Boost ZCT-PWM变换器的改进及仿真分析

针对传统的Boost ZCT-PWM变换器中存在的主开关管硬开通和辅助开关管硬关断的问题,提出一种改进型的Boost ZCT-PWM变换器,使主开关管零电流开通,辅助开关管零电流通断,并且特别适用于IGBT作为开关器件的高电压、大功率应用场合。分析电路的工作原理并用PSpice仿真软件进行仿真研究。仿真结果表明所有开关器件实现了软开关,变换器的效率得到提高。     

基于PWM变换器的新型无源无损软开关

详细分析了一种基于PWM变换器的新型无源无损软开关，并给出了其最优化设计步骤。通过一台满载输出功率为900w的带有该无源无损软开关的Boost变换器验证了其开关管实现零电流开通和零电压关断，并与传统的Boost变换器比较，验证其具有较高的效率。     

一种Boost软开关变换器的改进方法

为了减小Boost软开关变换器高频工作状态下开关管的功率损耗,文中提出了一种改进调制策略,传统调制策略下主开关管只能实现零电流开通,通过改变主开关管的开通时刻和辅助开关管的关断时刻可实现主开关管零电压零电流开通,辅助开关管可提前实现零电压零电流关断,提高了电路工作效率。仿真波形中观察到改进调制策略下主开关管实现了零电压零电流开通,辅助开关管提前实现了零电压零电流关断。     

新颖的含PFC的PWM ZVS AC-DC变换器

提出了一种新的具有功率因数补偿(PFC)功能的零电压开关(ZVS)AC-DC变换器,该变换器基于不连续导电模式(DCM)下的Boost环节实现PFC功能,但其具有ZVS机制,从而解决了DCM下因开关关断大的峰值电流引起的关断损耗高、EMI严重的问题,同时还消除了由于开关的寄生电容引起的开通损耗.该变换器可以采用通用控制芯片并工作在PWM模式.文中分析了提出变换器的工作原理,并给出了基本设计原则.模拟和实验结果证明了提出的电路是可行的.     

采用辅助变压器的零电压零电流开关全桥直-直变换器

本文给出了一种新型的零电压零电流开关全桥移相脉宽调制变换器,该变换器采用IGBT为功率开关管,在传统变换器的基础上通过增加辅助变压器的方式提高了变换器的性能,通过增加正激能量恢复缓冲器和辅助电路,使变换器在各种负载以及短路工作状态下都能够保证所有开关管实现零电压零电流开关工作模式。介绍了变换器的工作原理并通过试验得到了较好的结果。     

新型软开关Boost ZCT-PWM变换器

针对传统Boost ZCT—PWM变换器存在主开关管电流应力大和辅助管硬关断的问题，提出了一种新型Boost ZCT—PWM电路，对其工作原理做了详细的分析并给出了谐振参数的计算。仿真结果表明该电路不仅实现了主开关和辅助开关管的软开关，同时主开关管不增加额外的电流应力，而且电路中所有二极管也都实现了软通断。     

一种等离子显示系统专用电源

设计了一个用于多屏拼接等离子显示系统的专用电源。该电源采用两级变换,前级AC/DC变换采用Boost型有源功率因数校正电路,后级变换器对于不同的回路根据功率的大小分别采用全桥变换器和单端反激变换器。对传统Boost型功率因数校正电路提出了一点改进,有效抑制了传统Boost型功率因数校正电路中大功率时开关管开通时二极管上瞬时大电流。后级变换器中主回路采用一种次级无源箝位ZVZCS全桥变换器,适宜大功率的输出且有效降低了开关损耗。     

双向Buck/Boost变换器的教学探析

本文针对现有“电力电子技术”相关教材中存在的对双向变换器的分析不完善和各知识点之间缺乏联系等问题,探析了双向Buck/Boost变换器的拓扑生成原理,并且详细分析了变换器运行于电感电流过零模式下实现零电压开关的具体过程,并推导出了软开关的实现条件。本文有助于学生理解并加深双向变换器与基本Buck和Boost变换器之间的联系和差别,并了解软开关技术在基本变换器中的应用,具有一定的教学指导意义。     

