Title :
An advanced tool for analyzing multiple cascading failures
Author :
Hardiman, Rodney C. ; Kumbale, Murali ; Makarov, Yuri V.
Author_Institution :
Southern Co. Services Inc., Birmingham, AL, USA
Abstract :
This paper summarizes the Southern Company methodology and experience in advanced analysis of cascading failures. Cascading failures occur due to loss of generating units at a station, breaker failures, common tower and common right-of-way circuit outages, etc. Once an initiating event occurs, the protection system opens the surrounding breakers so that several protection control groups (PCGs, a set of components which go out of service due to action of breakers) are forced out of service. In its turn, these initial outages could cause severe overloads and voltage deviations on the operational transmission facilities. This may trigger further actions by the protection system isolating other PCGs and tripping generators, and so on. Cascading outages can propagate through the interconnection incurring significant loss of load potentially leading to a system collapse. Southern Company has developed and implemented a unique methodology that allows screening multiple initiating contingencies, simulating the cascading process, evaluating the system impacts, ranking the cascading scenarios based on their severity and likelihood, and identifying the top contingencies that require primarily attention. The methodology has been successfully used for several years. It has already influenced real-life decision-making in transmission system enhancement project prioritization and selection. This methodology is reported in this paper. This paper also provides a brief description of the recent system blackouts worldwide and develops their generic scenario. It is shown that the proposed approach is capable of simulating similar scenarios.
Keywords :
circuit breakers; decision making; power generation control; power generation faults; power generation protection; power system dynamic stability; power system interconnection; power transmission control; power transmission faults; power transmission protection; Southern Company methodology; breaker failure; cascading scenario; circuit outage; common tower outage; generating unit loss; multiple cascading failure analysis; overload deviation; protection control group; real-life decision-making; system blackout; system collapse; system impact; transmission facilities; transmission system enhancement; tripping generator; voltage deviation; Control systems; Decision making; Failure analysis; Force control; Integrated circuit interconnections; Poles and towers; Power system faults; Power system protection; Propagation losses; Voltage;
Conference_Titel :
Probabilistic Methods Applied to Power Systems, 2004 International Conference on
Print_ISBN :
0-9761319-1-9