Information Notice 2010-17, Common Cause Failure of Boiling-Water Reactor Recirculation Pumps with Variable Speed Drives: Difference between revisions

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{{#Wiki_filter:UNITED STATES
{{#Wiki_filter:ML101330321 UNITED STATES


NUCLEAR REGULATORY COMMISSION
NUCLEAR REGULATORY COMMISSION
Line 22: Line 22:
OFFICE OF NEW REACTORS
OFFICE OF NEW REACTORS


WASHINGTON, DC 20555-0001 September 10, 2010
WASHINGTON, DC 20555-0001  
NRC INFORMATION NOTICE 2010-17:               COMMON CAUSE FAILURE OF BOILING-WATER
 
September 10, 2010  
 
NRC INFORMATION NOTICE 2010-17:  
COMMON CAUSE FAILURE OF BOILING-WATER


REACTOR RECIRCULATION PUMPS WITH
REACTOR RECIRCULATION PUMPS WITH
Line 49: Line 53:
addressees about two international events at boiling-water reactor (BWR) plants that
addressees about two international events at boiling-water reactor (BWR) plants that


experienced a common cause failure of all recirculation pumps. The NRC expects that
experienced a common cause failure of all recirculation pumps. The NRC expects that


recipients will review this information for applicability to their facilities and consider actions, as
recipients will review this information for applicability to their facilities and consider actions, as


appropriate, to avoid similar problems. However, suggestions contained in this IN are not NRC
appropriate, to avoid similar problems. However, suggestions contained in this IN are not NRC


requirements; therefore, no specific action or written response is required.
requirements; therefore, no specific action or written response is required.
Line 60: Line 64:
On June 13, 2008, at Forsmark Unit 2 in Sweden, lightning strikes caused a short circuit on the
On June 13, 2008, at Forsmark Unit 2 in Sweden, lightning strikes caused a short circuit on the


offsite power grid. This resulted in a transient that tripped all eight reactor recirculation pumps.
offsite power grid. This resulted in a transient that tripped all eight reactor recirculation pumps.


Each recirculation pump circuit contains an integral flywheel to prevent a rapid reduction in
Each recirculation pump circuit contains an integral flywheel to prevent a rapid reduction in


pump speed. The mass of the rotating flywheel stores mechanical energy that is converted to
pump speed. The mass of the rotating flywheel stores mechanical energy that is converted to


electrical power by a flywheel-generator and inverter/rectifier to continue to power the drive
electrical power by a flywheel-generator and inverter/rectifier to continue to power the drive
Line 70: Line 74:
system DC-bus (one DC-bus common for two pump-drive inverters) upon a dip in or loss of the
system DC-bus (one DC-bus common for two pump-drive inverters) upon a dip in or loss of the


normal electrical power. When the inverter/rectifier is operable, the alternate power allows for
normal electrical power. When the inverter/rectifier is operable, the alternate power allows for


an unchanged pump speed (in case of power dips) or a more gradual reduction in pump speed
an unchanged pump speed (in case of power dips) or a more gradual reduction in pump speed


(in case of significant loss, signaled by equipment protection). In the case of a reactor
(in case of significant loss, signaled by equipment protection). In the case of a reactor


recirculation pump, the coastdown produces a correspondingly more gradual reduction in
recirculation pump, the coastdown produces a correspondingly more gradual reduction in


recirculation flow. However, at Forsmark Unit 2, the lightning strike tripped the normal electric
recirculation flow. However, at Forsmark Unit 2, the lightning strike tripped the normal electric


power rectifier due to a sensitive protection setting; furthermore, due to a design flaw, the
power rectifier due to a sensitive protection setting; furthermore, due to a design flaw, the


protective action was not signaled to the inverter/rectifier controller for the flywheel-generator.
protective action was not signaled to the inverter/rectifier controller for the flywheel-generator. As a result, the recirculation pump motors rapidly consumed the flywheel-generators stored
 
As a result, the recirculation pump motors rapidly consumed the flywheel-generators stored


energy. With no available energy storage, the recirculation pumps reduced speed faster than
energy. With no available energy storage, the recirculation pumps reduced speed faster than


the assumed transient analyses in the Forsmark Unit 2 safety analysis report. The reduced
the assumed transient analyses in the Forsmark Unit 2 safety analysis report. The reduced


coastdown time resulted in a short violation of the safety limit minimum critical power ratio on
coastdown time resulted in a short violation of the safety limit minimum critical power ratio on
Line 100: Line 102:
affected fuel.
affected fuel.


