A Novel Decentralized PWM Interleaving Technique for Ripple Minimization in Series-stacked DC-DC Converters

S. Dutta, B. Majmunović, S. Mukherjee, R. Mallik, Gab-Su Seo, D. Maksimović, Brian B. Johnson
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引用次数: 1

Abstract

Cascaded dc-dc converters are commonly used in applications where distributed energy sources or loads are connected to elevated voltage levels for power transfer. In such systems, it is advantageous to minimize the ripple on the bus current and voltage by proper phase shifting of the pulse-width modulation (PWM) pulses among the converters via a method known as interleaving. Existing approaches use either a centralized controller or separate communication lines among the stacked converters to control their relative PWM switch transitions. The key drawbacks are that these methods entail significant wiring, the central controller acts as a single point of failure, and implementation on very large numbers of units is impractical. In this paper, we introduce a decentralized interleaving control (DIC) strategy that acts on local current measurements at every converter and achieves communication-free PWM interleaving among the series-stacked converters. The proposed controller is simple in structure and is shown to converge asymptotically to the interleaved state irrespective of clock drifts among the digital signal processors. Experimental results are provided for a system of five series-connected converters showing a 10× reduction in the current ripple compared to normal operation.
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串联堆叠DC-DC变换器纹波最小化的分散PWM交织技术
级联dc-dc转换器通常用于分布式能源或负载连接到高电压电平进行电力传输的应用中。在这样的系统中,通过一种称为交错的方法,在变换器之间适当地移相脉宽调制(PWM)脉冲,可以使母线电流和电压上的纹波最小化。现有的方法要么使用集中控制器,要么在堆叠的变换器之间使用单独的通信线路来控制它们的相对PWM开关转换。主要的缺点是这些方法需要大量的布线,中央控制器充当单点故障,并且在大量单元上实现是不切实际的。本文介绍了一种分散交错控制(DIC)策略,该策略作用于每个变换器的本地电流测量,并在串联堆叠变换器之间实现无通信的PWM交错。所提出的控制器结构简单,并且与数字信号处理器之间的时钟漂移无关,可以渐近收敛到交错状态。实验结果表明,与正常工作相比,五个串联变换器系统的电流纹波减小了10倍。
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