Unit Commitment with Primary Frequency Regulation Consideration in the Southern Sulawesi Power System

Unit Commitment with Primary Frequency Regulation Consideration in the Southern Sulawesi Power System

To increase the penetration level of renewable energy generation, the readiness of the existing power system needs to be considered, especially in terms of the system's ramping rate and frequency response capability. Even, a high penetration level of renewable energy can potentially reduce gene...

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Bibliographic Details
Published in:2020 12th International Conference on Information Technology and Electrical Engineering (ICITEE) pp. 210 - 215
Main Authors: Nugraha, Candra Febri, Multa Putranto, Lesnanto, Bambang Setyonegoro, Muhammad Isnaeni, Sarjiya, Isnandar, Suroso
Format: Conference Proceeding
Language:English
Published: IEEE 06-10-2020
Subjects:
free governor
Frequency control
Frequency response
Generators
Mathematical model
Power generation
primary frequency regulation
Time-frequency analysis
Unit commitment
wind farm
Wind power generation
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Summary:To increase the penetration level of renewable energy generation, the readiness of the existing power system needs to be considered, especially in terms of the system's ramping rate and frequency response capability. Even, a high penetration level of renewable energy can potentially reduce generating units generation cost, the system capability to perform the frequency response is decreased. For this reason, the quality of the frequency response needs to be considered in operation planning. In this paper, a unit commitment model was developed with considering the adequacy of primary frequency regulation (PFR). The effect of PFR constraints was analyzed by comparing the scheduling results and the frequency response with the conventional UC models. The result of this research shows that by considering the PFR constraints, the optimization results in an increasing number of committed generating units, thus resulting in more distributed reserves. The additional constraints increase the conventional unit generation costs from 48,017 to 51,636 on the simulated scenario. However, the proposed model shows its advantages in the system dynamic frequency performance, shown by an increase in frequency nadir and steady-state frequency of 490 mHz and 70 mHz respectively during low load conditions.
DOI:10.1109/ICITEE49829.2020.9271759