Abstract

Maintaining the stability of a conventional power system during under frequency events is partially dominated by a natural behavior called inertial response. Although a variable speed wind turbine (VSWT) is fundamentally deprived from such behavior, it was shown recently that it can virtually emulate this response, hence increasing its output power given to the grid to sustain the power balance. This paper reviews and analyzes the performance of four primary frequency control structures, and provides comparison between these controllers in terms of security indices. The results reflect the superiority of the inertia emulation controller and the droop control type in low and high wind speed respectively. To enhance the system frequency control response and take any inherent advantage of each controller, this paper proposes two novel controllers based on combination (hybridization) strategy between the four controllers. The results show that the combination between the inertia emulation controller and the de-loading controller will lead to reducing the rate of change of frequency (ROCOF) and raising the frequency nadir (FN) values. Finally, the role of each discussed controller in determining the correlations among ROCOF, FN and wind power penetration level are explored.

Highlights

  • The worldwide power system is shifting towards integrating more renewable energy generation technologies

  • The proposed controller extends the results found in the literature by arresting the frequency excursion, maintaining the system stability, and enhancing the system security indices, namely rate of change of frequency (ROCOF) and frequency nadir (FN)

  • The de‐loading controller concept isvia achieved of using control scheme for the frequency control problem under the proposed system configuration

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Summary

Introduction

The worldwide power system is shifting towards integrating more renewable energy generation technologies. The increased utilization of switched mode high power converters to facilitate integrating wind turbines into the electric grid modifies the total system inertia and impacts the system’s ability to overcome frequency excursion due to inevitable production consumption imbalance or frequency disturbance events due to fault conditions. This problem is of interest for isolated and weak electric networks [3], it may adversely affect large interconnected power systems with high wind power penetration and more halted

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