ML13246A318: Difference between revisions
StriderTol (talk | contribs) (Created page by program invented by StriderTol) |
StriderTol (talk | contribs) (Created page by program invented by StriderTol) |
||
Line 18: | Line 18: | ||
=Text= | =Text= | ||
{{#Wiki_filter:1Burkhardt, | {{#Wiki_filter:1Burkhardt, Janet From:Kalyanam, Kaly Sent:Wednesday, August 28, 2013 9:02 AM To:PELLEGRIN, BRYAN J (BPELLEG@entergy.com) | ||
Cc:Burkhardt, Janet | |||
==Subject:== | ==Subject:== | ||
RAI on Licensee's letter dated February 28, 2013, re. Requirements for Reliable SFP InstrumentationSUNSI Information: | RAI on Licensee's letter dated February 28, 2013, re. Requirements for Reliable SFP InstrumentationSUNSI Information: | ||
Licensee: Entergy Operations Inc. | |||
Plant: Waterford Steam | Licensee: Entergy Operations Inc. | ||
Plant: Waterford Steam El ectric Station, Unit 3 Docket No.: 50/382 From: N. Kalyanam | |||
To: Bryan Pellegrin | |||
==Subject:== | ==Subject:== | ||
RAI on Licensee's letter dated February 28, 2013, re. Requirements for Reliable SFP Instrumentation TAC No.: MF0946 SUNSI Review Done: Yes. | RAI on Licensee's letter dated February 28, 2013, re. Requirements for Reliable SFP Instrumentation | ||
Publicly Available, Normal Release, Non-sensitive, | |||
TAC No.: MF0946 | |||
SUNSI Review Done: Yes. | |||
Publicly Available, Normal Release, Non-sensitive, | |||
To: Bryan Pellegrin | To: Bryan Pellegrin | ||
By letter dated February 28, 2013 (Agencywide Documents Access and | By letter dated February 28, 2013 (Agencywide Documents Access and Managemen t System (ADAMS) Accession No. ML13063A263), Entergy Operations, Inc. submitted an Overall Integrated Plan (OIP) in response to the March 12, 2012, Commission Order to modify licenses with regard to requirements for Reliable | ||
Spent Fuel Pool (SFP) Instrumentation (Order Number EA-12-051) for Waterford Steam Electric Station, Unit 3. The NRC staff has identified additional information that is needed to complete the Technical Review (TR). The staff's Request for Additional Information (RAI) is as below. | |||
Thanks (Kaly) N. Kalyanam | Thanks (Kaly) N. Kalyanam | ||
REQUEST FOR ADDITIONAL INFORMATION 2OVERALL INTEGRATED PLAN IN RESPONSE TO ORDER EA-12-051 "RELIABLE SPENT FUEL POOL INSTRUMENTATION" ENTERGY OPERATIONS, INC WATERFORD STEAM ELECTRIC STATION, UNIT 3 DOCKET NO. 50-382 | REQUEST FOR ADDITIONAL INFORMATION 2OVERALL INTEGRATED PLAN IN RESPONSE TO ORDER EA-12-051 "RELIABLE SPENT FUEL POOL INSTRUMENTATION" ENTERGY OPERATIONS, INC WATERFORD STEAM ELECTRIC STATION, UNIT 3 DOCKET NO. 50-382 | ||
==1.0 INTRODUCTION== | ==1.0 INTRODUCTION== | ||
By letter dated February 28, 2013 (Agencywide Documents Access and | |||
By letter dated February 28, 2013 (Agencywide Documents Access and Managemen t System (ADAMS) Accession No. ML13063A263), Entergy Operations, Inc. submitted an Overall Integrated Plan (OIP) in response to the March 12, 2012, Commission Order modifying licenses with regard to requirements for Reliable Spent Fuel Pool (SFP) Instrumentation (Order Number EA-12-051; ADAMS Accession No. | |||
ML12054A679) for Waterford Steam Electric Station, Unit 3. The NRC staff endorsed Nuclear Energy Institute (NEI) 12-02 "Industry Guidance for Compliance with NRC Order EA-12-051, to Modify Licenses with Regard to Reliable Spent Fuel Pool Instrumentation," Revision 1, dated August 2012 (ADAMS Accession No. | ML12054A679) for Waterford Steam Electric Station, Unit 3. The NRC staff endorsed Nuclear Energy Institute (NEI) 12-02 "Industry Guidance for Compliance with NRC Order EA-12-051, to Modify Licenses with Regard to Reliable Spent Fuel Pool Instrumentation," Revision 1, dated August 2012 (ADAMS Accession No. | ||
ML12240A307), with exceptions, as documented in Interim Staff Guidance (ISG) 2012-03 "Compliance with Order EA-12-051, Reliable Spent Fuel Pool Instrumentation," Revision 0, dated August 29, 2012 (ADAMS Accession No. ML12221A339). | ML12240A307), with exceptions, as documented in Interim Staff Guidance (ISG) 2012-03 "Compliance with Order EA-12-051, Reliable Spent Fuel Pool Instrumentation," Revision 0, dated August 29, 2012 (ADAMS Accession No. ML12221A339). | ||
The NRC staff has reviewed the February 28, 2013, response by the licensee and determined that the following Request for Additional Information (RAI) is needed to complete its Technical Review. If any part of this information is not available within the 30-day response period for this RAI, please provide the date this information will be submitted. | The NRC staff has reviewed the February 28, 2013, response by the licensee and determined that the following Request for Additional Information (RAI) is needed to complete its Technical Review. If any part of this information is not available within the 30-day response period for this RAI, please provide the date this information will be submitted. | ||
2.0 LEVELS OF REQUIRED MONITORING The OIP states, in part, that LEVEL 1: Level 1 is the level adequate to support operation of the normal fuel pool cooling system. It is the higher of the following two points: (1) the level at which reliable suction loss occurs due to uncovering the coolant inlet pipe or any weirs or vacuum breakers associated with suction loss. For Waterford, this level, (1), is established based on the level at which the SFP cooling pumps automatically trip which is at elevation 41 feet 6 inches (Reference 6). This elevation is above the point where the pumps lose suction (Reference 7). (2) the level at which the normal fuel pool cooling pumps lose required NPSH assuming saturated conditions in the pool. An evaluation will be completed to demonstrate that this elevation is below the elevation that defines Level 1. The higher of the above points is (1). Therefore, LEVEL 1 is elevation 41 feet 6 inches. | 2.0 LEVELS OF REQUIRED MONITORING | ||
3LEVEL 2: Level 2 is the level adequate to provide substantial radiation shielding for a person standing on the spent fuel pool operating deck. Level 2 may be based on either of the following: | |||
