提出了用于功率因数校正时主要储能元件参数的计算方法。
The calculating method to identify the system parameters is recommended.
文中分析TCSC、UPFC、TCPST和储能元件对距离保护产生影响的决定性因素。
This paper analyzes the affection of UPFC, TCPST, TCSC and energy storage elements to distance protection.
超级电容器作为一种新型的储能元件,兼具了电解电容器的高功率和电池的高比能的优势。
Supercapacitors are new energy storage, combining the advantages of the high specific power of dielectric capacitors and the high specific energy of rechargeable batteries.
本论文从开关变换器实际应用的场合考虑,分析了变换器主要储能元件以及负载的干扰因素成分。
This paper analyses the disturbances components of energy storage device and load in main circuit based on the practical application of switching converter.
本文中研究了超级电容器储能系统的发电控制,其中的储能元件采用超级电容器这一新型能源器件。
This paper studies control of the energy system based on super capacitors. Super capacitor, a novel energy storage component, is used here.
高压储能电容器作为脉冲功率系统的核心储能元件,其绝缘性能直接关系到脉冲功率系统工作可靠性。
The insulation capability of High Voltage Storage Capacitor (HVSC), which is the kernel of impulse power, determines the service reliability of impulse power system.
基于以电容器为直流侧储能元件STATCOM在系统不对称情况下的数学模型,详细分析和解释了STATCOM在系统不对称条件下的运行特点、谐振现象以及参数对STATCOM的性能影响。
The model can be used to research the STATCOM behavior to provide theoretical guidance for optimal parameter design and to enhance STATCOM viability for asymmetric power systems.
目前常规弹性元件有弹簧、橡皮和气垫,被广泛地应用在工业企业中,满足了工业领域很多弹性储能的需求。
Current conventional elastic elements are springs, rubber and air cushion, which are widely used in industrial enterprises meeting a lot of elastic energy storage needs.
本文提出了一种基于超导线圈与可控电力变换器储能系统的主要元件。
This article presents the main elements of an energy storage system based on a superconducting coil and a controlled power converter.
磁性元件在开关电源中起着非常重要的作用,如储能、变压、滤波等。
The magnetic component plays a very important role in Switching Power Supply, for instance energy storage, converting voltage, filtering waves, etc.
在储能电容器中,双电层电容器的储能密度特别高,但其内电阻大,且元件的输出电压低。
Electric double-layer capacitors (EDLC) exhibit very high storage energy density compared with other capacitors, but their inner resistance is rather higher and output voltage lower.
该系统采用电容存储电荷的方式积蓄能量,避免了电感储能方式带来的电磁干扰,减小了存储元件的寄生电阻。
The system adopts capacitor to reserve charge and accumulate energy, which avoids the electromagnetic interference and reduces the parasitic resistance comparing with the method of using inductor.
该系统采用电容存储电荷的方式积蓄能量,避免了电感储能方式带来的电磁干扰,减小了存储元件的寄生电阻。
The system adopts capacitor to reserve charge and accumulate energy, which avoids the electromagnetic interference and reduces the parasitic resistance comparing with the method of using inductor.
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