储能元件

  • 网络energy storage element;energy-storage elements
储能元件储能元件
  1. 根据点火储能元件的不同,点火器主要有电容充放电点火(CDI)和晶体管点火(TCI)两种类型。

    The ignition module can be divided into 2 types , id est : the capacitor discharge ignition module ( CDI ), and transistorized coil ignition module ( TCI ) according to the difference of the energy storage element .

  2. 新型电控液驱车辆储能元件特性分析

    Study on Characteristics of Energy Storage Element for a New Vehicle with Electronic Control and Hydraulic Drive

  3. PWM整流器根据直流储能元件不同可分为电压型PWM整流器和电流型PWM整流器。

    According to the dc-link energy storage elements , PWM rectifiers are classified into voltage-source PWM rectifiers and current-source PWM rectifiers .

  4. 动力电池作为HEV的主要储能元件,直接影响到HEV的性能。

    As the main energy storage components , battery affects the performance of HEV directly .

  5. 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 .

  6. 本文首先简要介绍了脉冲功率技术和储能元件、国内外多层陶瓷电容器(MLC)的发展现状,阐明了论文研究的主要内容。

    First of all , the pulsed power technology and energy storage components are represented in chapter 1 . Mean while , the development status of multi-layer ceramic capacitor ( MLC ) home and aboard and the main research contents are described as well .

  7. 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 .

  8. 飞轮是一种重要的储能元件。

    The-flywheel is a kind of important energy storage component .

  9. 无额外直流储能元件的串联型电能质量控制器新型控制策略

    Novel Control for Series Power Quality Controller Without External DC Energy Source

  10. 新能源形势下储能元件及其装备的发展机遇

    Development Opportunities of Energy Storage Component and Its Equipment for New Energy

  11. 分析了各种储能元件的性能特点。

    The characteristics of energy storage components are analyzed .

  12. 因此,这种陶瓷电容器适合用作强脉冲大功率电源的储能元件。

    It can be used as energy storage component in large pulse power electric sources .

  13. 由于操作,暂态过程使电力系统中的电容、电感等储能元件的工作状态发生了变化。

    Because of operation , transient process can make the energy storage components in the power system working state changed .

  14. 超级电容器是一种具有更高能量密度的新型储能元件。其显示出极好的可逆性和长的循环寿命,在世界范围内引起了极大关注。

    Supercapacitors are novel charge-storage devices of high power energy density , which exhibit excellent reversibility and a long cycle life .

  15. 本文介绍了以超级电容器作为储能元件的储能系统在直流电力系统中的应用。

    This paper analyzes the super-capacitor applied in the DC power system , in which super-capacitor plays as an energy storage element .

  16. 由于无损耗电阻器可由理想开关阵列和电路储能元件组成,所以损耗极小。

    The Loss-Less Resistor is realized using a switch mode circuit technique and a storage element to reduce the lose of LFR .

  17. 超级电容器作为储能元件,具有重要的战略意义,与常规的电解电容器相比,明显地提高了比容量、比能量;

    S : Compared with conventional electrolytic , supercapacitor ( electrochemical capacitor ) improves the specific capacitance , the specific energy density dramatically .

  18. 由于电感是储能元件,其能量的释放若不加控制将呈指数衰减,并不能有效的得到利用。

    Because the inductor is energy storage component , the energy will exponentially decay if uncontrolled , and can not be effectively utilized .

  19. 纯电动汽车以电池作为储能元件,性能优越的锂离子电池正在逐渐成为市场主流。

    Pure electric vehicle take battery as an energy storing device . Lithium-ion battery for its superior performance is gradually becoming the market mainstream .

  20. 脉冲功率技术中常见的储能元件为电容器,实现电容器快速高效的充电是脉冲功率技术的前提。

    The charging speed and efficiency of the capacitor , a common energy storage device , is crystal prerequisite for the pulsed power technology .

  21. 在燃料电池供电系统中,一般加入储能元件和双向变换器来辅助供电,以提高整个系统的动态性能。

    In fuel cell power system , energy storage device and bi-directional dc-dc converter ( BDC ) are employed to improve the system dynamic performance .

  22. 根据电解电容器的放电寿命指标以及非振荡放电特点,提出了以电解电容器为储能元件的高效能脉冲电源方案。

    Considering discharge life limit and non-vibration demand about electrolytic capacitor , a high-performance pulsed power supply project using electrolytic capacitor to store energy is proposed .

  23. 本文中研究了基于超级电容器的电压控制技术,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 .

  24. 超级电容器是近年发展起来的一种新型储能元件,具有功率密度高、寿命长、无需维护及充放电迅速等特性。

    The supercapacitor is a new type of energy storage device with performance of high power density , long cycle life , maintenance-free , quick charging and discharging .

  25. 它兼具传统物理电容器高功率及化学电池高能量密度的优点,是一种介于电池和静电电容器之间的新型储能元件。

    It combines the high-power of traditional physical capacitor and the high-energy density of chemical batteries , it is a new energy storage components between batteries and electrostatic capacitors .

  26. 电力驱动系统作为混合动力汽车的核心部分,主要涉及到储能元件的功率变换、电机驱动等技术。

    To being the core part of HEV system , the power drive equipment mainly involves power conversion of the storage energy cell , motor drive and so on .

  27. 研究了自适应电流速断保护中实时计算系统等值参数的一种傅氏算法。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 algorithms of real-time calculating system parameters are studied for adaptive current fast-tripping protection of power system . The calculating method to identify the system parameters is recommended .

  28. 超级电容器作为新型储能元件,由于循环寿命长,可逆性良好,能量密度和功率密度高等的优点,一经问世便受到广泛关注。

    As new energy storge devices , supercapacitors have received extensive attention because of their unique including long cycle life , superior reversibility , and high energy and power density .

  29. 核心是根据光伏电池和混合储能元件的工作状态,保证三个变换器工作在系统设定的工作模式下,使得系统中的三种电源协调工作,保证系统稳定运行。

    The core is to ensure three converters work in set mode and three power sources coordinating and stable work according to the photovoltaic cells and hybrid energy storage components working condition .

  30. 电容器是脉冲功率设备的重要储能元件,提高电容器的储能密度能有效地减小脉冲电源的体积。

    Capacitors are important storage components in pulsed power equipment . In order to reduce the volume of the power source equipment , the energy storage density of the capacitors must be increased .