一种高效的同步整流Boost软开关变换器

针对同步整流Boost变换器的效率问题,提出一种同步整流Boost软开关拓扑。在辅助电路的帮助下,实现了主开关管的零电压通断和辅助开关管的零电流通断,显著改善了因开关管导致的变换器损耗严重的问题,使变换器的效率得到了有效提高。详细分析了所提变换器的工作原理并对主要参数的选取和变换器的特性进行了讨论,最后通过Pspice仿真实验对理论分析进行了验证。     

低损耗软开关Boost变换器

介绍一种新的软开关Boost变换器。传统的Boost变换器在开通和关断时将产生开关损耗,因此使整个系统的效率下降。新的Boost变换器利用软开关方法增加了辅助开关管和谐振电路。这样,相比硬开关情况下,变换器减小了开关损耗。这种变换器可以应用在光伏系统、功率因子校正等装置中。详细分析电路的工作原理以及实现软开关的条件,利用Pspice9．2软件进行仿真验证。仿真结果表明,该变换器的所有开关器件都实现了软开关,从而使效率得到提高。     

A zero-voltage-switched PWM boost converter with an energyfeedforward auxiliary circuit

A zero-voltage-switched (ZVS) pulsewidth-modulated (PWM) boost converter with an energy feedforward auxiliary circuit is proposed in this paper. The auxiliary circuit, which is a resonant circuit consisting of a switch and passive components, ensures that the converter's main switch and boost diode operate with soft switching. This converter can function with PWM control because the auxiliary resonant circuit operates for a small fraction of the switching cycle. Since the auxiliary circuit is a resonant circuit, the auxiliary switch itself has both a soft turn on and turn off, resulting in reduced switching losses and electromagnetic interference (EMI). This is unlike other proposed ZVS boost converters with auxiliary circuits where the auxiliary switch has a hard turn off. Peak switch stresses are only slightly higher than those found in a conventional PWM boost converter because part of the energy that would otherwise circulate in the auxiliary circuit and drastically increase peak switch stresses is fed to the load. In this paper, the operation of the converter is explained and analyzed, design guidelines are given, and experimental results obtained from a prototype are presented. The proposed converter is found to be about 2%-3% more efficient than the conventional PWM boost converter     

一种零电压开关Zeta变换器的设计

给出了一种零电压开关Zeta变换器,这种变换器可以提高效率和减小功率开关管的电压应力.当变换器工作在连续模式时,应用谐振电容和变压器的漏感实现功率开关管的零电压导通.详细分析了变换器的工作原理,并设计了相应的电路进行验证.仿真结果表明所设计的Zeta变换器效率达92.21%,输出电压纹波为125 mV.它可被用于等离子显示屏(PDP)电源系统.     

A new ZVT-PWM DC-DC converter

In this paper, a new active snubber cell that overcomes most of the drawbacks of the normal "zero voltage transition-pulse width modulation" (ZVT-PWM) converter is proposed to contrive a new family of ZVT-PWM converters. A converter with the proposed snubber cell can also operate at light load conditions. All of the semiconductor devices in this converter are turned on and off under exact or near zero voltage switching (ZVS) and/or zero current switching (ZCS). No additional voltage and current stresses on the main switch and main diode occur. Also, the auxiliary switch and auxiliary diodes are subjected to voltage and current values at allowable levels. Moreover, the converter has a simple structure, low cost, and ease of control. A ZVT-PWM boost converter equipped with the proposed snubber cell is analyzed in detail. The predicted operation principles and theoretical analysis of the presented converter are verified with a prototype of a 2 kW and 50 kHz PWM boost converter with insulated gate bipolar transistor (IGBT). In this study, a design procedure of the proposed active snubber cell is also presented. Additionally, at full output power in the proposed soft switching converter, the main switch loss is about 27% and the total circuit loss is about 36% of that in its counterpart hard switching converter, and so the overall efficiency, which is about 91% in the hard switching case, increases to about 97%     

