| author name = Groom J

| addressee name = Halpin E

| contact person = Groom J

{{#Wiki_filter:February 4, 2016

==SUBJECT:==

DIABLO CANYON POWER PLANT - NRC INTEGRATED INSPECTION REPORT 05000275/2015004 and 05000323/2015004

On December 31, 2015, the U.S. Nuclear Regulatory Commission (NRC) completed an inspection at your Diablo Canyon Power Plant Units 1 and 2. On January 11, 2016, the NRC inspectors discussed the results of this inspection with you and other members of your staff.

Inspectors documented the results of this inspection in the enclosed inspection report.

NRC inspectors documented three findings of very low safety significance (Green) in this report.

These findings involved violations of NRC requirements. The NRC is treating these violations as non-cited violations (NCVs) consistent with Section 2.3.2.a of the NRC Enforcement Policy.

 

 

In accordance with Title 10 of the Code of Federal Regulations (10 CFR) 2.390, Public Inspections, Exemptions, Requests for Withholding, a copy of this letter, its enclosure, and your response (if any) will be available electronically for public inspection in the NRCs Public Document Room or from the Publicly Available Records (PARS) component of the NRC's Agencywide Documents Access and Management System (ADAMS). ADAMS is accessible from the NRC Web site at http://www.nrc.gov/reading-rm/adams.html (the Public Electronic Reading Room).

/RA/  

Jeremy R. Groom, Chief Project Branch A Division of Reactor Projects

Docket Nos. 05000275, 05000323 License Nos. DPR-80, DPR-82  

RFI for Inservice Inspection RFI for O

October 1 through December 31, 2015 Inspectors: T. Hipschman, Senior Resident Inspector J. Reynoso, Acting Senior Resident Inspector M. Stafford, Project Engineer R. Alexander, Senior Project Engineer J. Drake, Senior Reactor Inspector N. Greene, PhD, Health Physicist J. ODonnell, CHP, Health Physicist Approved By:

Jeremy Groom, Chief Project Branch A Division of Reactor Projects

- 2 -  

=SUMMARY=

IR 05000275/2015004, 05000323/2015004; 10/01/2015 - 12/31/2015; Diablo Canyon Power

Plant; Fire Protection, Inservice Inspection Activities, Follow-up of Events and Notices of Enforcement Discretion

The inspection activities described in this report were performed between October 1 and December 31, 2015, by the resident inspectors at Diablo Canyon Power Plant and inspectors from the NRCs Region IV office. Three findings of very low safety significance (Green) are documented in this report. All three of these findings involved violations of NRC requirements.

The significance of inspection findings is indicated by their color (Green, White, Yellow, or Red), which is determined using Inspection Manual Chapter 0609, Significance Determination Process. Their cross-cutting aspects are determined using Inspection Manual Chapter 0310,

Aspects within the Cross-Cutting Areas. Violations of NRC requirements are dispositioned in accordance with the NRC Enforcement Policy. The NRCs program for overseeing the safe operation of commercial nuclear power reactors is described in NUREG-1649, Reactor Oversight Process.

: '''Green.'''

The inspectors identified a non-cited violation of Technical Specification 5.4.1.d,

Procedures, for the failure to follow approved fire protection program procedures to review the fire impairments list to assess the aggregate impact on the fire protection design and safe shutdown analysis. Specifically, from August 31 to September 2, 2015, the licensee failed to evaluate the aggregate impact of having three fire doors simultaneously blocked open in adjacent Unit 1 vital battery charger rooms. The licensee implemented immediate corrective actions by assigning a continuous fire watch to the area and documented the issue in the corrective action program as Notification 50826793.

Attachment 4, Phase 1-Initial Screening and Characterization of Findings. Because the finding involved fire protection, the inspectors transitioned to IMC 0609, Appendix F Fire Protection Significance Determination Process. The inspectors characterized the finding using IMC 0609, Appendix F, Attachment 1, "Fire Protection SDP Phase 1 Worksheet," dated September 20, 2013. The finding screened as very low safety significance (Green), per Attachment 1, Question 1.4.3-A since the fire finding category was determined to be fire confinement, due to the fire doors being propped open, and the combustion loading on both sides of the door was determined to be a duration of 30 minutes as documented in licensee calculation M-824, Controlled Combustion Loading Tracking. In addition, the inspectors determined this finding had a cross-cutting aspect in human performance associated with the teamwork component because the licensees work groups did not properly communicate and coordinate their activities within and across organizational boundaries to ensure nuclear safety was maintained. Specifically, the work planners did not properly communicate to the fire protection department that all three fire doors would be open at the same time during battery charger load testing. [H.4] (Section 1R05)  

The inspectors reviewed a self-revealing non-cited violation of 10 CFR Part 50,

Appendix B, Criterion XVI Corrective Action, for the failure to identify the cause and take corrective action to prevent recurrence of a significant condition adverse to quality impacting both trains of the Unit 1 safety-related residual heat removal (RHR) system. Specifically, the licensee failed to identify a definitive cause and implement corrective actions to prevent recurrent failures of the socket weld for relief valve RHR-1-RV-8708 for both trains of the RHR system. As immediate corrective actions, the licensee installed additional piping supports to mitigate the vibrations at the socket weld and documented this issue in the corrective action program as Notification 50680750.

The failure to identify the cause of the RHR vibration-induced problems and to take adequate corrective actions to prevent recurrence of the weld failures was a performance deficiency. The performance deficiency was more than minor, and therefore a finding, because if left uncorrected, it could lead to a more significant safety concern. Specifically, no additional supports were installed and no actions were taken to reduce or eliminate the vibrations to prevent recurring weld failures, which could affect the availability of the RHR system. The lack of corrective actions to prevent recurrence could leave RHR components and other components physically connected to the system susceptible to future failures.

 

Using Inspection Manual Chapter 0609, Appendix A, the inspectors determined the issue to have very low safety significance (Green) because the performance deficiency, which affected the mitigating systems cornerstone, did not result in a loss of safety function and did not result in an actual loss of function for greater than the technical specification allowed outage time. The licensee entered this into their corrective action program as Notification 50680750. In addition, this finding has a cross-cutting aspect in the human performance area associated with conservative bias decision making component because individuals failed to use decision making practices that emphasize prudent choices over those that are simply allowable. Specifically, the licensee chose to only install a fatigue resistance weld rather than install additional pipe supports as were in the Unit 2 system [H.14].  

(Section 1R08.5)  

The inspectors identified a non-cited violation of 10 CFR Part 50, Appendix B,

Criterion III Design Control, for the failure to implement design control measures to verify the adequacy of the Unit 1 emergency diesel generators (EDGs) cooling system design to ensure operation of the EDGs under worst-case environmental conditions. Specifically, since initial licensed operations began in 1984, the licensee failed to ensure the Unit 1 EDGs were designed and built to operate under worst-case high wind and temperature conditions. As a result, sustained high winds from specific directions could have impacted EDG radiator performance resulting in the unavailability of the Unit 1 EDGs. Immediate corrective actions included issuing shift orders to the reactor operators to monitor for specific weather conditions (high air temperature, high wind speed and direction) and provide additional room cooling using established procedures, as necessary. The licensee documented the issue in the corrective action program as Notification 50599190.

