Robust $N-k$ Security-constrained Optimal Power Flow Incorporating Preventive and Corrective Generation Dispatch to Improve Power System Reliability

Robust $N-k$ Security-constrained Optimal Power Flow Incorporating Preventive and Corrective Generation Dispatch to Improve Power System Reliability

$N-k$ security criterion

bender decomposition

Benders cut

Generators

line outage distribution factor

Load flow

optimal power flow

Optimization

power system reliability

Power system reliability

Power transmission lines

Reliability

resilience

robust optimization

Security

As extreme weather events have become more frequent in recent years, improving the resilience and reliability of power systems has become an important area of concern. In this paper, a robust preventive-corrective security-constrained optimal power flow (RO-PCSCOPF) model is proposed to improve power system reliability under $N-k$ outages. Both the short-term emergency limit (STL) and the long-term operating limit (LTL) of the post-contingency power flow on the branch are considered. Compared with the existing robust corrective SCOPF model that only considers STL or LTL, the proposed RO-PCSCOPF model can achieve a more reliable generation dispatch solution. In addition, this paper also summarizes and compares the solution methods for solving the $N-k$ SCOPF problem. The computational efficiency of the classical Benders decomposition (BD) method, robust optimization (RO) method, and line outage distribution factor (LODF) method are investigated on the IEEE 24-bus Reliability Test System and 118-bus system. Simulation results show that the BD method has the worst computation performance. The RO method and the LODF method have comparable performance. However, the LODF method can only be used for the preventive SCOPF and not for the corrective SCOPF. The RO method can be used for both.

351-364

L. Huang

C. S. Lai

Z. Zhao

G. Yang

B. Zhong

L. L. Lai

CSEE Journal of Power and Energy Systems

2023

journalArticle

2096-0042