Transient Stability Assessment of Cascade Tripping of Renewable Sources Using SOS
For power system planners, this provides a conservative stability region estimation to mitigate cascade tripping risks in renewable-rich grids.
The paper proposes a Lyapunov-based method using sum-of-squares programming to estimate the stability region for cascade tripping of renewable sources, and demonstrates it on a 3-machine system to identify trip sequences that should be blocked to improve stability.
There has been significant increase in penetration of renewable generation (RG) sources all over the world. Localized concentration of many such generators could initiate a cascade tripping sequence that might threaten the stability of the entire system. Understanding the impact of cascade tripping process would help the system planner identify trip sequences that must be blocked in order to increase stability. In this work, we attempt to understand the consequences of cascade tripping mechanism through a Lyapunov approach. A conservative definition for the stability region (SR) along with its estimation for a given cascading sequence using sum of squares (SOS) programming is proposed. Finally, a simple probabilistic definition of the SR is used to visualize the risk of instability and understand the impact of blocking trip sequences. A 3-machine system with significant RG penetration is used to demonstrate the idea.