Information Notice 2005-04, Single-Failure and Fire Vulnerability of Redundant Electrical Safety Buses: Difference between revisions
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{{#Wiki_filter: | {{#Wiki_filter:UNITED STATESNUCLEAR REGULATORY COMMISSIONOFFICE OF NUCLEAR REACTOR REGULATIONWASHINGTON, D.C. 20555-0001February 14, 2005NRC INFORMATION NOTICE 2005-04:SINGLE-FAILURE AND FIRE VULNERABILITYOF REDUNDANT ELECTRICAL SAFETY BUSES | ||
==ADDRESSEES== | |||
All holders of operating licenses for nuclear reactors, except those who have permanentlyceased operations and have certified that fuel has been permanently removed from the reactor | |||
vessel. | |||
==PURPOSE== | ==PURPOSE== | ||
The U.S. Nuclear Regulatory Commission (NRC) is issuing this information notice to informaddressees of a potential single-failure and fire vulnerability whereby a circuit failure couldresult in bus lockouts and prevent the reenergization of the redundant electrical safety | The U.S. Nuclear Regulatory Commission (NRC) is issuing this information notice to informaddressees of a potential single-failure and fire vulnerability whereby a circuit failure couldresult in bus lockouts and prevent the reenergization of the redundant electrical safety buses. It | ||
is expected that recipients will review the information for applicability to their facilities andconsider appropriate actions to avoid similar problems. However, suggestions contained in this | |||
information notice are not NRC requirements; therefore, no specific action or written responseis required. | |||
==DESCRIPTION OF CIRCUMSTANCES== | ==DESCRIPTION OF CIRCUMSTANCES== | ||
On January 27, 2005, during a triennial fire protection inspection of the Crystal River nuclearstation, NRC inspectors discovered an electrical protection and metering circuit which ifdamaged, could electrically lock out redundant safety buses and prevent reenergization of the buses both from offsite power sources and emergency diesel generators (EDGs).The power sources for the safety buses generally consist of two offsite power supplies, both ofwhich are designed to supply power to each of the safety | On January 27, 2005, during a triennial fire protection inspection of the Crystal River nuclearstation, NRC inspectors discovered an electrical protection and metering circuit which ifdamaged, could electrically lock out redundant safety buses and prevent reenergization of the | ||
buses both from offsite power sources and emergency diesel generators (EDGs).The power sources for the safety buses generally consist of two offsite power supplies, both ofwhich are designed to supply power to each of the safety buses. The normal bus alignment | |||
has one offsite power supply selected as the source for each safety bus. Each safety bus also | |||
has one EDG as a standby power source. The electrical protection and metering system usescurrent transformers (CTs) for measuring power consumption and sensing overloads and | |||
faulted conditions. At Crystal River, the electrical protection and metering circuit for each offsite | |||
power supply included three CTs at the feeder breaker to each safety bus, phase overcurrent | |||
relays, and ground overcurrent relays, all connected in a basic residual scheme. The circuit | |||
also included one watt-hour meter which would sum the power to both safety busses. This | |||
interconnection of a protection and metering circuit between two safety busses was identified by | |||
the inspectors as a common-mode failure vulnerability. A failure on this interconnected circuit(e.g., a fire-induced cable fault or watt-hour meter failure) would be interpreted by the protection | |||
system as an electrical bus fault on both safety busses. Consequently, the relay logic wouldlock out both redundant safety buses and prevent reenergization from any power source. The licensee has modified the wiring in the overcurrent protection circuits to align eachmonitoring circuit to one safety bus and to disconnect the watt-hour meters. In this corrected | |||
configuration, each circuit is contained within one switchgear, a single fault will affect only onesafety bus, and a fire in any area (e.g., at the watt-hour meters in the main control room) will notaffect safety busses that are relied upon for safe shutdown. | |||
==BACKGROUND== | ==BACKGROUND== | ||
The design function (to prevent single- failure vulnerabilities) is implemented through train-specific metering, monitoring, and protection systems to limit the probability of worst casefailures to a | The design function (to prevent single- failure vulnerabilities) is implemented through train-specific metering, monitoring, and protection systems to limit the probability of worst casefailures to a train. Whenever a signal is needed to the redundant train, the signal is electrically | ||
