilitate the small clamp coil in the transmitter, this article proposes a family of IPT battery chargers with a proper second-order compensation network on the secondary side. The output thresholds of the IPT charger with the proper compensation can be readily configured to cope with the desired charging profile, and the clamp coil can be designed very small to decrease the corresponding cost and size. In addition, the proposed three-coil IPT charger still features automatic and smooth CC-to-CV transition to eliminate wireless communication, near unity power factor to minimize voltage-ampere ratings, soft switching to improve transfer efficiency, and open-circuit protection during CC charging. An experimental prototype of a 48 V/2.5 A battery charger is built to verify the analysis.
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