Abstract
Most of the coil designs for wireless power transfer (WPT) systems have been developed based on the “single transmitter to a single receiver (S-S)” WPT systems by the empirical design approaches, partial domain searches, and shape optimization methods. Recently, the layout optimizations of the receiver coil for S-S WPT systems have been developed using gradient-based optimization, fixed-grid (FG) representation, and smooth boundary (SB) representation. In this paper, the new design optimization of the transmitter module for the “single transmitter to multiple receivers (S-M)” WPT system with the resonance optimization for the S-M WPT system is proposed to extremize the total power transfer efficiency while satisfying the load voltage (i.e., rated power) required by each receiver and the total mass used for the transmitter coil. The proposed method was applied to an application model (e.g., S-M WPT systems with two receiver modules). Using the sensitivity of design variables with respect to the objective function (i.e., total power transfer efficiency) and constraint functions (i.e., load voltage of each receiver module and transmitter coil mass) at each iteration of the optimization process, the proposed method determines the optimal transmitter module that can maximize the total power transfer efficiency while several constraints are satisfied. Finally, the optimized transmitter module for the S-M WPT system was demonstrated through comparison with experiments under the same conditions as the simulation environment.
Highlights
In order to successfully develop single transmitter to multiple receivers (S-M) Wireless power transfer (WPT) systems with the predetermined commercial receiver modules, the design of the transmitter module is very important because the transmitter coil, input power, and compensated capacitances are directly related to the inductances and reactive power for the power transfer capacity and efficiency
The proposed method is to maximize the objective function while satisfying all constraints by using the structural and electrical design variables
Mathematics 2021, 9, 2928 proposed method is to maximize the objective function while satisfying all constraints by using the structural and electrical design variables
Summary
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. The method in [26] can determine the optimal receiver coil layout for S-S WPT systems that can maximize the power transfer efficiency while satisfying all of the selected constraints (e.g., mass of the receiver coil and rated power required by a receiver module) under the given conditions. The proposed method is to maximize the objective function (e.g., total power transfer efficiency in this paper) while satisfying all constraints (e.g., total coil mass used for the transmitter coil and the load voltage required by each receiver module) by using the structural and electrical design variables. Mathematics 2021, 9, 2928 proposed method is to maximize the objective function (e.g., total power transfer effi of 16 ciency in this paper) while satisfying all constraints (e.g., total coil mass used for the transmitter coil and the load voltage required by each receiver module) by using the structural and electrical design variables.
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