模块化多电平换流器的环流抑制方法研究

模块化多电平换流器(MMC)在中高压直流输电中得到了广泛的研究和应用。其内部环流的存在是MMC的一种重要现象。在MMC的拓扑结构及其内部环流产生机理的基础上,利用二倍频负序旋转坐标变换,把换流器内部的三相环流分解为两个直流分量,并提出了相应的环流抑制方法。仿真结果证明,利用坐标变换提出的环流抑制控制器可以有效地消除桥臂电流中的环流分量,减小桥臂电流的畸变程度,同时不会对MMC外部输出的交流电压和电流产生负面影响。     

谈谈硅整流桥电路的学习与应用

硅整流桥电路是由四个硅二极管组成四个桥臂的一种电桥电路,在模拟电路中应用非常广泛。主要应用在直流电源、测量、极性选择等实际电路中。 本文结合硅整流桥的实际应用电路及教学实践,简要分析硅流桥电路的结构、原理及应用举例;使学生充分认识到该电路的重要性及普遍性,并掌握有关知识。     

高压直流输电晶闸管阀用饱和电抗器的设计

高压直流换流阀用饱和电抗器的作用是抑制流经晶闸管的电流变化率,限制晶闸管产生的电压,提高晶闸管换流阀分布电压的均匀性。主要研究高压直流换流阀用饱和电抗器的理论设计、结构排布及线圈选取等方法,具有一定的实际应用价值。     

应用于超级电容储能系统的双向DC/DC变换器混沌控制方法研究

超级电容储能系统(SCESS)主要通过对双向DC/DC变换器进行控制来快速平抑直流母线电压的波动。为了抑制控制过程中所产生的一些分岔和混沌现象,提出了一种应用于SCESS的混沌控制方法。分析了该方法的控制原理,并根据非线性动力学理论建立了双向DC/DC变换器的离散迭代模型；然后设计了一种能够自动调节补偿斜率的混沌控制信号；最后对该信号作用下的异步切换函数和同步切换映射式进行了数值求解,从而绘出系统分叉图。通过仿真和试验证明,该方法能够有效抑制SCESS的分岔和混沌现象,提高了系统的稳定工作范围和动态响应速度。     

基于四开关三相变频器的永磁同步电机驱动系统转矩脉动优化控制

针对低成本三相四开关变频器构成的永磁同步电机驱动系统存在转矩脉动较大的问题,提出了一种系统转矩脉动优化控制策略。系统中存在的转矩脉动分为低频和高频转矩脉动,对于由直流电容电压波动产生的低频脉动,采用了引入一种基于非正交坐标变换的补偿方案,而对于高频脉动,分析评估了不同调制策略的影响,选择了最优调制策略。此外,线性调制范围设置考虑了系统直流电容电压波动,避免了低频脉动造成的过调制。同时,还设计了电容电压偏移抑制控制以扩大线性调制区范围。试验结果验证了新型控制策略抑制系统转矩脉动的效果明显。     

永磁直驱风电机组的机侧多整流器并联运行控制研究

永磁直驱风电机组的容量通常达到了兆瓦级,采用并联型结构是主要的扩容方式。传统的风电变流器机侧整流器具有独立的直流母线,虽具有控制简单的优点,但也存在成本高、体积增加等问题。针对这个问题,提出了一种新型的永磁直驱风电机组机侧多整流器共直流母线并联运行控制策略。该控制策略的控制目的是抑制共直流母线的整流器模块之间由于不同步造成的环流,因此首先对具有公共直流母线的多整流器运行的直流环路和零序电流动态进行了建模和分析,设计了独立的电流控制器,并通过同步载波移相配合生成了多簇脉冲调制信号给不同的整流器模块,但相互的控制器使用了同一个转子位置观测器,从而实现了每个模块的电流同步和均衡,并匹配了最优的总发电机转矩。最后,为了验证控制策略的有效性,基于1.5MW的永磁直驱风电机组试验平台进行了试验研究。试验结果表明,在新型控制策略下,变流器机侧多整流器模块能正常运行,并具有较优的性能。     

一种交流固态功率控制器新型建模仿真方法

为解决交流(AC)固态功率控制器(SSPC)利用Saber软件基于真实结构及器件的仿真方法仿真速度慢、三相AC SSPC带整流桥负载无法仿真的问题,提出一种新型建模仿真方法,只考虑AC SSPC对外工作行为,不依赖于真实结构及器件,利用Saber软件控制单元建模。分析该模型的工作行为,验证了各种负载的兼容性及保护特性,实现了三相带整流桥负载的仿真。与基于真实结构及器件的模型对比,仿真速度和收敛性能显著提高。     

用多整流器供电抑制电流谐波

本文提出用多整流器向直流电动机供电抑制电网电谐波的方法,分析了利用Ｐｓｐｉｃｅ仿真程序研究流器供电的特性,并给出了仿真实验结果。     

直流电阻数字化检测方法

介绍了直流电阻的三种数字化检测方法;对三种方法进行分析并给出了测量结果的不确定度;给出了直流电阻检测中可选择的方法.     