(2) A designated level that provides adequate radiation shielding to maintain personnel dose within acceptable limits while performing local operations in the vicinity of the pool. This level is based on plant-specific or appropriate generic shielding calculations. The elevation associated with this level is not calculated since item (1) is used to establish Level 2 as permitted by NEI 12-02 Revision 1. Therefore, LEVEL 2 is elevation 30 feet 0 inches + 1 foot (i.e., 10 feet above Level 3). LEVEL 3: Level 3 is the level where fuel remains covered. It is defined as the highest point of any fuel rack seated in the spent fuel pool (within + 1 foot). The highest point of any fuel rack seated in the spent fuel pool is elevation 20 feet 0 inches (Reference 8 and 9). Therefore, Level 3 is elevation 20 feet 0 inches + 1 foot. The SFP level instrument span will extend down to at least 3 inches below the upper limit of the range of LEVEL 3 to account for accuracy or instrument loop uncertainty. Therefore, the SFP level probe will extend down to at least elevation 20 feet 9 inches. RAI-1 Please provide the following: | The OIP states, in part, that | ||
Please provide a discussion regarding dose rates for stored spent fuel versus that of other material that may be stored in the pool. | |||
43.0 INSTRUMENTATION DESIGN FEATURES | LEVEL 1: Level 1 is the level adequate to support operation of the normal fuel pool cooling system. It is the higher of the following two points: | ||
(1) the level at which reliable suction loss occurs due to uncovering the coolant inlet pipe or any weirs or vacuum breakers associated with suction loss. For Waterford, this level, (1), is established based on the level at which the SFP cooling pumps automatically trip which is at elevation 41 feet 6 inches (Reference 6). This elevation is above the point where the pumps lose suction (Reference 7). | |||
(2) the level at which the normal fuel pool cooling pumps lose required NPSH assuming saturated conditions in the pool. An evaluation will be completed to demonstrate that this elevation is below the elevation that defines Level 1. The higher of the above points is (1). Therefore, LEVEL 1 is elevation 41 feet 6 inches | |||
. | |||
3LEVEL 2: Level 2 is the level adequate to provide substantial radiation shielding for a person standing on the spent fuel pool operating deck. Level 2 may be based on either of the following: | |||
(1) 10 feet + 1 foot above the highest point of any fuel rack seated in the spent fuel pool. The elevation associated with this level is 30 feet 0 inches + 1 foot (i.e., Level 3+10 feet). | |||
(2) A designated level that provides adequate radiation shielding to maintain personnel dose within acceptable limits while performing local operations in the vicinity of the pool. This level is based on plant-specific or appropriate generic shielding calculations. The elevation associated with this level is not calculated since item (1) is used to establish Level 2 as | |||
permitted by NEI 12-02 Revision 1. Therefore, LEVEL 2 is elevation 30 feet 0 inches + 1 foot (i.e., 10 feet above Level 3). | |||
LEVEL 3: Level 3 is the level where fuel remains covered. It is defined as the highest point of any fuel rack seated in the spent fuel pool (within + 1 foot). The highest point of any fuel rack seated in the spent fuel pool is elevation 20 feet 0 inches (Reference 8 and 9). Therefore, Level 3 is elevation 20 feet 0 inches + 1 foot. The SFP level instrument span will extend down to at least 3 inches below the upper limit of the range of LEVEL 3 to account for accuracy or instrument loop uncertainty. Therefore, the SFP level probe will extend down to at least elevation 20 feet 9 inches. | |||
RAI-1 Please provide the following: | |||
a) Specifically, for level 1, demonstrate that the results of the evaluation described shows that the identified elevation represents the HIGHER of the two points described in the NEI 12-02 guidance | |||
for this level. | |||
b) A clearly labeled sketch depicting the elevation view of the proposed typical mounting arrangement for the portions of instrument channel consisting of permanent measurement channel equipment (e.g., fixed level sensors and/or stilling wells, and mounting brackets). Indicate on this sketch the datum values representing Level 1, Level 2, and Level 3 as well as the top of the fuel racks. Indicate on this sketch the portion of the level sensor measurement range that is sensitive to measurement of the fuel pool level, with respect to the Level 1, Level 2, and Level 3 datum points. | |||
c) The OIP states, in section 3.3, Mounting, "Other hardware stored in the SFP will be evaluated to ensure that it does not adversely interact with the SFP instrument probes during a seismic event." | |||
Please provide a discussion regarding dose rates for stored spent fuel versus that of other material that may be stored in the pool. | |||
43.0 INSTRUMENTATION DESIGN FEATURES 3.2 Arrangement The OIP states, in part, that | |||
Level instruments will be installed in the approximate locations shown on Attachment 1. Separation of the channels/probes reduces the potential for falling debris or missiles affecting both channels of instrumentation. This placement coupled with separate routing paths for cables and use of rigid conduit provides reasonable protection against falling debris and structural damage. | |||
The location of the display/processors is in the Reactor Auxiliary Building as shown on Attachments 1 and 2. This building is expected to be a mild environment after a Beyond Design Basis External (BDBE) event and can be easily accessed from the Main Control Room; therefore, personnel can promptly obtain readings from the display. This building provides adequate protection against the effects of temperature, flood, humidity, radiation, seismic events, and missile hazards. | |||
RAI-2 Please modify the marked-up plant drawing of the plan view (in Attachment 1, Page 1 of 2) of the SFP area, to depict the approximate SFP inside dimensions. | |||
3.3 Mounting The OIP states, in part, that | |||
Both the primary and backup system will be installed as seismic category I to meet the NRC JLD-ISG-2012-03 and NEI 12-02 guidance requirements. | |||
Other hardware stored in the SFP will be evaluated to ensure that it does not adversely interact | |||
with the SFP instrument probes during a seismic event. | |||
RAI-3 Please provide the following: | |||
a) The design criteria that will be used to estimate the total loading on the mounting device(s), including static weight loads and dynamic loads. Describe the methodology that will be used to estimate the total loading, inclusive of design basis maximum seismic loads and the hydrodynamic loads that could result from pool sloshing or other effects that could accompany such seismic forces. | |||
b) A description of the manner in which the level sensor (and stilling well, if appropriate) will be attached to the refueling floor and/or other support structures for each planned point of attachment of the probe assembly. Indicate in a schematic the 5c) portions of the level sensor that will serve as points of attachment for mechanical/mounting or electrical connections. | |||
