研究目的
To introduce the Z-source converter for power factor correction (PFC) applications through a wireless power transfer (WPT) system for electric vehicle battery charging, demonstrating its ability to perform PFC and regulate the system output voltage simultaneously without additional semiconductor devices and control circuitry.
研究成果
The Z-source resonant converter (ZSRC) effectively performs power factor correction (PFC) and regulates output voltage in a single stage, offering advantages over conventional PFC converters, including immunity to shoot-through states and suitability for high-power applications. Experimental results validate the theoretical analysis and simulations, demonstrating the ZSN's effectiveness in PFC applications for WPT systems.
研究不足
The study focuses on a specific application (EV battery charging) and power level (1-kW prototype). The control scheme may require optimization to meet harmonic standards, and soft switching could improve efficiency.
1:Experimental Design and Method Selection:
The Z-source resonant converter (ZSRC) is designed for PFC applications in a WPT system for EV battery charging. The ZSN inherently performs PFC and regulates output voltage.
2:Sample Selection and Data Sources:
A 1-kW prototype with a 20-cm air gap between primary and secondary sides is used for simulations and experimental validation.
3:List of Experimental Equipment and Materials:
Components include ZSN capacitors (C1, C2), inductors (L1, L2), resonant capacitors (Ccp, Ccs), and a transformer with specific turns ratio.
4:Experimental Procedures and Operational Workflow:
The system operates at a switching frequency of 18.2kHz, with simulations and experiments conducted at full and half load conditions.
5:2kHz, with simulations and experiments conducted at full and half load conditions.
Data Analysis Methods:
5. Data Analysis Methods: Performance is evaluated based on power factor, output voltage regulation, and efficiency, with comparisons made to conventional PFC converters.
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