高准确度直流电阻仪整体检定方法探讨及不确定度评定

介绍了几种整体检定直流电阻仪器的检定方法 ,着重分析了用数字多用表整体检定高准确度直流电阻仪器的工作原理和检定方法 ,并进行了不确定度的计算。     

Frequency-controlled series-resonant converter with synchronous rectifier

This paper presents an analysis and experimental results for a frequency-controlled series-resonant dc-dc converter that consists of a Class-D zero-voltage-switching (ZVS) series-resonant inverter and a center-tapped synchronous rectifier. If the dc output voltage is low, the efficiency of the converter is dominated by the efficiency of the rectifier. Low on-resistance metal-oxide-semiconductor field-effect transistors (MOSFETs) are used in the rectifier instead of diodes because the forward voltage drop across the rectifying device is low, resulting in a high efficiency. The dc output voltage is regulated against variations in the load resistance and the dc input voltage by varying the operating frequency. Experimental results are presented for a converter with a dc input voltage of 150 V, an output voltage of 5 V, and a dc load resistance ranging from 0.5 to 5.5 R. The measured efficiency was 86% for a 50 W output and 89% for a 25 W output. The theoretical results were in good agreement with the measured results.     

ZCS-PWM boost rectifier with high power factor and low conduction losses

A new single-phase high power factor rectifier is proposed, which features regulation by conventional pulsewidth modulation (PWM), soft commutation, and instantaneous average line current control. A new zero-current-switching PWM (ZCS-PWM) auxiliary circuit is configured in the presented ZCS-PWM rectifier to perform ZCS in the switches and zero-voltage-switching (ZVS) in the diodes. Furthermore, soft commutation of the main switch is achieved without additional current stress by the presented ZCS-PWM auxiliary circuit. A significant reduction in the conduction losses is achieved, since the circulating current for the soft switching flows only through the auxiliary circuit and a minimum number of switching devices are involved in the circulating current path and the proposed rectifier uses a single converter instead of the conventional configuration composed of a four-diode front-end rectifier followed by a boost converter. Seven transition states for describing the behavior of the ZCS-PWM rectifier in one switching period are described. The PWM switch model is used to predict the system performance. A prototype rated at 1 kW, operating 60 kHz, with an input ac voltage of 220 V/sub rms/ and an output voltage 400 V/sub dc/ has been implemented in laboratory. An efficiency of 97.2% and power factor near 0.99 has been measured. The analysis and design of the control circuitry are also presented.     

Harmonic analysis of a parallel-loaded resonant converter

A method for calculating the harmonic components of the currents and voltages in a parallel-loaded resonant converter using frequency-domain techniques is presented. The converter is divided into an inverter section and a rectifier section. A harmonic model is developed for the resonant converter in which the rectifier section is treated as a voltage-dependent current sink. All voltages and currents in this model are represented by a Fourier series. The unknown coefficients in all Fourier series are calculated by using the harmonic model and Kirchhoff's laws. Because of the nonlinear nature of the rectifier section, an iterative technique must be utilized to find the unknown Fourier coefficients     

A novel resonant converter topology for DC-to-DC power supply

A class-E DC-to-DC converter with half-wave controlled current rectifier is proposed. Its output voltage is controlled by the conduction angle of the rectifier switch at constant switching frequency. Zero voltage switching for all the switches can be maintained from full load to no load. Its steady state characteristics are analyzed and the effects of the circuit parameters are studied. Some extensions of the proposed converter are also discussed. The analysis is verified by PSPICE simulation and an experimental prototype     

