Supercapacitor Consisting of a Form Core Sandwich with Woven Carbon Fiber Skin

Structural capacitors are composite structures that function as energy storage capacitors. Parallel plate-type capacitors have the advantage of high voltage resistance, but are limited by low capacitance. An electric double-layer capacitor with a composite structure using a solid polymer electrolyte matrix with a glass fiber fabric separator has recently been developed. However, the solid polymer electrolyte caused the capacitor to possess high internal resistance. In the present study, a new design of supercapacitor using a form core sandwich with high water retention is proposed and experimentally investigated. Activated carbon sheets are used as electrodes on the form core sandwich to make a supercapacitor. Woven carbon fabric is used as lead wires of the supercapacitor. The resulting supercapacitor displays a low surface resistance of 810 Ωcm2 and high areal capacitance of 520 mF/cm2.

Effect of milling process on the core-shell structures and dielectric properties of fine-grained BaTiO_3-based X7R ceramic materials

Fine-grained BaTiO3-based X7R ceramic materials were prepared and the effects of milling process on the core-shell structures and dielectric properties were investigated using scanning electron microscope, transmission electron microscope, and energy dispersive spectroscopy （EDS）. As the milling time extends, the dielectric constant of the ceramics increases, whereas the temperature coefficient of capacitance at 125℃ drops quickly. The changes in dielectric properties are considered relevant to the microstructure evolution caused by the milling process. Defects on the surface of BaTiO3 particles increase because of the effects of milling process, which will make it easier for additives to diffuse into the interior grains. As the milling time increases, the shell region gets thicker and the core region gets smaller; however, EDS results show that the chemical inhomogeneity between grain core and grain shell becomes weaker.

Analysis of output voltage on a planar insulating core transformer

Output voltage is an important performance characteristic of planar insulating core transformer (PICT).In PICT magnetic cores are insulated from their neighboring magnetic cores by solid insulating materials.Solid insulating materials can increase leakage flux.This results in a low generated voltage in secondary coils,especially on the upper stages.Connecting flux compensation capacitors to secondary coils can compensate the flux loss.Design equations to calculate the flux compensation capacitors value and relevant simulation by CST and Protel software were presented.Simulation results of an actual PICT showed that output voltage increased by 19% after being connected to flux compensation capacitors and the voltage on every stage was equally distributed.Results of simulation were consistent with the following experimental test,which revealed that flux compensation capacitors were effective.

Effect of Degree of Cure on Sandwich Structural Capacitor Using Ion-Conductive Polymer with Carbon Fabric Skins

Structural capacitors are composite structures that function as energy storage capacitors. An electric double-layer capacitor with a composite structure using a solid polymer electrolyte matrix with a glass fiber fabric separator has recently been developed. In the present study, new foam core sandwich structure is adopted and the effect of the degree of cure is experimentally investigated. Carbon fiber fabric cloth is used as electrodes, and the polystyrene foam core is used as separator. Material system of Poly Ethylene Glycol DiGlycidyl Ether (PEGDGE) with Lithium bisTriFluoromethane Sulfonyl Imide (LiTFSI) and hardener of TriEthylene TetrAmine (TETA) is adopted as ion-conductive polymer matrix. The effect of the cure degree is experimentally investigated by using 100% cure degree, 70% cure degree and 0% cure degree specimens. As a result, the polystyrene foam-core sandwich system is proved to be effective, but the capacitance is not enough because of the lack of surface area of the carbon fiber electrodes. As the remained TETA impedes the movement of Li+ cation in the solid polymer by means of the segment-motion-assisted diffusion process, the low degree of cure causes small capacitance with this material system.

特高压直流套管气-固界面长时闪络放电特性及其影响因素

胶浸纸(resin-impregnated paper,RIP)干式套管内部的SF_(6)气体与环氧树脂浸纸电容芯体组成的气-固界面是套管内部易发生放电的绝缘薄弱点。该文搭建闪络放电特性实验平台,测试套管环氧浸纸试样和芯体模型在不同表面状态、微粒影响下的表面电荷分布,揭示多种因素对表面电场及闪络特性的影响机制。同时,对套管芯体缺陷试样长时局部放电至闪络放电发展过程进行试验验证。结果表明:高压侧区域套管气-固界面存在高分散性的纤维凸起,运行过程中吸附微粒,在直流电压作用下电荷积聚和电场畸变引发微弱起始局部放电;长期的电压作用使电荷积聚加剧,电场畸变程度进一步增大,局部放电频次和幅值逐步增加,最终导致贯穿性闪络放电。该研究可为胶浸纸套管芯子表面处理工艺的优化,以及长期直流下闪络放电的抑制措施的制定提供理论和实验依据。

