In wireless energy transfer systems, the energy is transferred from a power source to an electrical load without the need of physical connections. In this scope, inductive links have been widely studied as a way of implementing these systems. Although high efficiency can be achieved when the system is operating in a static state, it can drastically decrease if changes in the relative position and in the coupling coefficient between the coils occur. In this paper, we analyze the coupling coefficient as a function of the distance between two planar and coaxial coils in wireless energy transfer systems. A simple equation is derived from Neumann’s equation for mutual inductance, which is then used to calculate the coupling coefficient. The coupling coefficient is computed using CST Microwave Studio and compared to calculation and experimental results for two coils with an excitation signal of up to 10 MHz. The results showed that the equation presents good accuracy for geometric parameters that do not lead the solution of the elliptic integral of the first kind to infinity.

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inductive links elliptic integral coupling coefficient cst microwave studio wireless energy transfer geometric parameters mutual inductance planar and coaxial coils

Rafael Mendes Duarte,Gordana Klaric Felic,.Analysis of the Coupling Coefficient in Inductive Energy Transfer Systems. 2014 (),.

Rafael Mendes Duarte,Gordana Klaric Felic,"Analysis of the Coupling Coefficient in Inductive Energy Transfer Systems" 2014

Rafael Mendes Duarte,Gordana Klaric Felic,"Analysis of the Coupling Coefficient in Inductive Energy Transfer Systems"