isolated (i.e., any potential failure or its deleterious effects cannot be transmitted to the | |||
redundant train). The redundant safety buses are expected to be fully independent (i.e., neither componentfailure, degradation of equipment, or electrical faults could disable both trains). NRC | |||
regulations in Title 10, of the Code of Federal Regulations (CFR) Part 50.55a(h)(2), requiresprotection systems to meet IEEE Std 279 -1971 "Criteria for Protection Systems for NuclearPower Generating Stations." This standard requires all electric and mechanical components | |||
(e.g., from sensors to actuation devices) to be free from single failure vulnerability. That is, no | |||
single failure in the protection system shall prevent proper protective actions at the systemlevel.General Design Criterion (GDC)17, of 10 CFR Part 50 Appendix A, states that "The onsiteelectric power supplies...and the onsite electric distribution system... shall have sufficientindependence [and] redundancy ....to perform their safety functions assuming a single failure." | |||
There may be other plant-specific commitments for keeping the plant configuration free ofsingle-failure vulnerability. | There may be other plant-specific commitments for keeping the plant configuration free ofsingle-failure vulnerability. | ||
==DISCUSSION== | ==DISCUSSION== | ||
The design deficiency identified at Crystal River had a protection scheme that used CTs formonitoring and metering power flow. The CTs installed on power feeders to redundant safety buses were electrically connected to generate a selective tripping scheme to isolate overcurrent and ground fault conditions on the | The design deficiency identified at Crystal River had a protection scheme that used CTs formonitoring and metering power flow. The CTs installed on power feeders to redundant safety | ||
buses were electrically connected to generate a selective tripping scheme to isolate overcurrent | |||
and ground fault conditions on the bus. This design is economical but results in a common- mode failure vulnerability disabling two redundant trains of safety buses. Further, the CToutputs from redundant safety buses were also connected to the same watt-hour meter, resulting in the same vulnerability to common-mode failure. The significance of such a vulnerability is that the failure of redundant buses generally disablesmost of the accident mitigation/emergency core cooling systems, except the steam-drivensystems actuated by DC power. Such electrical failures cannot be isolated with a reasonablechance of system recovery without expert help because of the interdependent electricalprotection system. In most cases, manually closing the breaker will result in a prompt trip. Thisis because the logic is designed to prevent such operations when actual fault conditions persist. Similar problems could exist in the buses that supply related plant pumping systems (e.g.,reactor coolant pumps, circulating water pumps, service water pumps), where a single failure | |||
could disable the full system of pumps connected to different buses.Similar common-mode failure vulnerabilities were identified at Quad Cities, Dresden, LaSalle,Prairie Island, and Monticello.GENERIC IMPLICATIONS | |||
After reviewing the events at the six sites (10 units), the staff concludes that such deficienciesare potentially wide-spread with varying levels of risk significance depending on plant-specific, unique design configurations. | |||
==CONTACT== | |||
This information notice requires no specific action or written response. Please direct anyquestions about this matter to the technical contact listed below or the appropriate Office of | |||
Nuclear Reactor Regulation (NRR) project manager./RA/Patrick L. Hiland, Chief | |||
===Reactor Operations Branch=== | |||
Division of Inspection Program Management | |||
===Office of Nuclear Reactor Regulation=== | |||
===Technical Contact:=== | |||
Thomas Koshy, NRR/EEIB301-415-1176 E-mail: txk@nrc.govNote: NRC generic communications may be found on the NRC public Website,http://www.nrc.gov, under Electronic Reading Room/Document Collections. Similar problems could exist in the buses that supply related plant pumping systems (e.g.,reactor coolant pumps, circulating water pumps, service water pumps), where a single failure | |||
could disable the full system of pumps connected to different buses.Similar common-mode failure vulnerabilities were identified at Quad Cities, Dresden, LaSalle,Prairie Island, and Monticello.GENERIC IMPLICATIONS | |||
After reviewing the events at the six sites (10 units), the staff concludes that such deficienciesare potentially wide-spread with varying levels of risk significance depending on plant-specific, unique design configurations. | |||
==CONTACT== | ==CONTACT== | ||