天然酯绝缘油与电容式电压互感器的相容性研究

本文作者从天然酯绝缘油与CVT的使用材料入手,研究彼此间的相容性,通过电容器心子小型样件的元件击穿耐压试验,验证电容器心子浸渍天然酯绝缘油的性能,对后续天然酯绝缘油在CVT及耦合电容器上的利用提供了依据。

Ni–MgO核–壳纳米粉体的制备

采用包覆热分解烧结法,制备了多层陶瓷电容器内部电极用MgO包覆Ni纳米粉体,讨论了反应物浓度和分散剂含量对包覆纳米镍盐前驱体颗粒大小和均匀性的影响,分析了还原烧结温度对包覆纳米Ni粉球形度和分散性的影响,并利用X射线衍射仪、扫描电镜、透射电镜、热机械分析仪对MgO包覆纳米Ni粉进行了表征分析。结果表明:反应物浓度达到足以引起反应爆炸成核时,能够获得纳米镍盐颗粒;添加适量的分散剂,可以得到分散良好的纳米镍盐前驱体颗粒;还原烧结温度700℃时,可以获得球形度和分散性良好的MgO包覆纳米Ni粉;MgO包覆在纳米Ni粉表面,形成了核壳结构,该纳米Ni粉具有良好的收缩延迟效果。

基于价值链的企业核心能力重构

主要探讨企业在同行业及产业链间的竞争中应关注的问题,将能力要素分析法和利润库分析法相结合,以一种全新的角度分析了价值链的组成,提出企业应该基于核心能力要素与战略能力要素综合考虑的基础上去重构企业的核心竞争力。

基于高温超导电缆终端的应力锥结构设计

对35kV高温超导电缆终端应力锥进行优化设计。以各层极板长度,半径,绝缘材料介电常数等作为优化变量,以各层极板之间的电压降相等作为优化目标,采用动态惯性权重因子的改进粒子群算法对高温超导电缆终端应力锥电气参数优化设计。应用matlab软件实现应力锥优化设计算法,通过循环迭代得到应力锥最优极值。

电容器芯包引脚自动刺孔裁切机的研制

电容器芯包由电极箔和电解纸钉接卷绕而成,钉接在对应电极箔上的多层铝箔卷绕后叠加形成芯包引脚。为了提高电容器芯包引脚刺孔裁切的自动化程度,根据电容器芯包引脚刺孔裁切的工艺要求,研制了电容器芯包引脚自动刺孔裁切机。该设备由华司输送部件、华司上料部件、线性移动部件、引脚刺孔裁切部件、铝屑负压收集装置、传感检测系统、气动系统、PLC控制系统等构成。该设备可以实现多种规格电容器芯包引脚的自动刺孔裁切,整机性能稳定,实际运行状况良好。

±800kV换流变压器阀侧电容式直流套管电场分析

为研究特高压直流套管的绝缘性能,建立了±800 kV复合电容式套管有限元模型,用ANSOFT分析软件对内采用绝缘环氧树脂绝缘纸和外绝缘采用高温硫化硅橡胶外套制造的复合电容式套管进行二维电场分析,获得特高压直流套管内部精确场强分布和电位分布。该结果表明:套管内部环氧树脂中的屏障强迫了电位分布,使法兰附近的电场分布均匀,却造成法兰顶端等位线发生剧烈变化,径向电位梯度大;法兰部分与高温硫化硅橡胶伞裙的接连处电场强度最大,最大值达3.44 MV/m,在特高压直流运行时最易产生闪络,是必须注意的问题。

变压器与并联电容器的铁磁谐振分析

当变压器空载或轻载运行时,线路发生断线故障或断路器非同期合闸,可能造成并联电容器组与变压器铁芯线圈发生铁磁谐振。以系统发生单相断线故障为例,推导出谐振时电网电压与并联电容器的谐振条件表达式。通过分析谐振时并联电容器组与变压器铁芯线圈伏安特性,给出并联电容器与变压器产生铁磁谐振的机理和特点,并提出了有效抑制铁磁谐振发生的具体措施。仿真结果验证了理论分析与抑制方法的正确性。

新型光电式电压互感器研究

本文提出一种应用于500KV的光电式电压互感器。该互感器基于石英晶体的逆压电效应。高压经圆筒电容器分压后加到圆柱状的石英晶体上,晶体的压电形变被缠绕在晶体圆柱表面上的椭圆芯双模光纤传感,由低相干干涉仪对光纤中传播的两个空间模(LP01模和偶数LP11模)的微分光波相位的调制进行检测。该互感器除电容分压、石英晶体外,是一个全光纤的解决方案,没有准直仪、偏振片和波片等块状光学元件;进而降低了成本、提高了精度、便于规模化生产。本文给出了电压互感器的系统结构及绝缘设计,研究了互感器的性能,为高压电压互感器的应用提供了理论依据。

