A half‐bridge resonant DC/DC converter with satisfactory soft‐switching characteristics

In this paper, a half‐bridge resonant DC/DC converter with constant output voltage is proposed, which possesses good soft‐switching characteristics. At rated operating point, the switches can operate almost without switching‐on and off losses. Further, at whole working range, both zero‐voltage‐switching mode of switches and zero‐current‐switching mode of diodes are maintained. Thus, the converter can achieve a high efficiency. Experimental results verify the low switching losses and high efficiency characteristics based on a 200 W prototype. System efficiency is as high as 96% and always above 90% when output power changes from 100% to 20%. Copyright © 2016 John Wiley & Sons, Ltd.     

电池储能系统的双向DC/DC变换器控制策略研究

研究电网与蓄电池之间的电能变换接口装置,为改善变换器的性能,提出一种基于双重移相控制的电池储能系统的双向全桥DC/DC变换器。从理论上对双向全桥DC/DC变换器的工作特性进行了分析,以抑制电路中的回流功率为目标,根据系统的传输功率与高频变压器两侧的变比理论上推导最优移相控制量,简化移相控制量实现对双向DC/DC变换器实时控制,实现了被控量的稳定,传输效率的提高。最后,搭建的小功率实验样机表明:该控制策略可以有效降低功率传输中的回流功率。     

脉冲移位PWM控制ZCS电流型半桥变换器

提出一种改进的电流型零电流半桥电路拓扑.与传统的电流型半桥电路相比,该拓扑电路增加了一个由辅助开关管、二极管以及电容组成的辅助支路,采用脉冲移位PWM控制方法,避免了直流偏磁的产生,使开关占空比在一定范围内可调的情况下实现主功率开关管和辅助开关管的零电流开关(ZCS),同时实现了整流二极管的软换流,使得整流二极管反向电...     

三端口DC/DC变换器预测电流移相控制

针对微电网储能系统中三端口DC/DC变换器,研究了基于半开关周期采样和全开关周期采样的预测电流移相控制。分析了变换器的工作状态和开关模态,采用Y-△等效变换得到电感电流斜率,在每个开关周期驱动信号的中点时刻采样电感电流,计算不同阶段变换器的电感电流增量。基于电流采样值和电流参考值预测变换器下一个开关周期上升沿和下降沿移相比,更新该移相比使电感电流达到参考值。然后分析了两种采样模式下电感电流中直流分量消除机理,并给出三端口DC/DC变换器闭环控制策略。仿真结果验证了该控制方法的有效性,较好地解决了三端口DC/DC变换器直流偏置问题,提高了系统的动态响应和鲁棒性能。     

A novel low‐loss control strategy for bidirectional DC–DC converter

Bidirectional DC–DC converter with phase‐shift control is commonly used for hybrid electric vehicle and fuel‐cell vehicle applications. This converter is characterized by simple circuit topology and soft‐switching implementation without additional devices. Despite these advantages, the efficiency is poor at light load condition because of high switching and conduction losses caused by high RMS inductor current. To achieve zero‐voltage switching (ZVS) for all power MOSFETs, a constant offset inductor current is maintained to conduct the antiparallel body diodes before MOSFETs turn on. A control strategy of combining duty ratio and phase‐shift modulation is proposed to reach the constant offset current. By reaching the constant offset current, the RMS inductor current can be reduced significantly, and ZVS can be achieved in all load variation ranges, resulting in high efficiency. A 2.5‐kW prototype is implemented to verify the control scheme, and a minimum efficiency of 97.3% is achieved at light load condition. Copyright © 2017 John Wiley & Sons, Ltd.     

Design of a ZVS PWM DC–DC converter for high gain applications

In this paper, a pulse width modulation DC‐DC converter with high step‐up voltage gain is proposed. The proposed converter achieves high step‐up voltage gain with appropriate duty ratio, coupled inductor, and voltage multiplier technique. The energy stored in the leakage inductor of the coupled inductor can be recycled in the proposed converter. Moreover, because both main and auxiliary switches can be turned on with zero‐voltage switching, switching loss can be reduced by soft‐switching technique. So the overall conversion efficiency is improved significantly. The theoretical steady‐state analyses and the operating principles of the proposed converter are discussed in detail for both continuous conduction mode and discontinuous conduction mode. Finally, a laboratory prototype circuit of the proposed converter is implemented to verify the performance of the proposed converter. Copyright © 2015 John Wiley & Sons, Ltd.     