d) A description of the manner by which the mechanical connections will attach the level instrument to permanent SFP structures so as to support the level sensor assembly. | |||
e) A description of how other material stored in the SFP will not create adverse interaction with the fixed instrument location(s). | |||
3.4 Qualification | |||
3. | The OIP states, in part, that Design criteria will ensure instrument channel reliability during normal, event, and post-event conditions for no fewer than seven days or until off-site resources can be deployed. Analyses, operating experience, and/or manufacturer testing of channel components will be used to validate design criteria and will consider the following: | ||
* Post event conditions in the area of instrument channel components | * Post event conditions in the area of instrument channel components | ||
* Effects of shock and vibration on all instrument channel components | * Effects of shock and vibration on all instrument channel components | ||
* Seismic effects on instrument channel components during and following a potential seismic event. RAI-4 Please provide the following: | * Seismic effects on instrument channel components during and following a potential seismic event. RAI-4 Please provide the following: | ||
a) A description of the specific method or combination of methods you intend to apply to demonstrate the reliability of the permanently installed equipment under Beyond-Design-Basis (BDB) ambient temperature, humidity, shock, vibration, and radiation conditions. | |||
b) A description of the testing and/or analyses that will be conducted to provide assurance that the equipment will perform reliably under the worst-case credible design basis loading at the location where the equipment will be mounted. Include a discussion of this seismic reliability demonstration as it applies to a) the level sensor mounted in the SFP area, and b) any control boxes, electronics, or read-out and re-transmitting devices that will be employed to convey the level information from the level sensor to the plant operators or emergency responders. c) A description of the specific method or combination of methods that will be used to confirm the reliability of the permanently installed equipment such that following a seismic event the instrument will maintain its required accuracy. | a) A description of the specific method or combination of methods you intend to apply to demonstrate the reliability of the permanently installed equipment under Beyond-Design-Basis (BDB) ambient temperature, humidity, shock, vibration, and radiation conditions. | ||
63.5 Independence | |||
a) A description of how the two channels of the proposed level measurement system in each pool meet this requirement so that the potential for a common cause event to adversely affect both channels is minimized to the extent practicable. | b) A description of the testing and/or analyses that will be conducted to provide assurance that the equipment will perform reliably under the worst-case credible design basis loading at the location where the equipment will be mounted. Include a discussion of this seismic reliability demonstration as it applies to a) the level sensor mounted in the SFP area, and b) any control boxes, electronics, or read-out and re-transmitting devices that will be employed to convey the level information from the level sensor to the plant operators or emergency responders. | ||
b) Further information describing the design and installation of each level measurement system, consisting of level sensor electronics, cabling, and readout devices. Please address how independence of signals sent to the location(s) of the readout devices, and the independence of the displays. 3.6 Power Supplies | c) A description of the specific method or combination of methods that will be used to confirm the reliability of the permanently installed equipment such that following a seismic event the instrument will maintain its required accuracy. | ||
63.5 Independence The OIP states, in part, that The primary instrument channel will be independent of the backup instrument channel. Independence is obtained by physical separation of components between channels and the use of normal power supplied from separate 480V buses. Independence of power sources is described in Section 11. The two (2) permanently mounted instruments in the pool are physically separated as described in Sections 6 and 7. | |||
RAI-5 Please provide the following: | |||
a) A description of how the two channels of the proposed level measurement system in each pool meet this requirement so that the potential for a common cause event to adversely affect both channels is minimized to the extent practicable. | |||
b) Further information describing the design and installation of each level measurement system, consisting of level sensor electronics, cabling, and readout devices. Please address how independence of signals sent to the location(s) of the readout devices, and the independence of the displays. | |||
3.6 Power Supplies The OIP states, in part, that The power supplies for the instrument channels are shown on Attachment 2 and arranged as follows: | |||
* Each instrument channel is normally powered from 120VAC 60 Hz plant power to support continuous monitoring of SFP level. The primary channel receives power from a different 480V bus than the backup channel. Therefore, loss of any one 480V bus does not result in loss of normal 120VAC power for both instrument channels. | * Each instrument channel is normally powered from 120VAC 60 Hz plant power to support continuous monitoring of SFP level. The primary channel receives power from a different 480V bus than the backup channel. Therefore, loss of any one 480V bus does not result in loss of normal 120VAC power for both instrument channels. | ||
* On loss of normal 120VAC power, each | * On loss of normal 120VAC power, each c hannel's UPS automatically transfers to a dedicated backup battery. If normal power is restored, the channel will automatically transfers back to the normal AC power. | ||
* The backup batteries are maintained in a charged state by commercial-grade uninterruptible power supplies. The batteries are sized to be capable of supporting intermittent monitoring for a minimum of 3 days of operation. This provides adequate time to allow the batteries to be replaced or until off-site resources can be deployed by the mitigating strategies resulting from Order EA-12-049 Revision 0. | * The backup batteries are maintained in a charged state by commercial-grade uninterruptible power supplies. The batteries are sized to be capable of supporting intermittent monitoring for a minimum of 3 days of operation. This provides adequate time to allow the batteries to be replaced or until off-site resources can be deployed by the mitigating strategies resulting from Order EA-12-049 Revision 0. | ||