This information notice requires no specific action or written | This information notice requires no specific action or written response. Please direct anyquestions about this matter to the technical contact listed below or the appropriate Office of | ||
Nuclear Reactor Regulation (NRR) project manager./RA/Patrick L. Hiland, Chief | |||
===Reactor Operations Branch=== | |||
Division of Inspection Program Management | |||
===Office of Nuclear Reactor Regulation=== | |||
===Technical Contact:=== | ===Technical Contact:=== | ||
Thomas Koshy, NRR/EEIB301-415-1176 E-mail: txk@nrc.govNote: NRC generic communications may be found on the NRC public Website,http://www.nrc.gov, under Electronic Reading Room/Document | Thomas Koshy, NRR/EEIB301-415-1176 E-mail: txk@nrc.govNote: NRC generic communications may be found on the NRC public Website,http://www.nrc.gov, under Electronic Reading Room/Document Collections.DISTRIBUTION:ADAMS | ||
IN File | |||
ADAMS ACCESSION NUMBER: ML050400090 | |||
DOCUMENT NAME: E:\Filenet\ML050400090.wpdOFFICEOES:IROB:DIPMTECH EDITOREEIB:DERIIRIIINAMERSchmittPkleeneTKoshyR. Schin (via e-mail)T. Kozak | |||
DATE02/09/200502/08/200502/09/200502/09/200502/09/2005OFFICESC:EEIB:DESPLB:DSSABC:SPLB:DSSASC:OES:IROB:DIPMC:IROB:DIPMNAMERJenkinsSDWeerakkodyJNHannonTReisPLHiland | |||
DATE02/09/200502/10/200502/10/200502/14/200502/14/2005OFFICIAL RECORD COPY | |||
}} | |||
{{Information notice-Nav}} | {{Information notice-Nav}} |
Revision as of 18:31, 6 April 2018
ML050400090 | |
Person / Time | |
---|---|
Issue date: | 02/14/2005 |
From: | Hiland P L NRC/NRR/DIPM/IROB |
To: | |
Koshy T, NRR/DE/EEIB, 415-1176 | |
References | |
IN-05-004 | |
Download: ML050400090 (4) | |
UNITED STATESNUCLEAR REGULATORY COMMISSIONOFFICE OF NUCLEAR REACTOR REGULATIONWASHINGTON, D.C. 20555-0001February 14, 2005NRC INFORMATION NOTICE 2005-04:SINGLE-FAILURE AND FIRE VULNERABILITYOF REDUNDANT ELECTRICAL SAFETY BUSES
ADDRESSEES
All holders of operating licenses for nuclear reactors, except those who have permanentlyceased operations and have certified that fuel has been permanently removed from the reactor
vessel.
PURPOSE
The U.S. Nuclear Regulatory Commission (NRC) is issuing this information notice to informaddressees of a potential single-failure and fire vulnerability whereby a circuit failure couldresult in bus lockouts and prevent the reenergization of the redundant electrical safety buses. It
is expected that recipients will review the information for applicability to their facilities andconsider appropriate actions to avoid similar problems. However, suggestions contained in this
information notice are not NRC requirements; therefore, no specific action or written responseis required.
DESCRIPTION OF CIRCUMSTANCES
On January 27, 2005, during a triennial fire protection inspection of the Crystal River nuclearstation, NRC inspectors discovered an electrical protection and metering circuit which ifdamaged, could electrically lock out redundant safety buses and prevent reenergization of the
buses both from offsite power sources and emergency diesel generators (EDGs).The power sources for the safety buses generally consist of two offsite power supplies, both ofwhich are designed to supply power to each of the safety buses. The normal bus alignment
has one offsite power supply selected as the source for each safety bus. Each safety bus also
has one EDG as a standby power source. The electrical protection and metering system usescurrent transformers (CTs) for measuring power consumption and sensing overloads and
faulted conditions. At Crystal River, the electrical protection and metering circuit for each offsite
power supply included three CTs at the feeder breaker to each safety bus, phase overcurrent
relays, and ground overcurrent relays, all connected in a basic residual scheme. The circuit
also included one watt-hour meter which would sum the power to both safety busses. This
interconnection of a protection and metering circuit between two safety busses was identified by
the inspectors as a common-mode failure vulnerability. A failure on this interconnected circuit(e.g., a fire-induced cable fault or watt-hour meter failure) would be interpreted by the protection
system as an electrical bus fault on both safety busses. Consequently, the relay logic wouldlock out both redundant safety buses and prevent reenergization from any power source. The licensee has modified the wiring in the overcurrent protection circuits to align eachmonitoring circuit to one safety bus and to disconnect the watt-hour meters. In this corrected
configuration, each circuit is contained within one switchgear, a single fault will affect only onesafety bus, and a fire in any area (e.g., at the watt-hour meters in the main control room) will notaffect safety busses that are relied upon for safe shutdown.
