Fault-Induced Delayed Voltage Recovery (FIDVR)

Fault-induced delayed voltage recovery (FIDVR) refers to unexpected delay in the recovery of voltage to its nominal value following the normal clearing of a fault. Initial observations of these delays by utilities in the western interconnection led to concerns that they might precipitate widespread cascading blackouts.

The FIDVR initiative sought to identify the physical mechanisms that caused the delay, assess the risks the delay and recovery posed to the reliability of the US power system, and, if appropriate, identify appropriate measures to manage these risks.

The initiative confirmed that stalled residential air conditioning (AC) units (powered by single-phase induction motors) were the cause of FIDVR. The initiative also confirmed that FIDVR events were common to utility distribution systems, but generally speaking did not pose a significant threat to the reliability of the bulk transmission system. The initiative is recognized as having contributed materially to renewed efforts by the power industry to better understand trends affecting the characteristics of loads, especially those involving power electronics, and their interactions with the power system.

Related Publications

Bravo, Richard J, and Steven Robles. 2013 FIDVR Events Analysis on Valley Distribution Circuits. Southern California Edison, 2013.

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   PDF (2.16 MB)
Bravo, Richard J. Commercial 3-Phase Rooftop Air Conditioner Test Procedures. Southern California Edison, 2013.

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   PDF (1.1 MB)
Bravo, Richard J, Robert J Yinger, Steven Robles, and Joseph H Eto. "FIDVR Events Analysis, Part I." Proceedings of the IEEE PES General Meeting. Vancouver, BC, Canada: IEEE, 2013.
Bravo, Richard J, Robert J Yinger, Steven Robles, and Joseph H Eto. "FIDVR in Distribution Circuits." Proceedings of the IEEE Power and Energy Society General Meeting. Vancouver, BC, Canada: IEEE, 2013.
Bravo, Richard J, and Steven Robles. Paralleled Residential Solar PV Inverter Test Report. Southern California Edison, 2013.

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   PDF (2.25 MB)
Bravo, Richard J. Residential Air Conditioner with VFD Test Procedures. Southern California Edison, 2013.

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   PDF (1.2 MB)
Bravo, Richard J, and Steven Robles. Residential German Solar PV Inverter Test Report. Southern California Edison, 2013.

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   PDF (9.18 MB)
Bravo, Richard J, and Steven Robles. Residential Solar PV Inverter Test Report. Southern California Edison, 2013.

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   PDF (5.99 MB)
Bravo, Richard J, and Steven Robles. Residential U.S. Solar PV Inverter with Advanced Features Test Report. Southern California Edison, 2013.

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   PDF (4.7 MB)
Bravo, Richard J, Roger Salas, Robert Yinger, and Steven Robles. "Solar photovoltaic inverters transient over-voltages." 2013: 1-5.
Bravo, Richard J, and Steven Robles. Solar PV Inverter Test Procedures. Southern California Edison, 2013.

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   PDF (1.76 MB)
Bravo, Richard J, Robert Yinger, and Steven Robles. "Three phase solar photovoltaic inverter testing." 2013: 1-5.
Bravo, Richard J. Three-Phase German Solar PV Inverter Test Report. Southern California Edison, 2013.

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   PDF (6.66 MB)
Bravo, Richard J. Transformerless Solar PV Inverters Test Report. Southern California Edison, 2013.

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   PDF (4.13 MB)
Liu, Yuan, Vijay Vittal, John Undrill, and Joseph H Eto. "Transient Model of Air-Conditioner Compressor Single Phase Induction Motor." IEEE Transactions on Power Systems 28.4 (2013) 4528-4536.
Composite Load Model for Dynamic Simulations. Western Electricity Coordinating Council, 2012.
Group, WECC Modeling. Composite Load Model for Dynamic Simulations - Report 1.0. Salt Lake City, UT: Western Electricity Coordinating Council, 2012.
Ravikumar, Krishnanjan Gubba. RTDS Testing Final Report. SEL Engineering Services, 2012.

Related Files

   PDF (4.56 MB)
Bravo, Richard J, Robert Yinger, Steven Robles, and W. Tamae. "Solar PV inverter testing for model validation." 2011: 1-7.
Lesieutre, Bernard C, Richard J Bravo, Robert Yinger, David Chassin, Henry Juang, Ning Lu, Ian Hiskens, and Giri Vendatarmanan. Load Modeling Transmission Research. California Institute for Energy and Environment, 2010.
Bravo, Richard J. Load Modeling Transmission Research: Appendix F: Air Conditioner Stalling Solutions Summary Report. Berkeley, CA: CIEE, 2010.
Group, WECC Modeling. Modeling and Studying FIDVR Events. Western Electricity Coordinating Council, 2010.

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   PDF (367.36 KB)
"2009 DOE-NERC Workshop on Fault-Induced Delayed Voltage Recovery (FIDVR).". 2009.

Related Files

   2009 FIDVR Workshop Agenda PDF (86.18 KB)   2009 Workshop Overview PDF (35.18 KB)   Load Modeling in WECC and Modeling Electrical End-Use PDF (1.97 MB)   Air Conditioner Stalling Solutions PDF (762.41 KB)   FIDVR: Rheem Manufacturing PDF (86.03 KB)   2009 FIDVR Workshop Summary PDF (26.51 KB)
NERC), North American E. A Technical Reference Paper Fault-Induced Delayed Voltage Recovery. Princeton, NJ: North American Electric Reliability Corporation, 2009.
Lu, N., B. Yang, Zhenyu Huang, and Richard J Bravo. "The system impact of air conditioner under-voltage protection schemes." 2009: 1-8.

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