7* An external connection permits powering the system from any portable DC source. | 7* An external connection permits powering the system from any portable DC source. | ||
* Instrument accuracy and performance are not affected by restoration of power or restarting the processor. RAI-6 Please provide the following: | * Instrument accuracy and performance are not affected by restoration of power or restarting the processor. | ||
RAI-6 Please provide the following: | |||
a) A description of the specific electrical AC power sources and capacities for the primary and backup channels. | |||
b) A description of the design criteria that will be applied to size the battery in a manner that ensures, with margin, that the channel will be available to run reliably and continuously following the onset of the BDB event for the minimum duration needed, consistent with the plant mitigation strategies for BDB external events (Order EA-12-049). | |||
3.7 Accuracy | |||
The OIP states, in part, that Accuracy will be consistent with the guidelines of NRC JLD-ISG-2012-03 Revision 0 and NEI 12-02 Revision 1. Accuracy and indication features are as follows: | |||
* Accuracy: The absolute system accuracy is better than + 3 inches. This accuracy is applicable for normal conditions and the temperature, humidity, chemistry, and radiation levels expected for BDBE event conditions. | * Accuracy: The absolute system accuracy is better than + 3 inches. This accuracy is applicable for normal conditions and the temperature, humidity, chemistry, and radiation levels expected for BDBE event conditions. | ||
* Trending: The display trends and retains data when powered from either normal or backup power. | * Trending: The display trends and retains data when powered from either normal or backup power. | ||
* Restoration after Loss of Power: The system automatically swaps to available power (backup battery power or external DC source) when normal power is lost. Neither the source of power nor system restoration | * Restoration after Loss of Power: The system automatically swaps to available power (backup battery power or external DC source) when normal power is lost. Neither the source of power nor system restoration impac t accuracy. Previously collected data is retained. | ||
* Diagnostics: The system performs and displays the results of real-time information related to the integrity of the cable, probe, and instrument channel. | * Diagnostics: The system performs and displays the results of real-time information related to the integrity of the cable, probe, and instrument channel. | ||
8RAI-7 Please provide the following: | 8RAI-7 Please provide the following: | ||
3.8 Testing The OIP states, in part, that | a) An estimate of the expected instrument channel accuracy performance (e.g., in % of span) under both a) normal SFP level conditions (approximately Level 1 or higher) and b) at the BDB conditions (i.e., radiation, temperature, humidity, post-seismic and post-shock conditions) that would be present if the SFP level were at the Level 2 and Level 3 datum points. | ||
The display/processor performs automatic in-situ calibration and automatically monitors for cable, connector, and probe faults using time domain reflectometry (TDR) technology. Channel degradation due to age or corrosion is not expected but can be identified by monitoring trends. | b) A description of the methodology that will be used for determining the maximum allowed deviation from the instrument channel design accuracy that will be employed under normal operating conditions as an acceptance criterion for a calibration procedure to flag to operators and to technicians that the channel requires adjustment to within the normal condition design accuracy. | ||
Station procedures and preventive maintenance tasks will be developed to perform required surveillance testing, calibration, backup battery maintenance, functional checks, and visual inspections of the probes. | |||
RAI- 8 Please provide the following: | 3.8 Testing | ||
a) A description of the capability and provisions the proposed level sensing equipment will have to enable periodic testing and calibration, including how this capability enables the equipment to be tested in-situ. b) A description of how such testing and calibration will enable the conduct of regular channel checks of each independent channel against the other, and against any other permanently-installed SFP level instrumentation. c) A description of how calibration tests and functional checks will be performed and the frequency at which they will be conducted. Discuss how these surveillances will be incorporated into the plant surveillance program. | |||
9d) A description of what preventative maintenance tasks are required to be performed during normal operation, and the planned maximum surveillance interval that is necessary to ensure that the channels are fully conditioned to accurately and reliably perform their functions when needed. 3.9 Display | The OIP states, in part, that Testing and calibration will be consistent with the guidelines of NRC JLD-ISG-2012-03 Revision 0 and NEI 12-02 Revision 1 and vendor recommendations. | ||
RAI-9 Please provide the following: | |||
b) The reasons justifying why the locations selected will enable the information from these instruments to be considered "promptly accessible". Include consideration of various drain-down scenarios. 4.0 PROGRAM FEATURES | The display/processor performs automatic in-situ calibration and automatically monitors for cable, connector, and probe faults using time domain reflectometry (TDR) technology. Channel degradation due to age or corrosion is not expected but can be identified by monitoring trends. | ||
Station procedures and preventive maintenance tasks will be developed to perform required surveillance testing, calibration, backup battery maintenance, functional checks, and visual inspections of the probes. | |||
RAI- 8 Please provide the following: | |||
a) A description of the capability and provisions the proposed level sensing equipment will have to enable periodic testing and calibration, including how this capability enables the equipment to be tested in-situ. | |||
b) A description of how such testing and calibration will enable the conduct of regular channel checks of each independent channel against the other, and against any other permanently-installed SFP level instrumentation. | |||