BACKGROUND
The design function (to prevent single- failure vulnerabilities) is implemented through train-specific metering, monitoring, and protection systems to limit the probability of worst casefailures to a train. Whenever a signal is needed to the redundant train, the signal is electrically
isolated (i.e., any potential failure or its deleterious effects cannot be transmitted to the
redundant train). The redundant safety buses are expected to be fully independent (i.e., neither componentfailure, degradation of equipment, or electrical faults could disable both trains). NRC
regulations in Title 10, of the Code of Federal Regulations (CFR) Part 50.55a(h)(2), requiresprotection systems to meet IEEE Std 279 -1971 "Criteria for Protection Systems for NuclearPower Generating Stations." This standard requires all electric and mechanical components
(e.g., from sensors to actuation devices) to be free from single failure vulnerability. That is, no
single failure in the protection system shall prevent proper protective actions at the systemlevel.General Design Criterion (GDC)17, of 10 CFR Part 50 Appendix A, states that "The onsiteelectric power supplies...and the onsite electric distribution system... shall have sufficientindependence [and] redundancy ....to perform their safety functions assuming a single failure."
There may be other plant-specific commitments for keeping the plant configuration free ofsingle-failure vulnerability.
DISCUSSION
The design deficiency identified at Crystal River had a protection scheme that used CTs formonitoring and metering power flow. The CTs installed on power feeders to redundant safety
buses were electrically connected to generate a selective tripping scheme to isolate overcurrent
and ground fault conditions on the bus. This design is economical but results in a common- mode failure vulnerability disabling two redundant trains of safety buses. Further, the CToutputs from redundant safety buses were also connected to the same watt-hour meter, resulting in the same vulnerability to common-mode failure. The significance of such a vulnerability is that the failure of redundant buses generally disablesmost of the accident mitigation/emergency core cooling systems, except the steam-drivensystems actuated by DC power. Such electrical failures cannot be isolated with a reasonablechance of system recovery without expert help because of the interdependent electricalprotection system. In most cases, manually closing the breaker will result in a prompt trip. Thisis because the logic is designed to prevent such operations when actual fault conditions persist. Similar problems could exist in the buses that supply related plant pumping systems (e.g.,reactor coolant pumps, circulating water pumps, service water pumps), where a single failure
could disable the full system of pumps connected to different buses.Similar common-mode failure vulnerabilities were identified at Quad Cities, Dresden, LaSalle,Prairie Island, and Monticello.GENERIC IMPLICATIONS
After reviewing the events at the six sites (10 units), the staff concludes that such deficienciesare potentially wide-spread with varying levels of risk significance depending on plant-specific, unique design configurations.
CONTACT
This information notice requires no specific action or written response. Please direct anyquestions about this matter to the technical contact listed below or the appropriate Office of
Nuclear Reactor Regulation (NRR) project manager./RA/Patrick L. Hiland, Chief
Reactor Operations Branch
Division of Inspection Program Management
Office of Nuclear Reactor Regulation
Technical Contact:
Thomas Koshy, NRR/EEIB301-415-1176 E-mail: txk@nrc.govNote: NRC generic communications may be found on the NRC public Website,http://www.nrc.gov, under Electronic Reading Room/Document Collections. Similar problems could exist in the buses that supply related plant pumping systems (e.g.,reactor coolant pumps, circulating water pumps, service water pumps), where a single failure
could disable the full system of pumps connected to different buses.Similar common-mode failure vulnerabilities were identified at Quad Cities, Dresden, LaSalle,Prairie Island, and Monticello.GENERIC IMPLICATIONS
After reviewing the events at the six sites (10 units), the staff concludes that such deficienciesare potentially wide-spread with varying levels of risk significance depending on plant-specific, unique design configurations.
CONTACT
This information notice requires no specific action or written response. Please direct anyquestions about this matter to the technical contact listed below or the appropriate Office of
Nuclear Reactor Regulation (NRR) project manager./RA/Patrick L. Hiland, Chief
Reactor Operations Branch
Division of Inspection Program Management
Office of Nuclear Reactor Regulation
Technical Contact:
Thomas Koshy, NRR/EEIB301-415-1176 E-mail: txk@nrc.govNote: NRC generic communications may be found on the NRC public Website,http://www.nrc.gov, under Electronic Reading Room/Document Collections.DISTRIBUTION:ADAMS
IN File
ADAMS ACCESSION NUMBER: ML050400090
DOCUMENT NAME: E:\Filenet\ML050400090.wpdOFFICEOES:IROB:DIPMTECH EDITOREEIB:DERIIRIIINAMERSchmittPkleeneTKoshyR. Schin (via e-mail)T. Kozak
DATE02/09/200502/08/200502/09/200502/09/200502/09/2005OFFICESC:EEIB:DESPLB:DSSABC:SPLB:DSSASC:OES:IROB:DIPMC:IROB:DIPMNAMERJenkinsSDWeerakkodyJNHannonTReisPLHiland
DATE02/09/200502/10/200502/10/200502/14/200502/14/2005OFFICIAL RECORD COPY