 

The regional senior reactor analyst performed a Phase 3 SDP analysis for the finding. The results of analysis established the incremental conditional core damage probability (ICCDP)was 2.74E-07, less than 1 x 10-6, and therefore the analyst determined that the subject finding was of very low safety significance (Green).

Units 1 and 2 began the inspection period at full power.

 

On October 4, 2015, Unit 1, was shut down for a planned refueling outage. On November 7, 2015, Unit 1 returned to operation and began a controlled power ascension; the unit attained full power on November 13, 2015.

On December 11, 2015, Units 1 and 2 experienced heavy influx of debris from ocean swells and carryover from the circulating water system screens which resulted in fouling of the main condensers. In response, both units 1 and 2 reduced power to 25 percent to perform maintenance to removed debris from the circulating water system and condensers. Following maintenance Unit 2 returned to full power on December 14, 2015, and Unit 1 returned to full power on December 15, 2015.

Units 1 and 2 operated at or near full power for the duration of this inspection period.

Cornerstones: Initiating Events, Mitigating Systems, and Barrier Integrity {{a|1R01}}

 

==1R01 Adverse Weather Protection==

{{IP sample|IP=IP 71111.01}}

Readiness for Seasonal Extreme Weather Conditions

On December 11, 2015, the inspectors completed an inspection of the stations readiness for seasonal extreme weather conditions. The inspectors reviewed the licensees adverse weather procedures for high ocean swells and circulating water intake management during the storm season and evaluated the licensees implementation of these procedures. The inspectors verified that prior to the onset of the storm season, the licensee had corrected weather-related equipment deficiencies identified during the previous storm season.

The inspectors reviewed the licensees procedures and design information to ensure that the circulating water systems would remain functional when challenged by debris loading due to high ocean swells. The inspectors verified that operator actions described in the licensees procedures were adequate to maintain readiness of these systems. The inspectors walked down portions of these systems to verify the physical condition of the circulating water system.

These activities constituted one sample of readiness for seasonal adverse weather, as defined in Inspection Procedure 71111.01.

====b. Findings====

The inspectors performed partial system walk-downs of the following risk-significant systems:

* October 5-9, 2015, Unit 1, reactor vessel refueling level indication system alignment

* December 22-23, 2015, Unit 1, emergency diesel generator air start and turbo air partial alignment The inspectors reviewed the licensees procedures and system design information to determine the correct lineup for the systems. They visually verified that critical portions of the systems were correctly aligned for the existing plant configuration.

 

These activities constituted two partial system walk-down samples as defined in Inspection Procedure 71111.04.

On November 14, 2015, the inspectors performed a complete system walk-down inspection of the Unit 2 emergency diesel generator 2-2. The inspectors reviewed the licensees procedures and system design information to determine the correct system lineup for the existing plant configuration. The inspectors also reviewed outstanding work orders, open condition reports, in-process design changes, temporary modifications, and other open items tracked by the licensees operations and engineering departments. The inspectors then visually verified that the system was correctly aligned for the existing plant configuration.

These activities constituted one complete system walk-down sample, as defined in Inspection Procedure 71111.04.

No findings were identified. {{a|1R05}}

==1R05 Fire Protection==

{{IP sample|IP=IP 71111.05}}

Quarterly Inspection

The inspectors evaluated the licensees fire protection program for operational status and material condition. The inspectors focused their inspection on four plant areas important to safety:

* October 5, 2015, Unit 1 containment 91 foot elevation

* October 20, 2015, Unit 1, turbine building 104 foot elevation, Area 1-TB-104

* November 24, 2015, Unit 2, emergency diesel generator and radiator fire areas located in turbine building 85 foot and 119 foot elevations

* December 18, 2015, Unit 1 and 2, turbine building 140 foot elevation For each area, the inspectors evaluated the fire plan against defined hazards and defense-in-depth features in the licensees fire protection program. The inspectors evaluated control of transient combustibles and ignition sources, fire detection and suppression systems, manual firefighting equipment and capability, passive fire protection features, and compensatory measures for degraded conditions.

These activities constituted four quarterly inspection samples, as defined in Inspection Procedure 71111.05.

The inspectors identified a Green, non-cited violation of Technical Specification 5.4.1.d, Procedures, for the failure to follow approved fire protection program procedures to review the fire impairments list to assess the aggregate impact on the fire protection design and safe shutdown analysis. Specifically, from August 31 to September 2, 2015, the licensee failed to evaluate the aggregate impact of having three fire doors simultaneously blocked open in adjacent Unit 1 vital battery charger rooms.

On August 31, 2015, the licensee implemented Work Order 64092332 and blocked open three fire barriers (doors) to route test cables for planned load testing of all three Unit 1 vital battery chargers. The testing setup involved running energized electrical cables through three blocked open vital fire doors. The blocked open fire doors affected several fire zones/areas and all three of the Unit 1 vital battery charger rooms. Since the work required fire doors to be blocked open, the licensee issued a fire impairment for each door. Each fire impairment required a one-hour roving fire watch as a compensatory measure.

On September 1, 2015, during a tour of the plant, the inspector observed multiple fire doors blocked open and reviewed the fire impairments to determine if this configuration was adequate. Specifically, the inspectors questioned if the aggregate impact of multiple fire doors open was acceptable with respect to the fire protection system design and safe shutdown analysis. The licensee documented the inspectors concern in Notification 50803608. Because of the inspector questions, the licensee re-evaluated the aggregate impact of multiple blocked open fire doors. The licensee determined that while it was acceptable to have multiple fire doors open, additional compensatory measures were necessary. Instead of a one-hour roving fire watch, the licensee was required to implement a continuous fire watch.

Diablo Canyon Procedure OM8.ID2, Fire System Impairment, Revision 19, Step 4.8, states, in part, that the fire protection engineer is responsible for reviewing the fire impairments list to assess the aggregate impact on the fire protection design and safe shutdown analysis. The inspectors determined the fire protection engineer did not assess the aggregate impact of multiple fire impairments, and a significant contributor to this issue was that work planners did not properly communicate to the fire protection department that all three fire doors would be open at the same time during battery charger load testing.

The failure to follow approved fire protection program procedures to review the fire impairments list to assess the aggregate impact on the fire protection design and safe shutdown analysis was a performance deficiency. This performance deficiency was more than minor, and therefore a finding, because it was associated with the Initiating Events cornerstone attribute of Protection against External Factors (Fire) and adversely affected the cornerstone objective of limiting the likelihood of those events that upset plant stability and challenge critical safety functions during plant operations. Specifically, the failure to evaluate the aggregate impact of multiple fire system impairments affected the licensee ability to limit the impact of a potential fire. The inspectors evaluated the finding using IMC 0609, Attachment 4, Phase 1-Initial Screening and Characterization of Findings.

