Real-time remedial action against aperiodic small signal rotor angle instability

Johannes Tilman Gabriel Weckesser; Hjörtur Jóhannsson; Jacob Østergaard

doi:10.1109/TPWRS.2015.2404872

Real-time remedial action against aperiodic small signal rotor angle instability

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Abstract

This paper presents a method that in real-time determines remedial actions, which restore stable operation with respect to aperiodic small signal rotor angle stability (ASSRAS) when insecure or unstable operation has been detected. An ASSRAS assessment method is used to monitor the stability boundary for each generator in real-time. The ASSRAS boundary represents the condition when a generator reaches the maximum steady state active power injection. The proposed control method exploits analytically derived expressions for the ASSRAS boundary and other characteristic curves in the injection impedance plane to determine an active power redispatch among selected generators to restore stable and secure operation. Since the method is purely based on analytically derived expression, the computation of the remedial actions is fast and well suited for real-time operation. The method was tested on the IEEE 14-bus and the Nordic32 test systems where results show that the method can efficiently determine the required active power redispatch to avoid an imminent instability.

Original language	English
Journal	IEEE Transactions on Power Systems
Volume	31
Issue number	1
Pages (from-to)	387-396
ISSN	0885-8950
DOIs	https://doi.org/10.1109/TPWRS.2015.2404872
Publication status	Published - 2016

Keywords

IEEE standards
load dispatching
power system security
power system stability
rotors
Components, Circuits, Devices and Systems
Power, Energy and Industry Applications
active power redispatch
aperiodic small signal rotor angle instability
Generators
IEEE 14-bus test system
Impedance
maximum steady state active power injection
Nordic32 test system
Power system control
power system generation redispatch
real-time remedial action
Real-time systems
remedial action schemes
secure operation
Security
Stability analysis
stability boundary monitoring
stable operation
Steady-state
Electric generators
Restoration
Stability
Characteristic curve
Control methods
Impedance plane
Real-time operation
Remedial actions
Rotor angle stability
Stability boundaries
Stable operation
Rotors (windings)

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title = "Real-time remedial action against aperiodic small signal rotor angle instability",

abstract = "This paper presents a method that in real-time determines remedial actions, which restore stable operation with respect to aperiodic small signal rotor angle stability (ASSRAS) when insecure or unstable operation has been detected. An ASSRAS assessment method is used to monitor the stability boundary for each generator in real-time. The ASSRAS boundary represents the condition when a generator reaches the maximum steady state active power injection. The proposed control method exploits analytically derived expressions for the ASSRAS boundary and other characteristic curves in the injection impedance plane to determine an active power redispatch among selected generators to restore stable and secure operation. Since the method is purely based on analytically derived expression, the computation of the remedial actions is fast and well suited for real-time operation. The method was tested on the IEEE 14-bus and the Nordic32 test systems where results show that the method can efficiently determine the required active power redispatch to avoid an imminent instability.",

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author = "Weckesser, \{Johannes Tilman Gabriel\} and Hj{\"o}rtur J{\'o}hannsson and Jacob {\O}stergaard",

year = "2016",

doi = "10.1109/TPWRS.2015.2404872",

language = "English",

volume = "31",

pages = "387--396",

journal = "IEEE Transactions on Power Systems",

issn = "0885-8950",

publisher = "Institute of Electrical and Electronics Engineers Inc.",

number = "1",

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T1 - Real-time remedial action against aperiodic small signal rotor angle instability

AU - Weckesser, Johannes Tilman Gabriel

AU - Jóhannsson, Hjörtur

AU - Østergaard, Jacob

PY - 2016

Y1 - 2016

N2 - This paper presents a method that in real-time determines remedial actions, which restore stable operation with respect to aperiodic small signal rotor angle stability (ASSRAS) when insecure or unstable operation has been detected. An ASSRAS assessment method is used to monitor the stability boundary for each generator in real-time. The ASSRAS boundary represents the condition when a generator reaches the maximum steady state active power injection. The proposed control method exploits analytically derived expressions for the ASSRAS boundary and other characteristic curves in the injection impedance plane to determine an active power redispatch among selected generators to restore stable and secure operation. Since the method is purely based on analytically derived expression, the computation of the remedial actions is fast and well suited for real-time operation. The method was tested on the IEEE 14-bus and the Nordic32 test systems where results show that the method can efficiently determine the required active power redispatch to avoid an imminent instability.

AB - This paper presents a method that in real-time determines remedial actions, which restore stable operation with respect to aperiodic small signal rotor angle stability (ASSRAS) when insecure or unstable operation has been detected. An ASSRAS assessment method is used to monitor the stability boundary for each generator in real-time. The ASSRAS boundary represents the condition when a generator reaches the maximum steady state active power injection. The proposed control method exploits analytically derived expressions for the ASSRAS boundary and other characteristic curves in the injection impedance plane to determine an active power redispatch among selected generators to restore stable and secure operation. Since the method is purely based on analytically derived expression, the computation of the remedial actions is fast and well suited for real-time operation. The method was tested on the IEEE 14-bus and the Nordic32 test systems where results show that the method can efficiently determine the required active power redispatch to avoid an imminent instability.

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KW - load dispatching

KW - power system security

KW - power system stability

KW - rotors

KW - Components, Circuits, Devices and Systems

KW - Power, Energy and Industry Applications

KW - active power redispatch

KW - aperiodic small signal rotor angle instability

KW - Generators

KW - IEEE 14-bus test system

KW - Impedance

KW - maximum steady state active power injection

KW - Nordic32 test system

KW - Power system control

KW - power system generation redispatch

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KW - remedial action schemes

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KW - Characteristic curve

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KW - Stability boundaries

KW - Stable operation

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DO - 10.1109/TPWRS.2015.2404872

M3 - Journal article

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SP - 387

EP - 396

JO - IEEE Transactions on Power Systems

JF - IEEE Transactions on Power Systems

IS - 1

ER -

Real-time remedial action against aperiodic small signal rotor angle instability

Abstract

Keywords

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