Development of a Wireless Charging System Using Resonant Inductive Coupling and Simulation

Abstract

Throughout this thesis, I will explore wireless power transfer (WPT) systems based on resonant inductive coupling. Compensation topologies, coil parameters and other significant parameters such as coupling efficiency, operating frequency, and the effect of ferrite backing will be analyzed as well. A circular coil is selected due to its symmetrical field and efficiency advantages. Series–Series (SS) compensation topology is taken into account due to its simplicity and voltage stability. Simulation tools like ANSYS Maxwell and LTspice are used to supplement theoretical analysis. Power point is used for design. A full circuit design and physical model of the coil will then be developed in the subsequent stage based on the findings elaborated.Throughout this thesis, I will explore wireless power transfer (WPT) systems based on resonant inductive coupling. Compensation topologies, coil parameters and other significant parameters such as coupling efficiency, operating frequency, and the effect of ferrite backing will be analyzed as well. A circular coil is selected due to its symmetrical field and efficiency advantages. Series–Series (SS) compensation topology is taken into account due to its simplicity and voltage stability. Simulation tools like ANSYS Maxwell and LTspice are used to supplement theoretical analysis. Power point is used for design. A full circuit design and physical model of the coil will then be developed in the subsequent stage based on the findings elaborated.