应用于大功率场合的移相全桥ZCS DC/DC变换器

对ZCS DC／DC全桥变换器进行了全面的分析。由于所有的开关管均可实现ZCS,因此该变换器广泛应于大电压大功率场合。该变换器对于吸收器件的寄生参数,特别是吸收高压变压器的寄生参数．并对利用固定频率移相控制来实现ZCS有着非常明显的作用。详细分析了半周期的工作过程。并对之进行了稳态分析,提出了该变换器的一些主要特点。最后给出一台实验样机．对理论分析进行了有效的论证。     

A model‐based dead‐band compensation for the dual‐active‐bridge isolated bidirectional DC–DC converter

The dual active bridge (DAB)‐based isolated bidirectional converter has been used to realize bidirectional energy flow while offering needed isolation between the primary and secondary side: for example, the battery side and grid side of one plug‐in hybrid electric vehicle (PHEV). Even though the operation of a DAB‐based DC–DC converter is straightforward, various transient processes exist, such as the dead‐band effect, which deeply affects the dynamic performance of the converter in real world applications. Compensation of this effect is not easy because of the strong nonlinearity of the entire system. This paper quantitatively analyzed the dead‐band effect at different output powers, and presented a model‐based controller to realize the nonlinear dead‐band compensation strategy, which can effectively mitigate demerits of the traditional PI‐based control strategy. The proposed control algorithm is validated through theoretical simulation and experimental results. © 2011 Institute of Electrical Engineers of Japan. Published by John Wiley & Sons, Inc.     

A step‐up PWM DC–DC converter for renewable energy applications

A step‐up pulse width modulation (PWM) direct current (DC)–DC converter is presented in this paper, which has its origin in quasi Z‐source inverter. Analysis of this converter in steady state is presented, and relevant expressions are derived for the proposed converter operating in continuous conduction mode. The power loss expressions for each component of the converter are derived, and thereby, obtained expressions for overall converter efficiency are presented. Further, a dynamic model is derived to design an appropriate controller for this converter. The simulation and experimental results are presented to support the theoretical analysis. The advantages such as continuous input current, high step‐up gain at lower duty ratio, and common ground for source, load, and switch makes the converter suitable for renewable energy applications. Copyright © 2015 John Wiley & Sons, Ltd.     

Design and implementation of a high‐efficiency bidirectional DC‐DC Converter for DC micro‐grid system applications

This paper studies the design and implementation of a non‐isolated dual‐half‐bridge bidirectional DC‐DC converter for DC micro‐grid system applications. High efficiency can be achieved under wide‐range load variations by the zero‐voltage‐switching features and an adaptive phase‐shift control method. A three‐stage charging scheme is designed to meet the fast‐charging demand and prolong the lifetime of LiFePO₄ batteries. A digital‐signal‐processing control IC is used to realize the power flow control, DC‐bus voltage regulation, and battery charging/ discharging of the studied bidirectional DC‐DC converter. Finally, a 10 kW prototype converter with Enhanced Controller Area Network communication function is built and tested for micro‐grid system applications. A light‐load efficiency over 96% and a rated‐load efficiency over 98% can be achieved. Copyright © 2013 John Wiley & Sons, Ltd.     

High‐efficiency current‐doubler rectifier with low output current ripple and high step‐down voltage ratio

This paper presents a current‐doubler rectifier with low output current ripple and high step‐down voltage ratio. In the proposed rectifier, two extra inductors are introduced to extend the duty ratio of the switches, which in turn reduces the peak current through the isolation transformer as well as the output current ripple; two extra diodes are used to provide discharge paths for the two extra inductors. To highlight the merits of the proposed rectifier, its performance indexes, such as voltage gain function, secondary winding peak current of the isolation transformer, and output current ripple, are analyzed and compared with the conventional current‐doubler rectifier. In this paper, a zero‐voltage‐switching phase‐shift full‐bridge converter with the proposed rectifier with an input voltage of 400 V, output voltage of 12 V, and full load power of 500 W has been implemented and verified, and experimental results have shown that 90% conversion efficiency could be achieved at full load. © 2013 Institute of Electrical Engineers of Japan. Published by John Wiley & Sons, Inc.     

