JST-NSF-DFG-RCN Workshop on Distributed Energy Management Systems Arlington, Virginia, April 20-22, 2015 Virtual Synchronous Machines for Supporting Flexible Operation of Distribution Systems Jon Are Suul pos.doc. researcher Department of Electric Power Engineering Norwegian University of Science and Technology Research Scientist SINTEF Energy Research
Traditional grids vs. "SmartGrids" Traditional Utility grid "SmartGrid" Scenario 2 F. Rahimi, A. Ipakchi, Demand Response as a Market Resource Under the Smart Grid Paradigm, in IEEE Transactions on Smart Grid, Vol. 1, No. 1, June 2010, pp. 82 88
Virtual Power Plant (VPP) Aggregating energy resources for dispatchable operation Commercial VPP For operation in the market Technical VPP For power system operation and control Demand-Response VPP (load) Supply-Side VPP (generation) Mixed-Asset VPP (generation load and storage) Requires extensive ability for: Data acquisition and communication Remote and local control 3 D. Pudjianto, C. Ramsay, G. Strbac, Virtual power plant and systems integration of distributed energy resources, in IET Renewable Power Generation, Vol. 1, No. 1, 2007, pp. 10 16 Karlsruhe Institute of Technology, http://www.commputation.kit.edu/73.php http://envirosynthesis.blogspot.com/2010/05/ventyx virtual power plants.html
Virtual Synchronous Machine (VSM) 4 Power Electronic converter controlled to emulate the behavioral characteristics of synchronous machines Concept first introduced about one decade ago Several possible implementations Parameters are not limited by physical design constraints Emulated characteristics: Inertia and damping Corresponding powerbalance-based grid synchronization mechanism Active and reactive power control mechanisms S. D'Arco, J. A. Suul, "Virtual Synchronous Machines Classification of Implementations and Analysis of Equivalence to Droop Controllers for Microgrids," in Proceedings of IEEE PES PowerTech 2013, Grenoble, France, 16-20 June 2013, 7 pp.
VSMs in distribution systems VSMs can provide ancillary services in local grids: Power-frequency control Reactive power control Inertia emulation MicroGrid operation with temporary islanding Most residential sources and loads in distribution systems have single-phase grid interfaces EV chargers Load with storage Possibility for temporary islanding Domestic PV systems Down-regulation capability Typical configuration: Grid equivalent V R g g L g R l Local Bus B g I o B l R 2 L 2 Filter Vo R1 C f L 1 Ic Vc Battery/DC voltage source V DC C DC 5 Local Load
Single-phase VSM for EV charger Assuming bi-directional EV charger for V2G/V2H operation Single-phase VSMs require particular attention to implementation of virtual inertia L 2 Measurement i o v o Processing L 1 C 1 q o p o q o vˆo p o Reactive Power Control Virtual Inertia and Power Control ˆr v o VSM VSM A r v o ' qi o i o Virtual Impedance v o v o Resonant Voltage Controller i c v o i c Resonant Current Controller m PWM g PWM i c C dc v dc J. A. Suul, S. D'Arco, G, Guidi, "Virtual Synchronous Machine-based Control of a Single-phase Bi-directional Battery Charger for Providing Vehicle-to-Grid Services," in Proceedings of the 9 th International Conference on Power Electronics, ICPE ECCE Asia, Seoul, Korea, 1-5 June 2015, 8 pp. 6
VSM Power Control Mechanism Based on synchronous machine swing equation Reduced order approximation of the inertia and damping of a traditional synchronous machine Provides a frequency and phase angle reference that can be used to control the converter Reactive power controller can provide voltage amplitude reference p Frequency Droop Virtual Synchronous Machine Swing Equation VSM k r p 1 T a VSM 1 s VSM b s VSM VSM VSM p p d k d VSM, f g 1 1 Tf, s 7
Active and reactive power feedback Single-phase power circuit implies double frequency oscillations in active and reactive power A virtual two-phase system is established to calculate active and reactive power feedback Avoids influence of double frequency power oscillations on virtual inertia ' v o i o Voltage processing SOGI-QSG ' e v ' v qv' SOGI-QSG ' e i ' i qi ' Current processing ' vo, ' vo, ' io, ' io, Voltage amplitude estimation 2 x 2 x '2 vˆo Power calculation x ' vˆo p o q o 8
