中国电机工程学报
中國電機工程學報
중국전궤공정학보
ZHONGGUO DIANJI GONGCHENG XUEBAO
2013年
24期
52-58
,共7页
矩阵变换器%模块化多电平矩阵变换器%模块化多电平变换器%电容纹波电压%频率
矩陣變換器%模塊化多電平矩陣變換器%模塊化多電平變換器%電容紋波電壓%頻率
구진변환기%모괴화다전평구진변환기%모괴화다전평변환기%전용문파전압%빈솔
matrix converters%modular multilevel matrix converters (M3C)%modular multilevel converters (MMC)%capacitors ripple voltage%frequency
模块化多电平矩阵变换器(modular multilevel matrix converters,M3C)是一种新型的基于级联 H 桥的直接交–交变换器拓扑结构,可用中/高压功率频率变换场合,但其应用范围受 H 桥子模块直流侧电容纹波电压的限制。从能量守恒角度研究M3C子模块电容电压的一般性波动规律,导出稳态条件下电容纹波电压与M3C输入/出频率、功率因数、电压比值等参量之间的定量关系。对各参量对纹波电压的影响程度进行理论分析并得出下列结论:电容纹波电压中一般含有输入/输出频率的二倍频、差频及和频4种频率成分,在几种特例中仅包含3种频率成分;电容纹波电压幅值对输入/输出频率比值变化非常敏感,当输入和输出频率彼此接近或一个趋近于零时,纹波电压幅值会逐渐变得很大,导致M3C无法正常工作。仿真计算验证了理论分析的正确性。
模塊化多電平矩陣變換器(modular multilevel matrix converters,M3C)是一種新型的基于級聯 H 橋的直接交–交變換器拓撲結構,可用中/高壓功率頻率變換場閤,但其應用範圍受 H 橋子模塊直流側電容紋波電壓的限製。從能量守恆角度研究M3C子模塊電容電壓的一般性波動規律,導齣穩態條件下電容紋波電壓與M3C輸入/齣頻率、功率因數、電壓比值等參量之間的定量關繫。對各參量對紋波電壓的影響程度進行理論分析併得齣下列結論:電容紋波電壓中一般含有輸入/輸齣頻率的二倍頻、差頻及和頻4種頻率成分,在幾種特例中僅包含3種頻率成分;電容紋波電壓幅值對輸入/輸齣頻率比值變化非常敏感,噹輸入和輸齣頻率彼此接近或一箇趨近于零時,紋波電壓幅值會逐漸變得很大,導緻M3C無法正常工作。倣真計算驗證瞭理論分析的正確性。
모괴화다전평구진변환기(modular multilevel matrix converters,M3C)시일충신형적기우급련 H 교적직접교–교변환기탁복결구,가용중/고압공솔빈솔변환장합,단기응용범위수 H 교자모괴직류측전용문파전압적한제。종능량수항각도연구M3C자모괴전용전압적일반성파동규률,도출은태조건하전용문파전압여M3C수입/출빈솔、공솔인수、전압비치등삼량지간적정량관계。대각삼량대문파전압적영향정도진행이론분석병득출하렬결론:전용문파전압중일반함유수입/수출빈솔적이배빈、차빈급화빈4충빈솔성분,재궤충특례중부포함3충빈솔성분;전용문파전압폭치대수입/수출빈솔비치변화비상민감,당수입화수출빈솔피차접근혹일개추근우령시,문파전압폭치회축점변득흔대,도치M3C무법정상공작。방진계산험증료이론분석적정학성。
The modular multilevel matrix converter (M3C) is a novel direct AC converter topology based on the cascaded H-bridge, and is available in medium/high voltage power frequency conversion occasions. However, its application fields are limited by the DC capacitor ripple voltage of the H-bridge sub-module. In this paper, a general variation rule of the capacitor voltage ripple was studied from the energy conservation point of view, and the quantitative relationships among the ripple voltage and the M3C input/output frequency, power factor, voltage ratio were derived on the steady-state conditions. The impacts of the different parameters on the ripple voltage were analyzed in details. The following conclusions were drawn:the ripple voltage in general contains the doubling, difference and sum frequency components of the M3C input and output, while only three kinds of frequency components were included in several special cases; the ripple voltage amplitude was very sensitive to the input/output frequency ratio, and when the input and output frequencies approach each other or one of them tends to zero, the ripple voltage amplitude will gradually become very large, causing the M3C to work improperly. The simulation and calculation results validate the correctness of the theoretical analysis.