基于TI控制器UCC28950的全桥移相ZVS变换器设计

采用TI移相控制器UCC28950设计了全桥移相变换器,实现了其超前桥臂、滞后臂的零电压开关,其系统具有结构简单、占空比丢失较小、软开关较容易实现等特点。首先全面分析了全桥移相的工作原理,讨论实现软开关的必要条件,计算了主要器件参数,然后利用PSIM仿真软件对电路进行仿真,最后通过实际搭建的5k W大功率AC/DC开关电源进行测试,验证了此方法设计的合理性。     

A switch‐mode boost DC–DC converter for IR‐drop compensation of charging cable

A switch‐mode boost DC–DC converter has been developed to compensate for the IR‐drop because of the finite resistance of a charging cable. The boost ratio of the DC–DC converter is adaptively controlled by an IR‐drop sensing circuit to provide the required voltage level to a battery charger regardless of the cable resistance. Implemented in a 0.18 µm BCDMOS process, the IR‐drop compensating switch‐mode boost DC–DC converter occupies 6.2 mm² active area and shows the 93.2% peak efficiency. The proposed IR‐drop compensating boost converter can be applied to compensate for the IR‐drop of any type of charging cables. Copyright © 2014 John Wiley & Sons, Ltd.     

An interleaved high step‐up DC‐DC converter with double boost paths

This paper proposed a novel high step‐up converter with double boost paths. The circuit uses two switches and one double‐path voltage multiplier cell to own the double boost and interleaved effects simultaneously. The voltage gain ratio of the proposed DC‐DC converter can be three times the ratio of the conventional boost converter such that the voltage stress of the switch can be lower. The high step‐up performance is in accordance with only one double‐path voltage multiplier cell. Therefore, the number of diodes and capacitors in the proposed converter can be reduced. Furthermore, the interleaved property of the proposed circuit can reduce the losses in the rectifier diode and capacitor. The prototype circuit with 24‐V input voltage, 250‐V output voltage, and 150‐W output power is experimentally realized to verify the validity and effectiveness of the proposed converter. Copyright © 2014 John Wiley & Sons, Ltd.     

Hybrid DC–DC converter with high efficiency,wide ZVS range,and less output inductance

In this paper, a new soft switching direct current (DC)–DC converter with low circulating current, wide zero voltage switching range, and reduced output inductor is presented for electric vehicle or plug‐in hybrid electric vehicle battery charger application. The proposed high‐frequency link DC–DC converter includes two resonant circuits and one full‐bridge phase‐shift pulse‐width modulation circuit with shared power switches in leading and lagging legs. Series resonant converters are operated at fixed switching frequency to extend the zero voltage switching range of power switches. Passive snubber circuit using one clamp capacitor and two rectifier diodes at the secondary side is adopted to reduce the primary current of full‐bridge converter to zero during the freewheeling interval. Hence, the circulating current on the primary side is eliminated in the proposed converter. In the same time, the voltage across the output inductor is also decreased so that the output inductance can be reduced compared with the output inductance in conventional full‐bridge converter. Finally, experiments are presented for a 1.33‐kW prototype circuit converting 380 V input to an output voltage of 300–420 V/3.5 A for battery charger applications. Copyright © 2015 John Wiley & Sons, Ltd.     