On May 30, 2008, Olkiluoto Unit 1 in Finland had a reactor trip from 60 percent power. An
On May 30, 2008, Olkiluoto Unit 1 in Finland had a reactor trip from 60 percent power. An


electrical transient resulted in a common cause failure that caused all six recirculation pumps to
electrical transient resulted in a common cause failure that caused all six recirculation pumps to


stop unexpectedly. Although the coastdown of the recirculation pumps was shorter than
stop unexpectedly. Although the coastdown of the recirculation pumps was shorter than


expected, the transient had no effect on fuel integrity.
expected, the transient had no effect on fuel integrity.


==BACKGROUND==
==BACKGROUND==
Related NRC Generic Communications include the following:
Related NRC Generic Communications include the following:  


* NRC IN 96-56, Problems Associated with Testing, Tuning, or Resetting of Digital Control
* NRC IN 96-56, Problems Associated with Testing, Tuning, or Resetting of Digital Control
Line 115: Line 117:
Systems While at Power, dated October 22, 1996 (Agencywide Documents Access and
Systems While at Power, dated October 22, 1996 (Agencywide Documents Access and


Management System (ADAMS) Accession No. ML031050587). This IN highlighted the
Management System (ADAMS) Accession No. ML031050587). This IN highlighted the


importance of evaluating and controlling on-line manipulations of digital control systems, such as resetting a processor or performing on-line software changes, to avoid reactor
importance of evaluating and controlling on-line manipulations of digital control systems, such as resetting a processor or performing on-line software changes, to avoid reactor
Line 123: Line 125:
* IN 2010-10, Implementation of a Digital Control System under 10 CFR 50.59, dated
* IN 2010-10, Implementation of a Digital Control System under 10 CFR 50.59, dated


May 28, 2010 (ADAMS Accession No. ML100080281). This IN discusses that for digital
May 28, 2010 (ADAMS Accession No. ML100080281). This IN discusses that for digital


upgrades to systems that are highly safety-significant, a defense-in-depth and diversity
upgrades to systems that are highly safety-significant, a defense-in-depth and diversity
Line 136: Line 138:
that rely on energy storage separate from the recirculation pump motor and generator that could
that rely on energy storage separate from the recirculation pump motor and generator that could


influence recirculation system flow following a scram. In the U.S. BWR designs, the combined
influence recirculation system flow following a scram. In the U.S. BWR designs, the combined


rotating inertias of the recirculation pump and motor, the motor generator set, and the variable
rotating inertias of the recirculation pump and motor, the motor generator set, and the variable
Line 146: Line 148:
The specific common cause failure that occurred at Olkiluoto and Forsmark is not an issue for
The specific common cause failure that occurred at Olkiluoto and Forsmark is not an issue for


U.S. BWRs. However, digital variable speed drive (VSD) technology may increase the
U.S. BWRs. However, digital variable speed drive (VSD) technology may increase the


complexity of the recirculation pump control system and may introduce new failure modes such
complexity of the recirculation pump control system and may introduce new failure modes such
Line 152: Line 154:
as software programming errors, network problems, loss of power, and the failure of control
as software programming errors, network problems, loss of power, and the failure of control


boards, that can lead to unplanned changes in pump speed. Previous operating experience for
boards, that can lead to unplanned changes in pump speed. Previous operating experience for


recirculation pump VSD includes instances of unintentional reactivity changes during power
recirculation pump VSD includes instances of unintentional reactivity changes during power


operation. Although the recirculation pump motors are generally non-safety related, as the
operation. Although the recirculation pump motors are generally non-safety related, as the


industry upgrades their systems to digital VSD, it is important that licensees understand the potential unexpected recirculation pump behaviors that might affect core reactivity or safety
industry upgrades their systems to digital VSD, it is important that licensees understand the potential unexpected recirculation pump behaviors that might affect core reactivity or safety


limits. As part of the design process when upgrading to digital VSD technology on recirculation
limits. As part of the design process when upgrading to digital VSD technology on recirculation
 
pump systems, the following are important considerations: 


pump systems, the following are important considerations:
*
    *  Perform evaluations to identify failure modes for digital VSDs to include sources of
Perform evaluations to identify failure modes for digital VSDs to include sources of


common-cause failure, such as software.
common-cause failure, such as software.