Because the finding involved fire protection, the inspectors transitioned to IMC 0609, Appendix F Fire Protection Significance Determination Process. The inspectors characterized the finding using IMC 0609, Appendix F, Attachment 1, "Fire Protection SDP Phase 1 Worksheet," dated September 20, 2013. The finding screened as very low safety significance (Green), per Attachment 1, Question 1.4.3-A since the fire finding category was determined to be fire confinement, due to the fire doors being propped open, and the combustion loading on both sides of the door was determined to be a duration of 30 minutes as documented in licensee calculation M-824, Controlled Combustion Loading Tracking. In addition, the inspectors determined this finding had a cross-cutting aspect in human performance associated with the teamwork component because the licensees work groups did not properly communicate and coordinate their activities within and across organizational boundaries to ensure nuclear safety was maintained. Specifically, the work planners did not properly communicate to the fire protection department that all three fire doors would be open at the same time during battery charger load testing. [H.4]  

Technical Specification 5.4.1.d, Procedures, requires, in part, that the licensee establish, implement, and maintain applicable written procedures covering fire protection program implementation. The licensee established Procedure OM8.ID2, Fire System Impairment, Revision 19, to implement, in part, the requirement of Technical Specification 5.4.1.d. Procedure OM8.ID2, Step 4.8, states that the Fire protection engineer is responsible for reviewing the fire impairments list to assess the aggregate impact on the fire protection design and safe shutdown analysis. Contrary to this requirement, from August 31 to September 2, 2015, the fire protection engineer failed to review the fire impairment list to assess the aggregate impact on the fire protection design and safe shutdown analysis. Specifically, the fire protection engineer failed to evaluate the aggregate impact of multiple fire system impairments involving three simultaneously blocked open fire doors in adjacent Unit 1 vital battery charger rooms.

The licensee implemented immediate corrective actions by assigning a continuous fire watch to the area. This violation is being treated as an NCV, consistent with Section 2.3.2 of the Enforcement Policy. The violation was entered into the licensees corrective action program as Notification 50826793. (NCV 05000275/2015004-01, Failure to Properly Evaluate for Aggregate Impact of Fire Impairments)

==1R06 Flood Protection Measures==

{{IP sample|IP=IP 71111.06}}

On October 16, 2015, the inspectors completed an inspection of underground bunkers susceptible to flooding. The inspectors selected two underground vaults that contained risk-significant or multiple-train cables whose failure could disable risk-significant equipment:

* October 6, 2015, Unit 1, inspection of reactor pressure vessel lower head vault below the 91 foot elevation

* October 15-16, 2015, Unit 1, auxiliary saltwater system underground vault / pull boxes inspection BP 034 and 35 The inspectors observed the material condition of the cables and splices contained in the vaults and looked for evidence of cable degradation due to water intrusion. The inspectors verified that the cables and vaults met design requirements.

These activities constitute completion of two bunker/manhole samples, as defined in Inspection Procedure 71111.06.

No findings were identified. {{a|1R07}}

==1R07 Heat Sink Performance==

{{IP sample|IP=IP 71111.07}}

On October 30, 2015, the inspectors completed an inspection of the readiness and availability of the Unit 1 and 2 spent fuel pool risk-significant heat exchangers. The inspectors reviewed the data from a performance test for the heat exchanger.

 

Additionally, the inspectors walked down the heat exchanger to observe its performance and material condition.

 

These activities constitute completion of one heat sink performance annual review sample, as defined in Inspection Procedure 71111.07.

No findings were identified. {{a|1R08}}

==1R08 Inservice Inspection Activities==

{{IP sample|IP=IP 71111.08}}

===.1 Non-destructive Examination (NDE) Activities and Welding Activities===

Liquid Penetrant Auxiliary Feedwater FW-1-680 FW-1 Liquid Penetrant Reactor Vessel Hot Leg Nozzle Visual (VT-1)

Reactor Vessel Bottom Bare Metal Visual Visual (VT-1)  

 

The inspectors reviewed records for the following nondestructive examinations:

SYSTEM WELD IDENTIFICATION EXAMINATION/TYPE CVCS CVCS-1-9, weld 2,3 Liquid Penetrant Auxiliary Feedwater FW-1-680 FW-2,3,4 Liquid Penetrant Reactor Vessel Upper Bare Metal Visual Visual (VT-1)  

 

SYSTEM WELD IDENTIFICATION TYPE Chemical and Volume Control System CVCS-1-9 FW-1 Gas Tungsten Arc Welding Auxiliary Feedwater FW-1-680 FW-1 Gas Tungsten Arc Welding  

 

The inspectors reviewed records for the following welding activities:

SYSTEM WELD IDENTIFICATION TYPE Chemical and Volume Control System CVCS-1-9 FW-2,3 Gas Tungsten Arc Welding Auxiliary Feedwater FW-1-680 FW-2,3,4 Gas Tungsten Arc Welding  

 

The inspectors reviewed whether the welding procedure specifications and the welders had been properly qualified in accordance with ASME Code Section IX requirements.

 

The inspectors also determined whether essential variables were identified, recorded in the procedure qualification record, and formed the bases for qualification of the welding procedure specifications.

The inspectors reviewed the results of the licensees bare metal visual inspection of the Reactor Vessel Upper Head Penetrations to determine whether the licensee identified any evidence of boric acid challenging the structural integrity of the reactor head components and attachments. The inspectors also verified that the required inspection coverage was achieved and limitations were properly recorded. The inspectors reviewed whether the personnel performing the inspection were certified examiners to their respective nondestructive examination method.

The inspectors reviewed the licensees implementation of its boric acid corrosion control program for monitoring degradation of those systems that could be adversely affected by boric acid corrosion. The inspectors reviewed the documentation associated with the licensees boric acid corrosion control walk-down as specified in Procedure ER1.ID2, Boric Acid Corrosion Control Program, Revision 7. The inspectors reviewed whether the visual inspections emphasized locations where boric acid leaks could cause degradation of safety-significant components, and whether engineering evaluations used corrosion rates applicable to the affected components and properly assessed the effects of corrosion-induced wastage on structural or pressure boundary integrity. The inspectors observed whether corrective actions taken were consistent with the ASME Code, and 10 CFR Part 50, Appendix B requirements.

Sludge lancing and foreign object search and retrieval (FOSAR) activities were conducted during Refueling Outage 1R19. Sludge lancing activities removed a total of approximately 8 pounds of sludge for all four steam generators. FOSAR examination included an in-bundle inspection of the center 10 columns of the hot leg and cold leg top-of-tube support region, and columns 20, 40, 60, 80, and 100 in both hot and cold legs. The examination also included 100 percent of the trough and outer periphery tubes.

Finally, the inspectors reviewed selected eddy current test data to verify that the analytical techniques used were adequate.

The inspectors reviewed a self-revealing Green non-cited violation of 10 CFR Part 50, Appendix B, Criterion XVI, Corrective Action, associated with the licensees failure to identify the cause and take corrective action to prevent recurrence of a significant condition adverse to quality impacting both safety-related residual heat removal (RHR) systems in Unit 1. Specifically, the licensee failed to identify a definitive cause and implement corrective actions to prevent recurrent failures of the socket weld for relief valve RHR-1-RV-8708 for both trains of the RHR system.

On June 25, 2013, during a walk down of the Unit 1 Containment, maintenance personnel noted an accumulation of boric acid on the inlet pipe to valve RHR-1-RV-8708. The problem was reported in Notification 50570623. Subsequent clean-up of the boric acid accumulation revealed an active leak of 3 drops per minute (DPM) from a circumferential crack on the socket weld. The active boric acid leak was located on the common header from the RHR pump discharge to RCS Hot Legs 1 and 2.

The active boric acid leak could not be isolated from the rest of the system. Both trains of the RHR system were declared inoperable and Technical Specification 3.0.3 was entered on June 25, 2013, at 9:58 p.m. The technical specification required a shutdown of Unit 1 within 7 hours. The condition also required a 4-hour notification to the NRC.

The licensee did not classify this initial failure of the weld as a significant condition adverse to quality.

