IR 05000255/2014008: Difference between revisions

From kanterella
Jump to navigation Jump to search
(Created page by program invented by StriderTol)
(Created page by program invented by StriderTol)
Line 18: Line 18:


=Text=
=Text=
{{#Wiki_filter:
{{#Wiki_filter:UNITED STATES NUCLEAR REGULATORY COMMISSION REGION III 2443 WARRENVILLE RD. SUIT E 210 LISLE, IL 60532
[[Issue date::December 2, 2014]]
-4352 December 2, 2014 Mr. Anthony Vitale Vice-President, Operations Entergy Nuclear Operations, Inc.


Mr. Anthony Vitale Vice-President, Operations Entergy Nuclear Operations, Inc. Palisades Nuclear Plant 27780 Blue Star Memorial Highway Covert, MI 49043-9530
Palisades Nuclear Plant 27780 Blue Star Memorial Highway Covert, MI 49043
-9530


SUBJECT: PALISADES NUCLEAR PLANT COMPONENT DESIGN BASES INSPECTION 05000255/2014008
SUBJECT: PALISADES NUCLEAR PLANT COMPONENT DESIGN BASES INSPECTION 05000255/2 014008


==Dear Mr. Vitale:==
==Dear Mr. Vitale:==
On November 4, 2014, the U.S. Nuclear Regulatory Commission (NRC) completed a Component Design Bases Inspection (CDBI) inspection at your Palisades Nuclear Plant. The enclosed report documents the results of this inspection, which were discussed on November 4, 2014, with you, and other members of your staff. Based on the results of this inspection, ten NRC-identified findings of very low safety significance were identified. The findings involved violations of NRC requirements. However, because of their very low safety significance, and because the issues were entered into your Corrective Action Program, the NRC is treating the issues as Non-Cited Violations (NCVs) in accordance with Section 2.3.2 of the NRC Enforcement Policy. Additionally, one licensee-identified violation is listed in Section 4OA7 of this report. If you contest the subject or severity of these NCVs, you should provide a response within 30 days of the date of this inspection report, with the basis for your denial, to the U.S. Nuclear Regulatory Commission, ATTN: Document Control Desk, Washington, DC 20555-0001, with a copy to the Regional Administrator, U.S. Nuclear Regulatory Commission - Region III, 2443 Warrenville Road, Suite 210, Lisle, IL 60532-4352; the Director, Office of Enforcement, U.S. Nuclear Regulatory Commission, Washington, DC 20555-0001; and the Resident Inspector Office at the Palisades Nuclear Plant. In addition, if you disagree with the cross-cutting aspect assigned to any finding in this report, you should provide a response within 30 days of the date of this inspection report, with the basis for your disagreement, to the Regional Administrator, Region III, and the NRC Resident Inspector at the Palisades Nuclear Plant. In accordance with Title 10, Code of Federal Regulations (CFR) "Rules of Practice," a copy of this letter and its enclosure a copy of this letter, its enclosure, and your response (if any), will be available electronically for public inspection in the NRC Public Document Room or from the Publicly Available Records System (PARS) component of NRC's Agencywide Documents Access and Management System (ADAMS), accessible from the NRC Web site at http://www.nrc.gov/reading-rm/adams.html (the Public Electronic Reading Room).
On November 4, 2014
, the U.S. Nuclear Regulatory Commission (NRC)
completed a Component Design Bases Inspection (CDBI)
inspection at your Palisades Nuclear Plant
. The enclosed report documents the results of this inspection, which were discussed on November 4, 2014
, with you, and other members of your staff.
 
Based on the results of this inspection, ten NRC-identified findings of very low safety significance were identified. The finding s involved violation s of NRC requirements. However, because of their very low safety significance, and because the issues were entered into your Corrective Action Program, the NRC is treating the issues as Non-Cited Violations (NCVs) in accordance with Section 2.3.2 of the NRC Enforcement Policy. Additionally, one licensee-identified violation is listed in Section 4OA7 of this report.
 
If you contest the subject or severity of these NCVs, you should provide a response within 30 days of the date of this inspection report, with the basis for your denial, to the U.S. Nuclear Regulatory Commission, ATTN: Document Control Desk, Washington, DC 20555-0001, with a copy to the Regional Administrator, U.S. Nuclear Regulatory Commission  
- Region III, 2443 Warrenville Road, Suite 210, Lisle, IL 60532
-4352; the Director, Office of Enforcement, U.S. Nuclear Regulatory Commission, Washington, DC 20555
-0001; and the Resident Inspector Office at the Palisades Nuclear Plant. In addition, if you disagree with the cross
-cutting aspect assigned to any finding in this report, you should provide a response within 30 days of the date of this inspection report, with the basis for your disagreement, to the Regional Administrator, Region III, and the NRC Resident Inspector at the Palisades Nuclear Plant
. In accordance with Title 10, Code of Federal Regulations (CFR) "Rules of Practice," a copy of this letter and its enclosure a copy of this letter, its enclosure, and your response (if any),
will be available electronically for public inspection in the NRC Public Document Room or from the Publicly Available Records System (PARS) component of NRC's Agencywide Documents Access and Management System (ADAMS), accessible from the NRC Web site at http://www.nrc.gov/reading
-rm/adams.html (the Public Electronic Reading Room).


Sincerely,/RA/
Sincerely,/RA/
Ann Marie Stone, Chief Engineering Branch 2 Division of Reactor Safety Docket No. 50-255 License No. DPR-20  
Ann Marie Stone, Chief Engineering Branch 2 Division of Reactor Safety Docket No. 50
-255 License No. DPR
-20  


===Enclosure:===
===Enclosure:===
Inspection Report 05000255/2014008  
Inspection Report 05000 255/2014008  


===w/Attachment:===
===w/Attachment:===
Supplemental Information cc w/encl: Distribution via LISTSERV Enclosure U.S. NUCLEAR REGULATORY COMMISSION REGION III Docket No: 50-255 License No: DPR-20 Report No: 05000255/2014008 Licensee: Entergy Nuclear Operations, Inc. Facility: Palisades Nuclear Plant Location: Covert, MI Dates: September 8, 2014 through November 4, 2014 Inspectors: S. Sheldon, Senior Engineering Inspector, Lead J. Corujo-Sandin, Engineering Inspector, Mechanical C. Brown, Engineering Inspector, Electrical C. Zoia, Operations Engineer L. Rodriguez, Engineering Inspector, Observer H. Leake, Electrical Contractor C. Baron, Mechanical Contractor Approved by: Ann Marie Stone, Chief Engineering Branch 2 Division of Reactor Safety i  
Supplemental Information cc w/encl:
Distribution via LISTSERV Enclosure U.S. NUCLEAR REGULATORY COMMISSION REGION III Docket No:
50-255 License N o: DPR-20 Report No:
05000255/2014008 Licensee:
Entergy Nuclear Operations, Inc.
 
Facility:
Palisades Nuclear Plant Location:
Covert, MI Dates: September 8, 2014 through November 4, 2014 Inspectors:
S. Sheldon, Senior Engineering Inspector, Lead J. Corujo
-Sandin, Engineering Inspector, Mechanical C. Brown, Engineering Inspector, Electrical C. Zoia, Operations Engineer L. Rodriguez, Engineering Inspector, Observer H. Leake, Electrical Contractor C. Baron, Mechanical Contractor Approved by:
Ann Marie Stone, Chief Engineering Branch 2 Division of Reactor Safety i  


=SUMMARY OF FINDINGS=
=SUMMARY OF FINDINGS=
Inspection Report 05000255/2014008, 9/8/2014 - 11/4/2014, Palisades Nuclear Plant Component Design Bases Inspection (CDBI). The inspection was a 3-week onsite baseline inspection that focused on the design of components. The inspection was conducted by regional engineering inspectors and two consultants. Ten Green findings were identified by the inspectors. The findings were considered Non-Cited Violations (NCVs) of NRC regulations. The significance of inspection findings is indicated by their color (i.e., greater than Green, or Green, White, Yellow, Red) and determined using IMC 0609, "Significance Determination Process" dated June 2, 2011. Cross-cutting aspects are determined using IMC 0310, "Aspects Within the Cross-Cutting Areas" effective date January 1, 2014. All violations of NRC requirements are dispositioned in accordance with the NRC's Enforcement Policy dated July 9, 2013. The NRC's program for overseeing the safe operation of commercial nuclear power reactors is described in NUREG-1649, "Reactor Oversight Process" Revision 5, dated February 2014.
Inspection Report 05000255/2014008, 9/8/2014  
- 11/4/2014
, Palisades Nuclear Plant Component Design Bases Inspection (CDBI).
 
The inspection was a 3
-week onsite baseline inspection that focused on the design of components. The inspection was conducted by regional engineering inspectors and two consultants. Ten Green finding s were identified by the inspectors. The finding s were considered Non-Cited Violations (NCVs) of NRC regulations. The significance of inspection findings is indicated by their color (i.e., greater than Green, or Green, White, Yellow, Red)and determined using IMC 0609, "Significance Determination Process" dated June 2, 2011.
 
Cross-cutting aspect s are determined using IMC 0310, "Aspects Within the Cross-Cutting Areas" effective date January 1, 2014.
 
All violations of NRC requirements are dispositioned in accordance with the NRC's Enforcement Policy dated Jul y 9, 2013. The NRC's program for overseeing the safe operation of commercial nuclear power reactors is described in NUREG
-1649, "Reactor Oversight Process" Revision 5, dated February 2014
.  


===A. NRC-Identified and Self-Revealing Findings===
===A. NRC-Identified and Self-Revealing Findings===
Line 44: Line 85:
===Cornerstone: Initiating Events===
===Cornerstone: Initiating Events===
: '''Green.'''
: '''Green.'''
The inspectors identified a finding having very low safety significance and an associated Non-Cited Violation (NCV) of 10 CFR Part 50.36(c)(3), "Surveillance Requirements," for the failure to ensure the channel time delay for the degraded-voltage monitor was included in Technical Specification (TS) Surveillance Requirement (SR) 3.3.5.2.a. Specifically, the licensee failed to include in the TS SR the required time delay after the voltage relay trips before the preferred source of power is isolated and 1E electrical loads transferred to the stand-by Emergency Diesel Generators (EDGs). This finding was entered into the licensee's Corrective Action Program and the licensee's preliminary verification determined the degraded voltage monitors were still operable but degraded or non-conforming. The performance deficiency was determined to be more than minor because if left uncorrected, it would have the potential to lead to more significant safety concern. Specifically, by not incorporating the total time delay requirements into the Technical Specifications, (TS) the time could be changed without going through the TS change process, possibly leading to spurious trips of offsite power sources or possibly exceeding the accident analysis time is the FSAR. The inspectors determined the finding was of very low safety significance (Green) because it did not cause a reactor trip and the loss of mitigation equipment relied upon to transition the plant from the onset of the trip to a stable shutdown condition. The inspectors did not identify a cross-cutting aspect associated with this finding because the finding was not representative of the licensee's present performance.  (Section 1R21.3.b(9))  
The inspectors identified a finding having very low safety significance and an associated Non-Cited Violation (NCV) of 10 CFR Part 50.36(c)(3), "Surveillance Requirements," for the failure to ensure the channel time delay for the degraded-voltage monitor was included in Technical Specification (TS) Surveillance Requirement (SR) 3.3.5.2.a. Specifically, the licensee fail ed to include in the TS SR the required time delay after the voltage relay trips before the preferred source of power is isolated and 1E electrical loads transferred to the stand-by Emergency Diesel Generator s (EDGs). This finding was entered into the licensee's Corrective Action Program and the licensee
's preliminary verification determined the degraded voltage monitors were still operable but degraded or non-conforming.
 
The performance deficiency was determined to be more than minor because if left uncorrected, it would have the potential to lead to more significant safety concern. Specifically, by not incorporating the total time delay requirements into the Technical Specifications
, (TS) the time could be changed without going through the TS change process, possibly leading to spurious trips of offsite power sources or possibly exceeding the accident analysis time is the FSAR. The inspectors determined the finding was of very low safety significance (Green) because it did not cause a reactor trip and the loss of mitigation equipment relied upon to transition the plant from the onset of the trip to a stable shutdown condition. The inspectors did not identify a cross-cutting aspect associated with this finding because the finding was not representative of the licensee's present performance.
 
  (Section 1R21.3.b(
9))  
 
===Cornerstone: Mitigating Syste===


===Cornerstone: Mitigating Systems===
ms
: '''Green.'''
: '''Green.'''
The inspectors identified a finding of very low safety significance and associated Non-Cited Violation of 10 CFR Part 50, Appendix B, Criterion III, "Design Control" for the failure to ensure the safety-related Engineered Safeguard Systems trains would not be adversely affected by air entrainment when aligned to the Safety Injection and Refueling Water (SIRW) Tank. Specifically, calculation EA-C-PAL-0877D, assumed incorrectly only one train of the Engineered Safeguards System (ESS) was in operation when evaluating if the SIRW Tank reaches the limit for critical submergence during a tank drawdown. As part of their corrective actions, the licensee re-evaluated the scenarios of concern, performed an operability evaluation, and implemented compensatory actions. The performance deficiency was determined to be more than minor because it impacted the Equipment Performance attribute of the Reactor Safety, Mitigating Systems Cornerstone and adversely affected the cornerstone objective to ensure the availability, reliability, and capability of systems that respond to initiating events to prevent undesirable consequences. Specifically, air entrainment into the ESS systems could potentially impact the operability of the system by air binding the pumps, reduce discharge flow, discharge pressure and/or delay injection. The inspectors determined the finding was of very low safety significance (Green) because the finding was a deficiency affecting the design or qualification of a mitigating structure system or component (SSC) but the SSC maintained its operability. The inspectors did not identify a cross-cutting aspect associated with this finding because the finding was not representative of the licensee's present performance. (Section 1R21.3.b(1))
The inspectors identified a finding of very low safety significance and associated Non-Cited Violation of 10 CFR Part 50, Appendix B, Criterion III, "Design Control" for the failure to ensure the safety-related Engineered Safeguard Systems trains would not be adversely affected by air entrainment when aligned to the Safety Injection and Refueling Water (SIRW) Tank. Specifically, calculation EA
-C-PAL-0877D, assumed incorrectly only one train of the Engineered Safeguards System (ESS) was in operation when evaluating if the SIRW Tank reaches the limit for critical submergence during a tank drawdow n. As part of their corrective actions, the licensee re-evaluated the scenario s of concern, performed an operability evaluation, and implemented compensatory actions.
 
The performance deficiency was determined to be more than minor because it impacted the Equipment Performance attribute of the Reactor Safety, Mitigating Systems Cornerstone and adversely affected the cornerstone objective to ensure the availability, reliability, and capability of systems that respond to initiating events to prevent undesirable consequences
. Specifically, air entrainment into the ESS systems could potentially impact the operability of the system by air binding the pumps, reduce discharge flow, discharge pressure and/or delay injection
. The inspectors determined the finding was of very low safety significance (Green) because the finding was a deficiency affecting the design or qualification of a mitigating structure system or component (SSC) but the SSC maintained its operability. The inspectors did not identify a cross-cutting aspect associated with this finding because the finding was not representative of the licensee's present performance.
 
  (Section 1R21.3.b(1))
: '''Green.'''
: '''Green.'''
The inspectors identified a finding of very low safety significance and associated NCV of 10 CFR Part 50, Appendix B, Criterion III, "Design Control," for the licensee's failure to ensure the incoming feeder cables from startup transformer 1-2 to 2400 V safety-related Buses 1C and 1D were sized in accordance with their design basis, as described in Palisades FSAR Section 8.5.2. Specifically, the licensee failed to ensure the ampacity of the cables was at least as high as their maximum steady-state current. The licensee entered this finding into their Correction Action Program and verified the operability of the cables. The performance deficiency was determined to be more than minor, because it impacted the Design Control attribute of the Reactor Safety, Mitigating Systems Cornerstone and adversely affected the cornerstone objective to ensure the availability, reliability, and capability of systems that respond to initiating events to prevent undesirable consequences. Specifically, cables were undersized with respect to the loading that would automatically occur as the result of a design basis accident. The inspectors determined the finding was of very low safety significance (Green) because the SSC maintained its operability and functionality. This finding had a crosscutting aspect in the area of Human Performance, associated with the Design Margin component, because the licensee did not ensure that equipment is operated and maintained within design margins, and margins are carefully guarded and changed only through a systematic and rigorous process. [H.6] (Section 1R21.3.b(2))
The inspectors identified a finding of very low safety significance and associated NCV of 10 CFR Part 50, Appendix B, Criterion III, "Design Control," for the licensee's failure to ensure the incoming feeder cables from startup transformer 1
-2 to 2400 V safety-related Buses 1C and 1D were sized in accordance with their design basis, as described in Palisades FSAR Section 8.5.2. Specifically, the licensee failed to ensure the ampacity of the cables was at least as high as their maximum steady-state current. The licensee entered this finding into their Correction Action Program and verified the operability of the cables.
 
The performance deficiency was determined to be more than minor, because it impacted the Design Control attribute of the Reactor Safety,
Mitigating Systems Cornerstone and adversely affected the cornerstone objective to ensure the availability, reliability, and capability of systems that respond to initiating events to prevent undesirable consequences. Specifically, cables were undersized with respect to the loading that would automatically occur as the result of a design basis accident. The inspectors determined the finding was of very low safety significance (Green) because the SSC maintained its operability and functionality. This finding had a crosscutting aspect in the area of Human Performance, associated with the Design Margin component, because the licensee did not ensure that equipment is operated and maintained within design margins, and margins are carefully guarded and changed only through a systematic and rigorous process
. [H.6] (Section 1R21.3.b(
2))
: '''Green.'''
: '''Green.'''
The inspectors identified a finding of very low safety significance and associated NCV of 10 CFR Part 50, Appendix B, Criterion III, "Design Control," for the licensee's failure to ensure electric motors are sized in accordance with the design basis, as discussed in Palisades FSAR Section 6.2.3.1. Specifically, the horsepower ratings of certain motors are less than power demands of their driven equipment, and they were not analyzed to ensure overheating would not occur. The licensee entered this finding into their Correction Action Program with a recommended action to analyze the effect of the condition, and has verified the operability of the motors. This performance deficiency was determined to be more than minor, because it impacted the Design Control attribute of the Reactor Safety, Mitigating Systems Cornerstone and adversely affected the cornerstone objective to ensure the availability, reliability, and capability of systems that respond to initiating events to prevent undesirable consequences. Specifically, motors serving loads with power demands in excess of the motor horsepower ratings were not analyzed to ensure that motor damage would not occur. The inspectors determined the finding was of very low safety significance (Green) because the SSC maintained its operability and functionality. This finding had a crosscutting aspect in the area of Human Performance, associated with the Design Margin component, because the licensee failed to ensure that equipment is operated within design margins, and margins are carefully guarded and changed only through a systematic and rigorous process. [H.6] (Section 1R21.3.b(3))
The inspectors identified a finding of very low safety significance and associated NCV of 10 CFR Part 50, Appendix B, Criterion III, "Design Control," for the licensee's failure to ensure electric motors are sized in accordance with the design basis, as discussed in Palisades FSAR Section 6.2.3.1. Specifically, the horsepower ratings of certain motors are less than power demands of their driven equipment, and they were not analyzed to ensure overheating would not occur. The licensee entered this finding into their Correction Action Program with a recommended action to analyze the effect of the condition, and has verified the operability of the motors.
 
This performance deficiency was determined to be more than minor, because it impacted the Design Control attribute of the Reactor Safety, Mitigating Systems Cornerstone and adversely affected the cornerstone objective to ensure the availability, reliability, and capability of systems that respond to initiating events to prevent undesirable consequences. Specifically, motors serving loads with power demands in excess of the motor horsepower ratings were not analyzed to ensure that motor damage would not occur. The inspectors determined the finding was of very low safety significance (Green) because the SSC maintained its operability and functionality. This finding had a crosscutting aspect in the area of Human Performance, associated with the Design Margin component, because the licensee failed to ensure that equipment is operated within design margins, and margins are carefully guarded and changed only through a systematic and rigorous process. [H.6]
(Section 1R21.3.b(
3))
: '''Green.'''
: '''Green.'''
The inspectors identified a finding of very low safety significance and associated NCV of 10 CFR Part 50, Appendix B, Criterion III, "Design Control," for the licensee's failure to ensure that voltages on the 480V system do not exceed equipment ratings. Specifically, the licensee increased the output voltage of the supply transformers to the 480V safety-related buses by 2.5 percent, but failed to ensure the resulting voltages would not exceed equipment ratings when the system is powered from the station power transformer or emergency diesel generator. The licensee entered this finding into their Correction Action Program and verified the operability of the affected equipment. The performance deficiency was determined to be more than minor, because it impacted the Design Control attribute of the Reactor Safety, Mitigating Systems Cornerstone and adversely affected the cornerstone objective to ensure the availability, reliability, and capability of systems that respond to initiating events to prevent undesirable consequences. Specifically, the licensee failed to verify or check the voltage increase on the 480V system to ensure the maximum allowable voltage would not exceed equipment ratings. The inspectors determined the finding was of very low safety significance (Green) because the affected SSCs maintained their operability and functionality. The inspectors did not identify a cross-cutting aspect associated with this finding, because the finding was not representative of the licensee's present performance. (Section 1R21.3.b(4))
The inspectors identified a finding of very low safety significance and associated NCV of 10 CFR Part 50, Appendix B, Criterion III, "Design Control," for the licensee's failure to ensure that voltages on the 480V system do not exceed equipment ratings. Specifically, the licensee increased the output voltage of the supply transformers to the 480V safety-related buses by 2.5 percent, but failed to ensure the resulting voltages would not exceed equipment ratings when the system is powered from the station power transformer or emergency diesel generator. The licensee entered this finding into their Correction Action Program and verified the operability of the affected equipment.
 
The performance deficiency was determined to be more than minor, because it impacted the Design Control attribute of the Reactor Safety, Mitigating Systems Cornerstone a nd adversely affected the cornerstone objective to ensure the availability, reliability, and capability of systems that respond to initiating events to prevent undesirable consequences. Specifically, the licensee failed to verify or check the voltage increase on the 480V system to ensure th e maximum allowable voltage would not exceed equipment ratings. The inspectors determined the finding was of very low safety significance (Green) because the affected SSCs maintained their operability and functionality.
 
The inspectors did not identify a cross-cutting aspect associated with this finding, because the finding was not representative of the licensee's present performance.
 
  (Section 1R21.3.b(
4))
: '''Green.'''
: '''Green.'''
The inspectors identified a finding of very low safety significance and associated Non-Cited Violation of Technical Specifications 5.5.7, "Inservice Testing Program," for the failure to perform comprehensive pump testing of Containment Spray Pump P-54A in accordance with the code of record. Specifically, the licensee did not rerun a comprehensive pump test, as required by the code's ISTB-6300 "Systematic Error" section. As part of their corrective actions, the licensee entered the issue into the Corrective Action Program, and determined the component remained operable. The performance deficiency was determined to be more than minor because it impacted the Equipment Performance attribute of the Reactor Safety, Mitigating Systems Cornerstone and adversely affected the cornerstone objective to ensure the availability, reliability, and capability of systems that respond to initiating events to prevent undesirable consequences. Specifically, failing to perform testing as required could result in the degradation of the equipment being undetected. The finding screened as having very low safety significance because the finding was a deficiency affecting the design or qualification of a mitigating structure system or component (SSC) but the SSC maintained its operability. The findings had a cross-cutting aspect in the area of Problem Identification and Resolution, Evaluation, because the licensee failed to thoroughly evaluate the issue to ensure that resolutions address causes and extents of conditions commensurate with their safety significance. [P.2]  (Section 1R21.3.b(5))
The inspectors identified a finding of very low safety significance and associated Non-Cited Violation of Technical Specifications 5.5.7, "Inservice Testing Program
," for the failure to perform comprehensive pump testing of Containment Spray Pump P-54A in accordance with the code of record.
 
Specifically, the licensee did not rerun a comprehensive pump test, as required by the code's ISTB
-6300 "Systematic Error" section. As part of their corrective actions, the licensee entered the issue into the Corrective Action Program, and determined the component remained operable.
 
The performance deficiency was determined to be more than minor because it impacted the Equipment Performance attribute of the Reactor Safety, Mitigating Systems Cornerstone and adversely affected the cornerstone objective to ensure the availability, reliability, and capability of systems that respond to initiating events to prevent undesirable consequences. Specifically, failing to perform testing as required could result in the degradation of the equipment being undetected. The finding screened as having very low safety significance because the finding was a deficiency affecting the design or qualification of a mitigating structure system or component (SSC) but the SSC maintained its operability.
 
The findings had a cross-cutting aspect in the area of Problem Identification and Resolution, Evaluation, because the licensee failed to thoroughly evaluate the issue to ensure that resolutions address causes and extents of conditions commensurate with their safety significance.
 
