高功率因数大功率LED路灯驱动电源的设计

文章结合LED路灯驱动电源发展的现状,设计了一款适用于大功率情况下的路灯驱动电源。该设计提出一款基于PLC810PG的半桥LLC谐振式LED路灯开关电源的设计方案,实现了功率因数校正作用且由于实现了软开关,提高了工作效率。文章对此电源的主电路和控制电路进行了理论设计和参数估算。最后经实验研究,表明该系统设计可行,性能指标基本可以满足设计要求。     

高功率因数大功率LED路灯驱动电源的设计

文章结合LED路灯驱动电源发展的现状,设计了一款适用于大功率情况下的路灯驱动电源.该设计提出一款基于PLC810PG的半桥LLC谐振式的LED路灯开关电源的设计方案,实现了功率因数校正作用且由于实现了软开关,提高了工作效率.文章对此电源的主电路和控制电路进行了理论设计和参数估算.最后经实验研究,表明该系统设计可行,性能...     

电力操作电源主电路参数设计

简单分析了2．2 kW的电力系统用直流操作电源移相全桥软开关拓扑结构,设计和选择了主电路的各元件参数,制作了软开关主要部件高频变压器、谐振电感；根据研制的开关电源实际特点,选择了功率管和次级整流二极管,最后利用实验来验证设计的正确性。     

串联谐振软开关高压充电电源仿真与设计

对用于高压脉冲电容器充电的串联谐振软开关高压充电电源进行了理论研究、参数设计、仿真分析及实验研究。主电路串联谐振频率为32kHz,IGBT开关工作频率为15kHz,输出电流平均值为2A。正弦化谐振电流经过脉冲变压器升压及高压整流桥整流后,对电磁轨道发射脉冲功率系统的高压电容器组进行恒流充电,实测数据、波形与设计值一致,表明该电源满足设计和实验要求。     

电力操作电源主电路参数设计

本文简单分析了2.2KW电力系统用直流操作电源移相全桥软开关拓扑结构,设计和选择了主电路的滤波电容和电感等元件,制作了软开关主电路的主要部件,包括高频变压器和谐振电感;根据设计的开关电源实际特点,选择了主功率管和次级整流二极管。     

一种ESP高频电源谐振变流器电路的研究

电除尘器以高压电场为基础将烟气中粉尘分离并收集清理,是效率很高的除尘设备。效率是电除尘器的关键,而电除尘器电源性能的好坏将直接影响除尘器除尘效率的高低。近年来我国对粉尘排放的要求越来越高,早期的工频除尘器电源已经无法满足排放要求,在此基础上人们提出了用高频高压整流直流电源代替传统工频电源以提高除尘器的效率进而达到排放要求。本文针对高频领域开关器件硬开关出现的问题,提出一种能实现软开关技术的全桥串并联谐振混合变流器的谐振元件参数选取依据和变流器的断续工作模式进行表格分析和说明,通过电路的开关模态分析各个过程电路特性。最后用设计所得参数进行仿真并与一套66k V/0.3A规格的产品参数对比,得出变流器在电除尘器高频电源中应用的可行性,具有很好的工程应用价值。     

高功率CO2激光器谐振开关变换型电源的计算仿真

研究了高功率CO2激光器用零电流开关准谐振开关电源,讨论了电源的工作原理和电路结构,进行了激光电源的计算仿真研究,得到了谐振电路的工作波形,通过谐振开关方式与PWM硬开关方式的比较,论述了零电流开关准谐振变换器的技术特点及优势。     

高功率CO_2激光器谐振开关变换型电源的计算仿真

研究了高功率ＣＯ２激光器用零电流开关准谐振开关电源，讨论了电源的工作原理和电路结构，进行了激光电源的计算仿真研究，得到了谐振电路的工作波形，通过谐振开关方式与ＰＷＭ硬开关方式的比较，论述了零电流开关准谐振变换器的技术特点及优势。     

解析PRT自激励振方式VRC软开关变换电源技术

从正交型变压器PRT的结构和控制技术出发,对先进的自激励振方式VRC软开关变换电源技术进行解析.利用电路图和工作波形图,重点说明自激励振方式VRC的4种控制方式的电路构成原理,简要阐述它们之间的区别、工作原理和实用技术参数.这4种控制方式是:并联谐振频率控制方式、谐振电压脉冲宽度控制方式、升压型电压控制方式和复合控制方式.它们都是基于控制PRT电感量来实现自动稳定输出电压的自激励振方式的软开关变换电源技术.     

