Development of a 4 MV Laser-Triggered Multi-Stage Switch

A 22-stage 4 MV laser-triggered multistage multi-channel switch （LTS） was designed according to the hypothesis that the well-proportioned electrical field distribution is helpful in reducing the jitter of delay. Field distribution in the switch section is regulated by a metal field regulation ring and several gradient rings. In order to reduce the jitter further, a SFB/N2 mixture is chosen as the switching medium. The generalized standard deviation of the self-breakdown voltage and the deviation of the average value from the prediction is less than 4.4% and 13% respectively. Linearity of the self-breakdown voltage is better than 0.95. Triggered by a laser pulse of 35 mJ/3 ns, the delay is about 26 ns at a working voltage of 85±3% USB （Self-breakdown Voltage）. Maximum deviation of delay is less than =t=2.5 ns. Jitter is less than 1.5 ns. The delay and jitter decrease with the increase in the working ratio （the ratio of working voltage to USB）, pressure or voltage.

Effect of Inertial Shock on RF MEMS Capacitive Switches Property in Low Vacuum

The influence of outside inertial shock combined with RF signal voltages on the properties of a shunt capacitive MEMS switch encapsulated in a low vacuum environment is analyzed considering the damping of the air around the MEMS switch membrane. An analytical expression that approximately computes the displacement induced by outside shock is obtained. According to the expression, the minimum required mechanical stiffness constant of an MEMS switch beam in some maximum tolerated insertion loss condition and some external inertial shock environment or the insertion loss induced by external inertial shock can also be obtained. The influence is also illustrated with an RF MEMS capacitive switch example,which shows that outside environment factors have to be taken into account when designing RF MEMS capacitive switches working in low vacuum. While encapsulating RF MEMS switches in low vacuum diminishes the air damping and improves the switch speed and operation voltage,the performances of a switch is incident to being influenced by outside environment. This study is very useful for the optimized design of RF MEMS capacitive switches working in low vacuum.

Experimental Study on Triggering Characteristics of a Surface Flashover Triggered Vacuum Switch

Triggering characteristics of triggered vacuum switch （TVS）, including the discharge delay time, delay jitter, range of operational voltage and peak of pulsed current, are investigated. Both structure and experimental circuit of TVS are presented. The results indicate that TVS, as a surface flashover triggering device with high dielectric permittivity material, is with excellent triggering characteristics. When the hold-off voltage reaches 120 kV, the minimum operational voltage is 1.3 kV, and the minimum discharge delay time and jitter are 100 ns and ±10 ns, respectively. The peak current is up to 240 kA when the operational voltage reaches 100 kV. TVS can well satisfy the main demands of high voltage and current applications, and can also be used under a multi-crowbar circuit.

Vacuum Switching Technology for Future of Power Systems

Even though switching in vacuum is a technology with almost 100 years of history,its recent develop-ments are still changing the future of power transmission and distribution systems.First,current switch-ing in vacuum is an eco-friendly technology compared to switching in SF 6 gas,which is the strongest greenhouse gas according to the Kyoto Protocol.Vacuum,an eco-friendly natural medium,is promising for reducing the usage of SF 6 gas in current switching in transmission voltage.Second,switching in vacuum achieves faster current interruption than existing alternating current(AC)switching technolo-gies.A vacuum circuit breaker(VCB)that uses an electromagnetic repulsion actuator is able to achieve a theoretical limit of AC interruption,which can interrupt a short-circuit current in the first half-cycle of a fault current,compared to the more common three cycles for existing current switching technologies.This can thus greatly enhance the transient stability of power networks in the presence of short-circuit faults,especially for ultra-and extra-high-voltage power transmission lines.Third,based on fast vacuum switching technology,various brilliant applications emerge,which are benefiting the power systems.They include the applications in the fields of direct current(DC)circuit breakers(CBs),fault current lim-iting,power quality improvement,generator CBs,and so forth.Fast vacuum switching technology is promising for controlled switching technology in power systems because it has low variation in terms of opening and closing times.With this controlled switching,vacuum switching technology may change the“gene”of power systems,by which power switching transients will become smoother.

