Triple Active Bridge Based Multiport Energy Router for Subsea – Renewable Interconnection

Abstract

In order to supply reliable power to the subsea loads at high system efficiency and low emissions, there is a growing interest in employing offshore renewable resources close to the point of use. However, such system has predominantly stayed in the conceptual stage so far. Hence, there is a need to develop methodologies for interconnecting multiple renewable sources with offshore loads. This paper proposes a Multiport Energy Router (MER) based on a Medium Frequency (MF) Solid-State Transformer (SST) that integrates renewable energy sources (RES) and Energy Storage Systems (ESS) to supply clean energy for subsea loads. The MER forms a three-port network, where HVDC Wind Turbine Generator (WTG) power system and MVDC ESS are interfaced with subsea loads. The MER is realized by series-parallel combination of Triple Active Bridge (TAB) converters. The TAB modules are critical to enhance the power density, fault-tolerance, and efficiency of the proposed system. In this paper, a novel simple algorithm for extending soft-switching region of TAB by selecting optimal control variables is proposed. Moreover, this paper presents a control strategy for the MER, which addresses the DC-link voltage imbalance issue for each of the cascaded TAB converters. The simulation and the Hardware-in-the-Loop (HIL) results based on Typhoon-HIL system are presented to verify the proposed converter operation and the control strategy.