Examples of results dynamic response Single-phase EV-charger 3.3 kva, 230 V RMS Response to power step Well damped emulation of inertial behavior Reactive power droop control on voltage amplitude ensures reactive power compensation when voltage drops due to increased load Grid equivalent V R g g L g R l B g B l Local Bus I o R 2 L 2 Filter Vo R1 C f Speed [pu] Power [pu] 0-0.2-0.4 p VSM p VSM -0.6 0 1 2 3 4 5 Time [s] 1 0.998 VSM VSM 0.996 0 1 2 3 4 5 Time [s] Reactive power [pu] Voltage amplitude [pu] 0.4 0.2 0 1 q VSM q VSM 0 1 2 3 4 5 Time [s] v VSM 0.95 v o v r 0.9 0 1 2 3 4 5 Time [s] L 1 Ic Vc Battery/DC voltage source V DC C DC Local Load 9
Examples of results - islanding Response to sudden islanding Power of local load is immediately supplied from the EV battery No severe transients Local frequency slowly settles to new value according to droop settings 0.6 0.4 0.2 0 1 0.995 0.99 VSM VSM Power [pu] -0.2-0.4 Speed [pu] 0.985-0.6 0.98-0.8 p VSM 0.975 p VSM -1 p o -0.02 0 0.02 0.04 0.06 0.08 0.1 0.12 0.14 0.16 Time [s] 0.97 0 2 4 6 8 10 12 14 Time [s] 10
Summary Virtual Synchronous Machines can provide ancillary services and support flexible operation of distribution systems Inertia emulation, active and reactive power control based on local measurements References and operational settings provided from higher level system controllers Can operate as part of Virtual Power Plants or any other system-level control Can ensure control of local MicroGrids in grid-connected and islanded modes Load and generation at distribution system level are often based on single-phase grid interfaces Three-phase VSM implementations cannot be directly applied for single-phase systems Active and reactive power oscillations of single-phase systems can be avoided in the VSM-based control by utilizing a virtual two-phase system for calculating local feedback signals With both three-phase and single-phase implementations VSMs provide a suitable general framework for local control that can support flexible operation of distribution systems 11
References J. A. Suul, S. D'Arco, G, Guidi, "Virtual Synchronous Machine-based Control of a Single-phase Bi-directional Battery Charger for Providing Vehicle-to-Grid Services," in Proceedings of the 9 th International Conference on Power Electronics, ICPE ECCE Asia, Seoul, Korea, 1-5 June 2015, 8 pp. J. A. Suul, S. D'Arco, G. Guidi, "A Single-Phase Virtual Synchronous Machine for Providing Vehicle-to-Grid Serviced from Electric Vehicle Battery Chargers," in Proceedings of the International Electric Vehicle Technology Conference & Automotive Power Electronics, EVTeC & APE Japan, Yokohama, Japan, 22-24 May 2014, 7 pp. S. D'Arco, J. A. Suul, O. B. Fosso, "Small-signal modelling and parametric sensitivity of a Virtual Synchronous Machine in islanded operation," accepted for publication in International Journal of Electric Power and Energy Systems, 2015 S. D'Arco, J. A. Suul, O. B. Fosso, "A Virtual Synchronous Machine Implementation for Distributed Control of Power Converters in SmartGrids," in Electric Power System Research, Vol. 122, May 2015, pp. 180-197 S. D'Arco, J. A. Suul, O. B. Fosso, "Small-Signal Modeling and Parametric Sensitivity of a Virtual Synchronous Machine," in Proceedings of the 18 th Power Systems Computation Conference, PSCC 2014, Wrocław, Poland, 18-22 August 2014, 9 pp. S. D'Arco, J. A. Suul, "Equivalence of Virtual Synchronous Machines and Frequency-Droops for Converter-Based MicroGrids," in IEEE Transactions on Smart Grid, Vol. 5, No. 1, January 2014, pp. 394-395 S. D'Arco; J. A. Suul; O. B. Fosso, "Control System Tuning and Stability Analysis of Virtual Synchronous Machines," in Proceedings of the 2013 IEEE Energy Conversion Congress and Exposition, ECCE 2013, Denver, Colorado, USA, 15-19 September 2013, pp. 2664-2671 S. D'Arco, J. A. Suul, "Virtual Synchronous Machines Classification of Implementations and Analysis of Equivalence to Droop Controllers for Microgrids," in Proceedings of IEEE PES PowerTech 2013, Grenoble, France, 16-20 June 2013, 7 pp. 12