Emission Current Characteristics of Triggered Device of Vacuum Switch

The characteristics of the triggered vacuum switch （TVS） are obviously influenced by the emission current ie and emission charge of the trigger device. In this paper, an RC charge collector is designed, and the characteristics of emission current ie and collecting charge Qc of the trigger device are studied. The experimental results indicate that the emission current ie which is produced by the initial plasma has both positive and negative components, and the polarity of the emission current ie depends mainly on the polarity of the bias voltage UBias. The emission current ie and collecting charge Qe increase with the increase of the trigger voltage Utr and the bias voltage UBias. The emission efficient r] increases linearly with the increase of the bias voltage UBias. When the gap distance is 15 mm and bias voltage UBias is 160 V and trigger voltage Utr is 2.6 kV, the emission efficiency r/reaches 6%

平板触头小开距高电流密度下真空电弧特性的实验研究

平板触头被广泛应用于真空触发开关和真空有载分接开关中,为研究其在高电流密度下的真空电弧特性及阳极模式的转变,该文针对直径15、20mm的平板触头,在3、6mm开距下进行触发燃弧实验,并依次对电弧电压特性、电弧能量特性、电弧形貌、触头烧蚀情况进行分析研究。结果表明:峰值电流一定时,随着触头直径与开距的比值的增大,电弧电压和电弧能量减小。触头直径与开距的比值越小,电弧出现阳极模式的阈值电流越小,且触头烧蚀越严重。在开距6mm时,直径15mm触头电弧电压在大部分时间比较稳定,阳极羽流在电弧快熄灭之前出现,而直径20mm触头电弧电压在整个燃弧期间频繁波动,电弧模式不断变化,阳极羽流在整个燃弧期间都有出现。研究结果对于大电流真空开断具有理论指导意义。

基于激光诱导等离子体的真空开关真空度检测稳定性研究

基于激光诱导等离子体成像的真空开关真空度检测方法是一种非接触式真空度检测方法,有望实现安全可靠的真空开关真空度带电检测。但是,激光诱导等离子体的演化是一个十分复杂的物理过程,激光能量、等离子体测量延迟时间等因素直接影响了等离子体成像,对等离子体成像稳定性的影响需要进行更加深入的研究。为此采用相对标准偏差研究了等离子体成像平均次数、激光能量和等离子体测量延迟时间等对等离子体图像和等离子体辐射强度积分稳定性的影响。结果显示,多次成像平均得到的等离子体图像和辐射强度积分不随平均次数发生明显变化,可用于表征真空度。更重要的是,等离子体辐射强度积分的相对标准偏差随平均次数和激光能量的增加而单调下降,随延迟时间的增加而增大,这意味着对等离子体进行多次成像平均,增加激光能量,减小等离子体成像的延迟时间可以提高等离子体辐射强度积分的稳定性,有利于提高真空度检测精度。该研究为基于激光诱导等离子体成像的真空开关真空度检测方法的参数优化提供了指导,为该方法的实际工程应用奠定了实验基础。

磁控触头旋转开断过程中直流真空电弧形态与电压特性

为探索直流断路器磁控触头开断产生的真空电弧形态演变规律及其电压特性,提出了一种在触头直拉基础上附加阴极旋转运动的开断方式“旋转—直拉开断”。由于磁控触头开断电流自生磁场会影响真空电弧发展过程,文章对阴极旋转开断产生的磁场进行了仿真分析。同时搭建了可拆卸真空灭弧实验平台,对万字型横磁触头和杯状纵磁触头在不同开断方式下的真空电弧的形态演化规律以及电弧电压特性进行了对比分析研究。仿真与实验结果表明:真空电弧在旋转开断方式下受到触头磁场和旋转离心力的共同作用,燃弧时间更短、由限制型电弧向扩散态的转变更快、熄弧效率更高。“旋转—直拉开断”使得在阴极表面的亮斑运动加速,使得电弧能量逸散更快有效提高熄弧能力。