c) A description of how calibration tests and functional checks will be performed and the frequency at which they will be conducted. Discuss how these surveillances will be incorporated into the plant surveillance program. | |||
9d) A description of what preventative maintenance tasks are required to be performed during normal operation, and the planned maximum surveillance interval that is necessary to ensure that the channels are fully conditioned to accurately and reliably perform their functions when needed. | |||
3.9 Display The OIP states, in part, that | |||
The primary and backup instrument displays will be located in the Reactor Auxiliary Building as shown on Attachments 1 and 2 | |||
. The display will be consistent with the guidelines of NRC JLD-ISG-2012-03 Revision 0 and NEI | |||
12-02 Revision 1. | |||
RAI-9 Please provide the following: | |||
a) For display locations that are not within the main control room, provide a description of the display location that addresses primary and alternate access route evaluation, continuous habitability at display location(s), continual resource availability for personnel responsible to promptly read displays, and provisions for verbal communications with decision makers for the various SFP drain down scenarios | |||
and external events. | |||
b) The reasons justifying why the locations selected will enable the information from these instruments to be considered "promptly accessible". Include consideration of various drain-down scenarios. | |||
4.0 PROGRAM FEATURES 4.2 Procedures | |||
The OIP states, in part, that Procedures for maintenance and testing will be developed using regulatory guidelines and vendor instructions. | |||
BDBE event operation guidance will also address the following: | BDBE event operation guidance will also address the following: | ||
* A strategy to ensure SFP water addition is initiated at an appropriate time consistent with implementation of NEI 12-06. | * A strategy to ensure SFP water addition is initiated at an appropriate time consistent with implementation of NEI 12-06. | ||
* Restoration of non-functioning SFP level channels after an event 10* Restoration timing will be consistent with the emergency condition. After an event, commercially available components that may not meet all qualifications may be used to replace components to restore functionality. RAI-10 Please provide the following: | * Restoration of non-functioning SFP level channels after an event | ||
a) A list of the operating (both normal and abnormal response) procedures, calibration/test procedures, maintenance procedures, and inspection procedures that will be developed for use of the SFP instrumentation in a manner that addresses the order requirements. b) A brief description of the specific technical objectives to be achieved within each procedure. If your plan incorporates the use of portable spent fuel level monitoring components, please include a description of the objectives to be achieved with regard to the storage location and provisions for installation of the portable components when needed. 4.3 Testing and Calibration | |||
10* Restoration timing will be consistent with the emergency condition. After an event, commercially available components that may not meet all qualifications may be used to replace components to restore functionality. | |||
RAI-10 Please provide the following: | |||
a) A list of the operating (both normal and abnormal response) procedures, calibration/test procedures, maintenance procedures, and inspection procedures that will be developed for use of the SFP instrumentation in a manner that addresses the order requirements. | |||
b) A brief description of the specific technical objectives to be achieved within each procedure. If your plan incorporates the use of portable spent fuel level monitoring components, please include a description of the objectives to be achieved with regard to the storage location and provisions for installation of the portable components when needed. | |||
4.3 Testing and Calibration The OIP states, in part, that | |||
Testing and calibration will be consistent with the guidelines of NRC JLD-ISG-2012- 03 Revision 0 and NEI 12-02 Revision 1 and vendor recommendations. | |||
Station procedures and preventive maintenance tasks will be developed to perform required surveillance testing, calibration, backup battery maintenance, functional checks, and visual inspections of the probes. | |||
RAI-11 Please provide the following: | |||
a) Further information describing the maintenance and testing program the licensee will establish and implement to ensure that regular testing and calibration is performed and verified by inspection and audit to demonstrate conformance with design and system readiness requirements. Include a description of your plans for ensuring that necessary channel checks, functional tests, periodic calibration, and maintenance will be conducted for the level measurement system and its supporting equipment. | |||
b) A description of how the guidance in NEI 12-02 Section 4.3 regarding compensatory actions for one or both non-functioning channels will be addressed. | |||
a) Further information describing the maintenance and testing program the licensee will establish and implement to ensure that regular testing and calibration is performed and verified by inspection and audit to demonstrate conformance with design and system readiness requirements. Include a description of your plans for ensuring that necessary channel checks, functional tests, periodic calibration, and maintenance will be conducted for the level measurement system and its supporting equipment. b) A description of how the guidance in NEI 12-02 Section 4.3 regarding compensatory actions for one or both non-functioning channels will be addressed. | |||
}} | c) A description of the compensatory actions to be taken in the event that one of the instrument channels cannot be restored to functional status within 90 days. a.}} |
Revision as of 08:53, 4 July 2018
ML13246A318 | |
Person / Time | |
---|---|
Site: | Waterford |
Issue date: | 08/28/2013 |
From: | Kalyanam K Plant Licensing Branch IV |
To: | Pellegrin B J Entergy Operations |
Kalyanam N | |
References | |
TAC MF0946 | |
Download: ML13246A318 (10) | |
Text
1Burkhardt, Janet From:Kalyanam, Kaly Sent:Wednesday, August 28, 2013 9:02 AM To:PELLEGRIN, BRYAN J (BPELLEG@entergy.com)
Cc:Burkhardt, Janet
Subject:
RAI on Licensee's letter dated February 28, 2013, re. Requirements for Reliable SFP InstrumentationSUNSI Information:
Licensee: Entergy Operations Inc.