Procedure OM4.1014, Notification Review Team, Revision 25, Section 3.21 defined a significant condition adverse to quality as a condition that, if left uncorrected, could seriously affect the ability to operate the plant in a safe manner or will require a major effort to restore capability to perform specific functions. The failure of this weld resulted in the licensee declaring both trains of residual heat removal inoperable and required the plant to be shutdown in order to repair the weld; therefore, the failure of the weld should have been classified as a significant condition adverse to quality. Title 10 CFR Part 50 Appendix B, Criterion XVI states in part, In the case of significant conditions adverse to quality, the measures shall assure that the cause of the condition is determined and corrective action taken to preclude repetition.

As part of the apparent cause evaluation, the licensee performed an inspection of the weld using the inservice inspection group and a metallurgist from Pacific Gas and Electric Applied Technology Services (ATS). The inspection identified that the source of the leak was a circumferential crack, approximately 110 degrees in length, in the socket weld at the half-coupling (sockolet) on line 1-S1-3/4 (inlet side of RV-8708). The observed crack was circumferentially oriented and predominately in the middle of the weld face, with one end of the crack tapering to the socket-side toe of the weld. Based on previous experience, the licensee determined the crack was indicative of a high cycle fatigue failure, but the weld was not cutout and failure analysis was not performed to identify the definitive cause of the failed weld.

Two snubbers (22-59SL & 22-60SL) had been removed from the piping in 1988, during the Snubber Reduction Program. The licensee determined that snubber removal probably contributed to this event. The equivalent piping on Unit 2 is generally similar in geometry, however it has two rigid restraints (one lateral and one vertical), and one lateral snubber on the discharge side of the relief valve.

The licensee assume that the only potential source of cyclical loading on the weld was from vibrations cause by components within the RHR system, but did not take additional vibrational data with the plant in normal operating conditions. The socket weld was replaced on June 27, 2013. The new weld used a 2:1 leg ratio fillet weld, which has improved fatigue resistance over the original equal-leg socket weld. This weld configuration is recommended by EPRI, and is used by the industry and Diablo Canyon Power Plant where enhanced fatigue resistance is required.

Based on a comparison with the Unit 2 piping system, the licensee determined that new rigid lateral support(s) on Line 1184-1 were necessary to reduce piping vibration.

However, the licensee decided to defer installation of the supports until refueling outage 1R19. The licensee assumed this was acceptable based on the new fatigue-resistant weld profile and the fact that it took approximately 25 years to fail the first time.

Because the licensee elected to perform an apparent cause evaluation rather than a root cause evaluation, no definitive root cause for the weld failure was identified, and no corrective actions to prevent recurrence (as defined in the licensees corrective action program) were taken. Upon the second failure of the relief valve RHR-1-RV-8708 weld (in December 2014), the licensee initiated Notification 50680750 to evaluate the failure and initiated a root cause evaluation to identify the cause of the residual heat removal system vibrations.

The failure to identify the cause of the failed weld for Relief Valve RHR-1-RV-8708 and to take corrective actions to prevent recurrence of a significant condition adverse to quality is a performance deficiency. The performance deficiency is more than minor because if left uncorrected, it could lead to a more significant safety concern.

Specifically, although individual actions were taken to address the failure caused by vibrations, the cause of the failure was not identified nor were adequate actions taken to prevent recurrence of the weld failure. The lack of corrective actions to prevent recurrence could leave RHR components and other components physically connected to the system susceptible to future failures. Using Inspection Manual Chapter 0609, Appendix A, the inspectors determined the issue to have very low safety significance (Green) because the finding, which affected the mitigating systems cornerstone, did not result in an actual loss of system function for greater than its technical specification allowed outage time.

This finding has a cross-cutting aspect in the human performance area of Conservative Bias decision making because individuals failed to use decision making-practices that emphasize prudent choices over those that are simply allowable. Specifically, the licensee chose to only install a fatigue resistance weld rather than install additional pipe supports as were in the Unit 2 system. [H.14].  

Title 10 CFR Part 50, Appendix B, Criterion XVI, Corrective Action, requires, in part, that for a significant condition adverse to quality, the measures shall assure that the cause of the condition is determined and corrective action taken to preclude repetition. Contrary to the above, between June 2013 and October 2015, the licensee failed to assure that the cause of a significant condition adverse to quality was determined and failed to implement corrective actions to preclude repetition.

Specifically, the licensee failed to determine that the vibration-induced failure of valve RHR-1-RV-8708 was significant and failed to identify a definitive cause for the failure and take corrective actions to prevent recurrence of the failure. After the second failure of valve RHR-1-RV-8708 in December 2014, the licensee installed additional piping supports to mitigate the vibrations at the weld. The licensee has planned additional actions to determine the cause of the vibrations and mitigate them, but vibration levels remain elevated. This violation is being treated as an NCV, consistent with Section 2.3.2 of the Enforcement Policy. The violation was entered into the licensees corrective action program as Notification 50680750. (NCV 05000275/2015004-02, Failure to Identify a Cause and Implement Actions to Prevent Recurrence of a Significant Condition Adverse to Quality)

 

==1R11 Licensed Operator Requalification Program and Licensed Operator Performance==

{{IP sample|IP=IP 71111.11}}

These activities constitute completion of one quarterly licensed operator requalification program sample, as defined in Inspection Procedure 71111.11.

The inspectors observed the performance of on-shift licensed operators in the plants main control room. At the time of the observations, the plant was in a period of heightened activity or risk due to startup activities. The inspectors observed the operators performance of the following activities:

* October 3-6, 2015, Unit 1, control room observations in preparations for refueling outage including plant shutdown, cooldown, reactor coolant drain down for core offloading

* October 11-12, 2015, Unit 1, reduced inventory for reactor coolant system vacuum fill

* November 6, 2015, plant start-up to criticality In addition, the inspectors assessed the operators adherence to plant procedures, including conduct of operations procedure and other operations department policies.

These activities constitute completion of one quarterly licensed operator performance sample, as defined in Inspection Procedure 71111.11.

No findings were identified. {{a|1R12}}

==1R12 Maintenance Effectiveness==

{{IP sample|IP=IP 71111.12}}

The inspectors reviewed one instance of degraded performance or condition of safety-related structures, systems, and components (SSCs):

* November 10, 2015, Unit 2, 480 volt vital switchgear room ventilation The inspectors reviewed the extent of condition of possible common cause SSC failures and evaluated the adequacy of the licensees corrective actions. The inspectors reviewed the licensees work practices to evaluate whether these may have played a role in the degradation of the SSCs. The inspectors assessed the licensees characterization of the degradation in accordance with 10 CFR 50.65 (the Maintenance Rule), and verified that the licensee was appropriately tracking degraded performance and conditions in accordance with the Maintenance Rule.

These activities constituted completion of one maintenance effectiveness sample, as defined in Inspection Procedure 71111.12.

No findings were identified. {{a|1R13}}

==1R13 Maintenance Risk Assessments and Emergent Work Control==

{{IP sample|IP=IP 71111.13}}

The inspectors reviewed two risk assessments performed by the licensee prior to changes in plant configuration and the risk management actions taken by the licensee in response to elevated risk:

* October 28, 2015, Unit 1 and 2, plant protected equipment in the 4 kV, emergency diesel generator rooms, 480 volt, and component cooling water rooms

* October 30-31, 2015, reactor coolant fill and venting activity including vacuum refill of the reactor coolant from a reduce inventory / mid-loop condition The inspectors verified that these risk assessments were performed timely and in accordance with the requirements of 10 CFR 50.65 (the Maintenance Rule) and plant procedures. The inspectors reviewed the accuracy and completeness of the licensees risk assessments and verified that the licensee implemented appropriate risk management actions based on the result of the assessments.

