A step‐up/step‐down direct current to direct current converter for high‐power, high‐current applications

Feretti, Paulo Henrique; Souza, Alencar Franco de; Gomes, Adjeferson Custódio; Morais, Aniel Silva de; Tofoli, Fernando Lessa

doi:10.1002/cta.2578

Cited by 2 publications

(2 citation statements)

References 25 publications

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“…Even though an autotransformer is required by the 3SSC boost converter, it contributes to the achievement of natural current sharing since both magnetically coupled windings have the same impedance if the physical implementation of such magnetic element is carefully performed in practise. In this case, slight differences regarding the inductors, switches, and diodes will not cause significant current unbalance as demonstrated in [35]. This issue is not expected in interleaved converters, which are prone to current unbalance and additional thermal stress on a given phase [36].…”

Section: 3ssc Versus Interleaving: Analysis Of Dc–dc Boost Convertersmentioning

confidence: 99%

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Survey on topologies based on the three‐state and multi‐state switching cells

Tofoli¹,

Tavares²,

Saldanha³

2019

IET Power Electronics

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The introduction of the three-state switching cell (3SSC) and the multi-state switching cell (MSSC) has led to the proposal of several converter topologies, where prominent characteristics regarding reduced dimensions of filter elements, high efficiency, and increase of maximum power levels are achieved. Even though the active switches associated to the 3SSC and MSSC are driven by signals obtained from multiple phase-shifted carriers similarly to the interleaving technique, there are significant differences between the aforementioned approaches. Within this context, this work intends to analyse several converter topologies employing the 3SSC and MSSC that were previously reported in the literature. An overview of important concepts regarding interleaved and 3SSC-based converters is initially presented, as potential advantages and drawbacks are discussed in detail. Besides, it is also shown how the 3SSC and MSSC can be employed in the conception of power converter topologies for distinct applications, e.g. high-voltage step-up non-isolated dc-dc converters, power factor correction rectifiers, and multilevel inverters.

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Section: 3ssc Versus Interleaving: Analysis Of Dc–dc Boost Convertersmentioning

confidence: 99%

“…The very same characteristics can then be addressed to the 3SSC buck–boost converter in Fig. 4 c [35, 38] and extended to other converter topologies such as Ćuk, SEPIC, and Zeta. Unfortunately, the voltage stresses regarding the aforementioned topologies are high, i.e.…”

Section: Topologies Based On the 3sscmentioning

confidence: 99%

Survey on topologies based on the three‐state and multi‐state switching cells

Tofoli¹,

Tavares²,

Saldanha³

2019

IET Power Electronics

Self Cite

View full text Add to dashboard Cite

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Overview of Main Electrolyzer Technologies and Power Electronic Converter Topologies for Enabling Hydrogen Production Through Water Electrolysis

El Kattel,

Praça,

Mayer

et al. 2024

Circuit Theory & Apps

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This manuscript offers an in‐depth exploration of electrolysis, focusing on the various types of electrolyzers and providing a detailed analysis of their respective advantages and disadvantages. Additionally, it presents a comprehensive review of DC–DC and AC–DC converters, highlighting their essential roles in green hydrogen production and explaining their functionality and applications in detail. Furthermore, the manuscript examines the diverse power electronic systems used in green hydrogen production, underscoring the crucial importance of converters. The investigation also covers effective strategies for integrating these technologies, with the goal of optimizing the green hydrogen production process. This study aims to significantly advance knowledge in sustainable technologies, emphasizing the pivotal role of power electronics in electrolysis, fostering the generation of renewable energy, and reinforcing the commitment to a greener and more sustainable future.

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A step‐up/step‐down direct current to direct current converter for high‐power, high‐current applications

Cited by 2 publications

References 25 publications

Survey on topologies based on the three‐state and multi‐state switching cells

Survey on topologies based on the three‐state and multi‐state switching cells

Overview of Main Electrolyzer Technologies and Power Electronic Converter Topologies for Enabling Hydrogen Production Through Water Electrolysis

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