Plant: Waterford Steam El ectric Station, Unit 3 Docket No.: 50/382 From: N. Kalyanam
To: Bryan Pellegrin
Subject:
RAI on Licensee's letter dated February 28, 2013, re. Requirements for Reliable SFP Instrumentation
SUNSI Review Done: Yes.
Publicly Available, Normal Release, Non-sensitive,
To: Bryan Pellegrin
By letter dated February 28, 2013 (Agencywide Documents Access and Managemen t System (ADAMS) Accession No. ML13063A263), Entergy Operations, Inc. submitted an Overall Integrated Plan (OIP) in response to the March 12, 2012, Commission Order to modify licenses with regard to requirements for Reliable
Spent Fuel Pool (SFP) Instrumentation (Order Number EA-12-051) for Waterford Steam Electric Station, Unit 3. The NRC staff has identified additional information that is needed to complete the Technical Review (TR). The staff's Request for Additional Information (RAI) is as below.
Thanks (Kaly) N. Kalyanam
REQUEST FOR ADDITIONAL INFORMATION 2OVERALL INTEGRATED PLAN IN RESPONSE TO ORDER EA-12-051 "RELIABLE SPENT FUEL POOL INSTRUMENTATION" ENTERGY OPERATIONS, INC WATERFORD STEAM ELECTRIC STATION, UNIT 3 DOCKET NO. 50-382
1.0 INTRODUCTION
By letter dated February 28, 2013 (Agencywide Documents Access and Managemen t System (ADAMS) Accession No. ML13063A263), Entergy Operations, Inc. submitted an Overall Integrated Plan (OIP) in response to the March 12, 2012, Commission Order modifying licenses with regard to requirements for Reliable Spent Fuel Pool (SFP) Instrumentation (Order Number EA-12-051; ADAMS Accession No.
ML12054A679) for Waterford Steam Electric Station, Unit 3. The NRC staff endorsed Nuclear Energy Institute (NEI) 12-02 "Industry Guidance for Compliance with NRC Order EA-12-051, to Modify Licenses with Regard to Reliable Spent Fuel Pool Instrumentation," Revision 1, dated August 2012 (ADAMS Accession No.
ML12240A307), with exceptions, as documented in Interim Staff Guidance (ISG) 2012-03 "Compliance with Order EA-12-051, Reliable Spent Fuel Pool Instrumentation," Revision 0, dated August 29, 2012 (ADAMS Accession No. ML12221A339).
The NRC staff has reviewed the February 28, 2013, response by the licensee and determined that the following Request for Additional Information (RAI) is needed to complete its Technical Review. If any part of this information is not available within the 30-day response period for this RAI, please provide the date this information will be submitted.
2.0 LEVELS OF REQUIRED MONITORING
The OIP states, in part, that
LEVEL 1: Level 1 is the level adequate to support operation of the normal fuel pool cooling system. It is the higher of the following two points:
(1) the level at which reliable suction loss occurs due to uncovering the coolant inlet pipe or any weirs or vacuum breakers associated with suction loss. For Waterford, this level, (1), is established based on the level at which the SFP cooling pumps automatically trip which is at elevation 41 feet 6 inches (Reference 6). This elevation is above the point where the pumps lose suction (Reference 7).
(2) the level at which the normal fuel pool cooling pumps lose required NPSH assuming saturated conditions in the pool. An evaluation will be completed to demonstrate that this elevation is below the elevation that defines Level 1. The higher of the above points is (1). Therefore, LEVEL 1 is elevation 41 feet 6 inches
.
3LEVEL 2: Level 2 is the level adequate to provide substantial radiation shielding for a person standing on the spent fuel pool operating deck. Level 2 may be based on either of the following:
(1) 10 feet + 1 foot above the highest point of any fuel rack seated in the spent fuel pool. The elevation associated with this level is 30 feet 0 inches + 1 foot (i.e., Level 3+10 feet).
(2) A designated level that provides adequate radiation shielding to maintain personnel dose within acceptable limits while performing local operations in the vicinity of the pool. This level is based on plant-specific or appropriate generic shielding calculations. The elevation associated with this level is not calculated since item (1) is used to establish Level 2 as
permitted by NEI 12-02 Revision 1. Therefore, LEVEL 2 is elevation 30 feet 0 inches + 1 foot (i.e., 10 feet above Level 3).
LEVEL 3: Level 3 is the level where fuel remains covered. It is defined as the highest point of any fuel rack seated in the spent fuel pool (within + 1 foot). The highest point of any fuel rack seated in the spent fuel pool is elevation 20 feet 0 inches (Reference 8 and 9). Therefore, Level 3 is elevation 20 feet 0 inches + 1 foot. The SFP level instrument span will extend down to at least 3 inches below the upper limit of the range of LEVEL 3 to account for accuracy or instrument loop uncertainty. Therefore, the SFP level probe will extend down to at least elevation 20 feet 9 inches.