 

These activities constitute completion of three maintenance risk assessments and emergent work control inspection samples, as defined in Inspection Procedure 71111.13.

No findings were identified. {{a|1R15}}

==1R15 Operability Determinations and Functionality Assessments==

{{IP sample|IP=IP 71111.15}}

* November 11-12, 2015, Unit 1, operability determination of increased flow into the reactor coolant drain tank

* November 13, 2015, Unit 2, operability determination of 480 volt vital switchgear room ventilation

* December 11-15, 2015, Unit 1 and 2, operability determination of operator work around conditions to compensate for degraded or non-conforming conditions The inspectors reviewed the timeliness and technical adequacy of the licensees evaluations. Where the licensee determined the degraded SSC to be operable, the inspectors verified that the licensees compensatory measures were appropriate to provide reasonable assurance of operability. The inspectors verified that the licensee had considered the effect of other degraded conditions on the operability of the degraded SSC.

 

These activities constitute completion of three operability and functionality review samples, which included one operator work-around sample, as defined in Inspection Procedure 71111.15.

No findings were identified. {{a|1R19}}

==1R19 Post-Maintenance Testing==

{{IP sample|IP=IP 71111.19}}

The inspectors reviewed two post-maintenance testing activities that affected risk-significant structures, systems, or components (SSCs):

* October 19, 2015, Unit 1, containment isolation valve testing of pressurizer relief tank isolation valves RCS 8034 A/B following air operator calibration description

* November 3-4, 2015, Unit 1, seal water return isolation valve, CVCS-8100, post maintenance testing The inspectors reviewed licensing-and design-basis documents for the SSCs and the maintenance and post-maintenance test procedures. The inspectors observed the performance of the post-maintenance tests to verify that the licensee performed the tests in accordance with approved procedures, satisfied the established acceptance criteria, and restored the operability of the affected SSCs.

These activities constitute completion of two post-maintenance testing inspection samples, as defined in Inspection Procedure 71111.19.

No findings were identified. {{a|1R20}}

==1R20 Refueling and Other Outage Activities==

{{IP sample|IP=IP 71111.20}}

During the stations refueling outage that concluded on November 4, 2015, the inspectors evaluated the licensees outage activities. The inspectors verified that the licensee considered risk in developing and implementing the outage plan, appropriately managed personnel fatigue, and developed mitigation strategies for losses of key safety functions. This verification included the following:

* Review of the licensees outage plan prior to the outage

* Review and verification of the licensees fatigue management activities

* Monitoring of shut-down and cool-down activities

* Verification that the licensee maintained defense-in-depth during outage activities

* Observation and review of reduced-inventory and mid-loop activities

* Observation and review of fuel handling activities

* Monitoring of heat-up and startup activities These activities constitute completion of one refueling outage sample, as defined in Inspection Procedure 71111.20.

No findings were identified. {{a|1R22}}

==1R22 Surveillance Testing==

{{IP sample|IP=IP 71111.22}}

In-service tests:

* October 5, 2015, Unit 1, containment spray pump 1-1, comprehensive in-service pump testing Containment isolation valve surveillance tests:

* October 19, 2015, Unit 1, penetration 76B containment isolation valve leak testing

* November 4, 2015, Unit 1, containment isolation valve leak testing of seal water return valve CVCS-1-8100 Other surveillance tests:

* November 5, 2015, Unit 1, control rod drop measurement and rod position functional testing

* November 17, 2015, Unit 1, emergency diesel generator 1-3 testing The inspectors verified that these tests met technical specification requirements, that the licensee performed the tests in accordance with their procedures, and that the results of the test satisfied appropriate acceptance criteria. The inspectors verified that the licensee restored the operability of the affected SSCs following testing.

These activities constitute completion of five surveillance testing inspection samples, as defined in Inspection Procedure 71111.22.

Cornerstones: Public Radiation Safety and Occupational Radiation Safety {{a|2RS1}}

 

==2RS1 Radiological Hazard Assessment and Exposure Controls==

{{IP sample|IP=IP 71124.01}}

The inspectors assessed the licensees performance in assessing the radiological hazards in the workplace associated with licensed activities. The inspectors assessed the licensees implementation of appropriate radiation monitoring and exposure control measures for both individual and collective exposures. The inspectors walked down various portions of the plant and performed independent radiation dose rate measurements. The inspectors interviewed the radiation protection manager, radiation protection supervisors, and radiation workers. The inspectors reviewed licensee performance in the following areas:

* The hazard assessment program, including a review of the licensees evaluations of changes in plant operations and radiological surveys to detect dose rates, airborne radioactivity, and surface contamination levels

* Instructions and notices to workers, including labeling or marking containers of radioactive material, radiation work permits, actions for electronic dosimeter alarms, and changes to radiological conditions

* Programs and processes for control of sealed sources and release of potentially contaminated material from the radiologically controlled area, including survey performance, instrument sensitivity, release criteria, procedural guidance, and sealed source accountability

* Radiological hazards control and work coverage, including the adequacy of surveys, radiation protection job coverage and contamination controls, the use of electronic dosimeters in high noise areas, dosimetry placement, airborne radioactivity monitoring, controls for highly activated or contaminated materials (non-fuel) stored within spent fuel and other storage pools, and posting and physical controls for high radiation areas and very high radiation areas

* Radiation worker and radiation protection technician performance with respect to radiation protection work requirements

* Audits, self-assessments, and corrective action documents related to radiological hazard assessment and exposure controls since the last inspection These activities constitute completion of one sample of radiological hazard assessment and exposure controls as defined in Inspection Procedure 71124.01.

No findings were identified. {{a|2RS3}}

==2RS3 In-Plant Airborne Radioactivity Control and Mitigation==

{{IP sample|IP=IP 71124.03}}

The inspectors evaluated whether the licensee controlled in-plant airborne radioactivity concentrations consistent with ALARA principles and that the use of respiratory protection devices did not pose an undue risk to the wearer. During the inspection, the inspectors interviewed licensee personnel, walked down various portions of the plant, and reviewed licensee performance in the following areas:

* The licensees use, when applicable, of ventilation systems as part of its engineering controls

* The licensees respiratory protection program for use, storage, maintenance, and quality assurance of NIOSH certified equipment, qualification and training of personnel, and user performance

* The licensees capability for refilling and transporting SCBA air bottles to and from the control room and operations support center during emergency conditions, status of SCBA staged and ready for use in the plant and associated surveillance records, and personnel qualification and training

* Audits, self-assessments, and corrective action documents related to in-plant airborne radioactivity control and mitigation since the last inspection These activities constitute completion of one sample of in-plant airborne radioactivity control and mitigation as defined in Inspection Procedure 71124.03.

Cornerstones: Initiating Events, Mitigating Systems, Barrier Integrity, Emergency Preparedness, Public Radiation Safety, Occupational Radiation Safety, and Security

 

==4OA1 Performance Indicator Verification==

{{IP sample|IP=IP 71151}}

These activities constituted verification of the reactor coolant system specific activity performance indicator for Units 1 and 2, as defined in Inspection Procedure 71151.