[P.2]  (Section 1R21.3.b(
5))
5
5
: '''Green.'''
: '''Green.'''
The inspectors identified a finding of very low safety significance and associated NCV of 10 CFR Part 50, Appendix B, Criterion XI, "Test Control," for the licensee's failure to have adequate acceptance criteria in the emergency diesel generator surveillance procedures. Specifically, the licensee failed to ensure the surveillance test procedures for the emergency diesel generator largest load rejection test bounded the power demand of the largest load, as required by Technical Specification SR 3.8.1.5. The licensee entered this finding into their Correction Action Program and verified the operability of the emergency diesel generators. The performance deficiency was determined to be more than minor, because it impacted the Procedure Quality attribute of the Reactor Safety, Mitigating Systems Cornerstone and adversely affected the cornerstone objective of ensuring the availability, reliability, and capability of systems to respond to initiating events to prevent undesirable consequences. Specifically, the surveillance procedure error could result in acceptance of test results that did not satisfy Technical Specification SR 3.8.1.5 for rejection of a load greater than or equal to the emergency diesel generator's single largest predicted post-accident load. The inspectors determined the finding was of very low safety significance (Green) because the SSC maintained its operability and functionality. This finding had a cross-cutting aspect in the area of Human Performance, associated with the Resources component, because the licensee failed to ensure that personnel, equipment, procedures, and other resources are adequate to assure nuclear safety by maintaining long term plant safety. [H.1] (Section 4OA2.1.b(1))  
The inspectors identified a finding of very low safety significance and associated NCV of 10 CFR Part 50, Appendix B, Criterion XI, "Test Control," for the licensee's failure to have adequate acceptance criteria in the emergency diesel generator surveillance procedures. Specifically, the licensee failed to ensure the surveillance test procedures for the emergency diesel generator largest load rejection test bounded the power demand o f the largest load, as required by Technical Specification SR 3.8.1.5. The licensee entered this finding into their Correction Action Program and verified the operability of the emergency diesel generators.
 
The performance deficiency was determined to be more than minor, because it impacted the Procedure Quality attribute of the Reactor Safety, Mitigating Systems Cornerstone and adversely affected the cornerstone objective of ensuring the availability, reliability, and capability of systems to respond to initiating events to prevent undesirable consequences. Specifically, the surveillance procedure error could result in acceptance of test results that did not satisfy Technical Specification SR 3.8.1.5 for rejection of a load greater than or equal to the emergency diesel generator's single largest predicted post-accident load. The inspectors determined the finding was of very low safety significance (Green) because the SSC maintained its operability and functionality. This finding had a cross-cutting aspect in the area of Human Performance, associated with the Resources component, because the licensee failed to ensure that personnel, equipment, procedures, and other resources are adequate to assure nuclear safety by maintaining long term plant safety. [H.1] (Section 4OA2.1.b(1))  


===Cornerstone: Barrier Integrity===
===Cornerstone: Barrier Integrity===
: '''Green.'''
: '''Green.'''
The inspectors identified a finding of very low safety significance (Green) and associated NCV of 10 CFR Part 50, Appendix B, Criterion III, "Design Control," for the licensee's failure to correctly translate design valve leakage limits into the applicable test procedure. Specifically, the acceptance criterion for emergency core cooling system (ECCS)/containment spray (CS) recirculation isolation valves CV-3027 and CV-3056 had not been correctly adjusted to account for the higher differential pressure associated with ECCS operation under post-accident conditions. The licensee entered this finding into their Corrective Action Program to correct the valve leakage limit. The performance deficiency was determined to be more than minor because it impacted the Design Control attribute of the Barrier Integrity Cornerstone and adversely affected the associated cornerstone objective to provide reasonable assurance that containment could protect the public from radionuclide releases caused by accidents or events. Specifically, leakage approaching the procedural values would exceed analyzed dose calculations. The finding screened as of very low safety significance (Green) because the finding did not represent an actual open pathway in the physical integrity of reactor containment, containment isolation system, or heat removal components and did not involve an actual reduction in function of hydrogen igniters in the reactor containment. The inspectors determined this finding did not have an associated cross-cutting aspect because it was not representative of present performance. (Section 1R21.3.b(6))
The inspectors identified a finding of very low safety significance (Green) and associated NCV of 10 CFR Part 50, Appendix B, Criterion III, "Design Control," for the licensee's failure to correctly translate design valve leakage limits into the applicable test procedure. Specifically, the acceptance criterion for emergency core cooling system (ECCS)/containment spray (CS) recirculation isolation valves CV
-3027 and CV
-3056 had not been correctly adjusted to account for the higher differential pressure associated with ECCS operation under post-accident conditions.
 
The licensee entered this finding into their Corrective Action Program to correct the valve leakage limit.
 
The performance deficiency was determined to be more than minor because it impacted the Design Control attribute of the Barrier Integrity Cornerstone and adversely affected the associated cornerstone objective to provide reasonable assurance that containment could protect the public from radionuclide releases caused by accidents or events.
 
Specifically, leakage approaching the procedural values would exceed analyzed dose calculations
. The finding screened as of very low safety significance (Green) because the finding did not represent an actual open pathway in the physical integrity of reactor containment, containment isolation system, or heat removal components and did not involve an actual reduction in function of hydrogen igniters in the reactor containment.
 
The inspectors determined this finding did not have an associated cross-cutting aspect because it was not representative of present performance.
 
  (Section 1R21.3.b(
6))
: '''Green.'''
: '''Green.'''
The inspectors identified a finding of very low safety significance (Green) and associated NCV of 10 CFR Part 50, Appendix B, Criterion VII, "Control of Purchased Material, Equipment, and Services," for the licensee's failure to identify non-safety-related sub-components improperly supplied with safety-related valves. Specifically, ECCS/CS recirculation isolation valves CV-3027 and CV-3056, which were installed in 2007, were supplied with non-safety-related sub-components. These components were identified as non-safety-related on the vendor drawings. In addition, the licensee later installed a section of non-safety-related tubing on valve CV-3027 based on the incorrect vendor drawing. The licensee entered this finding into their Corrective Action Program to correct the valve drawings and replace the non-safety-related parts. The performance deficiency was determined to be more than minor because it impacted the Design Control attribute of the Barrier Integrity Cornerstone and adversely affected the associated cornerstone objective to provide reasonable assurance that containment could protect the public from radionuclide releases caused by accidents or events. Specifically, the licensee failed to identify non-safety-related sub-components improperly supplied with safety-related valves which would form part of the containment barrier under post-accident conditions. The finding screened as of very low safety significance (Green) because the finding did not represent an actual open pathway in the physical integrity of reactor containment, containment isolation system, or heat removal components and did not involve an actual reduction in function of hydrogen igniters in the reactor containment. The inspectors determined this finding did not have an associated cross-cutting aspect because it was not representative of the licensee's present performance. (Section 1R21.3.b(7))
The inspectors identified a finding of very low safety significance (Green) and associated NCV of 10 CFR Part 50, Appendix B, Criterion VII, "Control of Purchased Material, Equipment, and Services," for the licensee's failure to identify non-safety-related sub-components improperly supplied with safety-related valves. Specifically, ECCS/CS recirculation isolation valves CV
-3027 and CV
-3056, which were installed in 2007, were supplied with non-safety-related sub-components. These components were identified as non-safety-related on the vendor drawings. In addition, the licensee later installed a section of non-safety-related tubing on valve CV
-3027 based on the incorrect vendor drawing.
 
The licensee entered this finding into their Corrective Action Program to correct the valve drawings and replace the non-safety-related parts
. The performance deficiency was determined to be more than minor because it impacted the Design Control attribute of the Barrier Integrity Cornerstone and adversely affected the associated cornerstone objective to provide reasonable assurance that containment could protect the public from radionuclide releases caused by accidents or events. Specifically, the licensee failed to identify non-safety-related sub-components improperly supplied with safety-related valves which would form part of the containment barrier under post-accident conditions.
 
The finding screened as of very low safety significance (Green) because the finding did not represent an actual open pathway in the physical integrity of reactor containment, containment isolation system, or heat removal components and did not involve an actual reduction in function of hydrogen igniters in the reactor containment.
 
The inspectors determined this finding did not have an associated cross-cutting aspect because it was not representative of the licensee's present performance.
 
  (Section 1R21.3.b(7))
: '''Green.'''
: '''Green.'''
The inspectors identified a finding of very low safety significance and associated NCV of 10 CFR Part 50, Appendix B, Criterion XI, "Test Control," for the licensee's failure to establish an adequate test program for the Shutdown Cooling (SDC) Heat Exchangers (HXs) to demonstrate they can perform as designed. Specifically, the licensee failed to take actions to ensure the SDC HXs' heat transfer capability met its design bases, as assumed in design bases calculations. The performance deficiency was determined to be more than minor because it impacted the Design Control attribute of the Barrier Integrity Cornerstone and adversely affected the associated cornerstone objective to provide reasonable assurance that containment could protect the public from radionuclide releases caused by accidents or events. Specifically, the licensee failed to verify the SDC HXs heat transfer capability met their design bases, as assumed in design bases calculations, to limit containment temperatures and pressures during an event. The finding screened as of very low safety significance (Green) because the finding did not represent an actual open pathway in the physical integrity of reactor containment, containment isolation system, or heat removal components and did not involve an actual reduction in function of hydrogen igniters in the reactor containment. The inspectors determined this finding had an associated cross-cutting aspect, Conservative Bias, in the Human Performance cross-cutting area. Specifically, on several occasions when the licensee identified the need to perform testing and/or inspection of the SDC HXs, the licensee did not take actions because they did not believe any regulatory requirements or technical issues existed that required the testing and/or inspections. [H.14]  (Section 1R21.3.b(8))  
The inspectors identified a finding of very low safety significance and associated NCV of 10 CFR Part 50, Appendix B, Criterion XI, "Test Control," for the licensee's failure to establish an adequate test program for the Shutdown Cooling (SDC) Heat Exchangers (HXs) to demonstrate they can perform as designed. Specifically, the licensee failed to take actions to ensure the SDC HXs' heat transfer capability met its design bases, as assumed in design bases calculations.
 
The performance deficiency was determined to be more than minor because it impacted the Design Control attribute of the Barrier Integrity Cornerstone and adversely affected the associated cornerstone objective to provide reasonable assurance that containment could protect the public from radionuclide releases caused by accidents or events. Specifically, the licensee failed to verify the SDC HXs heat transfer capability met their design bases, as assumed in design bases calculations, to limit containment temperatures and pressures during an event.
 
The finding screened as of very low safety significance (Green) because the finding did not represent an actual open pathway in the physical integrity of reactor containment, containment isolation system, or heat removal components and did not involve an actual reduction in function of hydrogen igniters in the reactor containment. The inspectors determined this finding had an associated cross-cutting aspect, Conservative Bias, in the Human Performance cross-cutting area
. Specifically, on several occasions when the licensee identified the need to perform testing and/or inspection of the SDC HXs, the licensee did not take actions because they did not believe any regulatory requirements or technical issues existed that required the testing and/or inspections.
 
[H.14]  (Section 1R21.3.b(
8))  


===B. Licensee-Identified Violations===
===B. Licensee-Identified Violations===
Violations of very low safety or security significance or Severity Level IV that were identified by the licensee have been reviewed by the NRC. Corrective actions taken or planned by the licensee have been entered into the licensee's Corrective Action Program (CAP). These violations and CAP tracking numbers are listed in Section 4OA7 of this report.
Violations of very low safety or security significance or Severity Level IV that were identified by the licensee have been reviewed by the NRC. Corrective actions taken or planned by the licensee have been entered into the licensee's Corrective Action Program (CAP). These violations and CAP tracking numbers are listed in Section 4OA7 of this report.


Line 84: Line 206:
{{IP sample|IP=IP 71111.21}}
{{IP sample|IP=IP 71111.21}}
===.1 Introduction===
===.1 Introduction===
The objective of the component design bases inspection is to verify the design bases have been correctly implemented for the selected risk significant components and the operating procedures and operator actions are consistent with design and licensing bases. As plants age, their design bases may be difficult to determine and an important design feature may be altered or disabled during a modification. The Probabilistic Risk Assessment (PRA) model assumes the capability of safety systems and components to perform their intended safety function successfully. This inspectable area verifies aspects of the Initiating Events, Mitigating Systems, and Barrier Integrity cornerstones for which there are no indicators to measure performance. Specific documents reviewed during the inspection are listed in the attachment to the report.


===.2 Inspection Sample Selection Process The inspectors used information contained in the licensee's PRA and the Palisades Standardized Plant Analysis Risk Model to identify a scenario to use as the basis for component selection.===
The objective of the component design bases inspection is to verify the design bases have been correctly implemented for the selected risk significant components and the operating procedures and operator actions are consistent with design and licensing bases. As plants age, their design bases may be difficult to determine and an important design feature may be altered or disabled during a modification. The Probabilistic Risk Assessment (PRA) model assumes the capability of safety systems and components to perform their intended safety function successfully. This inspectable area verifies aspects of the Initiating Events, Mitigating Systems, and Barrier Integrity cornerstones for which there are no indicators to measure performance.
The scenario selected was a Large Break Loss of Coolant Accident (LBLOCA) and subsequent transfer to recirculation. Based on this scenario, a number of risk significant components were selected for the inspection. The inspectors also used additional component information such as a margin assessment in the selection process. This design margin assessment considered original design reductions caused by design modification, power uprates, or reductions due to degraded material condition. Equipment reliability issues were also considered in the selection of components for detailed review. These included items such as performance test results, significant corrective actions, repeated maintenance activities, Maintenance Rule (a)(1) status, components requiring an operability evaluation, NRC resident inspector input of problem areas/equipment, and system health reports. Consideration was also given to the uniqueness and complexity of the design, operating experience, and the available defense in depth margins. A summary of the reviews performed and the specific inspection findings identified are included in the following sections of the report.


The inspectors also identified procedures and modifications for review that were associated with the selected components. In addition, the inspectors selected operating experience issues associated with the selected components. This inspection constituted 20 samples as defined in Inspection Procedure 71111.21-05.
Specific documents reviewed during the inspection are listed in the attachment to the report.
 
===.2 Inspection Sample Selection Process===
 
The inspectors used information contained in the licensee's PRA and the Palisades Standardized Plant Analysis Risk Model to identify a scenario to use as the bas is for component selection. The scenario selected was a Large Break Loss of Coolant Accident (LBLOCA)and subsequent transfer to recirculation. Based on this scenario, a number of risk significant components were selected for the inspection.
 
The inspectors also used additional component information such as a margin assessment in the selection process. This design margin assessment considered original design reductions caused by design modification, power uprates, or reductions due to degraded material condition. Equipment reliability issues were also considered in the selection of components for detailed review. These included items such as performance test results, significant corrective actions, repeated maintenance activities, Maintenance Rule (a)(1) status, components requiring an operability evaluation, NRC resident inspector input of problem areas/equipment, and system health reports. Consideration was also given to the uniqueness and complexity of the design, operating experience, and the available defense in depth margins. A summary of the reviews performed and the specific inspection findings identified are included in the following sections of the report.
 
The inspectors also identified procedures and modifications for review that were associated with the selected components. In addition, the inspectors selected operating experience issues associated with the selected components.
 
This inspection constituted 20 samples as defined in Inspection Procedure 71111.21-05.


8
8
Line 96: Line 226:


====a. Inspection Scope====
====a. Inspection Scope====
The inspectors reviewed the Final Safety Analysis Report (FSAR), Technical Specifications (TS), design basis documents, drawings, calculations and other available design basis information, to determine the performance requirements of the selected components. The inspectors used applicable industry standards, such as the American Society of Mechanical Engineers (ASME) Code, Institute of Electrical and Electronics Engineers (IEEE) Standards and the National Electric Code, to evaluate acceptability of the systems' design. The NRC also evaluated licensee actions, if any, taken in response to NRC issued operating experience, such as Bulletins, Generic Letters (GLs), Regulatory Issue Summaries (RISs), and Information Notices (INs). The review was to verify the selected components would function as designed when required and support proper operation of the associated systems. The attributes that were needed for a component to perform its required function included process medium, energy sources, control systems, operator actions, and heat removal. The attributes to verify that the component condition and tested capability was consistent with the design bases and was appropriate may include installed configuration, system operation, detailed design, system testing, equipment and environmental qualification, equipment protection, component inputs and outputs, operating experience, and component degradation. For each of the components selected, the inspectors reviewed the maintenance history, preventive maintenance activities, system health reports, operating experience-related information, vendor manuals, electrical and mechanical drawings, and licensee Corrective Action Program documents. Field walkdowns were conducted for all accessible components to assess material condition and to verify that the as-built condition was consistent with the design. Other attributes reviewed are included as part of the scope for each individual component. The following 14 components were reviewed: Containment Spray Pump P-54A:  The inspectors reviewed calculations related to pump hydraulics to ensure the pump was capable of performing its design bases accident mitigation functions. The calculations included analysis of net positive suction head (NPSH), discharge head, flow, and management of potential air entrainment mechanisms. The inspectors also reviewed procedures and system diagrams to ensure the pump would be operated within its design parameters during an event. Recent Inservice Test (IST) reports and historical trends data were reviewed to assess compliance with Technical Specification surveillance requirements, compliance with the applicable code of record, review potential component degradation, and impact on design margins. The inspectors discussed the component's performance with the system engineer and reviewed recent corrective action documents related to the SSC in order to assess the overall health of the component. In addition, the inspectors performed a walkdown to assess material condition of the pump and supporting components. 2400V Switchgear 1D:  In addition to the generic list of attributes listed above, the inspectors reviewed electrical diagrams, calculations, and procedures, including system short circuit and load flow calculations. Incoming breaker protective relay trip setpoints were reviewed to evaluate the adequacy of the switchgear bus and breakers to carry anticipated loads under limiting conditions and to withstand and interrupt maximum available faults. The inspectors also 9 reviewed the voltage profile of the offsite system, voltage drop calculations, and the undervoltage relay settings to assess adequacy of voltage at the terminals of the safety-related loads and ability to remain connected to offsite power under worst operating and accident conditions. Sizing of the incoming feeder cables was reviewed to determine their capability under worst accident conditions. SIRW Tank Suction Valve (CV-3057):  The inspectors reviewed procedures and system diagrams to ensure the component would be operated within its design parameters during a design basis event. The inspectors discussed the component's performance with the system engineer, and reviewed recent corrective action documents related to the SSC in order to assess the overall health of the component. Calculations related to the component's safety-related air supply was also reviewed. The inspectors reviewed the circuit protection and the environmental qualification to confirm the circuit was adequately protected, and the valve was capable of performing its intended safety function. Voltage drop calculations were reviewed to verify the associated control circuits had adequate voltage under degraded voltage conditions. The inspectors also reviewed surveillance test data, any operator control limitations, operating procedures, vendor and generic communications, recent CRs and operability evaluations for any anomalous indications or possible difficulties in system operation. In addition, the inspectors performed a walkdown to assess material condition of the valve, supporting components, and identify any potential concerns related to adverse interaction with the surrounding equipment. Containment Sump Outlet Valve CV-3029:  The inspectors reviewed the design basis of the air-operated valve including thrust calculations, the basis for valve stroke time requirements, and the associated control logic. The inspectors reviewed test, and emergency procedures, as well as the response of the system to the failure of the valve to operate under accident conditions. The inspectors reviewed the capacity of the high-pressure air system to verify its capability to operate the valve with a loss of normal instrument air. The inspectors reviewed air system leak test procedures and results and performed a walkdown of the valve to verify its material condition. The inspectors also reviewed the circuit protection, the environmental qualification of affected circuit components to confirm the circuit was adequately protected, and the valve was capable of performing its intended safety function during a design basis accident. Voltage drop calculations were reviewed to verify the associated control circuits had adequate voltage under degraded voltage conditions. The inspectors also reviewed operating procedures, vendor and generic communications, recent CRs and operability evaluations for any anomalous indications or possible difficulties in system operation. SIRW Tank Level Switch LS-327:  The inspectors reviewed installation drawings and vendor documentation to verify the switch was appropriate for its use. The inspectors reviewed the Recirculation Actuation Signal (RAS) logic to verify the switch met its design basis. The inspectors also reviewed switch calibration and testing procedures. In addition, the inspectors performed a walkdown of the SIRW tank to assess the level transmitters used for calibration of the switch. Shutdown Cooling Heat Exchanger E-60A:  The inspectors reviewed heat exchanger design documents to verify assumptions made in design bases calculations. The inspectors reviewed normal, test, and emergency procedures. The inspectors also reviewed historical information to understand how heat 10 exchanger performance had been validated since original installation. A walkdown was performed to assess the material condition of the heat exchanger and supporting components. In addition, the inspectors reviewed aging management aspects related to the heat exchanger. Component Cooling Water (CCW) Pump (P-52B):  The inspectors reviewed calculations related to pump hydraulics to ensure the pump was capable of performing its design bases accident mitigation functions. Included in the review were cooling requirements for the component and the supplied loads. Also, reviewed were potential alternate sources for cooling the supplied load if CCW were to become unavailable during an accident. The inspectors also reviewed procedures and system diagrams to ensure the pump would be operated within its design parameters during an event. The inspectors discussed the component's performance with the system engineer, and reviewed recent corrective action documents related to the SSC in order to assess the overall health of the component. In addition, the inspectors performed a walkdown to assess material condition of the pump, supporting components, and identify any potential concerns related to adverse interaction with the surrounding or nearby equipment. Component Cooling Water (CCW) Relief Valve RV-0956:  The inspectors also reviewed procedures and system diagrams to ensure the pump would be operated within its design parameters during an event. The inspectors discussed the component's performance with the system engineer, and reviewed recent corrective action documents related to the SSC in order to assess the overall health of the component. In addition, the inspectors reviewed vendor manuals and technical sheets for the component. The required licensing and design bases for the component were reviewed and discussed with NRR, and requires further evaluation. Containment Sump Strainer:  The inspectors reviewed results of sump inspections and ECCS pump NPSH analyses to verify the pressure drop across the screens under post-accident conditions. The inspectors reviewed normal, test, and emergency procedures. The inspectors also reviewed the basis for the maximum particle size. 125 VDC Bus D10:  The inspectors reviewed the circuit diagrams, the short circuit current calculation, and the coordination calculation to confirm the short circuit duty and the proper coordination between the panel fuses and branch circuit cabling with the upstream protective device. The inspectors also reviewed the panel electrical loading and voltage drop calculations, and the branch circuit cabling, to confirm bus and circuit cable ampacity was adequate and branch circuits had adequate voltage. The inspectors also reviewed recent CRs, operability evaluations, and operating procedures for any anomalous indications. LPSI Pump Suction Crosstie Valve MO-3090:  The inspectors reviewed the design basis of the motor-operated valve including thrust calculations, the basis for valve stroke time requirements, and the associated control logic. The inspectors reviewed normal, test, and emergency procedures including the response to the single failure of an electrical power supply to MO-3090. The inspectors also reviewed the interface between the electrical system distribution calculations and the valve thrust calculation to verify adequate voltage to the 11 valve motor under the most limiting conditions. The inspectors performed a walkdown of the valve to verify its material condition. 480V Motor Control Center (MCC) 23:  In addition to the generic list of attributes listed above, the inspectors reviewed electrical diagrams, calculations, and procedures, including system short circuit calculations and main alternating current (AC) electrical distribution analysis. Voltage calculations were reviewed to verify minimum and maximum voltages were within equipment capabilities, including downstream power and control components. Thermal overload protection for motor operated valves was reviewed to assess the adequacy of valve motor overload protection. ECCS/CS Minimum Flow Valve CV-3027:  The inspectors reviewed the design basis of the air-operated valve including thrust calculations, the basis for valve stroke time requirements, and the associated control logic. The inspectors reviewed normal, test, and emergency procedures as well as the response of the system to the single failure of the valve to operate under accident conditions. The inspectors reviewed the basis for the valve leakage limits and reviewed leak test procedures and results. The inspectors also reviewed the safety classification of valve sub-components. The inspectors performed a walkdown of the valve to verify its material condition. 125 VDC Bus D11:  The inspectors reviewed the circuit diagrams, the short circuit current calculation, and the coordination calculation to confirm the short circuit duty and the proper coordination between the panel fuses and branch circuit cabling with the upstream protective device. The inspectors reviewed the degraded voltage protection design scheme to determine whether it afforded adequate voltage to safety-related devices at all voltage distribution levels. The inspectors also reviewed the panel electrical loading and the branch circuit cabling, to confirm bus, circuit cable ampacity was adequate, and branch circuits had adequate voltage. The inspectors also reviewed recent CRs, operability evaluations, and operating procedures for any anomalous indications.
The inspectors reviewed the Final Safety Analysis Report (FSAR), Technical Specifications (TS), design basis documents, drawings, calculations and other available design basis information, to determine the performance requirements of the selected components. The inspectors used applicable industry standards, such as the American Society of Mechanical Engineers (ASME) Code, Institute of Electrical and Electronics Engineers (IEEE) Standards and the National Electric Code, to evaluate acceptability of the systems' design. The NRC also evaluated licensee actions, if any, taken in response to NRC issued operating experience, such as Bulletins, Generic Letters (GLs), Regulatory Issue Summaries (RISs), and Information Notices (INs). The review was to verify the selected components would function as designed when required and support proper operation of the associated systems. The attributes that were needed for a component to perform its required function included process medium, energy sources, control systems, operator actions, and heat removal. The attributes to verify that the component condition and tested capability was consistent with the design bases and was appropriate may include installed configuration, system operation, detailed design, system testing, equipment and environmental qualification, equipment protection, component inputs and outputs, operating experience, and component degradation.
 
For each of the components selected, the inspectors reviewed the maintenance history, preventive maintenance activities, system health reports, operating experience
-related information, vendor manuals, electrical and mechanical drawings, and licensee Corrective Action Program documents.
 
Field walkdowns were conducted for all accessible components to assess material condition and to verify that the as
-built condition was consistent with the design. Other attributes reviewed are included as part of the scope for each individual component.
 
The following 14 components were reviewed:
Containment Spray Pump P
-54A:  The inspectors reviewed calculations related to pump hydraulics to ensure the pump was capable of performing its design bases accident mitigation functions. The calculations included analysis of net positive suction head (NPSH), discharge head, flow, and management of potential air entrainment mechanisms. The inspectors also reviewed procedures and system diagrams to ensure the pump would be operated within its design parameters during an event. Recent Inservice Test (IST) reports and historical trends data were reviewed to assess compliance with Technical Specificatio n
surveillance requirements, compliance with the applicable code of record, review potential component degradation, and impact on design margins. The inspectors discussed the component's performance with the system engineer and reviewed recent corrective action documents related to the SSC in order to assess the overall health of the component. In addition, the inspectors performed a walkdown to assess material condition of the pump and supporting components.
 
