A New Multiport DC-DC Converter for DC Microgrid Applications

In this paper, a new multiport DC-DC converter is proposed for DC Microgrid applications. Besides, the proposed configuration has several benefits for the design and operation of DC microgrids such as reducing multiple power conversions, reducing number of elements and voltage boosting capability. T...

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Veröffentlicht in:	IEEE transactions on industry applications 2023-01, Vol.59 (1), p.601-611
Hauptverfasser:	Saafan, Ahmed Amr, Khadkikar, Vinod, Moursi, Mohamed Shawky El, Zeineldin, Hatem H.
Format:	Artikel
Sprache:	eng
Schlagworte:	Availability Batteries Battery Configurations Control systems design DC microgrid DC-DC power converters Distributed generation Electric potential Frequency response fuel cell Inductors Maximum power point trackers Microgrids multiport converter photovoltaic Power control Topology Voltage Voltage control Voltage converters (DC to DC)
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creator	Saafan, Ahmed Amr Khadkikar, Vinod Moursi, Mohamed Shawky El Zeineldin, Hatem H.
description	In this paper, a new multiport DC-DC converter is proposed for DC Microgrid applications. Besides, the proposed configuration has several benefits for the design and operation of DC microgrids such as reducing multiple power conversions, reducing number of elements and voltage boosting capability. The bidirectional buck-boost structure of the proposed topology allows for enhanced flexibility to connect sources and loads with different voltage and power levels. The control strategy is developed to achieve power control for renewable sources such as MPPT for PV, in addition to a certain degree of resilience for DC sources availability while maintaining boosted DC link voltage. The key feature of the proposed configuration is that it offers full control over DC link voltage regardless of resource availability (PV). A detailed steady-state analysis is conducted to derive the voltage relations between all ports. Additionally, the state-space averaging followed by small-signal modeling and frequency response-based controller design for the proposed topology is discussed. A MATLAB/Simulink-based simulation study is conducted to demonstrate the performance of the proposed multiport converter topology under different operating conditions. Finally, the performance of the proposed multiport converter is validated through an experimental study.
doi_str_mv	10.1109/TIA.2022.3213235
format	Article
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Besides, the proposed configuration has several benefits for the design and operation of DC microgrids such as reducing multiple power conversions, reducing number of elements and voltage boosting capability. The bidirectional buck-boost structure of the proposed topology allows for enhanced flexibility to connect sources and loads with different voltage and power levels. The control strategy is developed to achieve power control for renewable sources such as MPPT for PV, in addition to a certain degree of resilience for DC sources availability while maintaining boosted DC link voltage. The key feature of the proposed configuration is that it offers full control over DC link voltage regardless of resource availability (PV). A detailed steady-state analysis is conducted to derive the voltage relations between all ports. Additionally, the state-space averaging followed by small-signal modeling and frequency response-based controller design for the proposed topology is discussed. A MATLAB/Simulink-based simulation study is conducted to demonstrate the performance of the proposed multiport converter topology under different operating conditions. 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subjects	Availability Batteries Battery Configurations Control systems design DC microgrid DC-DC power converters Distributed generation Electric potential Frequency response fuel cell Inductors Maximum power point trackers Microgrids multiport converter photovoltaic Power control Topology Voltage Voltage control Voltage converters (DC to DC)
title	A New Multiport DC-DC Converter for DC Microgrid Applications
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