期刊
IEEE TRANSACTIONS ON POWER ELECTRONICS
卷 38, 期 3, 页码 4124-4139出版社
IEEE-INST ELECTRICAL ELECTRONICS ENGINEERS INC
DOI: 10.1109/TPEL.2022.3218709
关键词
Tuning; Topology; Resonant frequency; Optimization methods; Integrated circuit modeling; Capacitors; Zero voltage switching; Constant voltage (CV) output; double-sided LCC (DS-LCC); efficiency optimization; inductive power transfer (IPT); parameter tuning method; zero phase angle (ZPA)
This article proposes a parameter tuning method for the DS-LCC compensated IPT system to achieve load-independent constant voltage output and zero phase angle without changing the operating frequency. By optimizing the two compensation factors, the overall system efficiency is improved without affecting the properties of CV and ZPA.
A parameter tuning method is critical for inductive power transfer (IPT) systems because it ensures constant output and reduces reactive power. This is especially true for the double-sided LCC (DS-LCC) compensated IPT system due to its high parameter tuning freedom. This article proposes a parameter tuning method for the DS-LCC compensated IPT system. By reconfiguring key resonant parameters, the load-independent constant voltage (CV) output and zero phase angle (ZPA) can be achieved without varying operating frequency. Based on this, two compensation factors for the primary and secondary compensation inductances are defined, and the performance of the IPT system under different compensation factors and the optimal matching criterion of these two factors are investigated in detail. By optimizing these two compensation factors, the overall system efficiency is improved over the entire power range without affecting the property of CV and ZPA. A 2-kW experimental prototype is built to validate the practicability of the proposed tuning method. The experimental results indicate that when the dc load varies from 13.4 to 134 Omega, ZPA can always be achieved, and the output voltage fluctuation is only 4.6 V. The peak efficiency reaches 92.14% at a 1.6-kW output power.
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