2400V Switchgear 1D:  In addition to the generic list of attributes listed above, the inspectors reviewed electrical diagrams, calculations, and procedures, including system short circuit and load flow calculations. Incoming breaker protective relay trip setpoints were reviewed to evaluate the adequacy of the switchgear bus and breakers to carry anticipated loads under limiting conditions and to withstand and interrupt maximum available faults. The inspectors also 9 reviewed the voltage profile of the offsite system, voltage drop calculations, and the undervoltage relay settings to assess adequacy of voltage at the terminals of the safety
-related loads and ability to remain connected to offsite power under worst operating and accident conditions. Sizing of the incoming feeder cables was reviewed to determine their capability under worst accident conditions.
 
SIRW Tank Suction Valve (CV
-3057):  The inspectors reviewed procedures and system diagrams to ensure the component would be operated within its design parameters during a design basis event.
 
The inspectors discussed the component's performance with the system engineer, and reviewed recent corrective action documents related to the SSC in order to assess the overall health of the component.
 
Calculations related to the component
's safety-related air supply was also reviewed. The inspectors reviewed the circuit protection and the environmental qualification to confirm the circuit was adequately protected
, and the valve was capable of performing its intended safety function. Voltage drop calculations were reviewed to verify the associated control circuits had adequate voltage under degraded voltage conditions. The inspectors also reviewed surveillance test data, any operator control limitations, operating procedures, vendor and generic communications, recent CRs and operability evaluations for any anomalous indications or possible difficulties in system operation.
 
In addition, the inspectors performed a walkdown to assess material condition of the valve, supporting components, and identify any potential concerns related to adverse interaction with the surrounding equipment.
 
Containment Sump Outlet Valve CV
-3029:  The inspectors reviewed the design basis of the air
-operated valve including thrust calculations, the basis for valve stroke time requirements, and the associated control logic. The inspectors reviewed test, and emergency procedures
, as well as the response of the system to the failure of the valve to operate under accident conditions. The inspectors reviewed the capacity of the high
-pressure air system to verify its capability to operate the valve with a loss of normal instrument air. The inspectors reviewed air system leak test procedures and results and performed a walkdown of the valve to verify its material condition.
 
The inspectors also reviewed the circuit protection, the environmental qualification of affected circuit components to confirm the circuit was adequately protected, and the valve was capable of performing its intended safety function during a design basis accident. Voltage drop calculations were reviewed to verify the associated control circuits had adequate voltage under degraded voltage conditions. The inspectors also reviewed operating procedures, vendor and generic communications, recent CRs and operability evaluations for any anomalous indications or possible difficulties in system operation.
 
SIRW Tank Level Switch LS-327:  The inspectors reviewed installation drawings and vendor documentation to verify the switch was appropriate for its use. The inspectors review ed the Recirculation Actuation Signal (RAS) logic to verify the switch met its design basis. The inspectors also reviewed switch calibration and testing procedures.
 
In addition, the inspectors performed a walkdown of the SIRW tank to assess the level transmitters used for calibration of the switch
. Shutdown Cooling Heat Exchanger E
-60A:  The inspectors reviewed heat exchanger design documents to verify assumptions made in design bases calculations.
 
The inspectors reviewed normal, test, and emergency procedures.
 
The inspectors also reviewed historical information to understand how heat 10 exchanger performance had been validated since original installation. A walkdown was performed to assess the material condition of the heat exchanger and supporting components. In addition, the inspectors reviewed aging management aspects related to the heat exchanger.
 
Component Cooling Water (CCW) Pump (P
-52B):  The inspectors reviewed calculations related to pump hydraulics to ensure the pump was capable of performing its design bases accident mitigation functions.
 
Included in the review were cooling requirements for the component and the supplied loads. Also, reviewed were potential alternate sources for cooling the supplied load if CCW were to become unavailable during an accident. The inspectors also reviewed procedures and system diagrams to ensure the pump would be operated within its design parameters during an event.
 
The inspectors discussed the component's performance with the system engineer, and reviewed recent corrective action documents related to the SSC in order to assess the overall health of the component. In addition, the inspectors performed a walkdown to assess material condition of the pump, supporting components, and identify any potential concerns related to adverse interaction with the surrounding or nearby equipment.
 
Component Cooling Water (CCW) Relief Valve RV
-0956:  The inspectors also reviewed procedures and system diagrams to ensure the pump would be operated within its design parameters during an event.
 
The inspectors discussed the component's performance with the system engineer, and reviewed recent corrective action documents related to the SSC in order to assess the overall health of the component. In addition, the inspectors reviewed vendor manuals and technical sheets for the component. The required licensing and design bases for the component were reviewed and discussed with NRR, and requires further evaluation.
 
Containment Sump Strainer:  The inspectors reviewed results of sump inspections and ECCS pump NPSH analyses to verify the pressure drop across the screens under post
-accident conditions. The inspectors reviewed normal, test, and emergency procedures. The inspectors also reviewed the basis for the maximum particle size.
 
125 VDC Bus D10
:  The inspectors reviewed the circuit diagrams, the short circuit current calculation, and the coordination calculation to confirm the short circuit duty and the proper coordination between the panel fuses and branch circuit cabling with the upstream protective device. The inspectors also reviewed the panel electrical loading and voltage drop calculations, and the branch circuit cabling, to confirm bus and circuit cable ampacity was adequate and branch circuits had adequate voltage. The inspectors also reviewed recent CRs, operability evaluations, and operating procedures for any anomalous indications.
 
LPSI Pump Suction Crosstie Valve MO
-3090:  The inspectors reviewed the design basis of the motor
-operated valve including thrust calculations, the basis for valve stroke time requirements, and the associated control logic. The inspectors reviewed normal, test, and emergency procedures including the response to the single failure of an electrical power supply to MO
-3090. The inspectors also reviewed the interface between the electrical system distribution calculations and the valve thrust calculation to verify adequate voltage to the 11 valve motor under the most limiting conditions.
 
The inspectors performed a walkdown of the valve to verify its material condition.
 
480V Motor Control Center (MCC) 23:  In addition to the generic list of attributes listed above, the inspectors reviewed electrical diagrams, calculations, and procedures, including system short circuit calculations and main alternating current (AC) electrical distribution analysis. Voltage calculations were reviewed to verify minimum and maximum voltages were within equipment capabilities, including downstream power and control components. Thermal overload protection for motor operated valves was reviewed to assess the adequacy of valve motor overload protection.
 
ECCS/CS Minimum Flow Valve CV
-3027:  The inspectors reviewed the design basis of the air
-operated valve including thrust calculations, the basis for valve stroke time requirements, and the associated control logic. The inspectors reviewed normal, test, and emergency procedures as well as the response of the system to the single failure of the valve to operate under accident conditions. The inspectors reviewed the basis for the valve leakage limits and reviewed leak test procedures and results. The inspectors also reviewed the safety classification of valve sub
-components. The inspectors performed a walkdown of the valve to verify its material condition.
 
125 VDC Bus D11
:  The inspectors reviewed the circuit diagrams, the short circuit current calculation, and the coordination calculation to confirm the short circuit duty and the proper coordination between the panel fuses and branch circuit cabling with the upstream protective device. The inspectors reviewed the degraded voltage protection design scheme to determine whether it afforded adequate voltage to safety
-related devices at all voltage distribution levels. The inspectors also reviewed the panel electrical loading and the branch circuit cabling, to confirm bus, circuit cable ampacity was adequate, and branch circuits had adequate voltage. The inspectors also reviewed recent CRs, operability evaluations, and operating procedures for any anomalous indications.


====b. Findings====
====b. Findings====
(1) Failure to Ensure Engineered Safeguards Systems (ESS) Are Not Adversely Affected By Air Entrainment
(1) Failure to Ensure Engineered Safeguards Systems (ESS) Are Not Adversely Affected By Air Entrainment Introduction
:  A finding of very low safety significance (Green) and associated Non
-Cited Violation of 10 CFR Part 50, Appendix B, Criterion III, "Design Control" was identified by the inspectors for the failure to ensure the safety
-related ESS Trains would not be adversely affected by air entrainment when the ESS trains are aligned to the SIRW tank under design bases accidents.


=====Introduction:=====
Description
A finding of very low safety significance (Green) and associated Non-Cited Violation of 10 CFR Part 50, Appendix B, Criterion III, "Design Control" was identified by the inspectors for the failure to ensure the safety-related ESS Trains would not be adversely affected by air entrainment when the ESS trains are aligned to the SIRW tank under design bases accidents.  
: During a postulated design bases accident, the licensee's ESS would be required to operate. At the beginning of the accident the two trains of ESS would begin to operate with their associated pumps
' suction lined up to the SIRW Tank. Train A includes:
one Low Pressure Safety Injection (LPSI) pump, one Containment Spray (CS) pump and one High Pressure Safety Injection (HPSI) pump. Train B includes one LPSI pump, two CS pumps and one HPSI pump. When the water level in the SIRW tank reaches a pre
-determined low level, a Recirculation Actuation Signal (RAS) is generated. Once the RAS occurs, the LPCI pumps are tripped off and the pumps' suctions begin to automatically re-aligned to the containment sump. Per the licensee's
 
12 design bases this process can take up to 70 seconds to occur. If the water level were to get too low on the SIRW tank before the automatic swap to the containment sump concludes, air could be drawn into the system. If enough air entrainment occurred, the operability of the downstream pumps could be affected. Air entrainment can degrade pump performance, causing the pumps to air bind, reduce discharge pressure/flow and/or cause delays in injection.
 
The inspectors reviewed design bases calculation EA
-C-PAL-0877D, "Evaluation of the Potential for Excessive Air Entrainment Caused by Vortexing in the SIRW tank During a LOCA," Revision 1. In the calculation the licensee establishe d the critical submergences needed before air entrainment mechanisms could develop (vortexing and radial inflow) and evaluate d the lowest water levels reached in the SIRW tank during a design bases accident. The calculation determined the critical submergence limit for vortexing would be exceeded. The licensee estimated the maximum credible air entrainment at the pumps' suctions as 3.6 percent by volume. This value was determined using the "enveloping line" correlation based on Knauss, Jost, "Swirling Flow Problems at Intakes," A. A. Balkema, Rotterdam, Netherlands, 1987 and the expected void compression using the Ideal Gas Law. However, the inspectors noted the configuration described in the referenced material did not match the licensee's SIRW tank outlet piping configuration. The referenced material was based on horizontal outlet pipes, not vertical as in the case of the licensee's SIRW tank
. Also, the expected void fraction at the pumps exceeded those considered acceptable per NEI 09
-10, "Guidelines for Effective Prevention and Management of System Gas Accumulation
."  The NEI 09-10 provides the void fraction acceptance criteria used for operability calls in Palisades' Gas Accumulation Management Program Document. This is discussed in Attachment 9.5 of EN-DC-219, "Gas Accumulation Management
," Revision 3 (the licensee's Gas Management Program Document):
  "These guidelines do not provide acceptance criteria to support permanent design bases or procedural changes.
 
These guidelines do provide a toolset for establishing a Reasonable Expectation of Operability based on industry standards for non
-conforming conditions associated with gas intrusion.
 
Other tools may be utilized by a specific site if properly supported by site evaluation."


=====Description:=====
Upon further review, the inspectors noticed that when determining the lowest level reached in the SIRW tank, calculation EA
During a postulated design bases accident, the licensee's ESS would be required to operate. At the beginning of the accident the two trains of ESS would begin to operate with their associated pumps' suction lined up to the SIRW Tank. Train A includes:  one Low Pressure Safety Injection (LPSI) pump, one Containment Spray (CS) pump and one High Pressure Safety Injection (HPSI) pump. Train B includes one LPSI pump, two CS pumps and one HPSI pump. When the water level in the SIRW tank reaches a pre-determined low level, a Recirculation Actuation Signal (RAS) is generated. Once the RAS occurs, the LPCI pumps are tripped off and the pumps' suctions begin to automatically re-aligned to the containment sump. Per the licensee's 12 design bases this process can take up to 70 seconds to occur. If the water level were to get too low on the SIRW tank before the automatic swap to the containment sump concludes, air could be drawn into the system. If enough air entrainment occurred, the operability of the downstream pumps could be affected. Air entrainment can degrade pump performance, causing the pumps to air bind, reduce discharge pressure/flow and/or cause delays in injection. The inspectors reviewed design bases calculation EA-C-PAL-0877D, "Evaluation of the Potential for Excessive Air Entrainment Caused by Vortexing in the SIRW tank During a LOCA," Revision 1. In the calculation the licensee established the critical submergences needed before air entrainment mechanisms could develop (vortexing and radial inflow) and evaluated the lowest water levels reached in the SIRW tank during a design bases accident. The calculation determined the critical submergence limit for vortexing would be exceeded. The licensee estimated the maximum credible air entrainment at the pumps' suctions as 3.6 percent by volume. This value was determined using the "enveloping line" correlation based on Knauss, Jost, "Swirling Flow Problems at Intakes," A. A. Balkema, Rotterdam, Netherlands, 1987 and the expected void compression using the Ideal Gas Law. However, the inspectors noted the configuration described in the referenced material did not match the licensee's SIRW tank outlet piping configuration. The referenced material was based on horizontal outlet pipes, not vertical as in the case of the licensee's SIRW tank. Also, the expected void fraction at the pumps exceeded those considered acceptable per NEI 09-10, "Guidelines for Effective Prevention and Management of System Gas Accumulation."  The NEI 09-10 provides the void fraction acceptance criteria used for operability calls in Palisades' Gas Accumulation Management Program Document. This is discussed in Attachment 9.5 of EN-DC-219, "Gas Accumulation Management," Revision 3 (the licensee's Gas Management Program Document):  "These guidelines do not provide acceptance criteria to support permanent design bases or procedural changes. These guidelines do provide a toolset for establishing a Reasonable Expectation of Operability based on industry standards for non-conforming conditions associated with gas intrusion. Other tools may be utilized by a specific site if properly supported by site evaluation." Upon further review, the inspectors noticed that when determining the lowest level reached in the SIRW tank, calculation EA-C-PAL-0877D did not assume both trains of ESS could be in operation and taking suction from the SIRW tank concurrently. In addition, the calculation did not identify that a postulated single failure could result in a failure of RAS to occur for one train. Under this condition, one train of ESS would not realign to the containment sump and the LPCI pump on the affected train would continue to operate. Both of these concerns would result in a SIRW tank level lower than that assumed in the calculation. The licensee documented the inspectors' concerns under CR-PLP-2014-04472 and CR-PLP-2014-04665. An operability evaluation was also developed under CR-PLP-2014-04665. In order to maintain operability, the licensee re-evaluated the scenarios in Question (EC 53093) and adjusted their acceptance criteria for critical submergence. In addition, compensatory actions to ensure the system behaved as expected in their re-valuation were needed. These actions included:  (1) revising the acceptance criteria in QO-2 for the stroke times of the SIRW tank outlet isolation valves CV-3031 and CV-3057 (shortened the allowed stroke time), and (2) revising the acceptance criteria in RI-14 for the SIRW tank low level switches LS-0327, LS-0328, LS-0329 and LS-0330.
-C-PAL-0877D did not assume both trains of ESS could be in operation and taking suction from the SIRW tank concurrently. In addition, the calculation did not identify that a postulated single failure could result in a failure of RAS to occur for one train. Under this condition, one train of ESS would not realign to the containment sump and the LPCI pump on the affected train would continue to operate. Both of these concerns would result in a SIRW tank level lower than that assumed in the calculation. The licensee documented the inspectors' concerns under CR-PLP-2014-04472 and CR
-PLP-2014-04665. An operability evaluation was also developed under CR
-PLP-2014-04665. In order to maintain operability, the licensee re
-evaluated the scenarios in Question (EC 53093) and adjusted their acceptance criteria for critical submergence. In addition, compensatory actions to ensure the system behaved as expected in their re
-valuation were needed. These actions included:  
  (1) revising the acceptance criteria in QO
-2 for the stroke times of the SIRW tank outlet isolation valves CV
-3031 and CV
-3057 (shortened the allowed stroke time), and (2)revising the acceptance criteria in RI
-14 for the SIRW tank low level switches LS
-0327, LS-0328, LS-0329 and LS
-0330.


13
13


=====Analysis:=====
=====Analysis:=====
The inspectors determined the licensee's failure to ensure the safety-related ESS Trains would not be adversely affected by air entrainment when aligned to the SIRW tank was a performance deficiency. Specifically, when evaluating if the SIRW tank reaches the limit for critical submergence (during a tank drawdown) calculation EA-C-PAL-0877D, assumed only one train of ESS was in operation instead of both trains. Additionally, the licensee did not evaluate the potential effects on the ESS system if both trains are assumed to be in operation, or if one train fails to receive its RAS signal. Both scenarios result in lower water levels in the SIRW tank, and potential air ingestion into the ESS trains.
The inspectors determined the licensee
's failure to ensure the safety
-related ESS Trains would not be adversely affected by air entrainment when aligned to the SIRW tank was a performance deficiency. Specifically, when evaluating if the SIRW tank reaches the limit for critical submergence (during a tank drawdown) calculation EA-C-PAL-0877D, assumed only one train of ESS was in operation instead of both trains. Additionally, the licensee did not evaluate the potential effects on the ESS system if both trains are assumed to be in operation, or if one train fails to receive its RAS signal. Both scenarios result in lower water levels in the SIRW tank, and potential air ingestion into the ESS trains.
 
The performance deficiency was determined to be more than minor because it impacted the Equipment Performance attribute of the Reactor Safety, Mitigating Systems Cornerstone and adversely affected the cornerstone objective to ensure the availability, reliability, and capability of systems that respond to initiating events to prevent undesirable consequences. Specifically, air entrainment into the ESS systems could potentially impact the operability of the system by air binding the pumps, reduce discharge flow, discharge pressure and/or delay injection. The licensee performed an operability evaluation, and re
-analyzed the SIRW tank drain down (EC 53093) in order to ensure the ESS systems remained Operable.
 
The inspectors determined the finding could be evaluated using the SDP in accordance with IMC 0609, "Significance Determination Process," Attachment 0609.04,"
"Initial Characterization of Findings."  Specifically, the inspectors used IMC 0609 Appendix A "SDP for Findings At
-Power" Exhibit 2, "Mitigating Systems Screening Questions". The finding was a deficiency affecting the design or qualification of a mitigating structure system or component (SSC) but the SSC maintained its operability. Specifically, the licensee performed an operability evaluation CR
-PLP-2014-04665 and determined the performance deficiency would result in lower SIRW Tank levels but at least one train of ESS would remain operable during a design bases accident. As a result, the finding screened as having very low safety significance, i.e.
 
, Green.


The performance deficiency was determined to be more than minor because it impacted the Equipment Performance attribute of the Reactor Safety, Mitigating Systems Cornerstone and adversely affected the cornerstone objective to ensure the availability, reliability, and capability of systems that respond to initiating events to prevent undesirable consequences. Specifically, air entrainment into the ESS systems could potentially impact the operability of the system by air binding the pumps, reduce discharge flow, discharge pressure and/or delay injection. The licensee performed an operability evaluation, and re-analyzed the SIRW tank drain down (EC 53093) in order to ensure the ESS systems remained Operable.
The inspectors did not identify a cross
-cutting aspect associated with this finding because the finding was not representative of the licensee's present performance. Enforcement
:  Title 10 CFR Part 50, Appendix B, Criterion III, "Design Control" requires, in part, that measures shall be established to assure that applicable regulatory requirements and the design basis, as defined in 50.2 and as specified in the license application, for those structures, systems, and components to which this appendix applies are correctly translated into specifications, drawings, procedures, and instructions.


The inspectors determined the finding could be evaluated using the SDP in accordance with IMC 0609, "Significance Determination Process," Attachment 0609.04," "Initial Characterization of Findings."  Specifically, the inspectors used IMC 0609 Appendix A "SDP for Findings At-Power" Exhibit 2, "Mitigating Systems Screening Questions". The finding was a deficiency affecting the design or qualification of a mitigating structure system or component (SSC) but the SSC maintained its operability. Specifically, the licensee performed an operability evaluation CR-PLP-2014-04665 and determined the performance deficiency would result in lower SIRW Tank levels but at least one train of ESS would remain operable during a design bases accident. As a result, the finding screened as having very low safety significance, i.e., Green.
Contrary to the above, as of September 8, 2014, the licensee failed to ensure their ESS trains would not be adversely affected by air entrainment when these are aligned to the SIRW tank. Specifically, calculation EA
-C-PAL-0877D, "Evaluation of the Potential for Excessive Air Entrainment Caused by Vortexing in the SIRW tank During a LOCA
," Revision 1, failed to evaluate the potential effects on the ESS systems if both trains were assumed to be in operation, or if one train fail ed to receive its RAS signal. As part of their corrective actions, the licensee initiated CR-PLP-2014-04665, performed an operability evaluation
, and implemented compensatory measures needed to ensure the Engineered Safeguard Systems are able to perform their required safety functions during design bases conditions.


The inspectors did not identify a cross-cutting aspect associated with this finding because the finding was not representative of the licensee's present performance.
14 Because this violation was of very low safety significance, and it was entered into the licensee's Corrective Action Program as CR
-PLP-2014-04472 and CR
-PLP-2014-04665, this violation is being treated as an NCV, consistent with Section 2.3.2 of the NRC Enforcement Policy.  [NCV 05000255/201 4008-01, Failure to Ensure Engineered Safeguards Systems Are Not Adversely Affected By Air Entrainment.]
(2) Undersized Supply Cables from Startup Transformer to 2400V Buses Introduction
:  A finding of very low safety significance and associated Non-Cited Violation of 10 CFR Part 50, Appendix B, Criterion III, "Design Control," was identified by the inspectors for the licensee's failure to ensure the incoming feeder cables from startup transformer 1
-2 to 2400 V safety
-related Buses 1C and 1D were sized in accordance with their design basis, as described in Palisades FSAR Section 8.5.2
. Specifically, the licensee failed to ensure the ampacity of the cables was at least as high as their maximum predicted steady-state current.


=====Enforcement:=====
Description
Title 10 CFR Part 50, Appendix B, Criterion III, "Design Control" requires, in part, that measures shall be established to assure that applicable regulatory requirements and the design basis, as defined in 50.2 and as specified in the license application, for those structures, systems, and components to which this appendix applies are correctly translated into specifications, drawings, procedures, and instructions. Contrary to the above, as of September 8, 2014, the licensee failed to ensure their ESS trains would not be adversely affected by air entrainment when these are aligned to the SIRW tank. Specifically, calculation EA-C-PAL-0877D, "Evaluation of the Potential for Excessive Air Entrainment Caused by Vortexing in the SIRW tank During a LOCA," Revision 1, failed to evaluate the potential effects on the ESS systems if both trains were assumed to be in operation, or if one train failed to receive its RAS signal. As part of their corrective actions, the licensee initiated CR-PLP-2014-04665, performed an operability evaluation, and implemented compensatory measures needed to ensure the Engineered Safeguard Systems are able to perform their required safety functions during design bases conditions.
: On October 23, 2013, the licensee issued calculation EA-ELEC-EDSA-03, "LOCA with Offsite Power Available," Revision 2, which identified that the maximum steady-state load on Bus 1C during a LOCA would be 873 amps (Tables B2
-1C and SU-CD-1C-B2) and on Bus 1D would be 953 amps (Table SU
-1D-2355-B2). Palisades FSAR Section 8.5.2 states that "Cables installed in...underground ducts are thermally sized in accordance with NEC or IPCEA/ICEA ampacity values (depending on cable physical size) of concentric stranded insulated cable for the conductor operating temperature of the insulation."
 
According to Section 4.0 a of Engineering Analysis EA-ELEC-AMP-030, "Capability of the 2400V Feeder Cables to Buses 1C and 1D from the Startup Transformer 1
-2," Revision 2, the rated operating temperature of the cable insulation is 90°C.


14 Because this violation was of very low safety significance, and it was entered into the licensee's Corrective Action Program as CR-PLP-2014-04472 and CR-PLP-2014-04665, this violation is being treated as an NCV, consistent with Section 2.3.2 of the NRC Enforcement Policy.  [NCV 05000255/2014008-01, Failure to Ensure Engineered Safeguards Systems Are Not Adversely Affected By Air Entrainment.] (2) Undersized Supply Cables from Startup Transformer to 2400V Buses
According to Engineering Change EC 24546 to Design Basis Document DBD 3.04, "2400V AC System
," Revision 7, the ampacity is 636 amps (current that would raise the cable temperature to 90°C). Thus, the cable ampacity is exceeded by the loading levels calculated in EA-ELEC-EDSA-03, contrary to the requirement of FSAR Section 8.5.2. Although the licensee previously entered this issue into their Margin Management Program as Margin Issue 414, they failed to characterize it as a design basis deficiency.


=====Introduction:=====
Based on inspector concerns, the licensee entered this issue into the Corrective Action Program as CR
A finding of very low safety significance and associated Non-Cited Violation of 10 CFR Part 50, Appendix B, Criterion III, "Design Control," was identified by the inspectors for the licensee's failure to ensure the incoming feeder cables from startup transformer 1-2 to 2400 V safety-related Buses 1C and 1D were sized in accordance with their design basis, as described in Palisades FSAR Section 8.5.2. Specifically, the licensee failed to ensure the ampacity of the cables was at least as high as their maximum predicted steady-state current.
- CR-PLP-2014-4860 with a recommended action to provide additional procedural guidance for unloading the cables if an overload condition were to occur.


