Three-Coil Wireless Charging System Based on S-PS Topology

To protect the battery, radio energy transmission charging typically uses constant current (CC) charging before switching to constant voltage (CV) charging to enhance battery durability. This paper proposes adding an auxiliary clamp coil to the original circuit topology. The IPT battery charger desi...

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Bibliographic Details
Published in:Energies (Basel) 2024-08, Vol.17 (15), p.3606
Main Authors: Yan, Kai, Dang, Ruirong, Wang, Wenzhen
Format: Article
Language:English
Subjects:
auxiliary clamp coil
Battery chargers
battery charging
constant current and constant voltage output mode conversion
constant current output (CC)
constant voltage output (CV)
Design
Efficiency
induced power output (IPT)
Interoperability
Lithium
Load
Systems design
Systems stability
Ultrasonic transducers
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Summary:To protect the battery, radio energy transmission charging typically uses constant current (CC) charging before switching to constant voltage (CV) charging to enhance battery durability. This paper proposes adding an auxiliary clamp coil to the original circuit topology. The IPT battery charger designed with the auxiliary clamp coil can achieve both constant current (CC) and constant voltage (CV) outputs. The mutual inductance between the auxiliary clamp coil and the primary side coil greatly influences the output performance of the entire IPT system, so the auxiliary clamp coil should not be too large. To solve this problem, an S-S-PS circuit with secondary compensation topology in the secondary coil is proposed. This circuit topology reduces the size of the auxiliary clamp coil, allowing it to be placed in an optimal position. When the constant voltage output critical position is reached, the IPT system can still automatically, continuously, and smoothly switch between CC and CV modes. Consequently, this approach avoids increased cost consumption associated with detecting CC-CV switching thresholds, adding wireless transmission communication modules, real-time control of the power transmitter, and active protection of the circuit during constant current charging. Finally, a 48 V/2.5 A prototype was built to verify that the IPT system has CC-CV conversion functionality.
ISSN:1996-1073
1996-1073
DOI:10.3390/en17153606