An improved Z-source-derived converter for efficient PV integration

This paper proposes a high-voltage (HV) gain non-inverting an improved Z-source (ZS)-derived non-isolated boost converter topology. The achievement of HV gain is facilitated through the astute's integration of a ZS, a switched capacitor (SC), and a boost cell that operates with a reduced duty c...

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Bibliographic Details
Published in:International journal of electronics 2024-12, Vol.111 (12), p.2041-2059
Main Authors: Kishor, Yugal, Patel, Ramnarayan, Sahu, Lalit Kumar
Format: Article
Language:English
Subjects:
high-voltage gain
Passive components
Photovoltaic cells
reduced device
Semiconductors
solar PV
switched capacitor
Topology
z-source network
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Summary:This paper proposes a high-voltage (HV) gain non-inverting an improved Z-source (ZS)-derived non-isolated boost converter topology. The achievement of HV gain is facilitated through the astute's integration of a ZS, a switched capacitor (SC), and a boost cell that operates with a reduced duty cycle. In comparison with earlier developed topologies, the proposed topology uses fewer components and provides HV gain. In addition to this, the converter reduces voltage stress on semiconductors and passive components. As a result, low-voltage rating (small R ds(on) ) switches and diodes can be used to reduce conduction and reverse recovery losses, respectively. The converter emphasises on reducing device count while increasing device utilisation factor and accommodating a broad range of input variations; thus, it has potential application in HV low-power distributed photovoltaic (PV) systems. Additionally, the converter draws continuous input current from the low-voltage PV terminal. The proposed converter's operating principle is thoroughly examined in stead state. A 400 W prototype has been developed to verify the operational efficiency and theoretical assertions of the converter, with a switching frequency of 100 kHz. The converter obtained a peak efficiency of 93.25%.
ISSN:0020-7217
1362-3060
DOI:10.1080/00207217.2023.2248659