新型雷达固态收发模块电源的设计

为了达到雷达固态收发模块对电源高效变换的要求,提出了一种基于谐振技术的新型电源变换器设计方案。电源采用两级功率变换,前级为隔离型变换器,完成输入功率因数校正(PFC),起到降压、隔离及初步稳压的作用。后级为多路非隔离降压型(BUCK)谐振变换器,实现输出电压的进一步的调节。后级的BUCK谐振变换器利用电感和电容谐振实现了功率管的零电流(ZCS)和零电压(ZVS) 开关。在高频化的同时降低了开关损耗,同时电路工作原理简单,易于实现和控制。设计方案对该电路工作原理和特性进行了详细分析,并给出固态收发模块电源主要参数设计及电源工作的部分波形。     

ZVZCS移相全桥PWM变换器的分析与仿真研究

ZVZCS移相全桥PWM变换器实现了超前桥臂的零电压开关(ZVS)与滞后桥臂的零电流开关(ZCS),其软开关的实现条件比ZVS移相全桥与ZCS移相全桥要好。文章全面分析了这种变换器的工作原理,讨论了实现软开关的条件,设计关键参数并利用SIMetrix软件进行了仿真研究。     

ZVZCS移相全桥PWM变换器的设计与仿真

ZVZCS移相全桥PWM变换器实现了超前桥臂零电压开关(ZVS)和滞后桥臂零电流开关(ZCS),具有结构简单、占空比丢失较小、软开关较容易实现等特点。文章全面分析了该变换器的工作原理、讨论实现软开关的条件,设计了主要参数,然后利用SIMetrix仿真软件对电路进行仿真,通过波形验证了参数设计合理、变换器实现ZVZCS。     

零电压换流条件分析与设计

研究移相控制全桥零电压开关脉宽调制变换器(FB-ZVS-PWM)的换流过程。针对其滞后桥臂负载电感偏小给零电压导通造成困难的特点，文中放弃了负载电流为恒流源的假设，推导了描述其换流过程的方程。基于这些方程，研究了实现软开关的条件，并用仿真和实验结果验证了该方程的正确性。文中还用一设计实例来说明了这些等式的应用。     

A 1-MHz Zero-Voltage-Switching Asymmetrical Half-Bridge DC/DC Converter: Analysis and Design

The asymmetrical half-bridge (AHB) topology discussed in this paper is one of the complementary driven pulse-width modulated converter topologies, which presents an inherent zero-voltage switching (ZVS) capability. In the previous work, the ideal operation of the converter and the ZVS realization process have been analyzed. However, the influence of the circuit parasitics on the output voltage drop and the design constraints of the circuit parameters to ensure the ZVS operation have not been investigated. The minimum load needed to ensure the ZVS operation is also not readily available. This paper presents a detailed and practical design for a 1-MHz AHB converter. A revised voltage transfer ratio of the converter is derived considering the influence of circuit parasitics and the ZVS transition. Two circuit parameters responsible for maintaining the ZVS operation are the transformer leakage inductance and the interlock delay time between the gate signals of two switches. A design method of the two parameters is proposed, which can ensure the ZVS transition. The possible ZVS range of the load variation is also investigated. A 50-W AHB converter with 1-MHz switching frequency was constructed, and a maximum efficiency of 91% was achieved.     