===.2 Reactor Coolant System Identified Leakage (BI02)===

The inspectors reviewed the licensees records of reactor coolant system (RCS)identified leakage for the period of October 2014 through October 2015 to verify the accuracy and completeness of the reported data. The inspectors observed the performance of RCS leakage surveillance procedure on February 4, 2015. The inspectors used definitions and guidance contained in Nuclear Energy Institute Document 99-02, Regulatory Assessment Performance Indicator Guideline, Revision 7, to determine the accuracy of the reported data.

The inspectors verified that there were no unplanned exposures or losses of radiological control over locked high radiation areas and very high radiation areas during the period of July 1, 2014 to September 30, 2015. The inspectors reviewed a sample of radiologically controlled area exit transactions showing exposures greater than 100 mrem. The inspectors used definitions and guidance contained in Nuclear Energy Institute Document 99-02, Regulatory Assessment Performance Indicator Guideline, Revision 7, to determine the accuracy of the reported data.

===.4 Radiological Effluent Technical Specifications (RETS)/Offsite Dose Calculation Manual===

(ODCM) Radiological Effluent Occurrences (PR01)

The inspectors reviewed corrective action program records for liquid or gaseous effluent releases that occurred between July 1, 2014 and September 30, 2015, and were reported to the NRC to verify the performance indicator data. The inspectors used definitions and guidance contained in Nuclear Energy Institute Document 99-02, Regulatory Assessment Performance Indicator Guideline, Revision 7, to determine the accuracy of the reported data.

No findings were identified. {{a|4OA2}}

==4OA2 Problem Identification and Resolution==

{{IP sample|IP=IP 71152}}

Throughout the inspection period, the inspectors performed daily reviews of items entered into the licensees corrective action program and periodically attended the licensees condition report screening meetings. The inspectors verified that licensee personnel were identifying problems at an appropriate threshold and entering these problems into the corrective action program for resolution. The inspectors verified that the licensee developed and implemented corrective actions commensurate with the significance of the problems identified. The inspectors also reviewed the licensees problem identification and resolution activities during the performance of the other inspection activities documented in this report.

===.2 Semiannual Trend Review===

The inspectors reviewed the licensees corrective action program, performance indicators, system health reports, and other documentation to identify trends that might indicate the existence of a more significant safety issue. The inspectors verified that the licensee was taking corrective actions to address identified adverse trends.

* A negative trend identified involving reactor cavity seal leakage (Notifications 50817738 and 50818639)

* A potential adverse trend in foreign material exclusion trends (Notifications 50695123 and 50802021)

The specific documents reviewed during this trend review are listed in the attachment.

These activities constitute completion of one semiannual trend review sample, as defined in Inspection Procedure 71152.

* For negative trend in reactor cavity seal leakage, the licensee chartered a root cause team to evaluate the repeated leakage of the reactor cavity seal during the Unit 1 and 2 refueling outages. The repeated seal leakage resulted in the replacement of excore nuclear instrumentation, increased outage dose to workers, and boric acid leakage from the refueling cavity onto the reactor vessel.

 

 

The license performed a quick hit self-assessment to identify areas of potential weaknesses in the FME program and to identify potential focus areas for improvements.

The inspectors determined the licensee failed to apply appropriate measures to ensure containment cleanliness and loose debris be controlled and removed during the Unit 1 refueling outage 1R19, in accordance with station procedures STP M-45C, Outage Management Containment Inspection, and AD4.ID9, Containment Housekeeping and Material Controls. Specifically, the foreign material total square footage was very small compared to the available recirculation sump screen surface area margin. The licensee appropriately documented this condition in the corrective action program as Notifications 50817774, 50817820, and 50817822. The inspectors determined that this performance deficiency was a minor violation of 10 CFR Part 50, Appendix B, Criterion V, Procedures.

No findings were identified.

===.3 Annual Follow-up of Selected Issues===

The inspectors reviewed the licensees evaluation of the current notification, select evaluations of fuel inspections conducted during previous refueling outages, and the licensees evaluation of contemporary operating experience relative to the phenomena known as baffle jetting (as described in NRC Information Notice 82-27, Fuel Rod Degradation Resulting from Baffle Water-Jet Impingement).

The inspectors assessed the licensees problem identification threshold, cause analyses, extent of condition reviews, and compensatory actions for the selected issue. The inspectors verified that the licensee appropriately prioritized the planned corrective actions and that these actions were adequate.

These activities constitute completion of one annual follow-up sample as defined in Inspection Procedure 71152.

No findings were identified. {{a|4OA3}}

==4OA3 Follow-up of Events and Notices of Enforcement Discretion==

{{IP sample|IP=IP 71153}}

(Closed) LER 05000275/1-2013-009-01: Unanalyzed Condition Affecting Emergency Diesel Generators

The inspectors verified the accuracy and completeness of the Licensee Event Report (LER) and the appropriateness of the licensees corrective actions. The inspectors reviewed the immediate corrective actions that developed compensatory measures to allow the Unit 1 emergency diesel generators (EDGs) to remain operable with sustained winds up to 80 miles per hour (mph) with ambient air temperature up to 97 degrees Fahrenheit.

The inspectors identified a Green non-cited violation of 10 CFR Part 50, Appendix B, Criterion III Design Control. The licensees failure to implement design control measures to verify the adequacy of the Unit 1 emergency diesel generators (EDGs) cooling system design to ensure operation of the EDGs under worst-case environmental conditions was a performance deficiency. Specifically, since initial licensed operation in 1984, the licensee failed to ensure the Unit 1 EDGs were designed and built to operate under worst-case high wind and temperature conditions. As a result, sustained high winds from specific directions could have impacted EDG radiator performance resulting in the unavailability of the Unit 1 EDGs.

On December 14, 2013, the licensee determined that sustained high winds could result in not having adequate engine heat removal to support continuous operation of the Unit 1 EDGs. The licensee initiated an evaluation of its EDGs because the NRC requested all licensees determine the impact to air-cooled EDGs by winds blowing in the opposite direction of the radiator cooling air. The licensees engineers identified a vulnerability to extreme weather. A combination of sustained high winds over 60 miles per hour and ambient air temperatures exceeding 97 degrees Fahrenheit could reduce cooling capacity such that the emergency diesel generators would exceed design limits.

Unit 1 has three emergency diesel generators that provide vital emergency AC power to three electrical buses to mitigate the consequences of a design basis accident (DBA)whenever normal or offsite power sources are unavailable. The EDGs are designed to function so that a single failure of any EDG will not jeopardize the capability of the remaining EDGs to start and provide power to operate the shutdown systems required to mitigate any DBA condition. The EDGs use engine-driven fans that provide cooling air to the EDG radiators. The radiator fan draws air through the radiator, maintaining jacket water temperature and, in turn, maintaining lubricating oil temperature. Jacket water to the aftercooler also affects combustion air temperature. The radiator fan also draws ambient air through the engine compartment to cool the equipment housed within it.

Inability to maintain adequate radiator airflow will result in a rise in EDG jacket water temperature, higher component temperatures in the engine compartments, derating of the engine due to increased combustion air temperature, higher lubricating oil temperatures, and high cylinder jacket temperatures. This could result in a failure of the EDGs to perform their safety function. Due to the physical orientation and layout of the site, the Unit 2 EDGs were determined not to be susceptible to effects of the extreme weather conditions as described in the LER.