=====Description:=====
The licensee also verified current operability by confirming the cables would not fail as a result of the condition
On October 23, 2013, the licensee issued calculation EA-ELEC-EDSA-03, "LOCA with Offsite Power Available," Revision 2, which identified that the maximum steady-state load on Bus 1C during a LOCA would be 873 amps (Tables B2-1C and SU-CD-1C-B2) and on Bus 1D would be 953 amps (Table SU-1D-2355-B2). Palisades FSAR Section 8.5.2 states that "Cables installed in...underground ducts are thermally sized in accordance with NEC or IPCEA/ICEA ampacity values (depending on cable physical size) of concentric stranded insulated cable for the conductor operating temperature of the insulation."  According to Section 4.0 a of Engineering Analysis EA-ELEC-AMP-030, "Capability of the 2400V Feeder Cables to Buses 1C and 1D from the Startup Transformer 1-2," Revision 2, the rated operating temperature of the cable insulation is 90°C. According to Engineering Change EC 24546 to Design Basis Document DBD 3.04, "2400V AC System," Revision 7, the ampacity is 636 amps (current that would raise the cable temperature to 90°C). Thus, the cable ampacity is exceeded by the loading levels calculated in EA-ELEC-EDSA-03, contrary to the requirement of FSAR Section 8.5.2. Although the licensee previously entered this issue into their Margin Management Program as Margin Issue 414, they failed to characterize it as a design basis deficiency. Based on inspector concerns, the licensee entered this issue into the Corrective Action Program as CR- CR-PLP-2014-4860 with a recommended action to provide additional procedural guidance for unloading the cables if an overload condition were to occur. The licensee also verified current operability by confirming the cables would not fail as a result of the condition.
.


=====Analysis:=====
=====Analysis:=====
The inspectors determined the failure to ensure the supply cables to Buses 1C and 1D are sized in accordance with the design basis was contrary to 10 CFR Part 50, Appendix B, Criterion III, "Design Control," and was a performance deficiency. The finding was determined to be more than minor because the finding was associated with the Design Control attribute of the Reactor Safety, Mitigating Systems Cornerstone and adversely affected the cornerstone objective to ensure the availability, reliability, and capability of systems that respond to initiating events to prevent undesirable consequences. Specifically, cables were undersized with respect to the loading that would automatically occur as the result of a design basis event. The inspectors assessed this finding for significance in accordance with NRC Manual Chapter 0609, Appendix A, Exhibit 2, The Significance Determination Process (SDP) for Findings At-Power, and determined that it was of very low safety significance (Green),
The inspectors determined the failure to ensure the supply cables to Buses 1C and 1D are sized in accordance with the design basis was contrary to 10 CFR Part 50, Appendix B, Criterion III, "Design Control," and was a performance deficiency.
15 because the SSC maintained its operability and functionality. This finding had a crosscutting aspect in the area of Human Performance, associated with the Design Margin component, because the licensee did not ensure that equipment is operated and maintained within design margins, and margins are carefully guarded and changed only through a systematic and rigorous process. The licensee's margin management program had not corrected this known condition. [H.6]
 
The finding was determined to be more than minor because the finding was associated with the Design Control attribute of the Reactor Safety, Mitigating Systems Cornerstone and adversely affected the cornerstone objective to ensure the availability, reliability, and capability of systems that respond to initiating events to prevent undesirable consequences.
 
Specifically, cables were undersized with respect to the loading that would automatically occur as the result of a design basis event.


=====Enforcement:=====
The inspectors assessed this finding for significance in accordance with NRC Manual Chapter 0609, Appendix A, Exhibit 2
Title 10 CFR Part 50, Appendix B, Criterion III, "Design Control" requires, in part, "Measures shall be established to assure that applicable regulatory requirements and the design basis are correctly translated into specifications, drawings, procedures, and instructions. The design control measures shall provide for verifying or checking the adequacy of design, such as by the performance of design reviews, by the use of alternate or simplified calculational methods, or by the performance of a suitable testing program."   Contrary to the above, as of September 8, 2014, the licensee failed to assure that the design basis for cable sizing specified in FSAR Section 8.5.2 was translated into the design of the cables. Specifically, the design ampacity of the cables was less than their maximum predicted steady-state load. Because this violation was of very low safety significance, and it was entered into the licensee's Corrective Action Program as CR- CR-PLP-2014-4860 with a recommended action to provide additional procedural guidance for unloading the cables if an overload condition were to occur, this violation is being treated as an NCV, consistent with Section 2.3.2 of the NRC Enforcement Policy. The licensee also verified current operability by confirming the cables would not fail as a result of the condition.  [NCV 05000255/2014008-02, Undersized Supply Cables from Startup Transformer to 2400V Buses.]  (3) Undersized Motors
, The Significance Determination Process (SDP) for Findings At-Power, and determined that it was of very low safety significance (Green),
15 because the SSC maintained its operability and functionality
. This finding had a crosscutting aspect in the area of Human Performance, associated with the Design Margin component, because the licensee did not ensure that equipment is operated and maintained within design margins, and margins are carefully guarded and changed only through a systematic and rigorous process
. The licensee's margin management program had not corrected this know n condition.
 
[H.6] Enforcement
: Title 10 CFR Part 50, Appendix B, Criterion III, "Design Control" requires, in part, "Measures shall be established to assure that applicable regulatory requirements and the design basis are correctly translated into specifications, drawings, procedures, and instructions. The design control measures shall provide for verifying or checking the adequacy of design, such as by the performance of design reviews, by the use of alternate or simplified calculational methods, or by the performance of a suitable testing program."
 
Contrary to the above, as of September 8, 2014, the licensee failed to assure that the design basis for cable sizing specified in FSAR Section 8.5.2 was translated into the design of the cables. Specifically, the design ampacity of the cables was less than their maximum predicted steady-state load.
 
Because this violation was of very low safety significance, and it was entered into the licensee's Corrective Action Program as CR
- CR-PLP-2014-4860 with a recommended action to provide additional procedural guidance for unloading the cables if an overload condition were to occur, this violation is being treated as an NCV, consistent with Section 2.3.2 of the NRC Enforcement Policy. The licensee also verified current operability by confirming the cables would not fail as a result of the condition
.  [NCV 05000255/201400 8-02, Undersized Supply Cables from Startup Transformer to 2400V Buses
.]  (3) Undersized Motors


=====Introduction:=====
=====Introduction:=====
A finding of very low safety significance and associated Non-Cited Violation of 10 CFR Part 50, Appendix B, Criterion III, "Design Control," was identified by the inspectors for the licensee's failure to ensure that electric motors are sized in accordance with the design basis, as discussed in Palisades FSAR Section 6.2.3.1. Specifically, the horsepower ratings of certain motors are less than power demands of their driven equipment, and they were not analyzed to ensure that overheating would not occur.
A finding of very low safety significance and associated Non-Cited Violation of 10 CFR Part 50, Appendix B, Criterion III, "Design Control," was identified by the inspectors for the licensee's failure to ensure that electric motors are sized in accordance with the design basis, as discussed in Palisades FSAR Section 6.2.3.1. Specifically, the horsepower ratings of certain motors are less than power demands of their driven equipment, and they were not analyzed to ensure that overheating would not occur. Description
:  Palisades FSAR Section 6.2.3.1 states the containment spray "motor drivers have been selected to be non
-overloading over the entire pump operating range."  To the contrary, on August 6, 2014, the licensee issued calculation EA
-ELEC-LDTAB-005, "Emergency Diesel Generators 1
-1 and 1-2 Steady State Loadings," Revision 10, which identifies, in Table C.1, that the motor for containment spray pump P
-54A is rated 250 HP, but the power demand of the pump is 278 BHP. The calculation also lists other motors having ratings less than the power demand of their associated driven equipment
. Power demands of the containment spray pumps and other motor driven equipment would be even higher than those listed in Calculation Tables A.1 through E.2 when the emergency diesel generator is operating at its maximum allowable frequency and voltage. The calculation identifies, in Section 4.24, that this operating condition would cause a 6.32 percent increase in the power demands. The inspectors noted calculation EA-ELEC-LDTAB-005 does not analyze or justify the undersized motor condition, nor is there any other analysis that justifies this condition. In the, "Quality Assurance Program Manual," Revision 26, the licensee is committed to Regulatory Guide 1.64, "Quality Assurance Requirements for the Design of Nuclear Power Plants," Revision 2, which 16 cites ANSI N45.2.11
-1974, "Quality Assurance Requirements for the Design of Nuclear Power Plants."  ANSI N45.2.11 states, "Measures shall be applied to verify the adequacy of design. Design verification is the process of reviewing, confirming, or substantiating the design by one or more methods to provide assurance that the design meets the specified design inputs-. The results of design verification efforts shall be clearly documented."  Contrary to this requirement, the licensee had not verified and documented the thermal capability of motors serving loads in excess of the motor horsepower rating.
 
The licensee entered this issue into their Corrective Action Program as CR-PLP-2014-4902 with a recommended action to analyze the effect of the condition.


=====Description:=====
The licensee subsequently verified operability of the motors.
Palisades FSAR Section 6.2.3.1 states the containment spray "motor drivers have been selected to be non-overloading over the entire pump operating range."  To the contrary, on August 6, 2014, the licensee issued calculation EA-ELEC-LDTAB-005, "Emergency Diesel Generators 1-1 and 1-2 Steady State Loadings," Revision 10, which identifies, in Table C.1, that the motor for containment spray pump P-54A is rated 250 HP, but the power demand of the pump is 278 BHP. The calculation also lists other motors having ratings less than the power demand of their associated driven equipment. Power demands of the containment spray pumps and other motor driven equipment would be even higher than those listed in Calculation Tables A.1 through E.2 when the emergency diesel generator is operating at its maximum allowable frequency and voltage. The calculation identifies, in Section 4.24, that this operating condition would cause a 6.32 percent increase in the power demands. The inspectors noted calculation EA-ELEC-LDTAB-005 does not analyze or justify the undersized motor condition, nor is there any other analysis that justifies this condition. In the, "Quality Assurance Program Manual," Revision 26, the licensee is committed to Regulatory Guide 1.64, "Quality Assurance Requirements for the Design of Nuclear Power Plants," Revision 2, which 16 cites ANSI N45.2.11-1974, "Quality Assurance Requirements for the Design of Nuclear Power Plants."  ANSI N45.2.11 states, "Measures shall be applied to verify the adequacy of design. Design verification is the process of reviewing, confirming, or substantiating the design by one or more methods to provide assurance that the design meets the specified design inputs-. The results of design verification efforts shall be clearly documented."  Contrary to this requirement, the licensee had not verified and documented the thermal capability of motors serving loads in excess of the motor horsepower rating. The licensee entered this issue into their Corrective Action Program as CR-PLP-2014-4902 with a recommended action to analyze the effect of the condition. The licensee subsequently verified operability of the motors.


=====Analysis:=====
=====Analysis:=====
The inspectors determined the failure to ensure that electric motors are sized in accordance with the design basis and verified to be within their thermal capability was contrary to 10 CFR Part 50, Appendix B, Criterion III, "Design Control," and was a performance deficiency. The finding was determined to be more than minor because the finding was associated with the Design Control attribute of the Reactor Safety, Mitigating Systems Cornerstone and adversely affected the cornerstone objective to ensure the availability, reliability, and capability of systems that respond to initiating events to prevent undesirable consequences. Specifically, certain motors serve loads with demands in excess of the motor horsepower ratings, and they were not analyzed to ensure that overheating would not occur. The inspectors assessed this finding for significance in accordance with NRC Manual Chapter 0609, Appendix A, Exhibit 2, The Significance Determination Process (SDP) for Findings At-Power, and determined that it was of very low safety significance (Green), because the SSC maintained its operability and functionality. This finding had a crosscutting aspect in the area of Human Performance, associated with the Design Margin component, because the licensee did not ensure that equipment is operated and maintained within design margins, and margins are carefully guarded and changed only through a systematic and rigorous process.  [H.6]
The inspectors determined the failure to ensure that electric motors are sized in accordance with the design basis and verified to be within their thermal capability was contrary to 10 CFR Part 50, Appendix B, Criterion III, "Design Control," and was a performance deficiency. The finding was determined to be more than minor because the finding was associated with the Design Control attribute of the Reactor Safety, Mitigating Systems Cornerstone and adversely affected the cornerstone objective to ensure the availability, reliability, and capability of systems that respond to initiating events to prevent undesirable consequences
. Specifically, certain motors serv e loads with demands in excess of the motor horsepower ratings, and they were not analyzed to ensure that overheating would not occur
. The inspectors assessed this finding for significance in accordance with NRC Manual Chapter 0609, Appendix A, Exhibit 2, The Significance Determination Process (SDP) for Findings At
-Power, and determined that it was of very low safety significance (Green), because the SSC maintained its operability and functionality.
 
This finding had a crosscutting aspect in the area of Human Performance, associated with the Design Margin component, because the licensee did not ensure that equipment is operated and maintained within design margins, and margins are carefully guarded and changed only through a systematic and rigorous process
.  [H.6] Enforcement
:  Title 10 CFR Part 50, Appendix B, Criterion III, "Design Control" requires, in part, that "Measures shall be established to assure that applicable regulatory requirements and the design basis are correctly translated into specifications, drawings, procedures, and instructions.
 
The design control measures shall provide for verifying or checking the adequacy of design, such as by the performance of design reviews, by the use of alternate or simplified calculational methods, or by the performance of a suitable testing program."
 
Contrary to the above, as of September 8, 2014, the licensee failed to verify the adequacy of design of certain motors.
 
Specifically, the horsepower ratings of those motors did not bound the power demands of their driven equipment, and they were not analyzed to ensure that the condition would not cause overheating
. Because this violation was of very low safety significance, and it was entered into the licensee's Corrective Action Program as CR-PLP-2014-4902, this violation is being treated as an NCV, consistent with Section 2.3.2 of the NRC Enforcement Policy
.  [NCV 05000255/201400 8-03, Undersized Motors.
 
]
17 (4) Failure to Ensure that 480V System Voltages do not Exceed Equipment Ratings Introduction
:  A finding of very low safety significance and associated Non-Cited Violation of 10 CFR Part 50, Appendix B, Criterion III, "Design Control," was identified by the inspectors for the licensee's failure to ensure that voltages on the 480V system do not exceed equipment ratings.
 
Specifically, the licensee increased the output voltage of the supply transformers to the 480V safety-related buses by 2.5 percent, but failed to ensure that the resulting voltages would not exceed equipment ratings when the system is powered from the station power transformer or emergency diesel generator.
 
Description
:  On March 30, 1995, the licensee issued calculation EA
-ELEC-VOLT-036, "Station Power Transformers No. 11, 12, 19, and 20 Tap Change
- 2.5 percent," Revision 0, which states, in Section IV.2.1, "the maximum allowed voltage at 480 V Load Centers/MCC's is 1.058 pu (480 V base)."
 
On July 28, 1995, the licensee issued Specification Change document SC 102, Revision 0, to increase the output voltage of the supply transformers to the 480V safety
-related buses by 2.5 percent. The inspectors determined the licensee failed to recognize that this could result in voltages at the 480V buses in excess of the 1.058 per unit limit. In addition, calculation EA
-ELEC-VOLT-036, Section IV.4.3, postulated a non
-conservative maximum voltage on the 2400V buses of 1.0 per unit (2400V). However, voltages on the 2400V buses in excess of 1.0 per unit could occur due to 1) operation on the diesel generator supply within the diesel generator voltage range up to 1


=====Enforcement:=====
===.05 per unit, as allowed by Palisades===
Title 10 CFR Part 50, Appendix B, Criterion III, "Design Control" requires, in part, that "Measures shall be established to assure that applicable regulatory requirements and the design basis are correctly translated into specifications, drawings, procedures, and instructions. The design control measures shall provide for verifying or checking the adequacy of design, such as by the performance of design reviews, by the use of alternate or simplified calculational methods, or by the performance of a suitable testing program."  Contrary to the above, as of September 8, 2014, the licensee failed to verify the adequacy of design of certain motors. Specifically, the horsepower ratings of those motors did not bound the power demands of their driven equipment, and they were not analyzed to ensure that the condition would not cause overheating. Because this violation was of very low safety significance, and it was entered into the licensee's Corrective Action Program as CR-PLP-2014-4902, this violation is being treated as an NCV, consistent with Section 2.3.2 of the NRC Enforcement Policy.  [NCV 05000255/2014008-03, Undersized Motors.]
 
17 (4) Failure to Ensure that 480V System Voltages do not Exceed Equipment Ratings
Technical Specification SR 3.8.1.2, or 2) operation on the non
-regulated Station Power Transformer 1-2 supply during shutdown conditions, as discussed in Palisades Technical Specification Basis 3.8.2.


=====Introduction:=====
The inspectors were concerned these higher voltages on the 2400V buses, in conjunction with the 2.5 percent increase in voltage to the 480V buses, could result in over voltages on the 480V buses. Voltages higher than the 1.058 per unit calculation limit could cause exposure of load equipment to voltages in excess of the manufacturers' ratings and diminished capability of electrical protective devices to interrupt short circuit currents.
A finding of very low safety significance and associated Non-Cited Violation of 10 CFR Part 50, Appendix B, Criterion III, "Design Control," was identified by the inspectors for the licensee's failure to ensure that voltages on the 480V system do not exceed equipment ratings. Specifically, the licensee increased the output voltage of the supply transformers to the 480V safety-related buses by 2.5 percent, but failed to ensure that the resulting voltages would not exceed equipment ratings when the system is powered from the station power transformer or emergency diesel generator.


=====Description:=====
The licensee entered this issue into their Corrective Action Program as CR-PLP-2014-4696 with a recommended action to further analyze emergency diesel generator operation at its maximum allowable voltage and CR-PLP-2014-4864 with an action to restrict switchyard maximum voltage when the safety
On March 30, 1995, the licensee issued calculation EA-ELEC-VOLT-036, "Station Power Transformers No. 11, 12, 19, and 20 Tap Change - 2.5 percent," Revision 0, which states, in Section IV.2.1, "the maximum allowed voltage at 480 V Load Centers/MCC's is 1.058 pu (480 V base)."  On July 28, 1995, the licensee issued Specification Change document SC-94-102, Revision 0, to increase the output voltage of the supply transformers to the 480V safety-related buses by 2.5 percent. The inspectors determined the licensee failed to recognize that this could result in voltages at the 480V buses in excess of the 1.058 per unit limit. In addition, calculation EA-ELEC-VOLT-036, Section IV.4.3, postulated a non-conservative maximum voltage on the 2400V buses of 1.0 per unit (2400V). However, voltages on the 2400V buses in excess of 1.0 per unit could occur due to 1) operation on the diesel generator supply within the diesel generator voltage range up to 1.05 per unit, as allowed by Palisades Technical Specification SR 3.8.1.2, or 2) operation on the non-regulated Station Power Transformer 1-2 supply during shutdown conditions, as discussed in Palisades Technical Specification Basis 3.8.2.
-related buses are powered from the station power transformer.


The inspectors were concerned these higher voltages on the 2400V buses, in conjunction with the 2.5 percent increase in voltage to the 480V buses, could result in over voltages on the 480V buses. Voltages higher than the 1.058 per unit calculation limit could cause exposure of load equipment to voltages in excess of the manufacturers' ratings and diminished capability of electrical protective devices to interrupt short circuit currents. The licensee entered this issue into their Corrective Action Program as CR-PLP-2014-4696 with a recommended action to further analyze emergency diesel generator operation at its maximum allowable voltage and CR-PLP-2014-4864 with an action to restrict switchyard maximum voltage when the safety-related buses are powered from the station power transformer. The licensee subsequently determined that all equipment was operable at the full range of diesel operation.
The licensee subsequently determined that all equipment was operable at the full range of diesel operation.


=====Analysis:=====
=====Analysis:=====
The inspectors determined the licensee's failure to verify or check the adequacy of Specification Change document SC-94-102, Revision 0, was contrary to 10 CFR Part 50, Appendix B, Criterion III, "Design Control," and was a performance deficiency. The finding was determined to be more than minor because the finding was associated with the Design Control attribute of the Reactor Safety, Mitigating Systems Cornerstone and adversely affected the cornerstone objective to ensure the availability, reliability, and capability of systems that respond to initiating events to prevent undesirable consequences. Specifically, the licensee failed to verify or check the adequacy of Engineering Assessment EA-ELEC-VOLT-036, "Station Power Transformers Nos. 11, 12, 19, and 20 Tap Change - 2.5 percent," Revision 0, to ensure that postulated maximum source voltages bounded allowable operating conditions and thus that the voltage increase would not result in overvoltage conditions.
The inspectors determined the licensee's failure to verify or check the adequacy of Specification Change document SC 102, Revision 0, was contrary to 10 CFR Part 50, Appendix B, Criterion III, "Design Control,"
and was a performance deficiency.
 
The finding was determined to be more than minor because the finding was associated with the Design Control attribute of the Reactor Safety, Mitigating Systems Cornerstone and adversely affected the cornerstone objective to ensure the availability, reliability, and capability of systems that respond to initiating events to prevent undesirable consequences.
 
Specifically, the licensee failed to verify or check the adequacy of Engineering Assessment EA
-ELEC-VOLT-036, "Station Power Transformers Nos. 11, 12, 19, and 20 Tap Change  
- 2.5 percent," Revision 0, to ensure that postulated maximum source voltages bounded allowable operating conditions and thus that the voltage increase would not result in overvoltage conditions
.
 
18 The inspectors assessed this finding for significance in accordance with NRC Manual Chapter 0609, Appendix A, Exhibit 2
. The Significance Determination Process (SDP) for Findings At-Power, and determined that it was of very low safety significance (Green), because the SSCs maintained their operability and functionality
. The inspectors did not identify a cross
-cutting aspect associated with this finding
, because the finding was not representative of the licensee's present performance.
 
Enforcement
:  Title 10 CFR Part 50, Appendix B, Criterion III, "Design Control" requires, in part, that "Measures shall be established to assure that applicable regulatory requirements and the design basis are correctly translated into specifications, drawings, procedures, and instructions.
 
The design control measures shall provide for verifying or checking the adequacy of design, such as by the performance of design reviews, by the use of alternate or simplified calculational methods, or by the performance of a suitable testing program."  Contrary to the above, as of September 8, 2014, the licensee failed to verify the adequacy of the design of the transformer tap settings. Specifically, the 2.5 percent boost in voltages to the 480V buses could result in voltages in excess of equipment ratings under certain allowable operating conditions.


18 The inspectors assessed this finding for significance in accordance with NRC Manual Chapter 0609, Appendix A, Exhibit 2. The Significance Determination Process (SDP) for Findings At-Power, and determined that it was of very low safety significance (Green), because the SSCs maintained their operability and functionality. The inspectors did not identify a cross-cutting aspect associated with this finding, because the finding was not representative of the licensee's present performance.
Because this violation was of very low safety significance, and it was entered into the licensee's Corrective Action Program as CR-PLP-2014-4696, and CR-PLP-2014-4864 this violation is being treated as an NCV, consistent with Section 2.3.2 of the Enforcement Policy
. [NCV 05000255/201400 8-04, Failure to Ensure that 480V System Voltages do not Exceed Equipment Ratings
.] (5) Failure To Perform Comprehensive Pump Testing Of Containment Spray Pump P
-54A In Accordance With The Inservice Testing Program.


=====Enforcement:=====
Introduction
Title 10 CFR Part 50, Appendix B, Criterion III, "Design Control" requires, in part, that "Measures shall be established to assure that applicable regulatory requirements and the design basis are correctly translated into specifications, drawings, procedures, and instructions. The design control measures shall provide for verifying or checking the adequacy of design, such as by the performance of design reviews, by the use of alternate or simplified calculational methods, or by the performance of a suitable testing program."  Contrary to the above, as of September 8, 2014, the licensee failed to verify the adequacy of the design of the transformer tap settings. Specifically, the 2.5 percent boost in voltages to the 480V buses could result in voltages in excess of equipment ratings under certain allowable operating conditions. Because this violation was of very low safety significance, and it was entered into the licensee's Corrective Action Program as CR-PLP-2014-4696, and CR-PLP-2014-4864 this violation is being treated as an NCV, consistent with Section 2.3.2 of the Enforcement Policy. [NCV 05000255/2014008-04, Failure to Ensure that 480V System Voltages do not Exceed Equipment Ratings.] (5) Failure To Perform Comprehensive Pump Testing Of Containment Spray Pump P-54A In Accordance With The Inservice Testing Program.
: A finding of very low safety significance (Green) and associated Non
-Cited Violation of Technical Specifications 5.5.7, "Inservice Testing Program" was identified by the inspectors for the licensee's failure to perform comprehensive pump testing of Containment Spray pump P
-54A in accordance with the code of record.
 