AC/DC converter topologies for the Space Station

A new class of AC/DC converter topologies (Type-1 converters) is described, suitable for use in an advanced single-phase sine-wave voltage, high-frequency power distribution system, of the type that was proposed for a 20 kHz Space Station primary electrical power distribution system. The converter comprises a transformer, a resonant network, a current controller, a diode rectifier, and an output filter. The input AC voltage source is converted into a sinusoidal current source using the resonant network. The output of this current source is rectified by the diode rectifier and is controlled by the current controller. The controlled rectified current is then filtered by the output filter to obtain a constant voltage across the load. Three distinct converter topologies, Type-1A, Type-1B, and Type 1-C, are described, and their performance characteristics are presented. All three types have a close-to-unity rated power factor (greater than 0.98), low total harmonic distortion in input current (less than 5%), and high conversion efficiency (greater than 96%)     

Suitability of pulse train control technique for BIFRED converter

Pulse Train/spl trade/ control scheme is presented and applied to a boost integrated flyback rectifier/energy storage dc-dc (BIFRED) converter operating in discontinuous conduction mode (DCM), which avoids the light-load high-voltage stress problem. In contrast to the conventional control techniques, the principal idea of Pulse Train technique is to regulate the output voltage using a series of high and low energy pulses generated by the current of the inductor. The applicability of the proposed technique to both the input and magnetizing inductances of BIFRED converter is investigated. Analysis of BIFRED converter operating in DCM as well as the output voltage ripple estimation is given. Experimental results on a prototype converter are also presented.     

Analysis of series-parallel resonant converter

A frequency-domain steady-state analysis is given for a series-parallel resonant converter (SPRC) operating in the continuous conduction mode (CCM) using Fourier series techniques. Equations for performance parameters are derived under steady-state conditions to provide simple design tools. The topology of the SPRC combines the advantageous properties of both the series resonant converter (SRC) and the parallel resonant converter (PRC). The key results of the work are: a novel half-wave rectifier SPRC, conditions for obtaining high part-load efficiency; and several boundary frequencies and limiting conditions such as the capacitive/inductive load boundary and open-circuit and short-circuit cases. Experimental results measured for an 80-W converter above the resonance at different load resistances and input voltages show excellent agreement with the theoretical performance predicted by the equations     

集成低频脉冲功率解耦端口的机载电源系统

为了消除高峰均功率比低频脉冲负载对有限容量机载交流供电系统的周期性冲击等不利影响,对开关器件进行集成和复用,提出了能够同时提供功率解耦端口和直流输出端口的三端口功率解耦整流器。通过将三端口整流器与DC/DC变换器组合,构造出集成低频脉冲功率解耦端口的机载电源系统,实现了直流侧周期性脉动功率和交流源侧功率的解耦,并保证低频脉冲负载正常供电需求。详细分析了三端口整流器的工作原理,提出了与之相适应的功率控制方法和调制策略,基于开关器件分时复用原理,实现了交流端口到两个直流端口的功率传输和分配,并实现了两个直流端口功率切换过程的平滑过渡。实验结果验证了所提三端口脉冲功率解耦整流器的有效性和可行性。     

Full bridge ZCS PWM converter for high-voltage high-powerapplications

This paper presents a comprehensive study of a full bridge (FB) zero-current switched (ZCS) PWM converter which is suitable for high-voltage and high-power DC application that achieves ZCS for all active switches, and zero-voltage-switched (ZVS) operation for all diodes on the high voltage side. The given converter utilizes component parasitic parameters, particularly for the high-voltage transformer, and employs fixed-frequency phase-shift control to implement soft-switching commutations. Detailed steady state analysis of the converter power stage is presented for the first time and the major features of the converter's power stage are discussed. Small-signal characteristics are also presented and accompanied by a discussion of the controller design and implementation. A design example is also presented based on the steady state analysis and is validated by simulation. Theoretical and simulated results are in good agreement     

Single-phase three-level rectifier and random PWM inverter drives

A novel ac/dc/ac converter topology with three-level pulsewidth modulated (PWM) scheme for the single-phase ac/dc rectifier and random PWM scheme for ac drives is proposed. In order to improve the power quality in the single-phase rectifier, a ROM-based (read-only memory) control scheme, based on hysteresis current comparator, region detector, and capacitor compensator, is used to achieve a sinusoidal line current with low current distortion. The control scheme of the adopted three-level rectifier is easy to implement. The blocking voltage of power switches is clamped to half of the dc bus voltage. To reduce the mechanical vibration from an induction motor, random pulse position PWM scheme is adopted to spread the harmonics in a wide frequency range which results in the reduction of torque pulsation in the ac motor drives. Simulation and experimental results based on the laboratory prototype circuit are presented to verify the proposed control scheme