基于ΔΣ超频的高功率密度空间功率平台

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摘要空间功率平台(PCU)多采用电流型跨导控制的S4R架构, 母线输出电容滤波阵一般由低容值的自愈电容组成。针对功率平台基板面积、体积及重量的限制条件, 在满足与滞环跨导控制相同的开关管损耗和母线稳态纹波指标情况下, 提出采用ΔΣ控制策略对局部开关进行超频驱动, 降低了自愈电容阵的容值且提升了高功率密度。从功率谱分析角度阐述了超频驱动减小电容阵容值的机理, 给出了驱动电路, 定量分析了超频范围, 建立了超频电源控制器数学模型, 给出了控制参数设计办法。仿真及实验证实超频驱动的S4R的动态性及功率密度优于滞环驱动的S4R。

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关键词 ： S4R, &Delta, &, #x003a3, 控制策略, 超频, 功率密度, 建模, 稳定性分析

Abstract：Sequential switch series shunt regulator(S4R) is used as space photovoltaic(PV) 20kW power conditioning unit(PCU). In order to improve high power density, a reasonable solution is reducing the filter healing capacitor array size and weight. Sigma-delta control strategy is proposed to gate the shunt switch by overclocking at the same efficiency with the hysteretic control. Modeling, loop design and system stable of sigma-delta control is analyzed in this paper. A better dynamic performance and power density ratio than the Bang-Bang control is proved by simulation and experiment.

Key words： Sequential switch series shunt regulator(S4R) sigma-delta control strategy overclocking power density modeling stable

收稿日期: 2012-09-20 出版日期: 2014-03-25

PACS:

TM391.9

基金资助:国家国际合作计划资助项目(2010DFB63050)

作者简介: 苗狄男, 1980年生, 博士, 主要从事新能源电力电子技术的研究。张乃通男, 1934 年生, 教授, 博士生导师, 研究方向为通信与信息工程。

引用本文:

苗狄, 张东来, 张乃通. 基于ΔΣ超频的高功率密度空间功率平台[J]. 电工技术学报, 2013, 28(8): 233-240. Miao Di, Zhang Donglai, Zhang Naitong. Research on Space Power Conditioning Unit with High Power Density Based on ΔΣ Overclocking Characteristics. Transactions of China Electrotechnical Society, 2013, 28(8): 233-240.

链接本文:

http://dgjsxb.ces-transaction.com/CN/Y2013/V28/I8/233

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