Description
:  On February 25, 2014 the licensee performed WO 52435851 01, "RO-98 -LPSI PMP VIB, CONT SPRY PMP VIB, DIS CK
," which includes the comprehensive pump test of Containment Spray (CS) Pump P
-54A. The comprehensive pump test is performed every 18 months in accordance with the ASME OMb Code
-2001, through ASME OMb Code
-2003 Addenda, which according to FSAR Section 6.9.2.1, "Pump Testing Program
," and Site Engineering Program SEP
-PLP-IST-102, "Inservice Testing of Selected Safety-Related Pumps" is the code of record for Palisades. Comprehensive testing of pumps is performed in order to detect potential degradation of the equipment and helps ensure the SSC will be able to meet its design requirements. During the test, the recorded differential pressure (DP) was 142.0 psid as read on differential pressure indicator DPI-0319A (range 0 to 250 psid). This value was within the Alert Range established by the licensee's procedure. Procedure RO
-98 establishes the different criteria for P
-54A as follows:
The Acceptable Range was a 143.2 to 158.6 psid
;  The Alert Range was 138.6 to 143.2 psid
;  The Required Action Range was DP lower than 138.6 psid or greater than 158.6 psid; and  The Acceptance Criteria was DP greater than 136.9 psid at 2250 +/
- 35 gpm 19 The licensee documented the test results in the Alert Range under CR
-PLP-2014-01679. The licensee suspected instrumentation issues may have been the cause of the deviation. Site personnel performed a historical search of RO
-98 testing and identified several CRs related to instrumentation issues including CR
-PLP-2010-05181 and CR-PLP-2010-06403. On January 13, 2014
, the DPI-0319A had been calibrated to ensure it was within the comprehensive test required accuracy. On February 26, 2014
, a post-test calibration was performed in accordance with WO 52435851 01. The result of the calibrations showed pressure indicator DPI
-0319A was outside of the test requirements. The results indicated the gauge was reading lower than actual DP. The licensee determined the deviation was approximately 8.75 psid lower and concluded this would indicate an actual DP of approximately 150 psid under RO
-98 conditions for pump P-54A. The licensee concluded this would result in a DP within the acceptable range. In addition to the above, the license performed an assessment of the vibration results obtained and evaluated various pump result trends (comprehensive and quarterly testing) associated with pump performance. Based on this review, documented on CR
-PLP-2014-01679, the licensee concluded pump P
-54A was actually operating within its acceptable range and no additional corrective actions were required.


=====Introduction:=====
However, the inspectors were concerned the comprehensive pump test performed on February 25, 2014
A finding of very low safety significance (Green) and associated Non-Cited Violation of Technical Specifications 5.5.7, "Inservice Testing Program" was identified by the inspectors for the licensee's failure to perform comprehensive pump testing of Containment Spray pump P-54A in accordance with the code of record.
, was invalid because it did not meet the requirements specified by the ASME code. Specifically, the requirements for differential pressure instrument accuracy. Per ASME OMb Code
-2003, ISTB
-3510(a) "Accuracy" states:
  "Instrument accuracy shall be within the limits of Table ISTB
-3500-1."  Table ISTB
-3500-1, "Required Instrument Accuracy," requires the differential pressure instrument accuracy for differential pressure readings during a comprehensive test to be plus or minus 1/2 percent full scale. The post
-test calibration results showed DPI
-0319A did not meet the required accuracy. The ASME code, Section ISTB-6300 "Systematic Error" requires: 
"When a test shows measured parameter values that fall outside of the acceptable range of Table ISTB
-5100-1, Table ISTB
-5200-1, Table ISTB
-5300-1, or Table ISTB
-5300-2, as applicable, that have resulted from an identified systematic error, such as improper system lineup or inaccurate instrumentation, the test shall be rerun after correcting the error."


=====Description:=====
Containment Spray Pump, P
On February 25, 2014 the licensee performed WO 52435851 01, "RO-98 -LPSI PMP VIB, CONT SPRY PMP VIB, DIS CK," which includes the comprehensive pump test of Containment Spray (CS) Pump P-54A. The comprehensive pump test is performed every 18 months in accordance with the ASME OMb Code-2001, through ASME OMb Code-2003 Addenda, which according to FSAR Section 6.9.2.1, "Pump Testing Program," and Site Engineering Program SEP-PLP-IST-102, "Inservice Testing of Selected Safety-Related Pumps" is the code of record for Palisades. Comprehensive testing of pumps is performed in order to detect potential degradation of the equipment and helps ensure the SSC will be able to meet its design requirements. During the test, the recorded differential pressure (DP) was 142.0 psid as read on differential pressure indicator DPI-0319A (range 0 to 250 psid). This value was within the Alert Range established by the licensee's procedure. Procedure RO-98 establishes the different criteria for P-54A as follows:  The Acceptable Range was a 143.2 to 158.6 psid;  The Alert Range was 138.6 to 143.2 psid;  The Required Action Range was DP lower than 138.6 psid or greater than 158.6 psid; and  The Acceptance Criteria was DP greater than 136.9 psid at 2250 +/- 35 gpm 19 The licensee documented the test results in the Alert Range under CR-PLP-2014-01679. The licensee suspected instrumentation issues may have been the cause of the deviation. Site personnel performed a historical search of RO-98 testing and identified several CRs related to instrumentation issues including CR-PLP-2010-05181 and CR-PLP-2010-06403. On January 13, 2014, the DPI-0319A had been calibrated to ensure it was within the comprehensive test required accuracy. On February 26, 2014, a post-test calibration was performed in accordance with WO 52435851 01. The result of the calibrations showed pressure indicator DPI-0319A was outside of the test requirements. The results indicated the gauge was reading lower than actual DP. The licensee determined the deviation was approximately 8.75 psid lower and concluded this would indicate an actual DP of approximately 150 psid under RO-98 conditions for pump P-54A. The licensee concluded this would result in a DP within the acceptable range. In addition to the above, the license performed an assessment of the vibration results obtained and evaluated various pump result trends (comprehensive and quarterly testing) associated with pump performance. Based on this review, documented on CR-PLP-2014-01679, the licensee concluded pump P-54A was actually operating within its acceptable range and no additional corrective actions were required. However, the inspectors were concerned the comprehensive pump test performed on February 25, 2014, was invalid because it did not meet the requirements specified by the ASME code. Specifically, the requirements for differential pressure instrument accuracy. Per ASME OMb Code-2003, ISTB-3510(a) "Accuracy" states:  "Instrument accuracy shall be within the limits of Table ISTB-3500-1."  Table ISTB-3500-1, "Required Instrument Accuracy," requires the differential pressure instrument accuracy for differential pressure readings during a comprehensive test to be plus or minus 1/2 percent full scale. The post-test calibration results showed DPI-0319A did not meet the required accuracy. The ASME code, Section ISTB-6300 "Systematic Error" requires:  "When a test shows measured parameter values that fall outside of the acceptable range of Table ISTB-5100-1, Table ISTB-5200-1, Table ISTB-5300-1, or Table ISTB-5300-2, as applicable, that have resulted from an identified systematic error, such as improper system lineup or inaccurate instrumentation, the test shall be rerun after correcting the error."  Containment Spray Pump, P-54A, acceptance values for testing fall under Table ISTB-5100-1 "Centrifugal Pump Test Acceptance Criteria."  As such, the licensee should have rerun the comprehensive test once DPI-0319A was shown to be out of calibration.
-54A, acceptance values for testing fall under Table ISTB
-5100-1 "Centrifugal Pump Test Acceptance Criteria
."  As such, the licensee should have rerun the comprehensive test once DPI
-0319A was shown to be out of calibration.


Failing to perform the IST comprehensive test as prescribe by the code was contrary to Technical Specifications (TS) 5.5.7, which requires an Inservice Testing Program be establish, implemented, and maintained. Section TS 5.5.7 a. establishes the required IST intervals as required by the code. Complete details for pumps IST are contained in Site Engineering Program SEP-PLP-IST-102, "Inservice Testing of Selected Safety-Related Pumps."  The licensee documented the inspectors' concerns and documented the basis of operability under CR-PLP-2014-04881. The licensee determined the component remained operable based on the evaluation of the instruments calibration and the successful completion of the most recent quarterly IST.
Failing to perform the IST comprehensive test as prescribe by the code was contrary to Technical Specifications (TS) 5.5.7, which requires an Inservice Testing Program be establish, implemented, and maintained. Section TS 5.5.7 a. establishes the required IST intervals as required by the code. Complete details for pumps IST are contained in Site Engineering Program SEP
-PLP-IST-102, "Inservice Testing of Selected Safety-Related Pumps."  The licensee documented the inspectors' concerns and documented the basis of operability under CR
-PLP-2014-04881. The licensee determined the component remained operable based on the evaluation of the instruments calibration and the successful completion of the most recent quarterly IST
.


=====Analysis:=====
=====Analysis:=====
The inspectors determined the failure to perform comprehensive pump testing of CS pump P-54A in accordance with the code of record was contrary to Technical Specification 5.5.7., "Inservice Testing," and a performance deficiency. The performance deficiency was determined to be more than minor because it was associated with the mitigating system cornerstone attribute of equipment performance.
The inspectors determined the failure to perform comprehensive pump testing of CS pump P
-54A in accordance with the code of record was contrary to Technical Specification 5.5.7., "Inservice Testing
," and a performance deficiency. The performance deficiency was determined to be more than minor because it was associated with the mitigating system cornerstone attribute of equipment performance.
 
20 The PD adversely affected the associated cornerstone objective to ensure the availability, reliability, and capability of CS pump P
-54A to respond to initiating events to prevent undesirable consequences. Specifically, failing to perform testing as required could result in the degradation of the equipment being undetected.
 
The inspectors determined the finding could be evaluated using the SDP in accordance with IMC 0609, "Significance Determination Process," Attachment 0609.04," "Initial Characterization of Findings."  Specifically, the inspectors used IMC 0609 Appendix A "SDP for Findings At
-Power" Exhibit 2, "Mitigating Systems Screening Questions". The finding was a deficiency affecting the design or qualification of a mitigating structure system or component (SSC) but the SSC maintained its operability. This was based on the licensee's evaluation of recent pump quarterly testing, the risk evaluation performed by the licensee, and allowance to defer performing the surveillance in according with the Technical Specifications. As a result, the finding screened as having a very low safety significance, i.e. Green.


20 The PD adversely affected the associated cornerstone objective to ensure the availability, reliability, and capability of CS pump P-54A to respond to initiating events to prevent undesirable consequences. Specifically, failing to perform testing as required could result in the degradation of the equipment being undetected.
The inspectors determined the findings had a cross
-cutting aspect in the area of Problem Identification and Resolution, Evaluation, because the licensee failed to thoroughly evaluate the issue to ensure that resolutions address causes and extents of conditions commensurate with their safety significance. Specifically, the licensee failed to identify that the out of calibration instrument would result in an invalid IST results, which would require rerunning the test per the code. [P.2]
Enforcement
:  Palisades Technical Specifications 5.5, "Programs and Manuals
," states:  "The following programs shall be established, implemented, and maintained
," Technical Specifications 5.5.7, Inservice Testing Program, states:
  "This program provides controls for inservice testing of ASME Code Class 1, 2, and 3 components."


The inspectors determined the finding could be evaluated using the SDP in accordance with IMC 0609, "Significance Determination Process," Attachment 0609.04," "Initial Characterization of Findings." Specifically, the inspectors used IMC 0609 Appendix A "SDP for Findings At-Power" Exhibit 2, "Mitigating Systems Screening Questions". The finding was a deficiency affecting the design or qualification of a mitigating structure system or component (SSC) but the SSC maintained its operability. This was based on the licensee's evaluation of recent pump quarterly testing, the risk evaluation performed by the licensee, and allowance to defer performing the surveillance in according with the Technical Specifications. As a result, the finding screened as having a very low safety significance, i.e. Green.
Additionally, Site Engineering Program SEP
-PLP-IST-102, "Inservice Testing of Selected Safety-Related Pumps" provides the details for performing Inservice Testing at Palisades and lists ASME OMb Code
-2001, through ASME OMb Code
-2003 Addenda, as the code of record for Palisades.


The inspectors determined the findings had a cross-cutting aspect in the area of Problem Identification and Resolution, Evaluation, because the licensee failed to thoroughly evaluate the issue to ensure that resolutions address causes and extents of conditions commensurate with their safety significance. Specifically, the licensee failed to identify that the out of calibration instrument would result in an invalid IST results, which would require rerunning the test per the code. [P.2]
Contrary to the above, on February 25, 2014, the licensee failed to rerun a comprehensive pump test of Containment Spray pump P
-54A in accordance with ASME code. Specifically, the licensee failed to meet the requirements of Section ISTB
-6300, "Systematic Error
," which requires licensees, after correcting the error, to rerun tests when the test shows the measured parameter falls outside the acceptable range as a result of a systematic error such as inaccurate instrumentation.


=====Enforcement:=====
The licensee entered this issue into their Corrective Action Program and evaluated the operability of the component in accordance with their process.
Palisades Technical Specifications 5.5, "Programs and Manuals," states:  "The following programs shall be established, implemented, and maintained," Technical Specifications 5.5.7, Inservice Testing Program, states:  "This program provides controls for inservice testing of ASME Code Class 1, 2, and 3 components."  Additionally, Site Engineering Program SEP-PLP-IST-102, "Inservice Testing of Selected Safety-Related Pumps" provides the details for performing Inservice Testing at Palisades and lists ASME OMb Code-2001, through ASME OMb Code-2003 Addenda, as the code of record for Palisades.
 
Based on previously successful IST quarterly test the licensee determined the component remained operable.


Contrary to the above, on February 25, 2014, the licensee failed to rerun a comprehensive pump test of Containment Spray pump P-54A in accordance with ASME code. Specifically, the licensee failed to meet the requirements of Section ISTB-6300, "Systematic Error," which requires licensees, after correcting the error, to rerun tests when the test shows the measured parameter falls outside the acceptable range as a result of a systematic error such as inaccurate instrumentation. The licensee entered this issue into their Corrective Action Program and evaluated the operability of the component in accordance with their process. Based on previously successful IST quarterly test the licensee determined the component remained operable. Because this violation was of very low safety significance, and it was entered into the licensee's Corrective Action Program as CR-PLP-2014-04881, this violation is being treated as a Green NCV, consistent with Section 2.3.2 of the NRC Enforcement Policy.  [NCV 05000255/2014008-06, Failure to Perform Comprehensive Pump Testing of Containment Spray Pump P-54A in accordance with the Inservice Testing Program.] (6) Failure to Correctly Translate Valve Leakage Limits into Test Procedure
Because this violation was of very low safety significance, and it was entered into the licensee's Corrective Action Program as CR
-PLP-2014-04881, this violation is being treated as a Green NCV, consistent with Section 2.3.2 of the NRC Enforcement Policy.  [NCV 05000255/2014008
-06, Failure to Perform Comprehensive Pump Testing of Containment Spray Pump P
-54A in accordance with the Inservice Testing Program.]
  (6) Failure to Correctly Translate Valve Leakage Limits into Test Procedure


=====Introduction:=====
=====Introduction:=====
The inspectors identified a finding of very low safety significance (Green) and associated NCV of 10 CFR Part 50, Appendix B, Criterion III, "Design Control," for the licensee's failure to correctly translate design valve leakage limits into test procedures. Specifically, the acceptance criterion for ECCS/CS recirculation isolation 21 valves CV-3027 and CV-3056 had not been correctly adjusted to account for the higher differential pressure associated with ECCS operation under post-accident conditions.
The inspectors identified a finding of very low safety significance (Green) and associated NCV of 10 CFR Part 50, Appendix B, Criterion III, "Design Control
," for the licensee's failure to correctly translate design valve leakage limits into test procedures.
 
Specifically, the acceptance criterion for ECCS/CS recirculation isolation 21 valves CV
-3027 and CV
-3056 had not been correctly adjusted to account for the higher differential pressure associated with ECCS operation under post
-accident conditions.
 
Description
:  The inspectors reviewed the leak test procedure and acceptance criteria associated with ECCS/CS recirculation isolation valves CV
-3027 and CV
-3056. These valves were installed in series in the common minimum flow recirculation line from the ECCS and CS pumps to the SIRW tank. During post
-accident operation, these valves remain open during the ECCS injection phase to provide minimum flow protection for the low pressure safety injection (LPSI) and high pressure safety injection (HPSI) pumps. During the recirculation phase of post
-accident operation, these valves are required to be closed to limit the release of radiological material from the SIRW tank vent.
 
The inspectors observed the design basis alternate source term analysis, NAI
-1149-014, Revision 4 (dated 10/15/07), was based on a maximum allowable recirculation line leakage of 0.00625 gpm (23.7 ml/min).
 
Test procedure RO
-119, Inservice Testing o f Engineered Safeguards Valves CV
-3027 and CV
-3056, Revision 14 included a leakage acceptance criterion of 25.1 ml/min. The inspectors also observed test Procedure RO
-119 was performed with a LPSI pump in operation. The acceptance criterion had not been correctly adjusted to account for the higher differential pressure associated with HPSI pump operation under post
-accident conditions. The licensee performed an informal evaluation and determined that the correct leakage acceptance criterion would


=====Description:=====
be 6 ml/min. Condition Report CR-PLP-2014-04681 was initiated to address this issue.
The inspectors reviewed the leak test procedure and acceptance criteria associated with ECCS/CS recirculation isolation valves CV-3027 and CV-3056. These valves were installed in series in the common minimum flow recirculation line from the ECCS and CS pumps to the SIRW tank. During post-accident operation, these valves remain open during the ECCS injection phase to provide minimum flow protection for the low pressure safety injection (LPSI) and high pressure safety injection (HPSI) pumps. During the recirculation phase of post-accident operation, these valves are required to be closed to limit the release of radiological material from the SIRW tank vent. The inspectors observed the design basis alternate source term analysis, NAI-1149-014, Revision 4 (dated 10/15/07), was based on a maximum allowable recirculation line leakage of 0.00625 gpm (23.7 ml/min). Test procedure RO-119, Inservice Testing of Engineered Safeguards Valves CV-3027 and CV-3056, Revision 14 included a leakage acceptance criterion of 25.1 ml/min. The inspectors also observed test Procedure RO-119 was performed with a LPSI pump in operation. The acceptance criterion had not been correctly adjusted to account for the higher differential pressure associated with HPSI pump operation under post-accident conditions. The licensee performed an informal evaluation and determined that the correct leakage acceptance criterion would be 6 ml/min. Condition Report CR-PLP-2014-04681 was initiated to address this issue. The licensee determined that past leak test results for both CV-3027 and CV-3056 had exceeded the corrected acceptance criterion of 6 ml/min. However, the most recent leak test results for both CV-3027 and CV-3056 were less than 6 ml/min. The licensee also reviewed the results in the context of total containment leakage and verified the past leak test results did not exceed operability limits.
 
The licensee determined that past leak test results for both CV
-3027 and CV-3056 had exceeded the corrected acceptance criterion of 6 ml/min. However, the most recent leak test results for both CV
-3027 and CV
-3056 were less than 6 ml/min. The licensee also reviewed the results in the context of total containment leakage and verified the past leak test results did not exceed operability limits.


=====Analysis:=====
=====Analysis:=====
The inspectors determined the failure to correctly translate design valve leakage limits into test procedures was contrary to 10 CFR Part 50, Appendix B, Criterion III, "Design Control," and was a performance deficiency. The performance deficiency was determined to be more than minor because it was associated with the Barrier Integrity Cornerstone attribute of Design Control and it adversely affected the associated cornerstone objective to provide reasonable assurance that containment could protect the public from radionuclide releases caused by accidents or events. Specifically, measured leakage exceeded analyzed dose calculations.
The inspectors determined the failure to correctly translate design valve leakage limits into test procedures was contrary to 10 CFR Part 50, Appendix B, Criterion III, "Design Control," and was a performance deficiency. The performance deficiency was determined to be more than minor because it was associated with the Barrier Integrity Cornerstone attribute of Design Control and it adversely affected the associated cornerstone objective to provide reasonable assurance that containment could protect the public from radionuclide releases caused by accidents or events. Specifically, measured leakage exceed ed analyzed dose calculations
.


The inspectors determined the finding could be evaluated using the SDP in accordance with Inspection Manual Chapter (IMC) 0609, "Significance Determination Process,"
The inspectors determined the finding could be evaluated using the SDP in accordance with Inspection Manual Chapter (IMC) 0609, "Significance Determination Process,"
0609.04, "Initial Characterization of Findings," issued on June 19, 2012. Because the finding impacted the Barriers Cornerstone, the inspectors screened the finding through IMC 0609 Appendix A, "The Significance Determination Process for Findings At-Power," issued June 19, 2012, using Exhibit 3, "Barrier Integrity Screening Questions."  The finding screened as of very low safety significance (Green) because the inspectors answered "No" to all of the screening questions in Subsection B, "Reactor Containment," of Exhibit 3. Specifically, the finding did not represent an actual open pathway in the physical integrity of reactor containment, containment isolation system, or heat removal components and did not involve an actual reduction in function of hydrogen igniters in the reactor containment. The inspectors determined this finding did not have an associated cross-cutting aspect because it was not representative of the licensee's present performance.
0609.04, "Initial Characterization of Findings," issued on June 19, 2012. Because the finding impacted the Barriers Cornerstone, the inspectors screened the finding through IMC 0609 Appendix A, "The Significance Determination Process for Findings At
-Power," issued June 19, 2012, using Exhibit 3, "Barrier Integrity Screening Questions."  The finding screened as of very low safety significance (Green) because the inspectors answered "No" to all of the screening questions in Subsection B, "Reactor Containment," of Exhibit 3. Specifically, the finding did not represent an actual open pathway in the physical integrity of reactor containment, containment isolation system, or heat removal components and did not involve an actual reduction in function of hydrogen igniters in the reactor containment. The inspectors determined this finding did not have an associated cross
-cutting aspect because it was not representative of the licensee's present performance.


22
22
Line 204: Line 651:
Title 10 CFR Part 50, Appendix B, Criterion III, "Design Control," requires, in part, that measures shall be established to assure that applicable regulatory requirements and the design basis, as defined in §50.2 and as specified in the license application, for those structures, systems, and components to which this appendix applies are correctly translated into specifications, drawings, procedures, and instructions.
Title 10 CFR Part 50, Appendix B, Criterion III, "Design Control," requires, in part, that measures shall be established to assure that applicable regulatory requirements and the design basis, as defined in §50.2 and as specified in the license application, for those structures, systems, and components to which this appendix applies are correctly translated into specifications, drawings, procedures, and instructions.


Contrary to the above, as of September 25, 2014, the licensee failed to correctly translated design leakage limits into the test procedure for valves CV-3027 and CV-3056. Because this violation was of very low safety significance and was entered into the licensee's CAP as CR-PLP-2014-04681, this violation is being treated as an NCV, consistent with Section 2.3.2 of the NRC Enforcement Policy. [NCV 05000255/2014008-07, "Failure to Correctly Translate Valve Leakage Limits into Test Procedure." (7) Failure to Identify Non-Safety-Related Sub-Components Improperly Supplied with Safety-Related Valves
Contrary to the above, as of September 25, 2014, the licensee failed to correctly translated design leakage limits into the test procedure for valves CV-3027 and CV
-3056. Because this violation was of very low safety significance and was entered into the licensee's CAP as CR
-PLP-2014-04681, this violation is being treated as an NCV, consistent with Section 2.3.2 of the NRC Enforcement Policy. [NCV 05000255/2014008
-07, "Failure to Correctly Translate Valve Leakage Limits into Test Procedure
." (7) Failure to Identify Non
-Safety-Related Sub-Components Improperly Supplied with Safety-Related Valves Introduction
:  The inspectors identified a finding of very low safety significance (Green) and associated NCV of 10 CFR Part 50, Appendix B, Criterion VII, "Control of Purchased Material, Equipment, and Services," for the licensee's failure to identify non-safety-related sub
-components improperly supplied with safety
-related valves. Specifically, ECCS/CS recirculation isolation valves CV
-3027 and CV
-3056, which were installed in 2007, were supplied with non
-safety-related sub
-components. These components were identified as non
-safety- related on the vendor drawings. In addition, the licensee later installed a section of non
-safety-related tubing on valve CV
-3027 based on the incorrect vendor drawing.


=====Introduction:=====
Description
The inspectors identified a finding of very low safety significance (Green) and associated NCV of 10 CFR Part 50, Appendix B, Criterion VII, "Control of Purchased Material, Equipment, and Services," for the licensee's failure to identify non-safety-related sub-components improperly supplied with safety-related valves. Specifically, ECCS/CS recirculation isolation valves CV-3027 and CV-3056, which were installed in 2007, were supplied with non-safety-related sub-components. These components were identified as non-safety- related on the vendor drawings. In addition, the licensee later installed a section of non-safety-related tubing on valve CV-3027 based on the incorrect vendor drawing.
: The inspectors reviewed the vendor drawings for safety
-related ECCS/CS recirculation isolation valves CV
-3027 and CV
-3056, which were installed in 2007. Drawings VEN
-M241BC, Sheet 33, Revision 0 and VEN
-M241BC, Sheet 35, Revision 0 listed the sub
-components associated with these valves and identified the quality classification of each sub
-component. The inspection team noted that some of the sub
-components appeared to be incorrectly classified as non
-safety-related. The licensee investigated and determined the drawings were incorrect and that some of these components were actually supplied as safety
-related; however, several cap screws were inappropriately supplied as non
-safety-related. Condition report CR
-PLP-2014-04755 was initiated to correct the drawings and replace the non-safety-related cap screws with safety-related material.
 
The licensee performed additional investigation and determined a section of non-safety-related tubing had been installed on valve CV
-3027 during maintenance activities; this error was based on the incorrect vendor drawing.


=====Description:=====
Condition report CR
The inspectors reviewed the vendor drawings for safety-related ECCS/CS recirculation isolation valves CV-3027 and CV-3056, which were installed in 2007. Drawings VEN-M241BC, Sheet 33, Revision 0 and VEN-M241BC, Sheet 35, Revision 0 listed the sub-components associated with these valves and identified the quality classification of each sub-component. The inspection team noted that some of the sub-components appeared to be incorrectly classified as non-safety-related. The licensee investigated and determined the drawings were incorrect and that some of these components were actually supplied as safety-related; however, several cap screws were inappropriately supplied as non-safety-related. Condition report CR-PLP-2014-04755 was initiated to correct the drawings and replace the non-safety-related cap screws with safety-related material. The licensee performed additional investigation and determined a section of non-safety-related tubing had been installed on valve CV-3027 during maintenance activities; this error was based on the incorrect vendor drawing. Condition report CR-PLP-2014-04815 was initiated to correct the drawings and replace the tubing with safety-related material. The licensee performed an evaluation and determined both valves were operable in their current condition.
-PLP-2014-04815 was initiated to correct the drawings and replace the tubing with safety-related material. The licensee performed an evaluation and determined both valves were operable in their current condition.