Upon identification of this condition, Operations shift orders were issued that require, when conditions warrant, the implementation of existing procedural guidance to open plant doors to allow additional air flow, shown to provide adequate emergency diesel generator cooling to support continuous operation of the Unit 1 emergency diesel generators. An apparent cause evaluation concluded that the licensee did not have a design process requirement in place to evaluate GDC-2 design criteria relative to SSC functional requirements other than for structural integrity issues. The licensee revised plant procedures to include this requirement and PG&E will issue a design change to permanently modify the plant to resolve the wind issue.

The failure to implement design control measures to ensure the emergency diesel generators could perform their design basis function was a performance deficiency. The performance deficiency was more than minor and is therefore a finding because it was associated with the design control attribute of the mitigating system cornerstone, and affected the cornerstone objective of ensuring availability, reliability, and capability of systems that respond to initiating events. Specifically, the performance deficiency resulted in a condition where sustained high winds from specific directions could have impacted EDG radiator performance resulting in the unavailability of the Unit 1 EDGs. Using Table 2 of Inspection Manual Chapter (IMC) 0609.04, Significance Determination Process Initial Characterization of Findings, dated June 19, 2012, the inspectors concluded that the finding affected the mitigating system cornerstone. The inspectors evaluated the finding using Exhibit 2 of IMC 0609, Appendix A, The Significance Determination Process for Findings At-Power, dated June 19, 2012. The inspectors determined that a detailed risk evaluation by an NRC senior reactor analyst was required since the finding was associated with a loss of EDG function. The regional senior reactor analyst performed a Phase 3 significance determination process (SDP)analysis for the finding as follows:

The licensee performed a realistic evaluation of emergency diesel generator temperatures, given varying wind and ambient temperature combinations. Specifically, the licensee computed the emergency diesel generator room temperature, jacket water radiator inlet temperature, and the jacket water radiator outlet temperature. The design limits for the analysis were room temperatures less than 120 degrees, inlet temperatures less than 195 degrees, and outlet temperatures less than 160 degrees. The first two values represented points, if exceeded, at which the emergency diesel generator was assumed to fail. The last value, if exceed, was assumed to cause a derating of the diesel generator as opposed to direct failure. The analyst bounded the analysis by placing all postulated weather conditions resulting in diesel failure into the following three bins:

The analyst determined that the subject performance deficiency impacted plant risk from initial reactor startup through December 2013. Therefore, in accordance with the Risk Assessment of Operational Events Handbook, Volume 1, Internal Events, Revision 2, Section 2.6, Exposure Time Greater than 1 Year, the maximum exposure time (EXP)was set to the 1-year assessment period.

In order for the emergency diesel generators to be of importance, a loss of offsite power must occur. The analyst noted that the frequency of a loss of offsite power (LOOP) was 3.59 x 10-2/year from the Standardized Plant Analysis Risk (SPAR) model for Diablo Canyon Power Plant, Units 1 and 2.

Upon the occurrence of a loss of offsite power, the analyst assumed that high winds would need to occur within 24 hours to have any major impact on risk. Using the Severe Weather Database (1950-2011) from the National Weather Service, the analyst reviewed wind data over a 29-year period and found 47 occurrences of winds greater than 40 mph, four occurrences of winds over 60 mph, and no occurrences of winds over 80 mph. Using a noninformative prior distribution, the analyst calculated the following frequencies of exceedance (Wind):

4.44E-03

3.78E-04 0.5 4.72E-05

The probability of exceeding the minimum wind of interest (PWind) is the Wind multiplied by the 24 hour (1 day) period of the analysis.

The analyst determined that the best available information regarding temperatures onsite was the meteorological tower data. The analyst reviewed the following information provided by the licensee to determine the probability of exceedance (PTemp):

Met Tower Temperature Probability of Exceedance

9.15E-01

1.47E-01

 

1.50E-02

 

2.20E-03 100 4.59E-04

Using the SPAR model, the analyst quantified the conditional core damage probability (CCDP) for a postulated loss of offsite power with the failure of all emergency diesel generators on Unit 1. The result was 3.41 x 10-1. Therefore, assuming that, for the sake of this analysis, wind speed and temperature are independent variables, the incremental conditional core damage probability (ICCDP) for any given bin can be calculated as follows:

4.44E-03 2.20E-03 1.20E-07

3.78E-04 1.50E-02 6.94E-08

4.72E-05 1.47E-01 8.50E-08 Total ICCDP:

2.74E-07

Given that the internal events change in core damage frequency (equivalent to the ICCDP) is less than 1 x 10-6, the analyst determined that the subject finding was of very low safety significance (Green).

Contributions from External Events (Fire, Flooding, Seismic and High Winds): In accordance with the guidance in NRC Inspection Manual Chapter 0609, Appendix A, The Significance Determination Process (SDP) for findings At-Power, the analyst performed an evaluation of the external event risk contribution because the internal events detailed risk evaluation results were greater than 1.0 x 10-7. The analyst determined that the plant response to the external events fire, flooding and seismic would not be greatly impacted by this performance deficiency because none of the initiators would impact the probability of high winds and high temperatures occurring at the same time. Therefore, only high winds related initiators were considered to be potentially impacted by this performance deficiency.

For high winds initiators to be affected by the performance deficiency, winds must be strong enough to result in a loss of offsite power. As stated previously, using the Severe Weather Database (1950-2011) from the National Weather Service there were no winds greater than 80 mph reported within a 100 kilometer radius of the plant over the 29 years that strong winds were documented. Additionally, using SeverePlot output from January 1, 1950 to December 31, 2006, there were no F2 or stronger tornadoes within a 100 km radius of the plant over the 56-year period of the data. Traditionally, analysts have not correlated F0 and F1 tornadoes with winds that could cause widespread loss of offsite power. By definition, F1 tornado damage is limited to peeling off residential roof surfaces, breaking windows and pushing moving automobiles off roads, and not the more severe damage that would be associated with a complete loss of offsite power.

Therefore, the analyst determined qualitatively that the impact of this performance deficiency on plant response to high winds external initiators was negligible.

Potential Risk Contribution from Large, Early Release Frequency: In accordance with the guidance in NRC Inspection Manual Chapter 0609, Appendix H, Containment Integrity Significance Determination Process, this finding would not involve a significant increase in risk of a large, early release of radiation because Diablo Canyon Power Plant, Unit 1, has a large, dry containment and the dominant sequences contributing to the change in the core damage frequency did not involve either a steam generator tube rupture or an inter-system loss of coolant accident.

