13.2 kV Class 3-Phase Solid State Transformer System Based on EtherCAT Communication

This paper presents a 13.2 kV class 3-phase solid-state transformer (SST) based on EtherCAT communication. In general, when the structure of the unit module is determined, the number of high-frequency isolated transformers (HFIT) is also proportional to the number of modules. The structure most cons...

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Veröffentlicht in:	Electronics (Basel) 2022-10, Vol.11 (19), p.3092
Hauptverfasser:	Jeong, Dong-Keun, Yun, Hyeok-Jin, Park, Si-Ho, Kim, Myoung-Ho, Ryu, Myung-Hyo, Baek, Ju-Won, Kim, Ho-Sung
Format:	Artikel
Sprache:	eng
Schlagworte:	AC-DC converters Algorithms Communication Communications systems Control algorithms Control theory Controllers Cost control Cost reduction Design and construction Electric converters Electric current converters Electric fields Electric transformers Microcontrollers Modules Network topologies Solid state Topology Transformers Voltage converters (DC to DC)
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container_title	Electronics (Basel)
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creator	Jeong, Dong-Keun Yun, Hyeok-Jin Park, Si-Ho Kim, Myoung-Ho Ryu, Myung-Hyo Baek, Ju-Won Kim, Ho-Sung
description	This paper presents a 13.2 kV class 3-phase solid-state transformer (SST) based on EtherCAT communication. In general, when the structure of the unit module is determined, the number of high-frequency isolated transformers (HFIT) is also proportional to the number of modules. The structure most considered in SST is a 1:1 combination of AC/DC converter and DC/DC converter. To optimally implement a 3-phase SST, a topology for reducing passive elements such as switching elements and HFIT is proposed. It also describes the design of HFIT used in DC/DC converter. EtherCAT communication with high transmission speed and expandability is applied to control the SST composed of unit modules stably, and a multi-core microcontroller unit (MCU) is applied to achieve both a high-speed communication cycle and complicated control algorithm execution. The discussions are validated using a 300 kW 13.2 kV class 3-phase SST prototype in various conditions.
doi_str_mv	10.3390/electronics11193092
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subjects	AC-DC converters Algorithms Communication Communications systems Control algorithms Control theory Controllers Cost control Cost reduction Design and construction Electric converters Electric current converters Electric fields Electric transformers Microcontrollers Modules Network topologies Solid state Topology Transformers Voltage converters (DC to DC)
title	13.2 kV Class 3-Phase Solid State Transformer System Based on EtherCAT Communication
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