Power-Imbalance Allocation Control of Power Systems-Secondary Frequency Control

The traditional secondary frequency control of power systems restores nominal frequency by steering Area Control Errors (ACEs) to zero. Existing methods are a form of integral control with the characteristic that large control gain coefficients introduce an overshoot and small ones result in a slow...

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Veröffentlicht in:	arXiv.org 2018-07
Hauptverfasser:	Xi, Kaihua, Dubbeldam, Johan L A, Hai Xiang Lin, van Schuppen, Jan H
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Sprache:	eng
Schlagworte:	Control methods Control stability Control systems Controllers Convergence Frequency control Frequency deviation Integrals Mathematics - Optimization and Control Power dispatch Stability analysis Steering
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description	The traditional secondary frequency control of power systems restores nominal frequency by steering Area Control Errors (ACEs) to zero. Existing methods are a form of integral control with the characteristic that large control gain coefficients introduce an overshoot and small ones result in a slow convergence to a steady state. In order to deal with the large frequency deviation problem, which is the main concern of the power system integrated with a large number of renewable energy, a faster convergence is critical. In this paper, we propose a secondary frequency control method named Power-Imbalance Allocation Control (PIAC) to restore the nominal frequency with a minimized control cost,in which a coordinator estimates the power imbalance and dispatches the control inputs to the controllers after solving an economic power dispatch problem. The power imbalance estimation converges exponentially in PIAC, both overshoots and large frequency deviations are avoided. In addition, when PIAC is implemented in a multi-area controlled network, the controllers of an area are independent of the disturbance of the neighbor areas, which allows an asynchronous control in the multi-area network. A Lyapunov stability analysis shows that PIAC is locally asymptotically stable and simulation results illustrates that it effectively eliminates the drawback of the traditional integral control based methods.
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subjects	Control methods Control stability Control systems Controllers Convergence Frequency control Frequency deviation Integrals Mathematics - Optimization and Control Power dispatch Stability analysis Steering
title	Power-Imbalance Allocation Control of Power Systems-Secondary Frequency Control
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