Adaptive Droop for Control of Multiterminal DC Bus Integrating Energy Storage

Multiterminal dc (MTDC) systems are drawing a lot of interest lately in applications related to distributed generation, especially in those that integrate wind or photovoltaic (PV) generation with energy storage (ES). Several approaches for controlling the operation of such systems have been proposed in the literature; however, the existing structures are mainly application specific and, thus, can be still improved in order to provide a more generic approach. This paper proposes an improved primary control layer for an MTDC system. The concept is based on the combination of a droop control method and dc bus signaling in order to provide a more generic and flexible solution. In this paper, different droop characteristics are proposed for the various elements connected to the dc bus. All of them are specifically tailored around five operation bands, which depend on the dc bus voltage level. Special attention is paid to the integration of ES: the state of charge (SoC) is considered at the primary control level, yielding a surface characteristic that depends on the SoC and the dc bus voltage. The scaling of the system has been analyzed together with the proposed control strategy and the overall operation has been validated through simulations by considering a 100 kW PV system with energy storage. Experimental results were obtained on a scaled laboratory prototype rated at 10 kW.

[1]  Kjetil Uhlen,et al.  Primary frequency control of remote grids connected by multi-terminal HVDC , 2010, IEEE PES General Meeting.

[2]  Xiao-Ping Zhang,et al.  Multiterminal voltage-sourced converter-based HVDC models for power flow analysis , 2004 .

[3]  Tomonobu Senjyu,et al.  Control strategy for a distributed DC power system with renewable energy , 2011 .

[4]  Randy Wachal,et al.  Traveling-wave-based line fault location in star-connected multiterminal HVDC systems , 2012, 2013 IEEE Power & Energy Society General Meeting.

[5]  Kala Meah,et al.  A new simplified adaptive control scheme for multi-terminal HVDC transmission systems , 2010 .

[6]  Paolo Mattavelli,et al.  Digital Control in Power Electronics , 2006, Digital Control in Power Electronics.

[7]  O. Anaya-Lara,et al.  Small-Signal Stability Analysis of Multi-Terminal VSC-Based DC Transmission Systems , 2012, IEEE Transactions on Power Systems.

[8]  R. Wachal,et al.  Traveling-Wave-Based Line Fault Location in Star-Connected Multiterminal HVDC Systems , 2013, IEEE Transactions on Power Delivery.

[9]  Juan C. Vasquez,et al.  Hierarchical Control of Droop-Controlled AC and DC Microgrids—A General Approach Toward Standardization , 2009, IEEE Transactions on Industrial Electronics.

[10]  Richard Duke,et al.  DC-Bus Signaling: A Distributed Control Strategy for a Hybrid Renewable Nanogrid , 2006, IEEE Transactions on Industrial Electronics.

[11]  Boon-Teck Ooi,et al.  Locating and Isolating DC Faults in Multi-Terminal DC Systems , 2007, IEEE Transactions on Power Delivery.

[12]  Liangzhong Yao,et al.  DC voltage control and power dispatch of a multi-terminal HVDC system for integrating large offshore wind farms , 2011 .

[13]  D.D.-C. Lu,et al.  Photovoltaic-Battery-Powered DC Bus System for Common Portable Electronic Devices , 2008, IEEE Transactions on Power Electronics.

[14]  Jin Yang,et al.  Short-Circuit and Ground Fault Analyses and Location in VSC-Based DC Network Cables , 2012, IEEE Transactions on Industrial Electronics.

[15]  J. A. Pecas Lopes,et al.  Provision of Inertial and Primary Frequency Control Services Using Offshore Multiterminal HVDC Networks , 2012, IEEE Transactions on Sustainable Energy.

[16]  Damien Ernst,et al.  Coordinated primary frequency control among non-synchronous systems connected by a multi-terminal high-voltage direct current grid , 2012 .

[17]  Jin Yang,et al.  Multiterminal DC Wind Farm Collection Grid Internal Fault Analysis and Protection Design , 2010, IEEE Transactions on Power Delivery.

[18]  Ronnie Belmans,et al.  Generalized Dynamic VSC MTDC Model for Power System Stability Studies , 2010, IEEE Transactions on Power Systems.

[19]  M.E. Baran,et al.  Overcurrent Protection on Voltage-Source-Converter-Based Multiterminal DC Distribution Systems , 2007, IEEE Transactions on Power Delivery.

[20]  Tomonobu Senjyu,et al.  A hybrid smart AC/DC power system , 2010, ICIEA 2010.

[21]  Jun Liang,et al.  Topologies of multiterminal HVDC-VSC transmission for large offshore wind farms , 2011 .

[22]  Tore Undeland,et al.  Power Electronics: Converters, Applications and Design , 1989 .

[23]  Kjetil Uhlen,et al.  Frequency sensitivity analysis of AC grids connected to MTDC grid , 2010 .

[24]  R. Duke,et al.  Decentralized generator scheduling in a nanogrid using DC bus signaling , 2004, IEEE Power Engineering Society General Meeting, 2004..

[25]  Remus Teodorescu,et al.  Multilink DC transmission system for supergrid future concepts and wind power integration , 2011 .

[26]  F. Liu,et al.  DC Bus Voltage Control for a Distributed Power System , 2003 .

[27]  T. M. Haileselassie,et al.  Precise control of power flow in multiterminal VSC-HVDCs using DC voltage droop control , 2012, 2012 IEEE Power and Energy Society General Meeting.

[28]  Ronnie Belmans,et al.  A Distributed DC Voltage Control Method for VSC MTDC Systems , 2012 .

[29]  B. Chaudhuri,et al.  Adaptive Droop Control for Effective Power Sharing in Multi-Terminal DC (MTDC) Grids , 2013, IEEE Transactions on Power Systems.

[30]  Liangzhong Yao,et al.  Multi-terminal DC transmission systems for connecting large offshore wind farms , 2008, 2008 IEEE Power and Energy Society General Meeting - Conversion and Delivery of Electrical Energy in the 21st Century.

[31]  Sun A Distributed Control Strategy based on DC Bus Signaling for Modular Photovoltaic Generation Systems with Battery Energy Storage , 2011 .

[32]  Jiuping Pan,et al.  Stability Analysis of VSC MTDC Grids Connected to Multimachine AC Systems , 2011, IEEE Transactions on Power Delivery.