This paper discussed the LC series circuit, then proposed method to select the reactor reactance rate to support the use of the capacitor.
本文在讨论了LC串联电路之后,提出了与电容器配套使用的电抗器电抗率的选取方法。
As discussed in Section 2.3.2, the decreasing reactance of the capacitor with increasing frequency will increase the gain of the feedback ammeter.
如第2.3.2节所述,电容器的容抗随着频率的增加而降低,这就会增加反馈电流表的增益。
Analysis and simulation results show that different harmonic currents flowing into the capacitor circuit is different due to different reactance ratio of series reactor.
分析与计算结果表明,因串联电抗器的电抗率不同,其流进电容器回路的谐波电流也截然不同。
At present most of manufacturers filter 3rd harmonic by using Angle glaucoma connection capacitor to connect 14.5 reactance, in fact there is only slight effect.
目前大部分厂商采用角型连接电容器串接14.5%电抗器滤除3次谐波,其实作用甚微。
Capacitor Banks with various reactance ratio have different functions to harmonic.
不同电抗率的电容器组对谐波有不同的作用。
Using capacitor bank with two different reactance rates, 4.5%and 12%, can effectively suppress two main harmonies 3rd and 5th.
采用4.5%和12%两种不同电抗率下的电容器组,可有效地抑制5次、3次两个主要谐波。
The reactance of an ideal capacitor approaches to zero with increasing frequency.
随着频率增加,理想电容的电抗会接近零。
The influence of the DC capacitor value. transformer reactance and controller parameters on power system stability is analyzed.
系统地分析了ASVG直流侧电容量、变压器电抗值以及控制参数对电力系统稳定性的影响;
The influence of the DC capacitor value. transformer reactance and controller parameters on power system stability is analyzed.
系统地分析了ASVG直流侧电容量、变压器电抗值以及控制参数对电力系统稳定性的影响;
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