=====Analysis:=====
=====Analysis:=====
The inspectors determined the failure to identify non-safety-related sub-components improperly supplied with safety-related valves was contrary to 10 CFR Part 50, Appendix B, Criterion VII, "Control of Purchased Material, Equipment, and Services," and was a performance deficiency. The performance deficiency was determined to be more than minor because it was associated with the Barrier Integrity Cornerstone attribute of Design Control and it adversely affected the associated cornerstone objective to provide reasonable assurance that containment could protect 23 the public from radionuclide releases caused by accidents or events. Specifically, the licensee failed to verify the sub-components of valves CV-3027 and CV-3056 met their design requirements. The inspectors determined the finding could be evaluated using the SDP in accordance with Inspection Manual Chapter (IMC) 0609, "Significance Determination Process," Attachment 0609.04, "Initial Characterization of Findings," issued on June 19, 2012. Because the finding impacted the Barriers Cornerstone, the inspectors screened the finding through IMC 0609 Appendix A, "The Significance Determination Process for Findings At-Power," issued June 19, 2012, using Exhibit 3, "Barrier Integrity Screening Questions."  The finding screened as of very low safety significance (Green) because the inspectors answered "No" to all of the screening questions in Subsection B, "Reactor Containment," of Exhibit 3. Specifically, the finding did not represent an actual open pathway in the physical integrity of reactor containment, containment isolation system, or heat removal components and did not involve an actual reduction in function of hydrogen igniters in the reactor containment. The inspectors determined this finding did not have an associated cross-cutting aspect because it was not representative of current performance.
The inspectors determined the failure to identify non
-safety-related sub-components improperly supplied with safety-related valves was contrary to 10 CFR Part 50, Appendix B, Criterion VII, "Control of Purchased Material, Equipment, and Services," and was a performance deficiency. The performance deficiency was determined to be more than minor because it was associated with the Barrier Integrity Cornerstone attribute of Design Control and it adversely affected the associated cornerstone objective to provide reasonable assurance that containment could protect 23 the public from radionuclide releases caused by accidents or events. Specifically, the licensee failed to verify the sub
-components of valves CV
-3027 and CV
-3056 met their design requirements.
 
The inspectors determined the finding could be evaluated using the SDP in accordance with Inspection Manual Chapter (IMC) 0609, "Significance Determination Process," Attachment 0609.04, "Initial Characterization of Findings," issued on June 19, 2012. Because the finding impacted the Barriers Cornerstone, the inspectors screened the finding through IMC 0609 Appendix A, "The Significance Determination Process for Findings At
-Power," issued June 19, 2012, using Exhibit 3, "Barrier Integrity Screening Questions."  The finding screened as of very low safety significance (Green) because the inspectors answered "No" to all of the screening questions in Subsection B, "Reactor Containment," of Exhibit 3. Specifically, the finding did not represent an actual open pathway in the physical integrity of reactor containment, containment isolation system, or heat removal components and did not involve an actual reduction in function of hydrogen igniters in the reactor containment. The inspectors determined this finding did not have an associated cross
-cutting aspect because it was not representative of current performance.
 
Enforcement
:  Title 10 CFR Part 50, Appendix B, Criterion VII, "Control of Purchased Material, Equipment, and Services," requires, in part, that measures shall be established to assure that purchased material, equipment, and services, whether purchased directly or through contractors and subcontractors, conform to the procurement documents.
 
Contrary to the above, as of September 25, 2007 and October 8, 2007, when these valves were installed, the licensee failed to assure that purchased material conformed to the procurement documents.


=====Enforcement:=====
Because this violation was of very low safety significance and was entered into the licensee's CAP as CR
Title 10 CFR Part 50, Appendix B, Criterion VII, "Control of Purchased Material, Equipment, and Services," requires, in part, that measures shall be established to assure that purchased material, equipment, and services, whether purchased directly or through contractors and subcontractors, conform to the procurement documents.
-PLP-2014-04755 and CR
-PLP-2014-04815, this violation is being treated as an NCV, consistent with Section 2.3.2 of the NRC Enforcement Policy.  [NCV 05000255/2014008
-08, "Failure to Identify Non
-Safety-Related Sub-Components Improperly Supplied with Safety
-Related Valves."


Contrary to the above, as of September 25, 2007 and October 8, 2007, when these valves were installed, the licensee failed to assure that purchased material conformed to the procurement documents. Because this violation was of very low safety significance and was entered into the licensee's CAP as CR-PLP-2014-04755 and CR-PLP-2014-04815, this violation is being treated as an NCV, consistent with Section 2.3.2 of the NRC Enforcement Policy.  [NCV 05000255/2014008-08, "Failure to Identify Non-Safety-Related Sub-Components Improperly Supplied with Safety-Related Valves."]  (8) Failure to Establish an Adequate Test Program for the Shutdown Cooling Heat Exchangers
]  (8) Failure to Establish an Adequate Test Program for the Shutdown Cooling Heat Exchangers


=====Introduction:=====
=====Introduction:=====
The inspectors identified a finding of very low safety significance (Green) and associated NCV of 10 CFR Part 50, Appendix B, Criterion XI, "Test Control," for the licensee's failure to establish an adequate test program for the Shutdown Cooling (SDC) Heat Exchangers (HXs) to demonstrate they can perform as designed. Specifically, the licensee failed to take actions to ensure the SDC HXs' heat transfer capability met its design bases, as assumed in design bases calculations.
The inspectors identified a finding of very low safety significance (Green) and associated NCV of 10 CFR Part 50, Appendix B, Criterion XI, "Test Control," for the licensee's failure to establish an adequate test program for the Shutdown Cooling (SDC) Heat Exchangers (HXs) to demonstrate they can perform as designed. Specifically, the licensee failed to take actions to ensure the SDC HXs' heat transfer capability met its design bases, as assumed in design bases calculations.


=====Description:=====
Description
The SDC HXs were designed for use during primary system cooldown, refueling, and emergency plant operation. During plant cooldowns and refueling outages, the HXs remove decay heat by directly cooling the primary coolant system. During emergency plant operations, the HXs form part of the containment cooling system by cooling the containment spray water. In addition, during the recirculation phase of a loss of coolant accident (LOCA), the SDC HXs cool the containment sump water that is injected by the High Pressure Safety Injection (HPSI) pumps to provide long term core cooling. The SDC HXs are original plant equipment that has been intermittently operated since the beginning of plant operations in 1971. In over 40 years, they have never been 24 inspected, contrary to vendor recommendations. Section E-4.1 of the vendor manual states that, "at intervals as experience indicates, an examination should be made of the interior and exterior condition of all tubes."  Since the licensee has never inspected the interior of the SDC HXs, they have not established a frequency for performing the HX inspections as recommended by the vendor manual.
: The SDC HXs were designed for use during primary system cooldown, refueling, and emergency plant operation. During plant cooldowns and refueling outages, the HXs remove decay heat by directly cooling the primary coolant system. During emergency plant operations, the HXs form part of the containment cooling system by cooling the containment spray water. In addition, during the recirculation phase of a loss of coolant accident (LOCA), the SDC HXs cool the containment sump water that is injected by the High Pressure Safety Injection (HPSI) pumps to provide long term core cooling.
 
The SDC HXs are original plant equipment that has been intermittently operated since the beginning of plant operations in 1971. In over 40 years, they have never been 24 inspected, contrary to vendor recommendations. Section E
-4.1 of the vendor manual states that, "at intervals as experience indicates, an examination should be made of the interior and exterior condition of all tubes."  Since the licensee has never inspected the interior of the SDC HXs, they have not established a frequency for performing the HX inspections as recommended by the vendor manual.
 
In addition, the SDC HXs have never been successfully thermal performance tested. In 1992, the licensee identified the need to thermal performance test the SDC HXs to verify they could perform as designed. However, because they were successfully performing their SDC function and because both water streams flowing through the HXs had chemistry controls in place, the licensee decided it was not necessary to perform the test. In 1996, the licensee completed a thermal performance test, but the analysis of the test results concluded the test did not achieve its goal of recording useful data. The test has never been repeated, and the licensee instead continues to credit the SDC function and the chemistry controls in place to provide assurance that the SDC HXs can perform as designed.
 
In 1989 the NRC issued Generic Letter (GL) 89
-13, "Service Water System Problems Affecting Safety
-Related Equipment."  Although the GL was mostly related to open cycle cooling water systems, it did contain the following guidance related to closed cycle cooling water systems: 
"Operating experience and studies indicate that closed
-cycle service water systems, such as component cooling water systems, have the potential for significant fouling as a consequence of aging
-related in
-leakage and erosion or corrosion. The need for testing of closed
-cycle system heat exchangers has not been considered necessary because of the assumed high quality of existing chemistry control programs. If the adequacy of these chemistry control programs cannot be confirmed over the total operating history of the plant
[emphasis added] or if during the conduct of the total testing program any unexplained downward trend in heat exchanger performance is identified that cannot be remedied by maintenance of an open
-cycle system, it may be necessary to selectively extend the test program and the routine inspection and maintenance program addressed in Action III, below, to the attached closed
-cycle systems.
 
" Therefore, the NRC recognized that testing of closed cycle system heat exchangers was not necessary if high quality chemistry control programs were in place. However, this was dependent on whether or not the adequacy of the chemistry control programs could be confirmed over the total operating history of the plant. Although Palisades has chemistry controls in place for both water streams (Primary Coolant System and Component Cooling Water) flowing through the SDC HXs, the licensee ha d not verified the effectiveness of these chemistry controls in preventing degradation of the SDC HXs heat transfer capability.


In addition, the SDC HXs have never been successfully thermal performance tested. In 1992, the licensee identified the need to thermal performance test the SDC HXs to verify they could perform as designed. However, because they were successfully performing their SDC function and because both water streams flowing through the HXs had chemistry controls in place, the licensee decided it was not necessary to perform the test. In 1996, the licensee completed a thermal performance test, but the analysis of the test results concluded the test did not achieve its goal of recording useful data. The test has never been repeated, and the licensee instead continues to credit the SDC function and the chemistry controls in place to provide assurance that the SDC HXs can perform as designed. In 1989 the NRC issued Generic Letter (GL) 89-13, "Service Water System Problems Affecting Safety-Related Equipment."  Although the GL was mostly related to open cycle cooling water systems, it did contain the following guidance related to closed cycle cooling water systems:  "Operating experience and studies indicate that closed-cycle service water systems, such as component cooling water systems, have the potential for significant fouling as a consequence of aging-related in-leakage and erosion or corrosion. The need for testing of closed-cycle system heat exchangers has not been considered necessary because of the assumed high quality of existing chemistry control programs. If the adequacy of these chemistry control programs cannot be confirmed over the total operating history of the plant [emphasis added] or if during the conduct of the total testing program any unexplained downward trend in heat exchanger performance is identified that cannot be remedied by maintenance of an open-cycle system, it may be necessary to selectively extend the test program and the routine inspection and maintenance program addressed in Action III, below, to the attached closed-cycle systems." Therefore, the NRC recognized that testing of closed cycle system heat exchangers was not necessary if high quality chemistry control programs were in place. However, this was dependent on whether or not the adequacy of the chemistry control programs could be confirmed over the total operating history of the plant. Although Palisades has chemistry controls in place for both water streams (Primary Coolant System and Component Cooling Water) flowing through the SDC HXs, the licensee had not verified the effectiveness of these chemistry controls in preventing degradation of the SDC HXs heat transfer capability. The chemistry controls, in themselves, are not enough to demonstrate the SDC HXs can perform as assumed in design bases calculations.
The chemistry controls, in themselves, are not enough to demonstrate the SDC HXs can perform as assumed in design bases calculations.


The licensee also credits the SDC function of the HXs to provide justification that they can perform as designed. However, during SDC, the water temperatures and flow rates through the HX are different than those during emergency plant operation, and the licensee does not monitor or trend the SDC performance of the HXs to detect degradation. Therefore, although the HXs are successfully performing the routine SDC function, the licensee does not gather nor analyze sufficient HX performance information to demonstrate the HXs can perform as assumed in design bases calculations.
The licensee also credits the SDC function of the HXs to provide justification that they can perform as designed. However, during SDC, the water temperatures and flow rates through the HX are different than those during emergency plant operation, and the licensee does not monitor or trend the SDC performance of the HXs to detect degradation. Therefore, although the HXs are successfully performing the routine SDC function, the licensee does not gather nor analyze sufficient HX performance information to demonstrate the HXs can perform as assumed in design bases calculations.


25 The issue was entered into the licensee's Corrective Action Program as CR-PLP-2014-04912 to review the adequacy of testing performed to ensure the SDC HXs remain qualified to the capability assumed during design bases events. Based upon the available tube plugging margin and recent history of chemistry controls, the inspectors gained reasonable assurance of operability.
25 The issue was entered into the licensee's Corrective Action Program as CR
-PLP-2014-04912 to review the adequacy of testing performed to ensure the SDC HXs remain qualified to the capability assumed during design bases events.
 
Based upon the available tube plugging margin and recent history of chemistry controls, the inspectors gained reasonable assurance of operability.


=====Analysis:=====
=====Analysis:=====
The inspectors determined the failure to establish an adequate test program for the SDC HXs to demonstrate they could perform as designed was contrary to 10 CFR Part 50, Appendix B, Criterion XI, "Test Control," and was a performance deficiency. The performance deficiency was determined to be more than minor because it was associated with the Barrier Integrity Cornerstone attribute of Design Control and it adversely affected the associated cornerstone objective to provide reasonable assurance that containment could protect the public from radionuclide releases caused by accidents or events. Specifically, the licensee failed to verify that the SDC HXs heat transfer capability met their design bases, as assumed in design bases calculations, to limit containment temperatures and pressures during an event.
The inspectors determined the failure to establish an adequate test program for the SDC HXs to demonstrate they could perform as designed was contrary to 10 CFR Part 50, Appendix B, Criterion XI, "Test Control," and was a performance deficiency. The performance deficiency was determined to be more than minor because it was associated with the Barrier Integrity Cornerstone attribute of Design Control and it adversely affected the associated cornerstone objective to provide reasonable assurance that containment could protect the public from radionuclide releases caused by accidents or events. Specifically, the licensee failed to verify that the SDC HXs heat transfer capability met their design bases, as assumed in design bases calculations, to limit containment temperatures and pressures during an event.


The inspectors determined the finding could be evaluated using the SDP in accordance with Inspection Manual Chapter (IMC) 0609, "Significance Determination Process," Attachment 0609.04, "Initial Characterization of Findings," issued on June 19, 2012. Because the finding impacted the Barriers Cornerstone, the inspectors screened the finding through IMC 0609 Appendix A, "The Significance Determination Process for Findings At-Power," issued June 19, 2012, using Exhibit 3, "Barrier Integrity Screening Questions."  The finding screened as of very low safety significance (Green) because the inspectors answered "No" to all of the screening questions in Subsection B, "Reactor Containment," of Exhibit 3. Specifically, the finding did not represent an actual open pathway in the physical integrity of reactor containment, containment isolation system, or heat removal components and did not involve an actual reduction in function of hydrogen igniters in the reactor containment.
The inspectors determined the finding could be evaluated using the SDP in accordance with Inspection Manual Chapter (IMC)0609, "Significance Determination Process," Attachment 0609.04, "Initial Characterization of Findings," issued on June 19, 2012. Because the finding impacted the Barriers Cornerstone, the inspectors screened the finding through IMC 0609 Appendix A, "The Significance Determination Process for Findings At
-Power," issued June 19, 2012, using Exhibit 3, "Barrier Integrity Screening Questions."  The finding screened as of very low safety significance (Green) because the inspectors answered "No" to all of the screening questions in Subsection B, "Reactor Containment," of Exhibit 3. Specifically, the finding did not represent an actual open pathway in the physical integrity of reactor containment, containment isolation system, or heat removal components and did not involve an actual reduction in function of hydrogen igniters in the reactor containment.


The inspectors determined this finding had an associated cross-cutting aspect, Conservative Bias, in the Human Performance cross-cutting area. Specifically, on several occasions and as recently as October 2012 when the licensee identified the need to perform testing and/or inspection of the SDC HXs, the licensee did not take actions because they did not believe any regulatory requirements or technical issues existed that required the testing and/or inspections.  [H.14]
The inspectors determined this finding had an associated cross
-cutting aspect, Conservative Bias, in the Human Performance cross
-cutting area
. Specifically, on several occasions and as recently as October 2012 when the licensee identified the need to perform testing and/or inspection of the SDC HX s, the licensee did not take actions because they did not believe any regulatory requirements or technical issues existed that required the testing and/or inspections.  [H.14]


=====Enforcement:=====
=====Enforcement:=====
Title 10 CFR Part 50, Appendix B, Criterion XI, "Test Control," requires, in part, that a test program shall be established to assure all testing required to demonstrate  structures, systems, and components will perform satisfactorily in service is identified and performed in accordance with written test procedures which incorporate the requirements and acceptance limits contained in applicable design documents. Contrary to the above, as of November 4, 2014, the licensee failed to establish an adequate test program for the SDC HXs to demonstrate they could perform as designed. Specifically, the licensee failed to take actions to ensure the heat transfer capability of the SDC HXs met their design bases, as assumed in design bases calculations.
Title 10 CFR Part 50, Appendix B, Criterion XI, "Test Control," requires, in part, that a test program shall be established to assure all testing required to demonstrate  structures, systems, and components will perform satisfactorily in service is identified and performed in accordance with written test procedures which incorporate the requirements and acceptance limits contained in applicable design documents.


Because this violation was of very low safety significance and was entered into the licensee's CAP as CR-PLP-2014-04912, this violation is being treated as an NCV, consistent with Section 2.3.2 of the NRC Enforcement Policy. [NCV 05000255/2014008-09, "Failure to Establish an Adequate Test Program for the Shutdown Cooling Heat Exchangers"] 
Contrary to the above, as of November 4, 2014
(9) Failure To Include The Degraded Voltage Channel Time Delay In TS Surveillance Requirement 3.3.5.2.a
, the licensee failed to establish an adequate test program for the SDC HXs to demonstrate they could perform as designed. Specifically, the licensee failed to take actions to ensure the heat transfer capability of the SDC HXs met their design bases, as assumed in design bases calculations.


=====Introduction:=====
Because this violation was of very low safety significance and was entered into the licensee's CAP as CR
The inspectors identified a finding having very low safety significance and an associated Non-Cited Violation (NCV) of 10 CFR Part 50.36(c)(3), "Surveillance Requirements," for the failure to ensure the channel time delay for the degraded-voltage monitor was included in TS SR 3.3.5.2.a. Specifically, the licensee had only included the timing requirements for the voltage sensing relay in the TS SR; failing to include the required time delay after the voltage sensing relay trips before the preferred source of power is isolated and 1E electrical loads transferred to the stand-by EDGs.
-PLP-2014-04912, this violation is being treated as an NCV, consistent with Section 2.3.2 of the NRC Enforcement Policy.  [NCV 05000255/20 14008-09, "Failure to Establish an Adequate Test Program for the Shutdown Cooling Heat Exchangers
"] 
(9) Failure To Include The Degraded Voltage Channel Time Delay In TS Surveillance Requirement 3.3.5.2.a Introduction
: The inspectors identified a finding having very low safety significance and an associated Non-Cited Violation (NCV) of 10 CFR Part 50.36(c)(3), "Surveillance Requirements," for the failure to ensure the channel time delay for the degraded
-voltage monitor was included in TS SR 3.3.5.2.a. Specifically, the licensee had only included the timing requirements for the voltage sensing relay in the TS SR; failing to include the required time delay after the voltage sensing relay trips before the preferred source of power is isolated and 1E electrical loads transferred to the stand
-by EDGs. Description
:  The inspectors noted TS SR 3.3.5.2, Revision 189, requires the licensee to "Perform a CHANNEL CALIBRATION on each Loss of Voltage and Degraded Voltage channel with setpoints-:"  Part a. of SR 3.3.5.2 gives the degraded voltage function setpoint but only gives the time delay associated with the sensing element of the degraded voltage monitor. However, a channel of the degraded voltage monitor contains both the voltage sensing relay and a nominal 6
-second delay timer which has to time out before the trip relay actuates and off-site power supply breaker is opened.
 
The inspectors reviewed an NRC letter to the licensee dated December 22, 1981
, with the Subject:
SEP Topic VIII
-1.A, "Potential Equipment Failures Associated With Degraded Grid Voltage."  Enclosure 1 to this letter was the NRC staff's Safety Evaluation Report (SER) on degraded grid voltage protection for the Class 1E System. The SER conclusions were based on a detailed review and technical evaluation of the licensee's proposed modifications and changes to the Technical Specifications. This SER referenced EG&G Interim Report No. EGG
-EA-5321, Revision 3, Degraded Grid Protection for Class 1E Power Systems, Palisades Plant, Docket No. 50
-255, TAC No. 10043, Section 3.3, "Discussion,"  Paragraph 3, which states, in part, "The time delay selected shall be based on the following conditions:
a; The allowable time delay, including margin, shall not exceed the maximum time delay that is assumed in the FSAR accident analysis, and b
; The time delay shall minimize the effect of short duration disturbances from reducing the unavailability of the offsite power source(s)."  Paragraph 4 states, "The voltage monitors shall automatically initiate the disconnection of offsite power sources whenever the voltage setpoint and time
-delay limits have been exceeded."  Paragraph 6 states
, "The Technical Specifications shall include limiting conditions for operations, surveillance requirements, setpoints with minimum and maximum limits, and allowable values for the second
-level voltage protection monitors."  (Note that the degraded voltage setpoint is also known as the second
-level voltage relay setpoint.)  The total time delay evaluated by EGG was a nominal 6 seconds added to the time for the voltage relay to activate. From these statements, it was clear that a degraded voltage monitor channel consisted of both the voltage sensing relay and the delay timer.


=====Description:=====
The licensee did not make a change to the custom TS but decided to enter the changes when implementing the standardized Combustion Engineering TS. The inspectors reviewed the Combustion Engineering STS Bases 3.3.7.3
The inspectors noted TS SR 3.3.5.2, Revision 189, requires the licensee to "Perform a CHANNEL CALIBRATION on each Loss of Voltage and Degraded Voltage channel with setpoints-:"  Part a. of SR 3.3.5.2 gives the degraded voltage function setpoint but only gives the time delay associated with the sensing element of the degraded voltage monitor. However, a channel of the degraded voltage monitor contains both the voltage sensing relay and a nominal 6-second delay timer which has to time out before the trip relay actuates and off-site power supply breaker is opened. The inspectors reviewed an NRC letter to the licensee dated December 22, 1981, with the Subject:  SEP Topic VIII-1.A, "Potential Equipment Failures Associated With Degraded Grid Voltage."  Enclosure 1 to this letter was the NRC staff's Safety Evaluation Report (SER) on degraded grid voltage protection for the Class 1E System. The SER conclusions were based on a detailed review and technical evaluation of the licensee's proposed modifications and changes to the Technical Specifications. This SER referenced EG&G Interim Report No. EGG-EA-5321, Revision 3, Degraded Grid Protection for Class 1E Power Systems, Palisades Plant, Docket No. 50-255, TAC No. 10043, Section 3.3, "Discussion,"  Paragraph 3, which states, in part, "The time delay selected shall be based on the following conditions:  a; The allowable time delay, including margin, shall not exceed the maximum time delay that is assumed in the FSAR accident analysis, and b; The time delay shall minimize the effect of short duration disturbances from reducing the unavailability of the offsite power source(s)."  Paragraph 4 states, "The voltage monitors shall automatically initiate the disconnection of offsite power sources whenever the voltage setpoint and time-delay limits have been exceeded."  Paragraph 6 states, "The Technical Specifications shall include limiting conditions for operations, surveillance requirements, setpoints with minimum and maximum limits, and allowable values for the second-level voltage protection monitors."  (Note that the degraded voltage setpoint is also known as the second-level voltage relay setpoint.)  The total time delay evaluated by EGG was a nominal 6 seconds added to the time for the voltage relay to activate. From these statements, it was clear that a degraded voltage monitor channel consisted of both the voltage sensing relay and the delay timer. The licensee did not make a change to the custom TS but decided to enter the changes when implementing the standardized Combustion Engineering TS. The inspectors reviewed the Combustion Engineering STS Bases 3.3.7.3, which states, in part, "SR 3.3.7.3 is the performance of a CHANNEL CALIBRATION. The CHANNEL CALIBRATION verifies the accuracy of each component within the instrument channel."  Additionally, NRC Regulatory Issue Summary 2011-12, Revision 1, "Adequacy of Station Electric Distribution System Voltages," again states, in part, "The voltage monitors (or DVRs) shall automatically initiate the disconnection of offsite power source(s) whenever the voltage and time delay limits have been exceeded," and "The Technical 27 Specifications shall include - Allowable values for second-level voltage protection DVRs."  After the inspectors communicated this concern as a non-conservative TS, the licensee initiated condition report CR-PLP-2014-04903, "TS SR 3.3.5.2 is Non-Conservative," and implemented administrative controls in accordance with Administrative Letter 98-10 for SR 3.3.5.2 degraded voltage time. The operability evaluation found the diesel generator under voltage start circuitry to be operable DNC [degraded non-conforming] because the total time delay had been checked and calibrated to within acceptable values.
, which states, in part, "SR 3.3.7.3 is the performance of a CHANNEL CALIBRATION. The CHANNEL CALIBRATION verifies the accuracy of each component within the instrument channel."  Additionally, NRC Regulatory Issue Summary 2011
-12, Revision 1, "Adequacy of Station Electric Distribution System Voltages," again states, in part, "The voltage monitors (or DVRs) shall automatically initiate the disconnection of offsite power source(s) whenever the voltage and time delay limits have been exceeded," and "The Technical 27 Specifications shall include -
Allowable values for second
-level voltage protection DVRs."  After the inspectors communicate d this concern as a non-conservative TS, the licensee initiated condition report CR
-PLP-2014-04903, "TS SR 3.3.5.2 is Non
-Conservative
," and implemented administrative controls in accordance with Administrative Letter 98
-10 for SR 3.3.5.2 degraded voltage time. The operability evaluation found the diesel generator under voltage start circuitry to be operable DNC [degraded non
-conforming] because the total time delay had been checked and calibrated to within acceptable values
.


