A three‐level isolated dc‐dc SEPIC converter with parallel‐connected output

Ewerling, Marcos Vinicius Mosconi; Lazzarin, Telles Brunelli; Font, Carlos Henrique Illa

doi:10.1002/cta.3468

Cited by 2 publications

(3 citation statements)

References 39 publications

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“…In order to prevent the two switching devices from operating simultaneously, the duty cycle for each was set to less than 50% [59]. Switching between the two power devices (Q 1 ) and (Q 2 ) in the push-pull converter is accomplished by a 180°phase difference between the two signals [45,60]. Due to their simplicity, push-pull converters are ideal for medium-to-low power applications [61].…”

Section: Push-pull Converter Topologiesmentioning

confidence: 99%

Topologies and Design Characteristics of Isolated High Step-Up DC–DC Converters for Photovoltaic Systems

Meshael,

Elkhateb,

Best

2023

Electronics

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This paper aims to investigate the state-of-the-art isolated high-step-up DC–DC topologies developed for photovoltaic (PV) systems. This study categorises the topologies into transformer-based and coupled inductor-based converters, as well as compares them in terms of various parameters such as component count, cost, voltage conversion ratio, efficiency, voltage stress, input current ripple, switching mode, and power rating. The majority of the topologies examined exhibit peak efficiencies of 90% to 97%, with voltage conversions in excess of eight, as well as power ratings ranging from 100 W to 2 kW. The existing literature has found that most isolated DC–DC converters increase their turn ratios in order to achieve high step-up ratios. As a result, voltage spikes have increased significantly in switches, resulting in a decrease in overall system efficiency. In this research, the use of passive and active snubbers to provide soft switching in isolated step-up DC–DC converters is investigated. Moreover, a comprehensive analysis of the three most widely used boost techniques is provided. A reduction in turn ratio and a decrease in voltage stress were the results of this process. The main purpose of this study is to provide a comprehensive overview of the most used high-boost isolated DC–DC topologies in PV systems, including flyback, isolated SEPIC, forward, push-pull, half- and full-bridge, and resonant converter, with a focus on the recent research in the field and the recent advancements in these topologies. This study aims to guide further research and analysis in selecting appropriately isolated topologies for PV systems.

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Section: Push-pull Converter Topologiesmentioning

confidence: 99%

Topologies and Design Characteristics of Isolated High Step-Up DC–DC Converters for Photovoltaic Systems

Meshael,

Elkhateb,

Best

2023

Electronics

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“…In some high-power industrial applications, such as electric vehicle charging piles and server base station power supply systems, the technology of parallel expansion of power supply has been widely used. [1][2][3][4][5][6] The power parallel system composed of N power modules has the advantages of N + 1 flexible backup, easy to repair, and replacement of faulty parts. 7,8 Figure 1 shows the composition of a modular DC power supply system.…”

Section: Introductionmentioning

confidence: 99%

“…With the development of the economy, the demand for electricity in human society is increasing. In some high‐power industrial applications, such as electric vehicle charging piles and server base station power supply systems, the technology of parallel expansion of power supply has been widely used 1–6 . The power parallel system composed of N power modules has the advantages of N + 1 flexible backup, easy to repair, and replacement of faulty parts 7,8 .…”

Section: Introductionmentioning

confidence: 99%

Adaptive droop control strategy of parallel LLC converters

Tang,

Xu,

Pei

et al. 2023

Circuit Theory & Apps

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When the resonant converters are connected in parallel, the output current is unbalanced without additional current‐sharing measures due to differences in resonant component. In the input‐parallel output‐parallel resonant converter system, the output voltage accuracy of the converter under the traditional droop control is analyzed when the load changes. In this paper, an adaptive droop control is proposed, in which the droop coefficient is adaptively adjusted as the load changes. The control method proposed in this paper realizes the current sharing between the converters and solves the shortcomings of the output voltage changing under different loads in the conventional droop control. Taking two parallel LLC converters as an example, the control block diagram of the parallel control method for adaptive adjustment of the droop coefficient proposed in this paper is given, and the stability of the control loop is analyzed. Finally, two parallel prototypes of LLC converters with input 200 V/output 24 V input are built by digital control, and the experiment shows that the proposed control method improves the shortcomings of excessive output voltage droop caused by traditional droop control during dynamic load switching, which verifies the effectiveness of the method.

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A three‐level isolated dc‐dc SEPIC converter with parallel‐connected output

Cited by 2 publications

References 39 publications

Topologies and Design Characteristics of Isolated High Step-Up DC–DC Converters for Photovoltaic Systems

Topologies and Design Characteristics of Isolated High Step-Up DC–DC Converters for Photovoltaic Systems

Adaptive droop control strategy of parallel LLC converters

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