Soft-Switching Auxiliary Current Control for Improving Load Transient Response of Buck Converter

To balance the cost and volume when applying a low output current ripple, the power supply design should be able to eliminate the current ripple under any duty cycle in medium and high switching frequencies, and considerably reduce filter volume to improve power density. A stacked buck converter was eventually selected after reviewing the existing solutions and discussing their advantages and disadvantages. A stacked buck converter is used as a basis to propose the transient response and output current ripple elimination effect, boundary limit control method, and low output ripple dead time modulation method to make individual improvements. The principle, mathematical derivation, small-signal model, and compensator design method of the improvement method are presented in detail. Moreover, simulation results are used to mutually verify the correctness and effectiveness of the improvement method. A stacked buck converter with 330-V input, 50-V output, and 1-kW output power was implemented to verify the effect of the low output current ripple dead time modulation. Experimental results showed that the peak-to-peak value of the output current ripple was reduced from 2.09 A to 559 mA, and the RMS value was reduced from 551 mA to 91 mA, thereby effectively improving the output current ripple.

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Compensated Single Input Multiple Output Flyback Converter

Energies ◽

10.3390/en14113009 ◽

2021 ◽

Vol 14 (11) ◽

pp. 3009

Author(s):

Mohammad Tahan ◽

David O. Bamgboje ◽

Tingshu Hu

Keyword(s):

Transient Response ◽

Current Mode ◽

Voltage Regulation ◽

Buck Converter ◽

Output Channel ◽

Flyback Converter ◽

Input Multiple Output ◽

Voltage Deviation ◽

Single Input ◽

The Cross

A new single-input multiple-output (SIMO) converter is proposed in this work by incorporating flyback and buck converters in a master–slave configuration. The objective of this work is to address the cross regulation problem, achieve tight voltage regulation, improve the circuit form factor and attain a fast transient response for a SIMO flyback converter. The flyback converter maintains the output channels within 10% of their rated voltages and the SIMO buck converter is placed in series with the flyback converter such that it compensates for the output voltage deviation. Moreover, a time multiplexing switching scheme decouples output channel to eliminate the cross-regulation problem and remove the need for an additional winding transformer per each output channel. A type II compensator with a peak current mode controller was designed to achieve faster transient response which is critical for the proposed configuration. A thorough steady-state analysis was carried out on a triple output channel topology to obtain the design criteria and component values. MATLAB/Simscape modelling and simulation was used to validate the effectiveness of the proposed converter with the result yielding satisfactory transience even with load disturbance. Additionally, the result of the proposed converter is compared with previously published works.

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A fixed frequency dual-mode DC-DC buck converter with fast-transient response and high efficiency over a wide load range

2013 Twenty-Eighth Annual IEEE Applied Power Electronics Conference and Exposition (APEC) ◽

10.1109/apec.2013.6520243 ◽

2013 ◽

Cited By ~ 8

Author(s):

Somnath Maity ◽

Y. Suraj

Keyword(s):

Transient Response ◽

High Efficiency ◽

Buck Converter ◽

Fixed Frequency ◽

Dual Mode ◽

Load Range ◽

Fast Transient Response ◽

Fast Transient

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Soft Switching of Full-Bridge DC-DC Buck Converter

International Journal for Research in Engineering Application & Management ◽

10.35291/2454-9150.2020.0348 ◽

2020 ◽

pp. 561-565

Keyword(s):

Power Systems ◽

Power Flow ◽

Distribution Systems ◽

Buck Converter ◽

Soft Switching ◽

Power Supplies ◽

Power Circuit ◽

Zero Voltage Switching ◽

Zero Current Switching ◽

Zero Current

The conventional Bidirectional Full-bridge dc -dc converter is inefficient and may not be practical for the low power applications. This paper specifies an efficient DC-DC Converter that avoids power losses by using soft switching techniques like Zero Voltage Switching and Zero Current switching. The soft switching of Bidirectional Full-bridge DC-DC Converter operates as a buck converter when the power is positive and as a boost converter when the power flow is negative. Applications of soft switching Bidirectional Full-bridge DC-DC Converter are uninterrupted power supplies (UPS), distribution Systems, battery charger circuits, telecom power supplies, computer power systems. Detailed analysis of the converter is carried out in buck mode to obtain relations between the power circuit parameters. Based on the analysis, control schemes are described to operate the converter. The proposed full bridge DC-DC converter is simulated in Buck mode using MATLAB /SIMULINK.

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A solar fed BLDC motor drive for mixer grinder using a buck converter

International Journal of Electrical and Computer Engineering (IJECE) ◽

10.11591/ijece.v10i2.pp1113-1121 ◽

2020 ◽

Vol 10 (2) ◽

pp. 1113

Author(s):

Deekshitha S. Nayak ◽

R. Shivarudraswamy

Keyword(s):

Load Condition ◽

Performance Comparison ◽

Current Control ◽

Buck Converter ◽

Small Scale ◽

Motor Drive ◽

Bldc Motor ◽

Brushless Dc ◽

Photovoltaic Array ◽

Simulated System

In large and small scale applications, different kinds of variable speed driving systems can be found. For saving the energy consumption of these devices, eco-friendly electronics are used, which lead to the development of the Brushless DC motor (BLDC). Its higher power density, higher efficiency, higher torque at low speed, and low maintenance enhances the use of a BLDC motor. The existing mixer grinder consists of the universal motor, which operates in alternating current supply due to high starting torque characteristics and simple controlling of the speed. The absence of brushes and the reduction of noise in the BLDC extends its life and makes it ideal in a mixer grinder. A solar-powered BLDC motor drive for a mixer grinder is presented in this paper. A DC-DC buck converter is utilized to operate the PV (photovoltaic) array at its maximum power. The proposed hysteresis current control BLDC system has been developed in the MATLAB. The commercially available mixer grinder is presented along with the proposed simulated system for performance comparison. It can be concluded that at the no load condition, the efficiency of the experimental existing mixer grinder is 51.03% and simulated proposed system is 81.25% and at load condition, the efficiency of the experimental mixer grinder is 49.32% and simulated system is 79.85%.

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