双断口真空开关分断速度对动态电压分布影响

多断口真空开关的均压问题可以通过内在调控措施解决,分断速度是内在调控措施之一,但是对于速度调控的研究尚未深入。为研究操动机构分断速度对双断口真空开关动态电压分布的影响,在分析开断速度对电压分布影响机理的基础上,提出双阶段速度控制方法。并建立双断口真空开关模型,仿真分析同步、异步、变速分断情况下的电压分布情况。设计真空开关速度调控装置,搭建真空开关分断速度测试平台。试验表明:同步开断时,高低压侧开关速度变化对断口的电压分布影响较小。异步分断与变速分断均可以通过分断速度的改变调控动态电压分布,动态电压不均匀系数最多可降低15%。文中成果为研究多断口真空开关通过速度调控电压分布提供数据参考。

基于脉冲变压器的快前沿固态触发器

结合理论求解、仿真分析与实验验证,确定了影响脉冲变压器型触发器输出前沿的主要因素,并研制了一台能可靠触发真空沿面闪络开关导通的快前沿固态触发器。研究结果表明:影响触发器输出脉冲前沿的关键因素为脉冲变压器漏感、匝数比和半导体开关开通速度;不同绕制方式的脉冲变压器漏感差异很大,最小漏感绕法的变压器漏感值低1个数量级;选用开通速度优于15 ns的碳化硅金属氧化物半导体场效应晶体管(SiC MOSFET)、绕制低漏感(小于0.5μH)的脉冲变压器,实现了前沿为20.4 ns(10%~90%)、幅值为16.5 kV的快前沿输出;控制SiC MOSFET的驱动脉宽在35~55 ns变化可以控制触发电流峰值在35~55 A范围内变化。

环保型高压真空开关电流开断基础

针对“双碳”战略下绿色环保开关设备的发展需求,“真空灭弧+洁净空气”绝缘方案对于开关设备的SF_(6)替代目标而言是一种彻底的解决方案。对于真空开关向更高电压等级发展面临的关键问题进行全面分析,重点阐述真空开关在高电压大电流下的开断问题。基于真空电弧的基础理论,将弧后介质恢复过程分为残余等离子体消散阶段、金属蒸气恢复阶段、金属液滴与熔融触头表面恢复阶段,并对比分析3个阶段下真空灭弧室电极间隙的恢复特性。针对环保型真空开关向更高电压等级发展的需求,总结归纳真空灭弧室在绝缘设计、电弧控制、X射线辐射、载流发热方面的关键问题,阐述洁净空气绝缘在实际应用过程中的难点和解决措施,旨在为252 kV及以上电压等级真空开关的研究与设计提供参考。最后,讨论高压真空开关的研究现状和发展趋势。

快速真空开关合闸触头弹跳暂态过程研究

以电磁斥力驱动器作为操动机构的快速真空开关具有分闸速度快,分合闸时间短和分合闸时间分散性小的优势,目前已广泛应用于多种电力设备中。目前对于快速真空开关的分闸过程已有众多研究,但合闸过程的相关问题尚属空白。文中研究了快速真空开关合闸过程中触头弹跳问题。建立了多物理场耦合仿真模型,完整描述了快速真空开关的合闸过程。得到了快速真空开关的v1与Dmax的关系,其中v1为合闸过程中动静触头首次接触的瞬时速度,Dmax为动触头的最大弹跳距离。根据这一关系式,确定了合闸过程中无触头弹跳情况下的临界瞬时合闸速度vcri。根据vcri限制,设计了一种新型的油阻尼器来调节快速真空开关的合闸行程曲线,实现无触头弹跳合闸。研制了装备新型油缓冲器的快速真空开关,搭建了机械特性测试平台,对其合闸特性进行了测试。测试结果表明:测量结果与仿真结果之间的误差不超过10%,且实现了无触头弹跳合闸。

广播中波发射台三台发射机天线倒换开关设计与实现

两台发射机天线倒换开关只考虑一次倒换,倒换原理简单易操作。增加一台发射机,安全播出任务更有保障。为此,分析三台发射机天线倒换开关的设计需求,介绍倒换开关关键设备陶瓷真空继电器,详细介绍三台发射机天线倒换开关整体结构、关键设备及连接原理,阐述三台发射机的倒换流程。