*   Determine if the consequences of a digital VSD common-cause failure could lead to
*  
Determine if the consequences of a digital VSD common-cause failure could lead to


reactivity events that have not been analyzed in the plant safety analysis.
reactivity events that have not been analyzed in the plant safety analysis.


*   Ensure the reactor protection system maintains plant safety within its design basis even
*  
Ensure the reactor protection system maintains plant safety within its design basis even


with a common-cause failure.
with a common-cause failure.


==CONTACT==
==CONTACT==
This IN requires no specific action or written response. Please direct any questions about this
This IN requires no specific action or written response. Please direct any questions about this


matter to the technical contacts listed below or the appropriate Office of Nuclear Reactor
matter to the technical contacts listed below or the appropriate Office of Nuclear Reactor
Line 182: Line 188:
Regulation (NRR) project manager.
Regulation (NRR) project manager.


/RA/                                           /RA by JTappert for/
/RA/  
Timothy McGinty, Director                      Glenn Tracy, Director


Division of Policy and Rulemaking              Division of Construction Inspection and
/RA by JTappert for/


Office of Nuclear Reactor Regulation           Operational Programs
Timothy McGinty, Director
 
Glenn Tracy, Director
 
Division of Policy and Rulemaking
 
Division of Construction Inspection and
 
Office of Nuclear Reactor Regulation
 
Operational Programs


Office of New Reactors
Office of New Reactors


Technical Contacts:     Joseph Giantelli, NRR                 Pong Chung, NRR
Technical Contacts: Joseph Giantelli, NRR
 
Pong Chung, NRR
 
301-415-0504
301-415-2473
 
E-mail:  joseph.giantelli@nrc.gov


301-415-0504                          301-415-2473 E-mail: joseph.giantelli@nrc.gov      E-mail: pong.chung@nrc.gov
E-mail: pong.chung@nrc.gov


Note: NRC generic communications may be found on the NRC public Web site, http://www.nrc.gov, under Electronic Reading Room/Document Collections. potential unexpected recirculation pump behaviors that might affect core reactivity or safety
Note: NRC generic communications may be found on the NRC public Web site, http://www.nrc.gov, under Electronic Reading Room/Document Collections. potential unexpected recirculation pump behaviors that might affect core reactivity or safety


limits. As part of the design process when upgrading to digital VSD technology on recirculation
limits. As part of the design process when upgrading to digital VSD technology on recirculation


pump systems, the following are important considerations:
pump systems, the following are important considerations:
    *   Perform evaluations to identify failure modes for digital VSDs to include sources of
 
*  
Perform evaluations to identify failure modes for digital VSDs to include sources of


common-cause failure, such as software.
common-cause failure, such as software.


*   Determine if the consequences of a digital VSD common-cause failure could lead to
*  
Determine if the consequences of a digital VSD common-cause failure could lead to


reactivity events that have not been analyzed in the plant safety analysis.
reactivity events that have not been analyzed in the plant safety analysis.


*   Ensure the reactor protection system maintains plant safety within its design basis even
*  
Ensure the reactor protection system maintains plant safety within its design basis even


with a common-cause failure.
with a common-cause failure.


==CONTACT==
==CONTACT==
This IN requires no specific action or written response. Please direct any questions about this
This IN requires no specific action or written response. Please direct any questions about this


matter to the technical contacts listed below or the appropriate Office of Nuclear Reactor
matter to the technical contacts listed below or the appropriate Office of Nuclear Reactor
Line 219: Line 245:
Regulation (NRR) project manager.
Regulation (NRR) project manager.