采用分段式自适应PWM/PFM调制的Buck型DC-DC转换器设计北大核心

为了在轻重负载条件下获得更高的转换效率，采用分段式结构和导通电阻更小的NMOS作为输入级，并采用PWM/PFM双调制方式，设计了一种Buck型DC-DC转换器。为解决PWM/PFM调制信号切换问题，采用零电流检测方式进行切换。利用断续导通模式(DCM)和连续导通模式(CCM)下端NMOS管导通时电感电压的不同，检测下端NMOS在导通时电感电压大于零的周期。当电感电压大于零的周期大于2时，则处于DCM模式并自动采用PFM调制模式，关闭一部分功率管以减小开关频率和功率管寄生电容，优化轻载效率；反之则处于CCM模式并采用PWM调制。仿真结果表明，在负载电流10～1 000 mA范围内，该电路可以在两种调制模式平稳切换，在800 mA时峰值效率可提升到96%以上。     

A self core reset and zero voltage switching forward convertertopology

A self core reset and zero voltage switching (ZVS) forward converter topology is presented in this paper. By employing a simple auxiliary circuit, the proposed topology is able to achieve self reset of the power transformer without the use of the conventional tertiary reset winding, and its main switch can be turned on and turned off under ZVS independent of line and load conditions. This simplifies the power transformer, and the switching losses are substantially removed to improve the overall efficiency. Steady state analysis of the circuit is performed. Based on the analysis, a design procedure is presented, and the effects of the circuit parameters on the flux excursion of the power transformer are investigated to make sure self reset can be achieved without increasing the core losses. Simulation and experiment on a 5 V, 100 W prototype circuit operated at 200 kHz are carried out to verify the design, about 5% higher overall efficiency is obtained in the prototype converter than in its conventional counterpart     

脉冲激光双管正激开关电源的软拓扑

设计了一种双正激电路的软开关和预燃电路,分析了它们的工作原理,推导了一些关键技术参数的计 算公式。原边电路的主开关管和副边电路的功率二极管都实现了软开关,减小了开关过程中的能量损耗,减小了电 磁污染。     

脉冲激光双管正激开关电源的软拓扑

设计了一种双正激电路的软开关和预燃电路，分析了它们的工作原理，推导了一些关键技术参数的计算公式。原边电路的主开关管和副边电路的功率二极管都实现了软开关，减小了开关过程中的能量损耗，减小了电磁污染。     

A new soft-switched PWM boost converter with a lossless auxiliary circuit

A soft-switching scheme for the PWM boost converter is newly proposed to obtain the desirable features of both the conventional PWM boost and resonant converters such as ease of control, reduced switching losses and stresses, and low EMI. In order to achieve the soft-switching action, the proposed scheme employs an auxiliary circuit, which is added to the conventional boost converter and used to achieve soft-switching for both the main switch and the output diode while not incurring any additional losses due to the auxiliary circuit itself. The basic operations, in this paper, are discussed and design guidelines are presented. Through a 100?KHz, 60?W prototype, the usefulness of the proposed scheme is verified.     

负载并联LLC变换器的研究

随着电子产品越来越趋于高频化、模块化和集成化,小体积和高效性及低电磁干扰（EMI）成为研究的主要课题。因此,LLC变换器在高频开关电源领域得到快速的发展应用。为了提高电路的功率转换效率,文中设计了负载并联变换器。单一的输出负载浪费了电路的转换功率,而负载并联LLC变换器通过负载输出模块的并联,大大提高了电路的功率效率。通过Saber和Simplorer仿真软件进行仿真,得出该LLC变换器在不同负载和输入电压变化的情况下,能保持稳定的输出特性和良好的调节功能,而且开关管和二极管可以实现相应的ZVS和ZCS,验证了理论的正确和可行性。     

Novel Family of PWM Soft-Single-Switched DC–DC Converters With Coupled Inductors

In this paper, a novel family of pulsewidth-modulation soft-single-switched dc–dc converters without high voltage and current stresses is described. These converters do not require any extra switch to achieve soft switching, which considerably simplifies the control circuit. In all converter family members, the switch is turned on under zero-current condition and is turned off at almost zero-voltage condition. From the proposed converter family, the boost topology is analyzed, and its operating modes are explained. The presented experimental results of a prototype boost converter confirm the theoretical analysis.