Single‐stage single‐switch PFC converter for wide‐input extreme step‐down voltage applications

Self Cite

A novel single switch two diode wide conversion ratio step down/up converter is presented. The proposed converter is derived from the conventional single-ended primary inductor converter (SEPIC) topology, and it can operate as a capacitor-diode voltage multiplier, which offers simple structure, reduced electromagnetic interference (EMI), and reduced semiconductor voltage stress. The main advantages of the proposed converter are the continuous input/output current, higher voltage conversion ratio, and near-zero input and output current ripples compared with the conventional SEPIC converter. The absence of both a transformer and an extreme duty cycle permits the proposed converter to operate at high switching frequencies. Hence, the overall advantages will be: higher efficiency, reduced size and weight, simpler structure and control. The theoretical analysis results obtained with the proposed structure are compared with the conventional SEPIC topology. The performance of the proposed converter is verified through computer simulations and experimental results.proposed converter to operate at high switching frequencies. Hence, the overall advantages will be: higher efficiency, reduced size and weight, simpler structure and control.Comparison results with the conventional SEPIC converter show that the proposed modified SEPIC is more suitable for applications that require a high input-to-output voltage conversion ratio. The proposed converter has few extra components compared to the conventional SEPIC converter, and it is regulated by the conventional PWM technique at constant frequency. However, the additional components is outweighed by the significant advantages gained, thus expecting the popularity of this technique to other exiting topologies. The performance of the converter is verified by means of simulation and experimental tests which confirm the operating principles of the proposed converter. 374

Section: The Proposed Converter With Coupled Inductorsmentioning

confidence: 99%

Section: The Proposed Converter With Coupled Inductorsmentioning

confidence: 99%

Step‐up/step‐down DC‐DC converter with near zero input/output current ripples

Ismail

Fardoun

Zerai

2012

Self Cite

“…The first stage is a single-phase alternating current (AC)-direct current (DC) converter. Boost converters with diode bridge or bridgeless topologies have been discussed in [1][2][3]11] to achieve a stable DC bus voltage, low line harmonic current, and high input power factor. The second stage is a DC-DC converter with high-frequency link for battery current regulation and galvanic isolation.…”

Section: Introductionmentioning

confidence: 99%

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

Lin

Chu

2015

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.

“…But, the voltage conversion ratio of this converter is not improved, and also, because the switches are floating, additional isolated gate drivers are needed, making the gate driving circuit complicated. In , some non‐isolated high step‐down converters are proposed. The converters use switched inductors and switched capacitors to achieve high step‐down gain.…”

Section: Introductionmentioning

confidence: 99%

Non‐isolated large step‐down voltage conversion ratio converter with non‐pulsating output current

Hwu

Jiang

2015

SUMMARYA non-isolated dual half-bridge large step-down voltage conversion ratio converter with non-pulsating output current, utilizing one coupled inductor, one energy-transferring capacitor, and one output inductor, is presented herein. The coupled inductor is connected between the input voltage and the output inductor and plays a role to step down the input voltage. Furthermore, the output inductor is used not only to further step down the voltage but also to provide a non-pulsating output current. Moreover, the proposed converter can achieve zero-voltage switching. In this study, detailed theoretical deductions and some experimental results of a prototype with 48 V input voltage, 3.3 V output voltage, and 10 A output current are provided to demonstrate the feasibility and effectiveness of the proposed converter.