/RA/                                           /RA by JTappert for/
/RA/  
Timothy McGinty, Director                      Glenn Tracy, Director
 
/RA by JTappert for/  
 
Timothy McGinty, Director


Division of Policy and Rulemaking              Division of Construction Inspection and
Glenn Tracy, Director


Office of Nuclear Reactor Regulation             Operational Programs
Division of Policy and Rulemaking
 
Division of Construction Inspection and
 
Office of Nuclear Reactor Regulation
 
Operational Programs


Office of New Reactors
Office of New Reactors


Technical Contacts:     Joseph Giantelli, NRR                 Pong Chung, NRR
Technical Contacts: Joseph Giantelli, NRR
 
Pong Chung, NRR
 
301-415-0504
301-415-2473
 
E-mail:  joseph.giantelli@nrc.gov
 
E-mail:  pong.chung@nrc.gov
 
Note:  NRC generic communications may be found on the NRC public Web site, http://www.nrc.gov, under Electronic Reading Room/Document Collections.
 
ADAMS Accession Number:  ML101330321 
 
TAC ME3898 OFFICE DIRS/IOEB
 
DE/EICB
 
Tech Editor
 
BC/DIRS/IOEB
 
BC/D/EICB
 
D/NRR/DE
 
NAME
 
JGiantelli
 
PChung
 
CHsu
 
JThorp
 
BKemper
 
PHiland


301-415-0504                          301-415-2473 E-mail: joseph.giantelli@nrc.gov      E-mail: pong.chung@nrc.gov
DATE


Note: NRC generic communications may be found on the NRC public Web site, http://www.nrc.gov, under Electronic Reading Room/Document Collections.
07/27/10
07/27/10
08/15/10 e-mail 07/27/10
07/27/10
07/28/10
OFFICE NRR/PGCB


ADAMS Accession Number: ML101330321                                          TAC ME3898 OFFICE  DIRS/IOEB      DE/EICB        Tech Editor    BC/DIRS/IOEB  BC/D/EICB      D/NRR/DE
NRR/PGCB


NAME    JGiantelli    PChung        CHsu            JThorp        BKemper        PHiland
BC/NRR/PGCB DD/OIP


DATE    07/27/10      07/27/10      08/15/10 e-mail 07/27/10      07/27/10        07/28/10
D/NRO/DCIP
OFFICE  NRR/PGCB      NRR/PGCB      BC/NRR/PGCB    DD/OIP        D/NRO/DCIP     D/NRR/ DPR


NAME     CHawes         DBeaulieu     SRosenberg     SMoore         GTracy JTappert TMcGinty
D/NRR/ DPR
 
NAME
 
CHawes
 
DBeaulieu
 
SRosenberg
 
SMoore
 
GTracy JTappert


for
for


OFFICE 08/26/10         08/25/10       08/26/10       09/09/10       09/10/10       09/10/10
TMcGinty
                                    OFFICIAL RECORD COPY}}
 
OFFICE 08/26/10  
08/25/10  
08/26/10  
09/09/10  
09/10/10  
09/10/10  
OFFICIAL RECORD COPY}}


{{Information notice-Nav}}
{{Information notice-Nav}}

Latest revision as of 05:58, 14 January 2025

Common Cause Failure of Boiling-Water Reactor Recirculation Pumps with Variable Speed Drives
ML101330321
Person / Time
Issue date: 09/10/2010
From: Mcginty T, Tracy G
Office of New Reactors, Office of Nuclear Reactor Regulation
To:
Joseph Giantelli, NRR/DIRS/IOEB
References
IN-10-017
Download: ML101330321 (4)
v  d  e


ML101330321 UNITED STATES

NUCLEAR REGULATORY COMMISSION

OFFICE OF NUCLEAR REACTOR REGULATION

OFFICE OF NEW REACTORS

WASHINGTON, DC 20555-0001

September 10, 2010

NRC INFORMATION NOTICE 2010-17:

COMMON CAUSE FAILURE OF BOILING-WATER

REACTOR RECIRCULATION PUMPS WITH

VARIABLE SPEED DRIVES

ADDRESSEES

All holders of an operating license or construction permit for a nuclear power reactor issued

under Title 10 of the Code of Federal Regulations (10 CFR) Part 50, Domestic Licensing of

Production and Utilization Facilities, except those who have permanently ceased operations

and have certified that fuel has been permanently removed from the reactor vessel.

