用于提升同相供电潮流控制器运行可靠性的开关频率动态调节方法

同相供电潮流控制器是同相供电系统的薄弱环节,为降低系统运行与维护成本,亟待优化其可靠性。该文从物理失效机理入手,建立潮流控制器可靠性评估流程,研究潮流控制器可靠性影响因素,确定开关频率为潮流控制器可靠性优化的核心控制参数;计及牵引负荷特性,为平滑结温,降低失效率,提出开关频率动态调节方法,在可调区间内,根据牵引负荷匹配开关频率;基于潮流控制器输出波形质量和开关损耗约束,确定开关频率取值范围,以绝缘栅双极型晶体管(insulated gate bipolar transistor,IGBT)模块失效率单位下降比最大为目标,优化开关频率调节区间,得到最佳动态调节策略;最后以沙峪牵引变电所同相供电潮流控制器为例,结合实测数据,分析开关频率动态调节方法对同相供电潮流控制器可靠性的影响,结果表明IGBT模块失效率降低25.81%以上,验证所提方法的有效性,为潮流控制器的可靠运行与优化设计提供技术支撑。

VIENNA整流器改进同相双载波补偿控制的仿真研究

在实际应用中,VIENNA整流器在传统的同相双载波补偿控制方式下会导致直流母线欠压起动失效和空载时直流母线电压不受控等问题。针对这些问题,研究了同相双载波补偿控制对VIENNA整流器直流母线电压的影响,提出了在原有的同相双载波补偿控制基础上引入电流极性判断和加入空载电压控制环节的控制策略,搭建了VIENNA整流器的仿真模型。仿真结果表明,系统在过渡过程中可以平稳工作,在稳态时网侧功率因数高,输入电流畸变率低,验证了所提控制策略的有效性。

基于V/V牵引变压器的同相供电系统电能质量混合补偿研究

为了综合补偿V/V同相牵引供电系统中的谐波、无功和负序等电能质量问题,提出了一种基于磁控静止无功补偿器(MSVC)和综合电能质量补偿器(HPQC)的电能质量混合补偿方法。通过协同控制MSVC和HPQC使得HPQC的直流电压最小,从而达到完全补偿无功、负序条件下,HPQC有源容量最小。再利用无源滤波器和HPQC有源滤波共同滤除系统中的谐波,实现对系统的负序、无功和谐波的综合补偿。另外还分析了混合补偿系统的负序、无功和谐波电流的实时检测方法,提出了HPQC和MSVC的协同控制策略,使得整个系统响应速度满足补偿要求。与传统有源补偿设备相比,降低了有源部分的补偿容量和直流电压,降低了补偿成本。仿真和实验结果验证了本文提出的混合补偿方法的有效性和可行性。

新型振动破碎机同步同相运转控制的研究

提出了新型振动破碎机同步同相运转控制的策略，建立了该控制系统的数学模型，并利用windows95/NT环境下的可视化编程语言Delphi3.0开发出该控制系统软件。

三电平Z源逆变器SPWM调制策略的研究

传统逆变器上下桥臂直通时会造成逆变器短路,为避免这一情况通常需要在逆变器控制信号中引入死区,进而造成逆变系统安全性下降输出谐波含量增加。Z源逆变器成功地克服了传统逆变器的缺陷和不足。Z源三电平逆变器有效地结合了Z源网络特性与传统三电平逆变器的优点。文章通过分析Z源三电平逆变器的工作原理,结合传统三电平逆变器的PWM控制策略,分别研究了适于Z源三电平逆变器控制的改进载波同相层叠调制、改进载波反相层叠调制和三次谐波注入载波同相层叠载波调制。仿真结果验证了三种调制策略的可行性。

矿用高压变频器开关调制优化策略

针对矿用高压变频器采用载波调制PWM控制法时存在开关损耗大、电能质量畸变的问题,在载波同相层叠PWM控制法的基础上,对正弦调制波进行优化。通过对正弦调制波叠加3次谐波和直流分量,得到正半周为马鞍形调制波、负半周为梯形调制波的优化调制波。仿真结果表明,优化调制波的应用提高了变频器直流电压利用率,减小了开关损耗,降低了输出线电压总谐波畸变率。

Complex Cyber-Physical Networks： From Cybersecurity to Security Control

Complex cyber-physical network refers to a new generatio~ of complex networks whose normal functioning significantly relies on tight interactions between its physical and cyber compo- nents. Many modern critical infrastructures can be appropriately modelled as complex cyber-physical networks. Typical examples of such infrastructures are electrical power grids, WWW, public trans- portation systems, state financial networks, and the Interact. These critical facilities play important roles in ensuring the stability of society as well as the development of economy. Advances in informa- tion and communication technology open opportunities for malicious attackers to launch coordinated attacks on cyber-physical critical facilities in networked infrastructures from any Interact-accessible place. Cybersecurity of complex cyber-physical networks has emerged as a hot topic within this con- text. In practice, it is also very crucial to understand the interplay between the evolution of underlying network structures and the collective dynamics on these complex networks and consequently to design efficient security control strategies to protect the evolution of these networks. In this paper, cybersecu- rity of complex cyber-physical networks is first outlined and then some security enhancing techniques, with particular emphasis on safety communications, attack detection and fault-tolerant control, are suggested. Furthermore, a new class of efficient secure the achievement of desirable pinning synchronization control strategies are proposed for guaranteeing behaviors in complex cyber-physical networks against malicious attacks on nodes. The authors hope that this paper motivates to design enhanced security strategies for complex cyber-physical network systems, to realize resilient and secure critical infrastructures.