Abstract
Power system inertia is the inherent capability of a power system to resist changes in its frequency during disturbances. Real-time inertia estimation technology has become more important due to the low-inertia issues caused by the increasing integration levels of inverter-based resources (IBRs) from renewable energy; however, existing inertia estimation methods hardly consider multiple frequency response controls that act within the same time frame as conventional inertial response, thus making measured inertia values vary under different testing conditions. To resolve this issue, this paper proposes a novel real-time estimation method to simultaneously estimate a power system's inertia constant and frequency response droop constant using a well-designed probing signal. First, we formulate the inertia and frequency response model of a power system with IBRs. Second, through the integration and manipulation of the developed model, we propose a multivariate linear regression- based estimation method that is resilient to measurement noise. Third, we design a probing signal that can be injected by IBRs to incite the required transients for estimation. Finally, we validate the proposed estimation method through comprehensive power- hardware-in-the-loop experiments using inverter hardware and a realistic island power system model. The results demonstrate that the proposed method can accurately estimate the inertia and droop value of the power system with grid-following IBRs and grid-forming IBRs with virtual synchronous machine control.
Original language | American English |
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Number of pages | 8 |
State | Published - 2024 |
Event | IEEE PES General Meeting - Seattle, Washington Duration: 21 Jul 2024 → 25 Jul 2024 |
Conference
Conference | IEEE PES General Meeting |
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City | Seattle, Washington |
Period | 21/07/24 → 25/07/24 |
NREL Publication Number
- NREL/CP-5D00-87925
Keywords
- frequency response
- inertia
- inverter-based resources
- power-hardware-in-the-loop