=====Analysis:=====
=====Analysis:=====
The inspectors determined the failure to incorporate the total time delay in the 2400 V Class 1E bus degraded voltage monitor channel trip setpoints in the Technical Specification surveillance requirements was contrary to 10 CFR Part 50.36(c)(3), and was a performance deficiency. The performance deficiency was determined to be more than minor because if left uncorrected, it would have the potential to lead to more significant safety concern. Specifically, by not incorporating the total time delay requirements into the Technical Specifications, the time could be changed without going through the TS change process, possibly leading to spurious trips of offsite power sources or possibly exceeding the accident analysis time is the FSAR.
The inspectors determined the failure to incorporate the total time delay in the 2400 V Class 1E bus degraded voltage monitor channel trip setpoints in the Technical Specification surveillance requirements was contrary to 10 CFR Part 50.36(c)(3), and was a performance deficiency. The performance deficiency was determined to be more than minor because if left uncorrected, it would have the potential to lead to more significant safety concern. Specifically, by not incorporating the total time delay requirements into the Technical Specifications, the time could be changed without going through the TS change process, possibly leading to spurious trips of offsite power sources or possibly exceeding the accident analysis time is the FSAR.


In accordance with Inspection Manual Chapter (IMC) 0609, "Significance Determination Process," Attachment 0609.04, "Initial Characterization of Findings," Table 2 the inspectors determined the finding affected the Initiating Events cornerstone due to the potential to initiate a loss of offsite power. As a result, the inspectors determined the finding could be evaluated using Appendix A, "The Significance Determination Process (SDP) for Findings At-Power," Exhibit 1, "Initiating Events Screening Questions."  The inspectors determined the finding was of very low safety significance (Green) because it did not cause a reactor trip and the loss of mitigation equipment relied upon to transition the plant from the onset of the trip to a stable shutdown condition. The inspectors did not identify a cross-cutting aspect associated with this finding because the finding was not representative of the licensee's present performance.
In accordance with Inspection Manual Chapter (IMC) 0609, "Significance Determination Process," Attachment 0609.04, "Initial Characterization of Findings," Table 2 the inspectors determined the finding affected the Initiating Events cornerstone due to the potential to initiate a loss of offsite power. As a result, the inspectors determined the finding could be evaluated using Appendix A, "The Significance Determination Process (SDP) for Findings At
-Power," Exhibit 1, "Initiating Events Screening Questions."  The inspectors determined the finding was of very low safety significance (Green) because it did not cause a reactor trip and the loss of mitigation equipment relied upon to transition the plant from the onset of the trip to a stable shutdown condition.


=====Enforcement:=====
The inspectors did not identify a cross
Title10 CFR Part 50.36(c) states, Technical Specifications will include minimum surveillance requirements. Title10 CFR Part 50.36(c)(3) "Surveillance Requirements," states, in part, "are requirements relating to test, calibration, or inspection to assure that the necessary quality of systems and components is maintained, that facility operation will be within safety limits, and that the limiting conditions for operation will be met."   Contrary to the above, as of October 9, 2014, the licensee failed to include within TS SR the total time delay for all components in the degraded voltage, which is required to maintain facility operation within safety limits. Specifically, the licensee failed to incorporate the total time delay for all of the components in a channel as required in a CHANNEL CALIBRATION. Because this violation was of very low safety significance, and it was entered into the licensee's Corrective Action Program as CR-PLP-2014-04903, this violation is being treated as an NCV, consistent with Section 2.3.2 of the NRC Enforcement Policy. [NCV 05000255/2014008-10, Failure To Include The Degraded Voltage Channel Time Delay In TS Surveillance Requirement 3.3.5.2.a]. (10) Lack of Analysis for Electrical Containment Penetration Protection
-cutting aspect associated with this finding because the finding was not representative of the licensee's present performance.
 
Enforcement
: Title10 CFR Part 50.36(c) states, Technical Specifications will include minimum surveillance requirements.
 
Title10 CFR Part 50.36(c)(3) "Surveillance Requirements," states, in part, "are requirements relating to test, calibration, or inspection to assure that the necessary quality of systems and components is maintained, that facility operation will be within safety limits, and that the limiting conditions for operation will be met."
 
Contrary to the above, as of October 9, 2014, the licensee failed to include within TS SR the total time delay for all components in the degraded voltage
, which is required to maintain facility operation within safety limits. Specifically, the licensee failed to incorporate the total time delay for all of the components in a channel as required in a CHANNEL CALIBRATION. Because this violation was of very low safety significance, and it was entered into the licensee's Corrective Action Program as CR-PLP-2014-04903, this violation is being treated as an NCV, consistent with Section 2.3.2 of the NRC Enforcement Policy. [NCV 05000255/2014008
-10, Failure To Include The Degraded Voltage Channel Time Delay In TS Surveillance Requirement 3.3.5.2.a].
  (10) Lack of Analysis for Electrical Containment Penetration Protection Introduction
:  The inspectors identified an unresolved item (URI) regarding lack of an analysis to demonstrate that circuit breakers and fuses provide adequate protection 28 against short circuits and overloads for electrical containment penetrations, as discussed in Regulatory Guide 1.63.


=====Introduction:=====
Resolution of this issue will be based on clarification of Palisade's licensing basis by NRC staff.
The inspectors identified an unresolved item (URI) regarding lack of an analysis to demonstrate that circuit breakers and fuses provide adequate protection 28 against short circuits and overloads for electrical containment penetrations, as discussed in Regulatory Guide 1.63. Resolution of this issue will be based on clarification of Palisade's licensing basis by NRC staff.


=====Description:=====
=====Description:=====
As part of the review of power supplies to components inside containment, the inspectors requested to review the analysis that demonstrates protection of the electrical penetrations against short circuits and overloads. The licensee responded that such an analysis does not exist, and stated their position that it is not required by their design and licensing bases. Electrical protection of containment penetrations was the subject of the Palisades Systematic Evaluation Program (SEP) Topic VIII-4. A letter from Dennis M. Crutchfield, NRC, to David P. Hoffman, Consumers Power Company, "SEP Topic VIII-4, Electrical Penetrations of Reactor Containment," dated March 26, 1981, (ADAMS Accession No. ML8104080152) included an enclosure entitled "Position on Protection of Containment Electrical Penetrations against Failures Caused by Fault and Overload Currents for SEP Plants."  This position document states:  "-the staff requires compliance with the recommendations of Regulatory Guide 1.63 or an acceptable alternative method. For each containment electrical penetration, the protective systems provide primary and backup protection devices to prevent a single failure in conjunction with a circuit overload from impairing containment integrity." The licensee responded in a letter from Robert A. Vincent, Consumers Power Company, to Dennis M. Crutchfield, NRC, "SEP Topic VIII-4, Electrical Penetrations of Reactor Containment," dated June 15, 1981, (ADAMS Accession No. ML8106180170), in which they stated:  "The secondary (backup) interrupt devices (-) would fail to trip prior to the penetration reaching its limiting temperature of 302° C with the postulated combination of faults and failure of the primary interrupters."  The licensee committed to perform more detailed evaluations of the capabilities of the protective devices, as well as "An evaluation of the adequacy of the Palisades Plant overcurrent protection surveillance testing program."  In the following subsequent letters, the licensee reported on the progress of their further evaluations:  Letter from Robert A. Vincent, Consumers Power Company, to Dennis M. Crutchfield, NRC, "SEP Topic VIII-4, Electrical Penetrations of the Reactor Containment," dated November 16, 1981, (ADAMS Accession No. ML8111200805); Letter from Kerry A. Toner, Consumers Power Company, to Dennis M. Crutchfield, NRC, "SEP Topic VIII-4, Electrical Penetrations of the Reactor Containment," dated October 12, 1982, (ADAMS Accession No. ML8210190459); and letter from Kerry A. Toner, Consumers Power Company, to Dennis M. Crutchfield, NRC, "SEP Topic VIII-4, Status Update of Program to Evaluate the Adequacy of Penetration Protection from Overload and Short-Circuit Conditions," dated February 11, 1983, (ADAMS Accession No. ML8302240273). The NRC issued their Integrated Plant Safety Assessment Report on this SEP Topic in Letter from Thomas V. Wambach, NRC, to David J. VandeWalle, Consumers Power Company, "Integrated Plant Safety Assessment Report (IPSAR) Section 4.26, Electrical Penetrations of Reactor Containment - Palisades Plant," dated June 10, 1983, (ADAMS Accession No. ML8306160396). This IPSAR stated, "The staff has evaluated this issue for other plants- and concluded that no further action was required for these plants. Based upon the information contained in the licensee's letters dated June 15, 1981, October 12, 1982, and February 11, 1983, the staff concludes that the design of the Palisades electrical penetrations are similar to other SEP plants, that the probability of electrical failure is low and that any leakage path due to penetration failure would be small. Therefore, we consider this issue to have been completed satisfactorily and 29 further action by the licensee is not required."  This conclusion was reiterated in NUREG 0820, Supplement 1, "Integrated Plant Safety Assessment, Systematic Evaluation Program, Palisades Plant, Final Report," dated November 1983, (ADAMS Accession No. ML8311290133). The inspectors requested that the licensee discuss their lack of an analysis for electrical penetration protection in light of Palisades FSAR Section 8.5.1.2, which states: "10 CFR Part 50, General Design Criterion 50, as implemented by Regulatory Guide 1.63 and IEEE Standard 317-1972, requires that electrical penetrations be designed so that the containment structure can accommodate, without exceeding the design leakage rate, the calculated pressure, temperature and other environmental conditions resulting from any Loss of Coolant Accident (LOCA)."  The licensee responded by initiating corrective action CR-PLP-2014-04450, which states the licensee's position that Palisades is not committed to "the electrical circuit protection requirements of Regulatory Guide 1.63." Due to complexity of establishing the appropriate design and licensing bases for this issue, the concern will be resolved using the NRC's Task Interface Agreement (TIA) process. Pending resolution, this item will be tracked as an unresolved item.  [URI 05000255/2014008-05, Lack of Analysis for Electrical Containment Penetration Protection].
As part of the review of power supplies to components inside containment, the inspectors requested to review the analysis that demonstrates protection of the electrical penetrations against short circuits and overloads. The licensee responded that such an analysis does not exist, and stated their position that it is not required by their design and licensing bases.


(11) Classification of CCW Piping and Components Inside the Reactor Containment Building
Electrical protection of containment penetrations was the subject of the Palisades Systematic Evaluation Program (SEP) Topic VIII
-4. A letter from Dennis M. Crutchfield, NRC, to David P. Hoffman, Consumers Power Company, "SEP Topic VIII
-4, Electrical Penetrations of Reactor Containment," dated March 26, 1981
, (ADAMS Accession No. ML8104080152) included an enclosure entitled "Position on Protection of Containment Electrical Penetrations against Failures Caused by Fault and Overload Currents for SEP Plants."  This position document states:
"-the staff requires compliance with the recommendations of Regulatory Guide 1.63 or an acceptable alternative method. For each containment electrical penetration, the protective systems provide primary and backup protection devices to prevent a single failure in conjunction with a circuit overload from impairing containment integrity."


=====Introduction:=====
The licensee responded in a letter from Robert A. Vincent, Consumers Power Company, to Dennis M. Crutchfield, NRC, "SEP Topic VIII
The inspectors identified an unresolved issue (URI) regarding the Inservice Inspection (ISI) classification of component cooling water (CCW) piping and components inside the reactor containment building. This piping is currently classified as non-safety-related. Resolution of this issue will be based on clarification of Palisade's licensing basis by NRC staff.
-4, Electrical Penetrations of Reactor Containment," dated June 15, 1981
, (ADAMS Accession No. ML8106180170), in which they stated:
"The secondary (backup) interrupt devices
(-) would fail to trip prior to the penetration reaching its limiting temperature of 302° C with the postulated combination of faults and failure of the primary interrupters."  The licensee committed to perform more detailed evaluations of the capabilities of the protective devices, as well as "An evaluation of the adequacy of the Palisades Plant overcurrent protection surveillance testing program."  In the following subsequent letters, the licensee reported on the progress of their further evaluations:
Letter from Robert A. Vincent, Consumers Power Company, to Dennis M. Crutchfield, NRC, "SEP Topic VIII
-4, Electrical Penetrations of the Reactor Containment," dated November 16, 1981
, (ADAMS Accession No. ML8111200805); Letter from Kerry A. Toner, Consumers Power Company, to Dennis M. Crutchfield, NRC, "SEP Topic VIII
-4, Electrical Penetrations of the Reactor Containment," dated October 12, 1982
, (ADAMS Accession No. ML8210190459); and letter from Kerry A. Toner, Consumers Power Company, to Dennis M. Crutchfield, NRC, "SEP Topic VIII
-4, Status Update of Program to Evaluate the Adequacy of Penetration Protection from Overload and Sho rt-Circuit Conditions," dated February 11, 1983
, (ADAMS Accession No. ML8302240273).
 
The NRC issued their Integrated Plant Safety Assessment Report on this SEP Topic in Letter from Thomas V. Wambach, NRC, to David J. VandeWalle, Consumers Power Company, "Integrated Plant Safety Assessment Report (IPSAR) Section 4.26, Electrical Penetrations of Reactor Containment
- Palisades Plant," dated June 10, 1983
, (ADAMS Accession No. ML8306160396). This IPSAR stated
, "The staff has evaluated this issue for other plants- and concluded that no further action was required for these plants
. Based upon the information contained in the licensee's letters dated June 15, 1981, October 12, 1982
, and February 11, 1983, the staff concludes that the design of the Palisades electrical penetrations are similar to other SEP plants, that the probability of electrical failure is low and that any leakage path due to penetration failure would be small. Therefore, we consider this issue to have been completed satisfactorily and 29 further action by the licensee is not required."  This conclusion was reiterated in NUREG 0820, Supplement 1, "Integrated Plant Safety Assessment, Systematic Evaluation Program, Palisades Plant, Final Report," dated November 1983
, (ADAMS Accession No. ML8311290133). The inspectors requested that the licensee discuss their lack of an analysis for electrical penetration protection in light of Palisades FSAR Section 8.5.1.2, which states: "10 CFR Part 50, General Design Criterion 50, as implemented by Regulatory Guide 1.63 and IEEE Standard 317
-1972, requires that electrical penetrations be designed so that the containment structure can accommodate, without exceeding the design leakage rate, the calculated pressure, temperature and other environmental conditions resulting from any Loss of Coolant Accident (LOCA)."  The licensee responded by initiating corrective action CR
-PLP-2014-04450, which states the licensee's position that Palisades is not committed to "the electrical circuit protection requirements of Regulatory Guide 1.63."
 
Due to complexity of establishing the appropriate design and licensing bases for this issue, the concern will be resolved using the NRC's Task Interface Agreement (TIA) process. Pending resolution, this item will be tracked as an unresolved item.  [URI 05000255/201400 8-05, Lack of Analysis for Electrical Containment Penetration Protection].
  (11) Classification of CCW Piping and Components Inside the Reactor Containment Building Introduction
: The inspectors identified an unresolved issue (URI) regarding the Inservice Inspection (ISI) classification of component cooling water (CCW) piping and components inside the reactor containment building. This piping is currently classified as non
-safety-related. Resolution of this issue will be based on clarification of Palisade's licensing basis by NRC staff.
 
Description
:  The inspectors reviewed SEP
-ISI-PLP-002, ASME Code Boundaries for ASME Section XI Inservice Inspection Program, Revision 1. The purpose of this document was to establish classifications to ensure the proper scope of ASME Section XI system pressure tests, ASME Section V nondestructive examinations, ASME Section XI inspection of component supports, and ASME Section XI repairs, replacements and modifications. This program document stated that guidance for Class 2, 3, and non
-safety-related components is found in Regulatory Guide 1.26. The program referred to a set of color
-coded P&IDs.
 
The inspectors noted the CCW piping and components inside the reactor containment building were identified as non
-safety-related on the color
-coded P&IDs. The team also observed that Attachment 1 of SEP
-ISI-PLP-002 (page 45 of 75) identified the piping from the containment penetrations to the single containment isolation valve outside containment as class 2 (check valve CK
-CC910 for penetration MZ
-14, air-operated valve CV-0911 for penetration MZ
-15). This attachment referred to note H, which stated, in part: All containment penetration assemblies in Class 2, Class 3, and non
-class piping will be considered ASME Class 2 out to the second isolation valve where applicable.
 
In some cases, there is single isolation (e.g., MSS, FWS)-  Where a Class 3 system penetrates containment, that portion will be considered Class 2 and treated as such (ie, ASME Section XI Interpretation BC84
-603). The basis for classification of containment penetrations is contained in EGAD
-EP-12, "Mechanical Containment Penetrations Basis Program".
 
30 The current Mechanical Containment Penetrations Basis document was SEP
-APJ-PLP-101, Revision 0. This document included a similar description for CCW penetrations MZ-14 and MZ
-15. It stated that FSAR Table 5.8
-4 classifies these penetrations as class C1. The FSAR table also identified these penetrations as Class C1 and indicated that they are not subject to 10 CFR Part 50, Appendix J testing requirements. The FSAR Section 6.7 included a description of Class C1 penetrations, it stated, in part:
Penetrations in this class include those systems that are not connected to either the containment atmosphere or to the Primary Coolant System and are normally open or may be opened during power operation.
 
These lines are protected from missiles originating inside the containment and the lines themselves form the boundary of the containment.
 
One remote manually operated valve, locked closed manual valve or automatic isolation valve is provided in each line.
 
Check valves are considered automatic.
 
In SEP-APJ-PLP-101 also stated
, that both Penetrations MZ
-14 and MZ
-15 were originally classified as C2 (closed system outside containment per FSAR Section 6.7), until FSAR Revision 22. These were reclassified by SDR 0884, dated July 22, 199
 
===9. The basis for these changes included an evaluation that determined CCW piping inside ===
 
containment would not be damaged by internal missiles (as addressed by NRC's evaluation of SEP Topic III
-4,c, dated September 21, 1981)
, and the classification of CCW as a closed system inside containment. The associated 10 CFR 50.59 evaluation determined that NRC approval was not required for these changes.
 
The inspection team raised questions regarding the licensing basis classification of the CCW system inside containment:
1. FSAR Section 6.9 stated that Regulatory Guide 1.26 was used to select ASME Classes 2 and 3 systems and components for coverage by the inspection plan. Regulatory Guide 1.26, stated in part:
The Quality Group C standards given in Table 1 of this guide should be applied to water-, steam-, and radioactive
-waste-containing pressure vessels; heat exchangers (other than turbines and condensers); storage tanks; piping; pumps; and valves that are not part of the reactor coolant pressure boundary or included in Quality Group B but part of the following:
-(b) cooling water and seal water systems or portions of those systems important to safety that are designed for the functioning of components and systems important to safety, such as reactor coolant pumps, diesels, and the control room-The classification of the CCW system inside containment did not appear to be consistent with the guidance of Regulatory Guide 1.26. In addition, industry guidance provided by ANSI/ANS 51.1
- 1983 indicated that closed systems inside containment (with single active isolation valves) should be class 2 or class 3.
 
2. FSAR Section 6.7 addressed class C1 containment penetrations stating, "These lines are protected from missiles originating inside the containment and the lines themselves form the boundary of the containment."  The inspectors questioned whether it was appropriate to classify a portion of the containment boundary as non
-safety-related for the purpose of inspection, testing, and repairs.
 
31 The licensee has stated that the CCW system classification is in accordance with their current licensing basis. This position is primarily based on the NRC's evaluation of SEP Topic III
-4,c, dated September 21, 1981, the CCW system being protected from internal missiles, and seismic events not being postulated to occur coincidently with a LOCA.
 
Resolution of this issue will be based on clarification of Palisade's licensing basis.
 
Pending resolution, this item will be tracked as an URI.  [URI 05000255/201400 8-11, Classification of CCW Piping and Components Inside the Reactor Containment Building.]  (12) Component Cooling Water System Licensing Bases Introduction
:  The inspectors identified an Unresolved Item (URI) regarding the licensing bases for the Component Cooling Water (CCW) system. Specifically, the inspectors require clarification as to what failures of the CCW system the licensee needs to postulate and evaluate. The NRC will conduct further inspection to determine when these changes to the licensing bases occurred.


=====Description:=====
Description
The inspectors reviewed SEP-ISI-PLP-002, ASME Code Boundaries for ASME Section XI Inservice Inspection Program, Revision 1. The purpose of this document was to establish classifications to ensure the proper scope of ASME Section XI system pressure tests, ASME Section V nondestructive examinations, ASME Section XI inspection of component supports, and ASME Section XI repairs, replacements and modifications. This program document stated that guidance for Class 2, 3, and non-safety-related components is found in Regulatory Guide 1.26. The program referred to a set of color-coded P&IDs. The inspectors noted the CCW piping and components inside the reactor containment building were identified as non-safety-related on the color-coded P&IDs. The team also observed that Attachment 1 of SEP-ISI-PLP-002 (page 45 of 75) identified the piping from the containment penetrations to the single containment isolation valve outside containment as class 2 (check valve CK-CC910 for penetration MZ-14, air-operated valve CV-0911 for penetration MZ-15). This attachment referred to note H, which stated, in part: All containment penetration assemblies in Class 2, Class 3, and non-class piping will be considered ASME Class 2 out to the second isolation valve where applicable. In some cases, there is single isolation (e.g., MSS, FWS)-  Where a Class 3 system penetrates containment, that portion will be considered Class 2 and treated as such (ie, ASME Section XI Interpretation BC84-603). The basis for classification of containment penetrations is contained in EGAD-EP-12, "Mechanical Containment Penetrations Basis Program".
: As part of the 2014 Component Design Bases Inspection (CDBI), the inspectors selected CCW pump P
-52B and relief valve RV
-0956 for review. Both of these components were part of the CCW system. The CCW system was designed as a closed cycle system, where both trains share a common suction and common discharge header. This means that although there were redundant pumps and heat exchangers, the system's piping was not designed to be redundant and a single pipe break or failure of the pressure boundary could result in the complete loss of CCW. One of CCW's safety functions was to transfer heat from the reactor and containment (post
-Design Bases Events/Accidents) to the ultimate heat sink. Another important safety function for CCW was to provide cooling to the Engineered Safeguard Systems' (ESS) and containment spray (CS) pumps. Per the licensee's design bases, cooling to the ESS pumps was required to maintain their operability.


30 The current Mechanical Containment Penetrations Basis document was SEP-APJ-PLP-101, Revision 0. This document included a similar description for CCW penetrations MZ-14 and MZ-15. It stated that FSAR Table 5.8-4 classifies these penetrations as class C1. The FSAR table also identified these penetrations as Class C1 and indicated that they are not subject to 10 CFR Part 50, Appendix J testing requirements. The FSAR Section 6.7 included a description of Class C1 penetrations, it stated, in part: Penetrations in this class include those systems that are not connected to either the containment atmosphere or to the Primary Coolant System and are normally open or may be opened during power operation. These lines are protected from missiles originating inside the containment and the lines themselves form the boundary of the containment. One remote manually operated valve, locked closed manual valve or automatic isolation valve is provided in each line. Check valves are considered automatic. In SEP-APJ-PLP-101 also stated, that both Penetrations MZ-14 and MZ-15 were originally classified as C2 (closed system outside containment per FSAR Section 6.7), until FSAR Revision 22. These were reclassified by SDR-99-0884, dated July 22, 1999. The basis for these changes included an evaluation that determined CCW piping inside containment would not be damaged by internal missiles (as addressed by NRC's evaluation of SEP Topic III-4,c, dated September 21, 1981), and the classification of CCW as a closed system inside containment. The associated 10 CFR 50.59 evaluation determined that NRC approval was not required for these changes. The inspection team raised questions regarding the licensing basis classification of the CCW system inside containment: 1. FSAR Section 6.9 stated that Regulatory Guide 1.26 was used to select ASME Classes 2 and 3 systems and components for coverage by the inspection plan. Regulatory Guide 1.26, stated in part: The Quality Group C standards given in Table 1 of this guide should be applied to water-, steam-, and radioactive-waste-containing pressure vessels; heat exchangers (other than turbines and condensers); storage tanks; piping; pumps; and valves that are not part of the reactor coolant pressure boundary or included in Quality Group B but part of the following: -(b) cooling water and seal water systems or portions of those systems important to safety that are designed for the functioning of components and systems important to safety, such as reactor coolant pumps, diesels, and the control room- The classification of the CCW system inside containment did not appear to be consistent with the guidance of Regulatory Guide 1.26. In addition, industry guidance provided by ANSI/ANS 51.1 - 1983 indicated that closed systems inside containment (with single active isolation valves) should be class 2 or class 3. 2. FSAR Section 6.7 addressed class C1 containment penetrations stating, "These lines are protected from missiles originating inside the containment and the lines themselves form the boundary of the containment."  The inspectors questioned whether it was appropriate to classify a portion of the containment boundary as non-safety-related for the purpose of inspection, testing, and repairs.
When reviewing the licensing bases for the plant, it was not clear what type of failures needed to postulated for the CCW system under post
-accident conditions. The licensee's position was postulating a passive failure of CCW concurrent with a design bases accident (DBA) was not within their licensing bases. The licensee's position was that no active single failure, according to their definition in FSAR Section 1.4.16, would render CCW inoperable. They also considered a postulated failure of the non-safety-related portion of the CCW system inside containment as beyond design bases, except as result of a seismic event which was not postulated to occur in conjunction with an accident.


