Coordinated Control of Multiterminal DC Grid Power Injections for Improved Rotor-Angle Stability Based on Lyapunov Theory

Coordinated Control of Multiterminal DC Grid Power Injections for Improved Rotor-Angle Stability Based on Lyapunov Theory

The stability of an interconnected ac/dc system is affected by disturbances occurring in the system. Disturbances, such as three-phase faults, may jeopardize the rotor-angle stability and, thus, the generators fall out of synchronism. The possibility of fast change of the injected powers by the mult...

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Veröffentlicht in:IEEE transactions on power delivery 2014-08, Vol.29 (4), p.1789-1797
1. Verfasser: Eriksson, Robert
Format: Artikel
Sprache:eng
Schlagworte:
Applied sciences
Control Lyapunov function
Control systems
coordinated control
Direct current
Direct current networks
Disturbances
Electrical engineering. Electrical power engineering
Electrical machines
Electrical power engineering
energy function
Exact sciences and technology
high-voltage direct current (HVDC)
HVDC transmission
Lyapunov methods
Matlab
multiterminal dc (MTDC)
Nonlinearity
Power networks and lines
Power system stability
Regulation and control
small-signal stability
Stability
Stability criteria
Strategy
Time optimal
Trajectory
Transient analysis
transient stability
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Zusammenfassung:The stability of an interconnected ac/dc system is affected by disturbances occurring in the system. Disturbances, such as three-phase faults, may jeopardize the rotor-angle stability and, thus, the generators fall out of synchronism. The possibility of fast change of the injected powers by the multiterminal dc grid can, by proper control action, enhance this stability. This paper proposes a new time optimal control strategy for the injected power of multiterminal dc grids to enhance the rotor-angle stability. The controller is time optimal, since it reduces the impact of a disturbance as fast as possible, and is based on Lyapunov theory considering the nonlinear behavior. The time optimal controller is of a bang-bang type and uses wide-area measurements as feedback signals. Nonlinear simulations are run in the Nordic32 test system implemented in PowerFactory/DIgSILENT with an interface to Matlab where the controller is implemented.
ISSN:0885-8977
1937-4208
1937-4208
DOI:10.1109/TPWRD.2013.2293198