Toward Simulation-Free Estimation of Critical Clearing Time

Author(s)

Vu, Thanh Long; Al Araifi, Surour M.; El Moursi, Mohamed S.; Turitsyn, Konstantin

Abstract

Contingency screening for transient stability of large-scale, strongly nonlinear, interconnected power systems is one of the most computationally challenging parts of Dynamic Security Assessment and requires huge resources to perform time-domain simulations-based assessment. To reduce computational cost of time-domain simulations, direct energy methods have been extensively developed. However, these methods, as well as other existing methods, still rely on time-consuming numerical integration of the fault-on dynamics. This task is computationally hard, since possibly thousands of contingencies need to be scanned and thousands of accompanied fault-on dynamics simulations need to be performed and stored on a regular basis. In this paper, we introduce a novel framework to eliminate the need for fault-on dynamics simulations in contingency screening. This simulation-free framework is based on bounding the fault-on dynamics and extending the recently introduced Lyapunov Function Family approach for transient stability analysis of structure-preserving model. In turn, a lower bound of the critical clearing time is obtained by solving convex optimization problems without relying on any time-domain simulations. A comprehensive analysis is carried out to validate this novel technique on a number of IEEE test cases.

Date issued

2016-11

URI

https://hdl.handle.net/1721.1/155144

Department

Massachusetts Institute of Technology. Department of Mechanical Engineering

Journal

IEEE Transactions on Power Systems

Publisher

Institute of Electrical and Electronics Engineers

Citation

T. L. Vu, S. M. Al Araifi, M. S. El Moursi and K. Turitsyn, "Toward Simulation-Free Estimation of Critical Clearing Time," in IEEE Transactions on Power Systems, vol. 31, no. 6, pp. 4722-4731, Nov. 2016.

Version: Author's final manuscript

ISSN

0885-8950

1558-0679