中波发射系统自动倒换功能的设计与实现

本文提出了中波发射系统的自动切换功能设计理念,详细讨论了发射机的自动倒换、馈线的自动倒换以及调配网络的自动倒换功能。此外,本文还深入探讨了如何根据输入阻抗和输出阻抗设计调配网络,以及如何利用真空继电器实现中波发射系统的自动切换。期望能为中波广播发射系统的优化提供有价值的参考。

大功率光电器件光波导键合技术研究

光导开关是一种新型半导体光电子器件,在光通讯、雷达、微波等领域广泛应用,但在高工作电压的条件下会发生表面击穿等问题,因此需要对其进行封装提高侧面的耐压性能。该文选用光波导的方式对碳化硅晶片进行封装,通过玻璃浆料烧结键合、真空热压键合和光波导胶键合3种方法对小面积的侧面异质键合进行研究。通过3种方法的工艺优化及键合质量性能测试,光波导胶键合方法对激光功率的损耗最小,实现器件耐压值提升至10 kV。

真空断路器弹簧操动机构分闸弹簧的优化设计方法

操动机构分闸弹簧设计时,为解决分闸弹簧出力特性和负载特性不匹配带来的分闸保持不住、分闸速度过大或过小等问题,提出一种分闸弹簧的优化设计方法。首先计算出分闸过程中的力矩与功,然后根据功能原理计算出各位移点的分闸速度,最后根据分闸速度和能量要求等因素对分闸弹簧进行优化。结果表明,优化后的分闸弹簧可使分闸过程中的出力特性和负载特性合理匹配,保证机构可靠分闸的同时,得到满足要求的分闸速度。通过理论计算和试验验证证明了所提优化方法的可行性,为真空断路器弹簧操动机构的分闸弹簧优化设计提供了有益指导。

宁夏电网35kV电容器组关合涌流计算与仿真分析

随着宁夏电网新型电力系统建设的不断推进,新能源及新型用能负荷的特性对无功补偿需求更加迫切,而作为变电站无功补偿中最经济的并联电容组因投切用真空断路器及SF_6断路器受高频涌流影响,难以满足频繁投切要求,一定程度制约了供电电压质量提升。从宁夏电网35 kV电容器组配置特点出发,分析变电站通用典型设计后对电容器关合涌流的影响,开展关合涌流简化计算方法及仿真分析研究。实例计算及仿真结果表明,在单个电容器组及背靠背电容器组关合两种方式下,采用简化计算涌流峰值及仿真计算方式偏差分别在10%及20%以内,简化计算方法及仿真模型可为电容器投切开关选型和涌流影响下设备健康评估提供依据。

10kV智能投切开关的设计与开发

智能投切开关能够控制线路电压或者电流在期望的相位进行关合和开断,有效减少高压开关在投切电容器组时引起的合闸涌流和过电压,消除分闸重燃所引起的电路过电压。山东正本电气有限公司为某变电站10kV高压并联电容器成套装置研制的智能投切开关,三相动力独立驱动,既能同时分合闸,亦能相控分合闸,具备分合闸时间短、合闸无弹跳、分闸反弹小等特点,同时具有手动分闸功能。运行试验表明,完全能满足高压并联电容器组对智能投切开关的要求。

基于真空永磁的变压器干式有载分接开关研究

变压器的输出电压由分接开关来控制,通过改变变压器绕组抽头与分接开关的连接来改变绕组的匝数比,实现对变压器输出电压的控制。在直流输电中,有载调压开关尺寸大、价格相对昂贵的特点限制了有载调压方式的应用。针对传统有载分接开关体积大、操作复杂的不足,采用永磁直动型真空有载开关能更好地减小体积并降低成本,且由于直流输电电压电流没有零点,所以相较于交流输电会产生更大的弧光反应。因此文章研制了一种干式真空永磁有载分接开关,实现了负载电流和级间环流全部在真空灭弧室内切换,有效避免了机构失调运行引起的分接间弧光短路事故,实现了对直流系统电压的分级调整与优化处理,减少了换流变压器侧电压变化对整个直流系统造成的不利影响,提高了直流输电系统的运行稳定性及经济效益。