电容器同期合闸与变压器的铁磁谐振分析

并联电容器组进行无功补偿时,由于断路器开关投切方式不当,可能造成并联电容器组与变压器铁芯线圈发生铁磁谐振。文章通过断路器同期合闸时的系统发生过电压现象,对谐振时并联电容器组与变压器铁芯线圈伏安特性进行分析,给出并联电容器与变压器产生铁磁谐振的机理和特点,并提出了有效抑制铁磁谐振发生的具体措施。仿真结果验证了理论分析与抑制方法的正确性。

稀土掺杂对还原烧结钛酸钡陶瓷微结构和电性能的影响

采用固相工艺制备BaTiO3-R2O3-MgO-MnO2(R=La,Ce,Pr,Nd,Sm,Gd,Dy,Ho,Y,Er,Yb)系陶瓷,全面研究了稀土掺杂对还原烧结钛酸钡(BaTiO3)陶瓷微结构和电性能的影响。扫描电镜分析结果显示:小离子半径稀土比大离子半径稀土更有效地改善微观结构,并且随着稀土离子半径的减小,其晶粒抑制作用更加显著。实验发现:大半径稀土掺杂可生成化学均匀性晶粒,得到介电常数-温度(ε-T)单峰曲线,并导致Curie点下降;小半径稀土掺杂可生成壳-芯结构晶粒,获得ε-T双峰曲线,晶粒壳的体积相对膨胀,对晶粒芯产生的张应力作用促使Curie点上升,其平坦的电容变化率-温度(ΔC/C-T)特性满足X8R。随着稀土离子半径的增大,该体系的绝缘电阻率总体呈降低趋势,归因于稀土元素在BaTiO3中取代位及补偿方式的不同。

高压大功率反激变压器研究

利用电容可控充电方法构建雷电上行先导模拟试验用新型冲击电压发生装置,需要解决装置核心电路中高压大功率反激变压器的物理实现问题。该文从实现电场时变特征模拟的电路应用特点出发,研究提出了反激变压器技术要求,围绕其实现难点研究确定了变压器电磁设计方案,最后研制出反激变压器样机并通过电场时变特征模拟试验验证了变压器性能满足应用要求,解决了新型冲击电压发生装置构建中的关键技术难题。

螺线管空心线圈电子式电压互感器

目前,电子式电压互感器大都采用分压原理,一次侧与二次回路之间缺乏有效的电气隔离,为此提出一种螺线管空心线圈型电子式电压互感器。螺线管与电容器串联,通过测量流经电容器的电流来实现对一次侧高电压的测量。螺线管空心线圈作为电流传感器输出二次电压信号给处理电路,它不存在磁饱和问题,具有测量线性度好、测量动态范围宽等优点。装置中使用两套信号处理电路以提供多路测量信号供用户使用,采用功率放大器以保证电子式电压互感器有足够的二次负载能力。实验表明,该电子式电压互感器达到了一定的测量精度,具有良好的线性度,且响应速度快。

油浸纸套管电容芯子浸渍不良缺陷的放电过程及其特征

为了研究油浸纸套管浸渍不良缺陷的劣化机理,研制了透明的套管模型,利用良好套管模型漏油后补油不抽真空的方法,模拟浸渍不良缺陷;利用阶梯升压法,研究浸渍不良套管缺陷模型的局部放电参数、介质损耗正切值和电容量的变化情况,同时观测了放电过程中的产气部位和产气现象,并结合试验后解剖,分析油浸纸电树枝碳化通道。研究结果表明,对于油浸纸套管浸渍不良缺陷劣化过程,局部放电检测比较灵敏、特征显著,而介质损耗正切值、电容量检测不灵敏。放电位于芯子末屏极板边缘,沿极板边缘纸层表面发生电树枝沿面爬电并产生连续的气泡。放电相位呈现明显的对称分布,放电相位与放电量的φ-q散点图呈现"翼状"分布特点,可作为诊断和识别油浸纸套管电容芯浸渍不良缺陷放电严重程度的特征谱图。

核壳结构Co_3O_4水热法制备及其电化学性能

以硝酸钴为原料,柠檬酸三钠为模板,六次甲基四胺为成沉淀剂水热制备了核壳结构Co3O4,X射线衍射(XRD)、扫描电镜(SEM)测试表明,柠檬酸三钠的加入使制备的Co3O4呈现核壳状结构,循环伏安等电化学研究表明该材料的电化学电容性能较好,单电极比电容达到333 F/g。

35kV电容式电压互感器故障原因分析

针对电容式电压互感器油箱上部温度异常的问题,通过现场外观检查、电气试验和解体吊心检查发现电容式电压互感器防护铁磁谐振过电压装置损坏,详细分析了此类故障发生的原因并提出防护措施。