Design considerations of IGBT's in resonant converter applications

The switching dynamics of insulated gate bipolar transistors (IGBT's) in zero voltage switching (ZVS) resonant converter applications is studied and optimized using an advanced mixed device and circuit simulator. It is shown that bipolar and MOS device parameters must be carefully optimized to obtain the lowest total power loss. A simple circuit simulation model was used in an advanced behavioral circuit simulator where the model parameters were extracted from mixed device and circuit simulations. Performance analysis of a typical series resonant converter (SRC) shows that ZVS condition is more favorable than the zero current switching (ZCS) condition from the standpoint of obtaining efficient power conversion. It is shown that IGBT's with narrower source result in lower total switching power loss     

Analysis and Design for a New ZVS DC–DC Converter With Active Clamping

A new zero voltage switching (ZVS) boost converter is presented in this paper. By using an auxiliary switch and a capacitor, ZVS for all switches is achieved with an auxiliary winding in one magnetic core. A small diode is added to eliminate the voltage ringing across the main rectifier diode. This clamping technique can also be utilized in other dc-dc converters, and a family of new ZVS dc-dc converter is derived. A prototype (500 W/193 kHz) is made to verify the theoretical analysis. The efficiency is higher than 94% at 90-V input at full load     

SVM控制的复合有源箝位ZVS三相PFC变换器

采用复合有源箝位（CAC）的三相功率因数校正变换器，应用改进的空间矢量控制策略，所有的主开关和辅助开关均为零电压开关，有效的抑制了桥臂开关反并联二极管的反向恢复电流，减少反向恢复损耗。而且，具有开关器件电压应力较低，开关频率固定，输入波形质量好的特点。研制了一台基于DSP控制的10kW实验样机，分析了软开关过程及条件，得到了变换器效率同电路谐振参数之间的关系曲线。测量了软开关变换器的传导干扰频谱，验证了软开关变换器较硬开关变换器有更好的电磁兼容性。     

Series connection of power switches for very high-powerapplications and zero-voltage switching

The basic theoretical analysis for series connection of semiconductor power switches (valves) for zero-voltage switching (ZVS) is presented. The influences of the switching device parameters on its voltage distribution during steady and transient-state conditions are analyzed. When ZVS technique is used, the design of the voltage equalization elements is easier than when hard switching is used. Simulated results are presented to validate the analysis and design methodology. This work is important for very high-power soft-switching valves and converter designs. As an example to validate the theory, a study based on the gate turn-off thyristor (GTO)-controlled series capacitor is presented     

ZVS移相全桥双向DC／DC变换器

双向DC／DC变换器应用领域正在不断拓宽,前景很好,而软开关技术是高频化下减少损耗的最有效的方法。基于此深入的研究了ZVS移相全桥双向DC／DC变换器,介绍了单向全桥直流变换器,并在此基础上介绍了全桥双向DC／DC变换器的应用与特点,深入分析了其控制方式及其工作过程,剖析了其实现软开关的原理,介绍了其调压的实现,并列举了实例。     

Zero-voltage switching for three-level capacitor clamping inverter

A zero-voltage switching (ZVS) scheme for a three-level capacitor clamping inverter based on the true pulsewidth modulation (PWM) pole is proposed in this paper. With this scheme, the main switches work with ZVS through the assistance of a small rating zero current switching (ZCS) lossless auxiliary circuitry without imposing any voltage/current spikes on the main devices or any extra control complexities. Consequently, a three-level capacitor clamping inverter system can operate at a promoted switching frequency and becomes more eligible to be considered for high-power advanced applications, for example, in high-speed drives or power active filter areas. In this paper, the main circuit operation issues as regards the clamping voltage stability, damping capacitor stress, and output voltage spectrum are shortly reviewed first, after which the commutation principle, auxiliary circuitry stress analysis, and auxiliary circuitry designing methodology are presented in detail. Experimental results from a 700 V supply 3 kW half-bridge three-level capacitor clamping inverter are demonstrated which conform well to the proposal