A new‐high efficiency non‐isolated DC‐DC converter with combination of step‐up techniques

Summary In this paper, a new high‐step‐up DC‐DC converter without any coupled inductors or transformers is introduced. The structure of the introduced converter consists of two boost techniques, namely, switched inductor and switched capacitor, used simultaneously. The drawbacks of each technique ar...

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Published in:International journal of circuit theory and applications 2024-12, Vol.52 (12), p.6275-6301
Main Authors: Mizani, Amirreza, Gao, Hang, Amraei, Amin, Khaburi, Davood Arab
Format: Article
Language:English
Subjects:
Component reliability
Control methods
DC‐DC converter
Efficiency
Electric potential
Energy conversion efficiency
Fuel cells
high‐step‐up DC‐DC converter
Inductors
interleaved technique
non‐isolated converter
Photovoltaic cells
Semiconductor devices
switched capacitor technique
switched inductor technique
Topology
Voltage
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container_title International journal of circuit theory and applications
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Gao, Hang
Amraei, Amin
Khaburi, Davood Arab
description Summary In this paper, a new high‐step‐up DC‐DC converter without any coupled inductors or transformers is introduced. The structure of the introduced converter consists of two boost techniques, namely, switched inductor and switched capacitor, used simultaneously. The drawbacks of each technique are mitigated according to the proposed structure and the introduced control method. Therefore, the main contribution of the introduced converter is its ability to use boost techniques while avoiding high input current ripples and inrush currents in the path of semiconductor devices. Thus, there is no need for an auxiliary inductor. Additionally, the number of required components is low, and it benefits from a common ground, which are advantages of this converter in terms of economy and reliability. Another advantage is the high efficiency of the proposed converter in comparison with recent topologies, making it suitable for renewable energy applications such as photovoltaic (PV) systems and fuel cell applications. The proposed converter has been implemented in a laboratory to verify its performance. It operates at 94.51% efficiency with a 200 W output power, a 40 kHz switching frequency, a 40 V input voltage, and a 240 V output voltage. This paper introduces a novel high step‐up DC‐DC converter that utilizes switched inductor and switched capacitor techniques without the need for coupled inductors or transformers. The converter's design minimizes input current ripples and inrush currents, eliminating the need for auxiliary inductors and reducing component count, which enhances both economic and reliability aspects. The converter, tested in a laboratory setting, achieves a 94.51% efficiency, making it highly suitable for renewable energy applications such as photovoltaic systems and fuel cells.
doi_str_mv 10.1002/cta.4074
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The structure of the introduced converter consists of two boost techniques, namely, switched inductor and switched capacitor, used simultaneously. The drawbacks of each technique are mitigated according to the proposed structure and the introduced control method. Therefore, the main contribution of the introduced converter is its ability to use boost techniques while avoiding high input current ripples and inrush currents in the path of semiconductor devices. Thus, there is no need for an auxiliary inductor. Additionally, the number of required components is low, and it benefits from a common ground, which are advantages of this converter in terms of economy and reliability. Another advantage is the high efficiency of the proposed converter in comparison with recent topologies, making it suitable for renewable energy applications such as photovoltaic (PV) systems and fuel cell applications. The proposed converter has been implemented in a laboratory to verify its performance. 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source Wiley-Blackwell Read & Publish Collection
subjects Component reliability
Control methods
DC‐DC converter
Efficiency
Electric potential
Energy conversion efficiency
Fuel cells
high‐step‐up DC‐DC converter
Inductors
interleaved technique
non‐isolated converter
Photovoltaic cells
Semiconductor devices
switched capacitor technique
switched inductor technique
Topology
Voltage
title A new‐high efficiency non‐isolated DC‐DC converter with combination of step‐up techniques
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