RAI-1 Please provide the following:
a) Specifically, for level 1, demonstrate that the results of the evaluation described shows that the identified elevation represents the HIGHER of the two points described in the NEI 12-02 guidance
for this level.
b) A clearly labeled sketch depicting the elevation view of the proposed typical mounting arrangement for the portions of instrument channel consisting of permanent measurement channel equipment (e.g., fixed level sensors and/or stilling wells, and mounting brackets). Indicate on this sketch the datum values representing Level 1, Level 2, and Level 3 as well as the top of the fuel racks. Indicate on this sketch the portion of the level sensor measurement range that is sensitive to measurement of the fuel pool level, with respect to the Level 1, Level 2, and Level 3 datum points.
c) The OIP states, in section 3.3, Mounting, "Other hardware stored in the SFP will be evaluated to ensure that it does not adversely interact with the SFP instrument probes during a seismic event."
Please provide a discussion regarding dose rates for stored spent fuel versus that of other material that may be stored in the pool.
43.0 INSTRUMENTATION DESIGN FEATURES 3.2 Arrangement The OIP states, in part, that
Level instruments will be installed in the approximate locations shown on Attachment 1. Separation of the channels/probes reduces the potential for falling debris or missiles affecting both channels of instrumentation. This placement coupled with separate routing paths for cables and use of rigid conduit provides reasonable protection against falling debris and structural damage.
The location of the display/processors is in the Reactor Auxiliary Building as shown on Attachments 1 and 2. This building is expected to be a mild environment after a Beyond Design Basis External (BDBE) event and can be easily accessed from the Main Control Room; therefore, personnel can promptly obtain readings from the display. This building provides adequate protection against the effects of temperature, flood, humidity, radiation, seismic events, and missile hazards.
RAI-2 Please modify the marked-up plant drawing of the plan view (in Attachment 1, Page 1 of 2) of the SFP area, to depict the approximate SFP inside dimensions.
3.3 Mounting The OIP states, in part, that
Both the primary and backup system will be installed as seismic category I to meet the NRC JLD-ISG-2012-03 and NEI 12-02 guidance requirements.
Other hardware stored in the SFP will be evaluated to ensure that it does not adversely interact
with the SFP instrument probes during a seismic event.
RAI-3 Please provide the following:
a) The design criteria that will be used to estimate the total loading on the mounting device(s), including static weight loads and dynamic loads. Describe the methodology that will be used to estimate the total loading, inclusive of design basis maximum seismic loads and the hydrodynamic loads that could result from pool sloshing or other effects that could accompany such seismic forces.
b) A description of the manner in which the level sensor (and stilling well, if appropriate) will be attached to the refueling floor and/or other support structures for each planned point of attachment of the probe assembly. Indicate in a schematic the 5c) portions of the level sensor that will serve as points of attachment for mechanical/mounting or electrical connections.
d) A description of the manner by which the mechanical connections will attach the level instrument to permanent SFP structures so as to support the level sensor assembly.
e) A description of how other material stored in the SFP will not create adverse interaction with the fixed instrument location(s).
3.4 Qualification
The OIP states, in part, that Design criteria will ensure instrument channel reliability during normal, event, and post-event conditions for no fewer than seven days or until off-site resources can be deployed. Analyses, operating experience, and/or manufacturer testing of channel components will be used to validate design criteria and will consider the following:
- Post event conditions in the area of instrument channel components
- Effects of shock and vibration on all instrument channel components
- Seismic effects on instrument channel components during and following a potential seismic event. RAI-4 Please provide the following:
a) A description of the specific method or combination of methods you intend to apply to demonstrate the reliability of the permanently installed equipment under Beyond-Design-Basis (BDB) ambient temperature, humidity, shock, vibration, and radiation conditions.
b) A description of the testing and/or analyses that will be conducted to provide assurance that the equipment will perform reliably under the worst-case credible design basis loading at the location where the equipment will be mounted. Include a discussion of this seismic reliability demonstration as it applies to a) the level sensor mounted in the SFP area, and b) any control boxes, electronics, or read-out and re-transmitting devices that will be employed to convey the level information from the level sensor to the plant operators or emergency responders.
c) A description of the specific method or combination of methods that will be used to confirm the reliability of the permanently installed equipment such that following a seismic event the instrument will maintain its required accuracy.
63.5 Independence The OIP states, in part, that The primary instrument channel will be independent of the backup instrument channel. Independence is obtained by physical separation of components between channels and the use of normal power supplied from separate 480V buses. Independence of power sources is described in Section 11. The two (2) permanently mounted instruments in the pool are physically separated as described in Sections 6 and 7.
RAI-5 Please provide the following:
a) A description of how the two channels of the proposed level measurement system in each pool meet this requirement so that the potential for a common cause event to adversely affect both channels is minimized to the extent practicable.
b) Further information describing the design and installation of each level measurement system, consisting of level sensor electronics, cabling, and readout devices. Please address how independence of signals sent to the location(s) of the readout devices, and the independence of the displays.
3.6 Power Supplies The OIP states, in part, that The power supplies for the instrument channels are shown on Attachment 2 and arranged as follows:
- Each instrument channel is normally powered from 120VAC 60 Hz plant power to support continuous monitoring of SFP level. The primary channel receives power from a different 480V bus than the backup channel. Therefore, loss of any one 480V bus does not result in loss of normal 120VAC power for both instrument channels.
- On loss of normal 120VAC power, each c hannel's UPS automatically transfers to a dedicated backup battery. If normal power is restored, the channel will automatically transfers back to the normal AC power.
- The backup batteries are maintained in a charged state by commercial-grade uninterruptible power supplies. The batteries are sized to be capable of supporting intermittent monitoring for a minimum of 3 days of operation. This provides adequate time to allow the batteries to be replaced or until off-site resources can be deployed by the mitigating strategies resulting from Order EA-12-049 Revision 0.
7* An external connection permits powering the system from any portable DC source.
- Instrument accuracy and performance are not affected by restoration of power or restarting the processor.