All holders of or applicants for a standard design certification, standard design approval, or

combined license issued under 10 CFR Part 52, Licenses, Certifications, and Approvals for

Nuclear Power Plants.

PURPOSE

The U.S. Nuclear Regulatory Commission (NRC) is issuing this information notice (IN) to inform

addressees about two international events at boiling-water reactor (BWR) plants that

experienced a common cause failure of all recirculation pumps. The NRC expects that

recipients will review this information for applicability to their facilities and consider actions, as

appropriate, to avoid similar problems. However, suggestions contained in this IN are not NRC

requirements; therefore, no specific action or written response is required.

DESCRIPTION OF CIRCUMSTANCES

On June 13, 2008, at Forsmark Unit 2 in Sweden, lightning strikes caused a short circuit on the

offsite power grid. This resulted in a transient that tripped all eight reactor recirculation pumps.

Each recirculation pump circuit contains an integral flywheel to prevent a rapid reduction in

pump speed. The mass of the rotating flywheel stores mechanical energy that is converted to

electrical power by a flywheel-generator and inverter/rectifier to continue to power the drive

system DC-bus (one DC-bus common for two pump-drive inverters) upon a dip in or loss of the

normal electrical power. When the inverter/rectifier is operable, the alternate power allows for

an unchanged pump speed (in case of power dips) or a more gradual reduction in pump speed

(in case of significant loss, signaled by equipment protection). In the case of a reactor

recirculation pump, the coastdown produces a correspondingly more gradual reduction in

recirculation flow. However, at Forsmark Unit 2, the lightning strike tripped the normal electric

power rectifier due to a sensitive protection setting; furthermore, due to a design flaw, the

protective action was not signaled to the inverter/rectifier controller for the flywheel-generator. As a result, the recirculation pump motors rapidly consumed the flywheel-generators stored

energy. With no available energy storage, the recirculation pumps reduced speed faster than

the assumed transient analyses in the Forsmark Unit 2 safety analysis report. The reduced

coastdown time resulted in a short violation of the safety limit minimum critical power ratio on

84 core channels/fuel elements and a transient dryout condition in 18 of those core channels.

Based on its review of the analysis and inspection results that revealed no fuel damage, the

Swedish Radiation Safety Authority granted the licensees request for continued use of the

affected fuel.

On May 30, 2008, Olkiluoto Unit 1 in Finland had a reactor trip from 60 percent power. An

electrical transient resulted in a common cause failure that caused all six recirculation pumps to

stop unexpectedly. Although the coastdown of the recirculation pumps was shorter than

expected, the transient had no effect on fuel integrity.

BACKGROUND

Related NRC Generic Communications include the following:

  • NRC IN 96-56, Problems Associated with Testing, Tuning, or Resetting of Digital Control

Systems While at Power, dated October 22, 1996 (Agencywide Documents Access and

Management System (ADAMS) Accession No. ML031050587). This IN highlighted the

importance of evaluating and controlling on-line manipulations of digital control systems, such as resetting a processor or performing on-line software changes, to avoid reactor

transients and plant trips.

  • IN 2010-10, Implementation of a Digital Control System under 10 CFR 50.59, dated

May 28, 2010 (ADAMS Accession No. ML100080281). This IN discusses that for digital

upgrades to systems that are highly safety-significant, a defense-in-depth and diversity

analysis is performed as part of the design process to ensure that the plant has adequate

capability to cope with software common-cause failure vulnerabilities.

DISCUSSION

Unlike Olkiluoto Unit 1 and Forsmark Unit 2, U.S. BWRs do not have recirculation pump designs

that rely on energy storage separate from the recirculation pump motor and generator that could

influence recirculation system flow following a scram. In the U.S. BWR designs, the combined

rotating inertias of the recirculation pump and motor, the motor generator set, and the variable

speed coupling are used to provide a relatively slow coastdown of flow following loss of power

to the drive motors which helps ensure that the core is adequately cooled.