Adaptive saturated finite‐time control algorithm for buck‐type DC‐DC converter systems

To enhance the convergent rate and robustness of buck‐type DC‐DC converter system, a new finite‐time voltage regulation control algorithm is proposed in this paper. First, an average state space‐based model is analyzed, which considers both the parameters uncertainties and the variations of load and input voltage. By using saturation finite‐time control theory, at the first step, in the absence of disturbance, a new fast voltage regulation control algorithm is designed, which can guarantee that the output voltage converges to the reference voltage in a finite time. Because the saturation constraint is considered during the controller design, the duty ratio function of the converter satisfies the constraint between 0 and 1. Second, in the presence of disturbance, a finite‐time convergent disturbance observer is designed to estimate the unknown disturbances in a finite time. Finally, a disturbance observer‐based finite‐time voltage regulation control algorithm is developed. Compared with PI (Proportional‐Integral) control algorithm, circuit simulations show that the proposed algorithm has a faster regulation performance and stronger robustness performance on disturbance rejection.     

Fast‐transient DC‐DC converter using a high‐performance error amplifier with a rapid output‐voltage control technique

This letter presents a method for improving the transient response of DC‐DC converters. The proposed technique replaces the conventional error amplifier with a combination of two different amplifiers to achieve a high loop gain and high slew rate. In addition, a rapid output‐voltage control circuit is employed to further reduce the recovery time. The proposed technique was applied to a four‐phase buck converter, and the chip was implemented using a 0.18‐μm CMOS process. The switching frequency of each phase was set at 2 MHz. Using a supply voltage of 2.7–5.5 V and an output voltage of 0.6–1.5 V, the regulator provided up to 2‐A load current with maximum measured recovery time of only 6.2 and 6.5 μs for increasing and decreasing load current, respectively. Copyright © 2017 John Wiley & Sons, Ltd.     

Non‐invasive chaos control of DC–DC converter and its optimization

The frequency‐domain‐based realization condition related to a novel non‐invasive chaos control is presented in this paper. According to the common piecewise‐linear characteristics of PWM‐controlled DC–DC converter system, a general expression for its Jacobian matrix is derived for optimizing the control parameters of the proposed non‐invasive chaos control. The relevant simulation and experiment results about the application of the chaos control to a voltage‐mode Buck converter are given, which confirm the feasibility of the parameter‐optimization method and the validity of the proposed non‐invasive chaos control. Copyright © 2010 John Wiley & Sons, Ltd.     

A Five‐Element Multiplex Resonant Full‐Bridge DC‐DC Converter with a Variable Inductive Reactance

A five‐element multiplex resonant (LLCLC) full‐bridge DC‐DC converter controlled by pulse frequency modulation (PFM) is proposed in this paper. The high frequency (HF)‐link resonant DC‐DC converter proposed herein can perform wide‐range output power and voltage regulation with a narrow frequency range due to an antiresonant tank that works effectively as a wide‐range variable inductor. The advantageous characteristics of the antiresonant tank provide overcurrent protection in the case of the short‐circuited load condition as well as in the startup interval. Thus, the technical challenges of a conventional LLC DC‐DC converter can be overcome, and the reliability of the relevant switch‐mode power supplies can be improved. The operating principle of the LLCLC DC‐DC converter is described, after which its performance is evaluated in an experimental setup based on the 2.5 kW prototype. Finally, the feasibility of the proposed DC‐DC converter is discussed from a practical point of view.     

Multistage multiphase switched‐capacitor DC–DC converter with variable‐phase and PWM control

A closed‐loop multistage multiphase switched‐capacitor converter (n‐stage p‐phase MPSC) is proposed with a variable‐phase control (VPC) and a pulse‐width‐modulation (PWM) technique for low‐power step‐up conversion and high‐efficiency regulation. In this n‐stage MPSC, n voltage doublers are connected in series for boosting the voltage gain up to 2ⁿ at most. Here, VPC is suggested to realize a variable multiphase operation by changing the phase number p and topological path for the more suitable level of voltage gain so as to improve the power efficiency, especially for the lower output voltage Besides, PWM is adopted not only to enhance output regulation for different desired outputs, but also to reinforce output robustness to source/loading variation. Further, some theoretical analyses and designs include: n‐stage p‐phase MPSC model, steady‐state analysis, conversion ratio, power efficiency, output ripple, stability, capacitance selection, and control design. Finally, the closed‐loop MPSC is simulated, and the hardware is implemented and tested. All the results are illustrated to show the efficacy of the proposed scheme. Copyright © 2011 John Wiley & Sons, Ltd.