Generator Black Start Validation Using Synchronized Phasor Measurement

Generator Black Start Validation Using Synchronized Phasor Measurement

History has repeatedly demonstrated the need to start generating units without access to the external power grid. This "black start" ability speeds power system recovery from both system instabilities and natural disasters. Readiness for an actual black start condition can be demonstrated...

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Bibliographic Details
Published in:2007 60th Annual Conference for Protective Relay Engineers pp. 498 - 504
Main Authors: Koellner, K., Anderson, C., Moxley, R.
Format: Conference Proceeding
Language:English
Published: IEEE 01-03-2007
Subjects:
Frequency synchronization
History
Hydroelectric power generation
Hydroelectric-thermal power generation
Mesh generation
Power generation
Power grids
Power system measurements
Rivers
Thermal conductivity
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Summary:History has repeatedly demonstrated the need to start generating units without access to the external power grid. This "black start" ability speeds power system recovery from both system instabilities and natural disasters. Readiness for an actual black start condition can be demonstrated by bringing a generator up to speed and synchronizing it to the electric system without using any grid power for auxiliary functions. Salt River Project, based in Phoenix, Arizona, conducted an exercise using a number of hydroelectric generating stations and a thermal-generating station. This was a legitimate "black start" exercise because every part of the system connecting the hydro and thermal generation was fully isolated (islanded) from the Western Electric Coordinating Council (WECC) power grid. Synchronized phasor measurements, or synchrophasors, provided a real-time measurement of conditions during this black start exercise. Frequency and phase angles were monitored both within the island and on the WECC power grid. By using synchrophasor technology, frequency and phase angle in the two systems could be compared in real time without the use of a physical connection. This paper illustrates the use of synchrophasor data to view frequency stability, verify system independence, and observe the synchronization point. Phasor measurement units, together with synchrophasor collector and display software, provided valuable data to operators during the course of the exercise. This paper provides discussion of problems encountered, trade-offs made, and lessons learned during the exercise
ISBN:1424409942
9781424409945
DOI:10.1109/CPRE.2007.359919