The specific common cause failure that occurred at Olkiluoto and Forsmark is not an issue for

U.S. BWRs. However, digital variable speed drive (VSD) technology may increase the

complexity of the recirculation pump control system and may introduce new failure modes such

as software programming errors, network problems, loss of power, and the failure of control

boards, that can lead to unplanned changes in pump speed. Previous operating experience for

recirculation pump VSD includes instances of unintentional reactivity changes during power

operation. Although the recirculation pump motors are generally non-safety related, as the

industry upgrades their systems to digital VSD, it is important that licensees understand the potential unexpected recirculation pump behaviors that might affect core reactivity or safety

limits. As part of the design process when upgrading to digital VSD technology on recirculation

pump systems, the following are important considerations:

Perform evaluations to identify failure modes for digital VSDs to include sources of

common-cause failure, such as software.

Determine if the consequences of a digital VSD common-cause failure could lead to

reactivity events that have not been analyzed in the plant safety analysis.

Ensure the reactor protection system maintains plant safety within its design basis even

with a common-cause failure.

CONTACT

This IN requires no specific action or written response. Please direct any questions about this

matter to the technical contacts listed below or the appropriate Office of Nuclear Reactor

Regulation (NRR) project manager.

/RA/

/RA by JTappert for/

Timothy McGinty, Director

Glenn Tracy, Director

Division of Policy and Rulemaking

Division of Construction Inspection and

Office of Nuclear Reactor Regulation

Operational Programs

Office of New Reactors

Technical Contacts: Joseph Giantelli, NRR

Pong Chung, NRR

301-415-0504

301-415-2473

E-mail: joseph.giantelli@nrc.gov

E-mail: pong.chung@nrc.gov

Note: NRC generic communications may be found on the NRC public Web site, http://www.nrc.gov, under Electronic Reading Room/Document Collections. potential unexpected recirculation pump behaviors that might affect core reactivity or safety

limits. As part of the design process when upgrading to digital VSD technology on recirculation

pump systems, the following are important considerations:

Perform evaluations to identify failure modes for digital VSDs to include sources of

common-cause failure, such as software.

Determine if the consequences of a digital VSD common-cause failure could lead to

reactivity events that have not been analyzed in the plant safety analysis.

Ensure the reactor protection system maintains plant safety within its design basis even

with a common-cause failure.

CONTACT

This IN requires no specific action or written response. Please direct any questions about this

matter to the technical contacts listed below or the appropriate Office of Nuclear Reactor

Regulation (NRR) project manager.

/RA/

/RA by JTappert for/

Timothy McGinty, Director

Glenn Tracy, Director

Division of Policy and Rulemaking

Division of Construction Inspection and

Office of Nuclear Reactor Regulation

Operational Programs

Office of New Reactors

Technical Contacts: Joseph Giantelli, NRR

Pong Chung, NRR

301-415-0504

301-415-2473

E-mail: joseph.giantelli@nrc.gov

E-mail: pong.chung@nrc.gov

Note: NRC generic communications may be found on the NRC public Web site, http://www.nrc.gov, under Electronic Reading Room/Document Collections.

ADAMS Accession Number: ML101330321

TAC ME3898 OFFICE DIRS/IOEB

DE/EICB

Tech Editor

BC/DIRS/IOEB

BC/D/EICB

D/NRR/DE

NAME

JGiantelli

PChung

CHsu

JThorp

BKemper

PHiland

DATE

07/27/10

07/27/10

08/15/10 e-mail 07/27/10

07/27/10

07/28/10

OFFICE NRR/PGCB

NRR/PGCB

BC/NRR/PGCB DD/OIP

D/NRO/DCIP

D/NRR/ DPR

NAME

CHawes

DBeaulieu

SRosenberg

SMoore

GTracy JTappert

for

TMcGinty

OFFICE 08/26/10

08/25/10

08/26/10

09/09/10

09/10/10

09/10/10

OFFICIAL RECORD COPY


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