RAI-6 Please provide the following:
a) A description of the specific electrical AC power sources and capacities for the primary and backup channels.
b) A description of the design criteria that will be applied to size the battery in a manner that ensures, with margin, that the channel will be available to run reliably and continuously following the onset of the BDB event for the minimum duration needed, consistent with the plant mitigation strategies for BDB external events (Order EA-12-049).
3.7 Accuracy
The OIP states, in part, that Accuracy will be consistent with the guidelines of NRC JLD-ISG-2012-03 Revision 0 and NEI 12-02 Revision 1. Accuracy and indication features are as follows:
- Accuracy: The absolute system accuracy is better than + 3 inches. This accuracy is applicable for normal conditions and the temperature, humidity, chemistry, and radiation levels expected for BDBE event conditions.
- Trending: The display trends and retains data when powered from either normal or backup power.
- Restoration after Loss of Power: The system automatically swaps to available power (backup battery power or external DC source) when normal power is lost. Neither the source of power nor system restoration impac t accuracy. Previously collected data is retained.
- Diagnostics: The system performs and displays the results of real-time information related to the integrity of the cable, probe, and instrument channel.
8RAI-7 Please provide the following:
a) An estimate of the expected instrument channel accuracy performance (e.g., in % of span) under both a) normal SFP level conditions (approximately Level 1 or higher) and b) at the BDB conditions (i.e., radiation, temperature, humidity, post-seismic and post-shock conditions) that would be present if the SFP level were at the Level 2 and Level 3 datum points.
b) A description of the methodology that will be used for determining the maximum allowed deviation from the instrument channel design accuracy that will be employed under normal operating conditions as an acceptance criterion for a calibration procedure to flag to operators and to technicians that the channel requires adjustment to within the normal condition design accuracy.
3.8 Testing
The OIP states, in part, that Testing and calibration will be consistent with the guidelines of NRC JLD-ISG-2012-03 Revision 0 and NEI 12-02 Revision 1 and vendor recommendations.
The display/processor performs automatic in-situ calibration and automatically monitors for cable, connector, and probe faults using time domain reflectometry (TDR) technology. Channel degradation due to age or corrosion is not expected but can be identified by monitoring trends.
Station procedures and preventive maintenance tasks will be developed to perform required surveillance testing, calibration, backup battery maintenance, functional checks, and visual inspections of the probes.
RAI- 8 Please provide the following:
a) A description of the capability and provisions the proposed level sensing equipment will have to enable periodic testing and calibration, including how this capability enables the equipment to be tested in-situ.
b) A description of how such testing and calibration will enable the conduct of regular channel checks of each independent channel against the other, and against any other permanently-installed SFP level instrumentation.
c) A description of how calibration tests and functional checks will be performed and the frequency at which they will be conducted. Discuss how these surveillances will be incorporated into the plant surveillance program.
9d) A description of what preventative maintenance tasks are required to be performed during normal operation, and the planned maximum surveillance interval that is necessary to ensure that the channels are fully conditioned to accurately and reliably perform their functions when needed.
3.9 Display The OIP states, in part, that
The primary and backup instrument displays will be located in the Reactor Auxiliary Building as shown on Attachments 1 and 2
. The display will be consistent with the guidelines of NRC JLD-ISG-2012-03 Revision 0 and NEI
12-02 Revision 1.
RAI-9 Please provide the following:
a) For display locations that are not within the main control room, provide a description of the display location that addresses primary and alternate access route evaluation, continuous habitability at display location(s), continual resource availability for personnel responsible to promptly read displays, and provisions for verbal communications with decision makers for the various SFP drain down scenarios
and external events.
b) The reasons justifying why the locations selected will enable the information from these instruments to be considered "promptly accessible". Include consideration of various drain-down scenarios.
4.0 PROGRAM FEATURES 4.2 Procedures
The OIP states, in part, that Procedures for maintenance and testing will be developed using regulatory guidelines and vendor instructions.
BDBE event operation guidance will also address the following:
- A strategy to ensure SFP water addition is initiated at an appropriate time consistent with implementation of NEI 12-06.
- Restoration of non-functioning SFP level channels after an event
10* Restoration timing will be consistent with the emergency condition. After an event, commercially available components that may not meet all qualifications may be used to replace components to restore functionality.
RAI-10 Please provide the following:
a) A list of the operating (both normal and abnormal response) procedures, calibration/test procedures, maintenance procedures, and inspection procedures that will be developed for use of the SFP instrumentation in a manner that addresses the order requirements.
b) A brief description of the specific technical objectives to be achieved within each procedure. If your plan incorporates the use of portable spent fuel level monitoring components, please include a description of the objectives to be achieved with regard to the storage location and provisions for installation of the portable components when needed.
4.3 Testing and Calibration The OIP states, in part, that
Testing and calibration will be consistent with the guidelines of NRC JLD-ISG-2012- 03 Revision 0 and NEI 12-02 Revision 1 and vendor recommendations.
Station procedures and preventive maintenance tasks will be developed to perform required surveillance testing, calibration, backup battery maintenance, functional checks, and visual inspections of the probes.
RAI-11 Please provide the following:
a) Further information describing the maintenance and testing program the licensee will establish and implement to ensure that regular testing and calibration is performed and verified by inspection and audit to demonstrate conformance with design and system readiness requirements. Include a description of your plans for ensuring that necessary channel checks, functional tests, periodic calibration, and maintenance will be conducted for the level measurement system and its supporting equipment.
b) A description of how the guidance in NEI 12-02 Section 4.3 regarding compensatory actions for one or both non-functioning channels will be addressed.
c) A description of the compensatory actions to be taken in the event that one of the instrument channels cannot be restored to functional status within 90 days. a.