Modeling the Dynamics of Cascading Failures in Power Systems

In this paper, we use a circuit-based power flow model to study the cascading failure propagation process, and combine it with a stochastic model to describe the uncertain failure time instants, producing a model that gives a complete dynamic profile of the cascading failure propagation beginning from a dysfunctioned component and developing eventually to a large-scale blackout. The sequence of failures is determined by voltage and current stresses of individual elements, which are governed by deterministic circuit equations, while the time durations between failures are described by stochastic processes. The use of stochastic processes here addresses the uncertainties in individual components’ physical failure mechanisms, which may depend on manufacturing quality and environmental factors. The element failure rate is related to the extent of overloading. A network-based stochastic model is developed to study the failure propagation dynamics of the entire power network. Simulation results show that our model generates dynamic profiles of cascading failures that contain all salient features displayed in historical blackout data. The proposed model thus offers predictive information about occurrences of large-scale blackouts. We further plot cumulative distribution of the blackout size to assess the overall system’s robustness. We show that heavier loads increase the likelihood of large blackouts and that small-world network structure would make cascading failure propagate more widely and rapidly than a regular network structure.

[1]  Sakshi Pahwa,et al.  Abruptness of Cascade Failures in Power Grids , 2014, Scientific Reports.

[2]  Margaret J. Eppstein,et al.  Estimating Cascading Failure Risk With Random Chemistry , 2014, IEEE Transactions on Power Systems.

[3]  Chi K. Tse,et al.  A general stochastic model for studying time evolution of transition networks , 2016 .

[4]  Massimo Marchiori,et al.  A topological analysis of the Italian electric power grid , 2004 .

[5]  Michael Chertkov,et al.  Controlled Tripping of Overheated Lines Mitigates Power Outages , 2011, ArXiv.

[6]  Federico Milano,et al.  An Open Source Power System Virtual Laboratory: The PSAT Case and Experience , 2008, IEEE Transactions on Education.

[7]  Paul Hines,et al.  A “Random Chemistry” Algorithm for Identifying Collections of Multiple Contingencies That Initiate Cascading Failure , 2012, IEEE Transactions on Power Systems.

[8]  D. Gillespie Exact Stochastic Simulation of Coupled Chemical Reactions , 1977 .

[9]  Fang Yang,et al.  Effects of Protection System Hidden Failures on Bulk Power System Reliability , 2006, 2006 38th North American Power Symposium.

[10]  Osman Yagan,et al.  Robustness of power systems under a democratic fiber bundle-like model , 2015, Physical review. E, Statistical, nonlinear, and soft matter physics.

[11]  James S. Thorp,et al.  Analysis of electric power system disturbance data , 2001, Proceedings of the 34th Annual Hawaii International Conference on System Sciences.

[12]  Peng Wang,et al.  Operational reliability assessment of power systems considering condition-dependent failure rate , 2010 .

[13]  Nasir Ghani,et al.  Stochastic Analysis of Cascading-Failure Dynamics in Power Grids , 2014, IEEE Transactions on Power Systems.

[14]  Ian Dobson,et al.  An initial model fo complex dynamics in electric power system blackouts , 2001, Proceedings of the 34th Annual Hawaii International Conference on System Sciences.

[15]  R D Zimmerman,et al.  MATPOWER: Steady-State Operations, Planning, and Analysis Tools for Power Systems Research and Education , 2011, IEEE Transactions on Power Systems.

[16]  Duncan J. Watts,et al.  Collective dynamics of ‘small-world’ networks , 1998, Nature.

[17]  Ian Dobson,et al.  Branching Process Models for the Exponentially Increasing Portions of Cascading Failure Blackouts , 2005, Proceedings of the 38th Annual Hawaii International Conference on System Sciences.

[18]  Anna Scaglione,et al.  A Markov-Transition Model for Cascading Failures in Power Grids , 2012, 2012 45th Hawaii International Conference on System Sciences.

[19]  James S. Thorp,et al.  A stochastic study of hidden failures in power system protection , 1999, Decis. Support Syst..

[20]  I. Dobson,et al.  Estimating the Propagation and Extent of Cascading Line Outages From Utility Data With a Branching Process , 2012, IEEE Transactions on Power Systems.

[21]  D. Gillespie A General Method for Numerically Simulating the Stochastic Time Evolution of Coupled Chemical Reactions , 1976 .

[22]  Chuanwen Jiang,et al.  Probability models for estimating the probabilities of cascading outages in high-voltage transmission network , 2006, IEEE Transactions on Power Systems.

[23]  Feng Liu,et al.  Risk Assessment of Multi-Timescale Cascading Outages Based on Markovian Tree Search , 2016, IEEE Transactions on Power Systems.

[24]  Marco Aiello,et al.  The Power Grid as a Complex Network: a Survey , 2011, ArXiv.

[25]  C. K. Michael Tse,et al.  Assessment of Robustness of Power Systems From a Network Perspective , 2015, IEEE Journal on Emerging and Selected Topics in Circuits and Systems.

[26]  Hyde M. Merrill,et al.  Risk and uncertainty in power system planning , 1991 .