Abstract
With the potential environmental impacts of conventional fossil fuels and the technology advances of grid interactive power electronics, inverter-based resources (IBRs) are playing a crucial role in modern power grids. However, due to the lack of physical inertia, IBRs are vulnerable to system disturbances. Further, conventional grid-following (GFL) inverters cannot actively establish the frequency and voltage, which could not be a appropriate solution for 100% inverter-based power grids. Grid-forming (GFM) control, as an emerging inverter control function, has drawn great attention in recent years, while it is still under development and pre-mature for large-scale field deployment. A potential solution for gradually transitioning into a 100% inverter-based power grid is to combine both IBRs and synchronous machines into a mixed generation portfolio. More importantly, synchronous machines can be operated as synchronous condensers (SCs) until they are retired. It is also worth mentioning that the stability analysis is of great importance to ensure the smooth transition from existing power grids to 100% inverter-based system, which is the main focus of this work with detailed modeling and modal analysis.
Original language | American English |
---|---|
Number of pages | 8 |
State | Published - 2021 |
Event | ISGT2022 - Washington D.C. Duration: 21 Feb 2022 → 24 Feb 2022 |
Conference
Conference | ISGT2022 |
---|---|
City | Washington D.C. |
Period | 21/02/22 → 24/02/22 |
NREL Publication Number
- NREL/CP-5C00-80613
Keywords
- 100% renewable
- grid-following
- grid-forming
- modal analysis
- small-signal stability
- synchronous condenser