Title 10 CFR Part 50, Appendix B, Criterion III, Design Control, states, in part, that measures shall be established to assure the design basis for those SSCs to which this appendix applies are correctly translated into specifications and drawings and that the design control measures shall provide for verifying or checking the adequacy of design. FSARU Section 3.1.2, Criterion 2-Design Basis for Protection against Natural Phenomena, states, in part, that SSCs important to safety shall be designed to withstand effects of natural phenomena such as hurricanes without loss of capability to perform their safety function. FSARU Section 2.3.2.2.2, Maximum ambient Temperature, states that the maximum design temperature applied to the EDG radiator performance is 97 degrees Fahrenheit. FSARU Section 2.3.1.3, Maximum Wind Speed, states, in part, that the maximum wind assumed to act on the EDG radiators is 80 mph. Contrary to the above, from initial licensed operations to December 14, 2013, for quality-related components associated with Unit 1 emergency diesel generators to which 10 CFR Part 50, Appendix B applies, the licensee failed to assure the design basis was correctly translated into specifications and drawings. Specifically, the specifications for the Unit 1 EDGs air cooling systems failed to ensure that the design basis for the Unit 1 EDGs, as specified in FSARU Sections 3.1.2 were not adversely impacted by sustained high temperature and winds specified in FSARU Section 2.3.2.2.2 and 2.3.1.3. The licensee entered the issue into their corrective action program as Notification 50599190; revised plant procedures to include improve design reviews, as well as, issued a design change to permanently modify the plant to resolve the issue. This violation is being treated as an NCV, consistent with Section 2.3.2 of the Enforcement Policy. The violation was entered into the licensees corrective action program as Notification 50599190. (NCV 05000275/2015004-03, Failure to Design the Emergency Diesel Generators to operate under Worst Case Environmental Conditions)

These activities constitute completion of one event follow-up sample, as defined in Inspection Procedure 71153.

On October 15, 2015, the inspectors presented the radiation safety inspection results to Mr. E.

Halpin, Senior Vice-President and Chief Nuclear Officer, and other members of the licensee staff. The licensee acknowledged the issues presented. The licensee confirmed that any proprietary information reviewed by the inspectors had been returned or destroyed.

On January 11, 2016, the resident inspectors presented the inspection results to Mr. E. Halpin, Senior Vice-President and Chief Nuclear Officer, and other members of the licensee staff. The licensee acknowledged the issues presented. The licensee confirmed that any proprietary information reviewed by the inspectors had been returned or destroyed.

: [[contact::B. Allen]], Vice President Nuclear Services  

: [[contact::J. Arhar]], Advising Engineer, Senior

: [[contact::T. Baldwin]], Director, Nuclear Site Services  

: [[contact::D. Evans]], Director, Security & Emergency Services  

: [[contact::P. Gerfen]], Director of Operation Services  

: [[contact::M. Ginn]], Manager, Nuclear Emergency Planning  

: [[contact::D. Gonzalez]], Supervisor, Nuclear Engineering

: [[contact::H. Hamzehee]], Manager, Regulatory Services  

: [[contact::A. Heffner]], NRC Interface, Regulatory Services  

: [[contact::B. Highland]], Foreman, Radiation Protection  

: [[contact::J. Hill]], Nuclear Lead ISI, NDE Specialist

: [[contact::J. Hinds]], Director, Quality Verification  

: [[contact::K. Hinrichsen]], Foreman, Radiation Protection  

: [[contact::L. Hopson]], Assistant Director, Nuclear Maintenance

: [[contact::T. Irving]], Manager, Radiation Protection  

: [[contact::J. MacIntyre]], Director of Equipment Reliability  

: [[contact::M. McCoy]], NRC Interface, Regulatory Services  

: [[contact::L. Million]], General Foreman, Radiation Protection  

: [[contact::J. Morris]], Senior Advising Engineer  

: [[contact::C. Neary]], Nuclear Advising Engineer, Senior

: [[contact::J. Nimick]], Station Director  

: [[contact::A. Peck]], Director, Nuclear Engineering  

: [[contact::R. Rogers]], General Foreman and ALARA Supervisor, Radiation Protection  

: [[contact::R. Simmons]], Manager, Nuclear Maintenance  

: [[contact::P. Soenen]], Manager, Nuclear Regulatory Services

: [[contact::J. Welsch]], Site Vice President  

: [[contact::D. Wilson]], Lead ISI Inspector/NDE Specialist

: [[contact::M. Wright]], Nuclear Engineering, Manager  

: [[contact::D. Loveless]], Senior Reactor Analyst  

05000275/2015004-01

NCV

Failure to Properly Evaluate for Aggregate Impact of Fire

Impairments (Section 1R05)

05000275/2015004-02

NCV

Failure to Identify a Cause and Implement Actions to

Prevent Recurrence of a Significant Condition Adverse to

Quality (Section 1R08.5)

05000275/2015004-03

NCV

Failure to Design the Emergency Diesel Generators to

operate under Worst Case Environmental Conditions

(Section 4OA3)

Closed

05000275/1-2013-009-01 LER

Unanalyzed Condition Affecting Emergency Diesel

Generators (Section 4OA3)  

 

Section 1R01: Adverse Weather Protection

Number

Title

Revision

OP O-28

Intake Management

CP M-16

Severe Weather

MA1.ID23

Review of Intake Preparedness for High Debris Loading

Event

ENV.EM2

Ocean Jellyfish Influx Monitoring  

 

50824808

50698209  

 

Section 1R04: Equipment Alignment

Number

Title

Revision

OP A-2:X

RVRLIS Alignment for Refueling Outages

MP I-2.28

Activation and Deactivation of the Rx Vessel Refueling

Level Indication System (RVRLIS)

OP A-2:II

Reactor Vessel - Draining the RCS to the Vessel Flange -

With Fuel in Vessel

OP J-6B:II-A

Diesel Generator 2-2 - Alignment Checklist

OP1.DC20

Sealed Components  

 

OP K-10

Systems Requiring Sealed Component Checklists

OP J-6B:II

Diesel Generator 2-2 - Make Available

OP J-6B:III-A

Diesel Generator 1-3 - Alignment Checklist  

 

50708572

50821650

50640977

50593705

50820595

50812333

50815619

50708060

50803175

50703699  

 

Work Orders

64071190

60083058  

 

Number

Title

Revision

107721

Jacket Water Cooling System and Lube Oil System, Unit 2

108021

Combustion Air and Exhaust System 2-2

663082

Equipment Arrangement

108021

Engine Fuel Oil System 2-2

500852

Piping and Mechanical Plans at 85 and 107 foot elevation  

 

Section 1R05: Fire Protection

Number

Title

Revision

AD4.ID3

SISIP Housekeeping Activities

OM8.ID4

Control of Flammable and Combustible Materials

OM8.ID2

Fire System Impairment

STP M-70D

Inspection of Fire Barriers, Rated Enclosures, Credited

Cable Tray Fire Stops, and Equipment Hatches

PEP 18-02

Firewater Hose Station Flow Test

STP M-67C

Monthly Hose Reel Station Inspection

STP M-80B

Indoor Fire Hose Operability Test

STP M-80D

Fire Hose Hydrostatic Testing  

 

50681419

50817032

50826569

50803608

50803505

Work Orders

64092332  

 

Other Documents

Number

Title

Date

5391

Transient Combustible Permit - Fire Zone 14-A-2, Turbine

Building, 104 ft.

September

2, 2015

5505

Transient Combustible Permit - Fire Zone 14-A-2, Turbine

Building, 104 ft.

September 9,

2015

SDP 15-03

Risk Evaluation for Both Vital Switchgear Ventilation Trains

Unavailable  

 

Number

Title

Revision

111906 sheet 7

Unit 1, Turbine Building Elevation 104 foot

111906 sheet 26

Unit 1, Containment Building Elevation 91 foot

111906 sheet 27

Unit 1, Containment Building Elevation 117 foot

111906 sheet 28

Unit 1, Containment Building Elevation 140 foot

TB-16

Unit 2, Fire Strategy: Turbine Building Buttress Elev. 85 &

104 foot

TB-14