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引用次数: 2
摘要
介绍了在阻抗控制网络(ICN)谐振变换器中实现所有晶体管零电压开关(ZVS)的控制策略。采用传统的$\phi$控制策略,ICN变换器由于其逆变器晶体管的宽范围软开关能力,非常适合于输入电压变化较大的应用。本文提出的控制策略可以同时实现逆变和整流晶体管的软开关,从而扩展了变换器在更高、更宽输出电压下的适用性。提出了两种控制策略,即基于$\psi$和基于$\phi\psi$的控制,并对其软开关能力和谐振槽内剩余循环电流进行了比较。结果表明,基于$\phi\psi$的控制策略通过大幅减小循环电流提供了优越的性能。建立了一个15 V至2.5 V、10 W、400 khz的ICN变换器原型,并对所提出的控制策略进行了测试。基于$\phi\psi$的控制策略实现5% higher efficiency compared to the $\psi$-based control strategy.
Control Strategies for Complete Soft-Switching of ICN Converters
This paper introduces the control strategies that enable zero-voltage switching (ZVS) of all the transistors in impedance control network (ICN) resonant converters. With the conventional $\phi$-based control strategy, ICN converters are well-suited for applications with wide variation in input voltage, owing to wide range soft switching capability of their inverter transistors. The control strategies presented in this paper simultaneously allow soft switching of all its inverter and rectifier transistors, thus extending the converter’s applicability to higher and wider output voltages. Two such control strategies, namely, $\psi$ and $\phi\psi$-based control, are presented and compared in terms of their soft switching capability and residual circulating currents in the resonant tank. It is shown that $\phi\psi$-based control strategy offers superior performance by substantially reducing circulating currents. A 15 V-to-2.5 V, 10- W, 400-kHz ICN converter prototype is built and tested with the proposed control strategies. $\phi\psi$-based control strategy achieves 5% higher efficiency compared to the $\psi$-based control strategy.
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