31 The licensee has stated that the CCW system classification is in accordance with their current licensing basis. This position is primarily based on the NRC's evaluation of SEP Topic III-4,c, dated September 21, 1981, the CCW system being protected from internal missiles, and seismic events not being postulated to occur coincidently with a LOCA. Resolution of this issue will be based on clarification of Palisade's licensing basis. Pending resolution, this item will be tracked as an URI.  [URI 05000255/2014008-11, Classification of CCW Piping and Components Inside the Reactor Containment Building.]  (12) Component Cooling Water System Licensing Bases
Currently, the licensee credits post-accident heat being removed from containment by a combination of containment air coolers (CAC) and the containment spray (CS) system. The CAC are supplied by service water and are independent of the CCW system. Per the current design, the licensee needs either two CS pumps or one CS pump and three CACs. Both alternatives require the CCW system to remove heat from the CS system. However, the original design took credit for the CS and the CAC as independent and redundant in their capability to remove heat from the containment. In other words, originally the licensee needed either two CS pumps or three CACs.


=====Introduction:=====
Additionally, the original design allowed for the capability to swap cooling water to the ESS pumps from CCW to service water remotely from the main control room (MCR). Both of these design flexibilities have been either lost or eliminated due to subsequent design changes
The inspectors identified an Unresolved Item (URI) regarding the licensing bases for the Component Cooling Water (CCW) system. Specifically, the inspectors require clarification as to what failures of the CCW system the licensee needs to postulate and evaluate. The NRC will conduct further inspection to determine when these changes to the licensing bases occurred.
.


=====Description:=====
32 The inspectors noted the agency staff had previously evaluated the susceptibility of CCW to loss of function following certain assumed CCW pipe breaks during the Systematic Evaluation Program(SEP). This was documented on SEP Topic IX
As part of the 2014 Component Design Bases Inspection (CDBI), the inspectors selected CCW pump P-52B and relief valve RV-0956 for review. Both of these components were part of the CCW system. The CCW system was designed as a closed cycle system, where both trains share a common suction and common discharge header. This means that although there were redundant pumps and heat exchangers, the system's piping was not designed to be redundant and a single pipe break or failure of the pressure boundary could result in the complete loss of CCW. One of CCW's safety functions was to transfer heat from the reactor and containment (post-Design Bases Events/Accidents) to the ultimate heat sink. Another important safety function for CCW was to provide cooling to the Engineered Safeguard Systems' (ESS) and containment spray (CS) pumps. Per the licensee's design bases, cooling to the ESS pumps was required to maintain their operability. When reviewing the licensing bases for the plant, it was not clear what type of failures needed to postulated for the CCW system under post-accident conditions. The licensee's position was postulating a passive failure of CCW concurrent with a design bases accident (DBA) was not within their licensing bases. The licensee's position was that no active single failure, according to their definition in FSAR Section 1.4.16, would render CCW inoperable. They also considered a postulated failure of the non-safety-related portion of the CCW system inside containment as beyond design bases, except as result of a seismic event which was not postulated to occur in conjunction with an accident.
-3, Station Service and Cooling Water Systems Palisades, February 22, 1982.


Currently, the licensee credits post-accident heat being removed from containment by a combination of containment air coolers (CAC) and the containment spray (CS) system. The CAC are supplied by service water and are independent of the CCW system. Per the current design, the licensee needs either two CS pumps or one CS pump and three CACs. Both alternatives require the CCW system to remove heat from the CS system. However, the original design took credit for the CS and the CAC as independent and redundant in their capability to remove heat from the containment. In other words, originally the licensee needed either two CS pumps or three CACs. Additionally, the original design allowed for the capability to swap cooling water to the ESS pumps from CCW to service water remotely from the main control room (MCR). Both of these design flexibilities have been either lost or eliminated due to subsequent design changes.
The agency staff had concluded the CCW design was not in conformance with GDC 44, regarding capability and redundancy of essential functions of the system. However, the staff noted the essential functions of CCW could be performed by other systems under all operating conditions. The SEP evaluation explicitly addressed a passive failure of the CCW system under post
-accident conditions and concluded that the CACs would be capable of removing heat from containment.


32 The inspectors noted the agency staff had previously evaluated the susceptibility of CCW to loss of function following certain assumed CCW pipe breaks during the Systematic Evaluation Program(SEP). This was documented on SEP Topic IX-3, Station Service and Cooling Water Systems Palisades, February 22, 1982. The agency staff had concluded the CCW design was not in conformance with GDC 44, regarding capability and redundancy of essential functions of the system. However, the staff noted the essential functions of CCW could be performed by other systems under all operating conditions. The SEP evaluation explicitly addressed a passive failure of the CCW system under post-accident conditions and concluded that the CACs would be capable of removing heat from containment. The inspectors were concerned that if the CCW system became inoperable as the result of non-safety-related component failures, the plant would no longer have the redundant capability to remove heat from the containment during a DBA, or provide alternate cooling to the ESS pumps from the MCR. In addition, the inspectors needed to clarify the licensing bases regarding a postulated loss of CCW concurrent with a design bases accident.
The inspectors were concerned that if the CCW system became inoperable as the result of non-safety-related component failures, the plant would no longer have the redundant capability to remove heat from the containment during a DBA, or provide alternate cooling to the ESS pumps from the MCR. In addition, the inspectors needed to clarify the licensing bases regarding a postulated loss of CCW concurrent with a design bases accident.


This issue is unresolved pending further inspection to determine when these changes to the licensing bases occurred. [URI 05000255/2014008-12, Component Cooling Water System Licensing Bases]
This issue is unresolved pending further inspection to determine when these changes to the licensing bases occurred. [URI 05000255/2014008
-12, Component Cooling Water System Licensing Bases]


===.4 Operating Experience===
===.4 Operating Experience===


====a. Inspection Scope====
====a. Inspection Scope====
The inspectors reviewed six operating experience issues to ensure that NRC generic concerns had been adequately evaluated and addressed by the licensee. The operating experience issues listed below were reviewed as part of this inspection: Information Notice 1988-45, "Problems in Protective Relay and Circuit Breaker Coordination;"  Information Notice 2010-09, "Importance of Understanding Circuit Breaker Control Panel Indications";  Information Notice 2010- 11, "Potential for Steam Voiding Causing Residual Heat Removal System Inoperability";  Regulatory Issue Summary 2013-05, "NRC Position On The Relationship Between General Design Criteria and Technical Specification Operability";  NRC-21-2013-60-00 and -01, "K-Line Circuit Breaker Primary Close Latch"; and  IER-L4-13-54, "Unprotected DC Ammeters Result in Unanalyzed Condition."
The inspectors reviewed six operating experience issues to ensure that NRC generic concerns had been adequately evaluated and addressed by the licensee. The operating experience issues listed below were reviewed as part of this inspection:
Information Notice 1988
-45, "Problems in Protective Relay and Circuit Breaker Coordination
;"  Information Notice 2010
-09, "Importance of Understanding Circuit Breaker Control Panel Indications"
;  Information Notice 2010
- 11, "Potential for Steam Voiding Causing Residual Heat Removal System Inoperability
";  Regulatory Issue Summary 2013
-05, "NRC Position On The Relationship Between General Design Criteria and Technical Specification Operability
";  NRC-21-2013-60-00 and -01, "K-Line Circuit Breaker Primary Close Latch
"; and  IER-L4-13-54, "Unprotected DC Ammeters Result in Unanalyzed Condition."


====b. Findings====
====b. Findings====
Line 301: Line 966:
====a. Inspection Scope====
====a. Inspection Scope====
The inspectors reviewed one permanent plant modification related to selected risk significant components to verify that the design bases, licensing bases, and performance capability of the components had not been degraded through modifications. The modification listed below was reviewed as part of this inspection effort:
The inspectors reviewed one permanent plant modification related to selected risk significant components to verify that the design bases, licensing bases, and performance capability of the components had not been degraded through modifications. The modification listed below was reviewed as part of this inspection effort:
FC-718,RAS Logic Seal-In Circuit Addition;
FC-718,RAS Logic Seal
-In Circuit Addition
;


====b. Findings====
====b. Findings====
No findings of significance were identified.
No findings of significance were identified.


===.6 Operating Procedure Accident Scenarios===
===.6 Operating Procedure Accident Scenario===
 
s


====a. Inspection Scope====
====a. Inspection Scope====
The inspectors performed a detailed review of the operator actions and the procedures listed below associated with the selected components and associated with risk important operator actions. For the procedures listed, simulator scenarios were observed as applicable, and in-plant actions were walked down with a non-licensed operator or a licensed operator as appropriate. These activities were performed to determine whether there was sufficient information to perform the procedure, whether the steps could reasonably be performed in the available time, and whether the necessary tools and equipment were available. The procedures were compared to FSAR and design assumptions. In addition, the procedures were reviewed to ensure the procedure steps would accomplish the desired results. The following Time Critical Operator Actions (TCAs) and accidents were reviewed: TCA 1:  "Enable Closure of the ESS recirculation valves on RAS," TCA 6:  "Align hot leg injection," TCA 44:  "Switch CR HVAC to Emergency Mode," TCA 47:  "ESS Suction Header Cross-Tie,"  Large Break Loss of Coolant Accident (LBLOCA), Mode 4 Loss of Coolant Accident (LOCA). The following procedures were reviewed:   Administrative Procedure TCA, "Control of Time Critical Operator Actions," Revision 3; Emergency Operating Procedure Basis EOP TCA, "EOP Time Critical Operator Action Basis," Revision 0; Emergency Operating Procedure EOP-4.0, "Loss of Coolant Accident Recovery," Revision 23; Emergency Operating Procedure Supplement 42, "Pre and Post RAS Actions," Revision 7  Abnormal Operating Procedure AOP-30, Loss of Shutdown Cooling," Revision 1.
The inspectors performed a detailed review of the operator actions and the procedures listed below associated with the selected components and associated with risk important operator actions. For the procedures listed, simulator scenarios were observed as applicable, and in
-plant actions were walked down with a non
-licensed operator or a licensed operator as appropriate. These activities were performed to determine whether there was sufficient information to perform the procedure, whether the steps could reasonably be performed in the available time, and whether the necessary tools and equipment were available. The procedures were compared to FSAR and design assumptions. In addition, the procedures were reviewed to ensure the procedure steps would accomplish the desired results.
 
The following Time Critical Operator Actions (TCAs) and accidents were reviewed:
TCA 1:  "Enable Closure of the ESS recirculation valves on RAS,"
TCA 6:  "Align hot leg injection,"
TCA 44:  "Switch CR HVAC to Emergency Mode,"
TCA 47:  "ESS Suction Header Cross
-Tie,"  Large Break Loss of Coolant Accident (LBLOCA),
Mode 4 Loss of Coolant Accident (LOCA).
 
The following procedures were reviewed:
Administrative Procedure TCA, "Control of Time Critical Operator Actions," Revision 3; Emergency Operating Procedure Basis EOP TCA, "EOP Time Critical Operator Action Basis," Revision 0; Emergency Operating Procedure EOP
-4.0, "Loss of Coolant Accident Recovery," Revision 23; Emergency Operating Procedure Supplement 42, "Pre and Post RAS Actions," Revision 7  Abnormal Operating Procedure AOP
-30, Loss of Shutdown Cooling," Revision 1.


====b. Findings====
====b. Findings====
Line 318: Line 1,002:
==4OA2 Identification and Resolution of Problems==
==4OA2 Identification and Resolution of Problems==


===.1 Review of Items Entered Into the Corrective Action Program===
===.1 Review of===
 
Items Entered Into the Corrective Action Program


====a. Inspection Scope====
====a. Inspection Scope====
The inspectors reviewed a sample of the selected component problems that were identified by the licensee and entered into the Corrective Action Program. The inspectors reviewed these issues to verify an appropriate threshold for identifying issues and to evaluate the effectiveness of corrective actions related to design issues. In addition, corrective action documents written on issues identified during the inspection were reviewed to verify adequate problem identification and incorporation of the problem into the Corrective Action Program. The specific corrective action documents that were sampled and reviewed by the inspectors are listed in the attachment to this report. The inspectors also selected six issues that were identified during previous CDBIs to verify the concern was adequately evaluated and corrective actions were identified and implemented to resolve the concern, as necessary. The following issues were reviewed: NCV 05000255/2006009-08, "Emergency Diesel Generator Fuel Transfer System Temperature Ratings";  NCV 05000255/2006009-10, "Potential for Safety Injection and Refueling Water Tank Level Switch Setpoints to be Outside Technical Specification Limit";  NCV 05000255/2008009-01, "Inadequate Analysis of Emergency Diesel Generator 1-2 Loading During Design Basis Events";  NCV 05000255/2008009-02, Failure to Establish Correct Technical Specification Limits";  NCV 05000255/2011009-01, Failure to Adequately Evaluate the Enclosure Installed Over the 1F/1G Buses"; and  NCV 05000255/2011009-03, "Procedures Were Not Appropriate To Address Gas Accumulation Issues"
The inspectors reviewed a sample of the selected component problems that were identified by the licensee and entered into the Corrective Action Program. The inspectors reviewed these issues to verify an appropriate threshold for identifying issues and to evaluate the effectiveness of corrective actions related to design issues. In addition, corrective action documents written on issues identified during the inspection were reviewed to verify adequate problem identification and incorporation of the problem into the Corrective Action Program. The specific corrective action documents that were sampled and reviewed by the inspectors are listed in the attachment to this report.
 
The inspectors also selected six issues that were identified during previous CDBIs to verify the concern was adequately evaluated and corrective actions were identified and implemented to resolve the concern, as necessary. The following issues were reviewed:
NCV 05000255/2006009
-08, "Emergency Diesel Generator Fuel Transfer System Temperature Ratings"
;  NCV 05000255/2006009
-10, "Potential for Safety Injection and Refueling Water Tank Level Switch Setpoints to be Outside Technical Specification Limit
";  NCV 05000255/2008009
-01, "Inadequate Analysis of Emergency Diesel Generator 1-2 Loading During Design Basis Events
";  NCV 05000255/2008009
-02, Failure to Establish Correct Technical Specification Limits";  NCV 05000255/2011009
-01, Failure to Adequately Evaluate the Enclosure Installed Over the 1F/1G Buses
"; and  NCV 05000255/2011009
-03, "Procedures Were Not Appropriate To Address Gas Accumulation Issues"


====b. Findings====
====b. Findings====
(1) Non-Conservative Surveillance for Emergency Diesel Generator Largest Load Reject Test
(1) Non-Conservative Surveillance for Emergency Diesel Generator Largest Load Reject Test Introduction
:  A finding of very low safety significance and associated Non-Cited Violation of 10 CFR Part 50, Appendix B, Criterion XI, "Test Control,"
was identified by the inspectors for the licensee's failure to have adequate acceptance criteria in the emergency diesel generator surveillance procedures.
 
Specifically, the licensee failed to ensure the surveillance test procedures for the emergency diesel generator largest load reject test bounded the power demand of the largest load, as required by Technical Specification SR 3.8.1.
 
5 based upon full load reject testing
. Description
:  Palisades Technical Specification Surveillance Requirement SR 3.8.1.5 requires verification of the emergency diesel generator response following rejection of "a load greater than or equal to its associated single largest post
-accident load."  On June 20, 2013, the licensee issued Technical Specification Surveillance Procedure RE
-132, "Diesel Generator 1
-2 Load Reject," Revision 6. This procedure specifies, in Step 5.3.11, that the emergency diesel generator be loaded to "325 to 375 kw" in preparation 35 for the load reject test. On August 6, 2014, the licensee issued calculation EA
-ELEC-LDTAB-005, "Emergency Diesel Generators 1
-1 and 1-2 Steady State Loadings," Revision 10, which includes documentation of the magnitudes of the emergency diesel generator loads. The inspectors asked the licensee to compare the calculation data with the procedure criterion for a minimum test load of 325kW. The licensee concluded that, according to the calculation, the largest single emergency diesel generator load is High Pressure Safety Injection Pump P
-66A, which has a power demand of 360.25kW. Thus, surveillance Procedure RE
-132 allows an emergency diesel generator load test value (325kW) that does not bound the magnitude of the generator's single largest load (360.25kW).


=====Introduction:=====
The licensee entered this issue into their Corrective Action Program as CR-PLP-2014-4679 and CR-PLP-2014-4680 for Emergency Diesel Generators 1
A finding of very low safety significance and associated Non-Cited Violation of 10 CFR Part 50, Appendix B, Criterion XI, "Test Control," was identified by the inspectors for the licensee's failure to have adequate acceptance criteria in the emergency diesel generator surveillance procedures. Specifically, the licensee failed to ensure the surveillance test procedures for the emergency diesel generator largest load reject test bounded the power demand of the largest load, as required by Technical Specification SR 3.8.1.5 based upon full load reject testing.
-1 and 1-2, respectively, with recommended actions to revise the surveillance procedure minimum load limit for the load reject test to bound the magnitudes of the single largest loads.


=====Description:=====
The licensee also verified current operability by confirming the emergency diesel generators are capable of performing as required by SR 3.8.1.5
Palisades Technical Specification Surveillance Requirement SR 3.8.1.5 requires verification of the emergency diesel generator response following rejection of "a load greater than or equal to its associated single largest post-accident load."  On June 20, 2013, the licensee issued Technical Specification Surveillance Procedure RE-132, "Diesel Generator 1-2 Load Reject," Revision 6. This procedure specifies, in Step 5.3.11, that the emergency diesel generator be loaded to "325 to 375 kw" in preparation 35 for the load reject test. On August 6, 2014, the licensee issued calculation EA-ELEC-LDTAB-005, "Emergency Diesel Generators 1-1 and 1-2 Steady State Loadings," Revision 10, which includes documentation of the magnitudes of the emergency diesel generator loads. The inspectors asked the licensee to compare the calculation data with the procedure criterion for a minimum test load of 325kW. The licensee concluded that, according to the calculation, the largest single emergency diesel generator load is High Pressure Safety Injection Pump P-66A, which has a power demand of 360.25kW. Thus, surveillance Procedure RE-132 allows an emergency diesel generator load test value (325kW) that does not bound the magnitude of the generator's single largest load (360.25kW). The licensee entered this issue into their Corrective Action Program as CR-PLP-2014-4679 and CR-PLP-2014-4680 for Emergency Diesel Generators 1-1 and 1-2, respectively, with recommended actions to revise the surveillance procedure minimum load limit for the load reject test to bound the magnitudes of the single largest loads. The licensee also verified current operability by confirming the emergency diesel generators are capable of performing as required by SR 3.8.1.5.
.


=====Analysis:=====
=====Analysis:=====
The inspectors determined the failure to have adequate acceptance criteria in the emergency diesel generator surveillance procedure was contrary to 10 CFR Part 50, Appendix B, Criterion XI, "Test Control," and was a performance deficiency. The finding was determined to be more than minor because the finding was associated with the Procedure Quality attribute of the Reactor Safety, Mitigating Systems Cornerstone and adversely affected the cornerstone objective to ensure the availability, reliability, and capability of systems that respond to initiating events to prevent undesirable consequences. Specifically, the surveillance procedure error could result in acceptance of test results that did not satisfy Technical Specification SR 3.8.1.5 for rejection of a load greater than or equal to the emergency diesel generator's single largest post-accident load. The inspectors assessed this finding for significance in accordance with NRC Manual Chapter 0609, Appendix A, Exhibit 2, The Significance Determination Process (SDP) for Findings At-Power, and determined that it was of very low safety significance (Green), because the SSC maintained its operability and functionality. This finding has a cross-cutting aspect in the area of Human Performance, associated with the Resources component, because the licensee did not ensure that personnel, equipment, procedures, and other resources are adequate to assure nuclear safety by maintaining long term plant safety. [H.1]
The inspectors determined the failure to have adequate acceptance criteria in the emergency diesel generator surveillance procedure was contrary to 10 CFR Part 50, Appendix B, Criterion XI, "Test Control," and was a performance deficiency. The finding was determined to be more than minor because the finding was associated with the Procedure Quality attribute of the Reactor Safety, Mitigating Systems Cornerstone and adversely affected the cornerstone objective to ensure the availability, reliability, and capability of systems that respond to initiating events to prevent undesirable consequences
. Specifically, the surveillance procedure error could result in acceptance of test results that did not satisfy Technical Specification SR 3.8.1.5 for rejection of a load greater than or equal to the emergency diesel generator's single largest post
-accident load.
 
The inspectors assessed this finding for significance in accordance with NRC Manual Chapter 0609, Appendix A, Exhibit 2
, The Significance Determination Process (SDP) for Findings At-Power, and determined that it was of very low safety significance (Green), because the SSC maintained its operability and functionality
. This finding has a cross
-cutting aspect in the area of Human Performance, associated with the Resources component, because the licensee did not ensure that personnel, equipment, procedures, and other resources are adequate to assure nuclear safety by maintaining long term plant safety. [H.1]


=====Enforcement:=====
=====Enforcement:=====
Title 10 CFR Part 50, Appendix B, Criterion XI, "Test Control," requires, in part, "A test program shall be established to assure that all testing required to demonstrate that structures, systems, and components will perform satisfactorily in service is identified and performed in accordance with written test procedures which incorporate the requirements and acceptance limits contained in applicable design documents."  Contrary to the above, on June 20, 2013, the licensee failed to assure that written test procedures incorporate requirements contained in applicable design documents. Specifically, the licensee revised Technical Specification Surveillance Procedure RE-132, "Diesel Generator 1-2 Load Reject," but failed to identify that the specified kW level for the largest load rejection test did not bound the largest predicted post-accident load. Because this violation was of very low safety significance, and it was entered into the licensee's Corrective Action Program as CR-PLP-2014-4679 and CR-PLP-2014-4680, 36 this violation is being treated as an NCV, consistent with Section 2.3.2 of the NRC Enforcement Policy.  [NCV 05000255/2014008-13, Non-Conservative Surveillance for Emergency Diesel Generator Largest Load Reject Test.]
Title 10 CFR Part 50, Appendix B, Criterion XI, "Test Control," requires, in part, "A test program shall be established to assure that all testing required to demonstrate that structures, systems, and components will perform satisfactorily in service is identified and performed in accordance with written test procedures which incorporate the requirements and acceptance limits contained in applicable design documents."  Contrary to the above, on June 20, 2013, the licensee failed to assure that written test procedures incorporate requirements contained in applicable design documents. Specifically, the licensee revised Technical Specification Surveillance Procedure RE
-132, "Diesel Generator 1
-2 Load Reject
," but failed to identify that the specified kW level for the largest load rejection test did not bound the largest predicted post-accident load
. Because this violation was of very low safety significance, and it was entered into the licensee's Corrective Action Program as CR-PLP-2014-4679 and CR-PLP-2014-4680, 36 this violation is being treated as an NCV, consistent with Section 2.3.2 of the NRC Enforcement Policy.  [NCV 05000255/2014008
-13, Non-Conservative Surveillance for Emergency Diesel Generator Largest Load Reject Test
.]
{{a|4OA5}}
{{a|4OA5}}
==4OA5 Other Activities==
==4OA5 Other Activities==


===.1 (Closed) Unresolved Item (URI) 05000255/2012005-05:===
===.1 (Closed) Unresolved Item (URI) 05000255/2012005===
Concerns With The Methodology Used To Determine Suction Side Void Acceptance Criteria On January 11, 2008, the NRC requested each addressee of GL 2008-01 to evaluate its emergency core cooling, decay heat removal, and containment spray systems licensing basis, design, testing, and corrective actions to ensure gas accumulation was maintained less than the amount which would challenge the operability of these systems, and take appropriate actions when conditions adverse to quality were identified. In order to determine what amount of gas could challenge the operability of the subject systems, the licensee needed to develop appropriate acceptance criteria for evaluating identified voids. As part of this effort, the licensee developed acceptance criteria for evaluating voids identified in the suction side of the subject systems' pumps. During subsequent inspections the inspectors identified a concern with the methodology used by the licensee to develop acceptance criteria for suction side voids. At the time of the inspection the acceptance criteria was inconsistent with the 0.5-second criterion recommended by the Office of Nuclear Reactor Regulation (NRR) in TI 2515/177 Inspection Guidance (ML111660749). The NRR-recommended methodology was more conservative because it ensured there were no significant deviations exceeding the maximum recommended void fractions. However, because the licensee's methodology averaged over the entire transient duration time, it allowed void volumes that could significantly exceed the recommended void fraction when the actual duration transient time was shorter than the maximum allowable duration time specified by the recommended void fraction acceptance criteria. This issue was originally captured in the licensee's CAP as CR-HQN-2011-00853. Since then, and as result of other void related violations, the licensee revised their procedures including their Gas Accumulation Management Program Document (EN-DC-219, Revision 3). The revised Program Document incorporates, by reference, the Acceptance Criteria of NEI 09-10, "Guidelines for Effective Prevention and Management of System Gas Accumulation."  The NRC has issued a Safety Evaluation (SE) of the NEI 09-10, which discusses the Agency's position in regards to the use of NEI 09-10. In addition, based on the information discussed in the NEI 09-10 and the SE, the 0.5 second criterion discussed in the URI is no longer the recommended method proposed by NRR. Therefore, the inspectors concern is no longer valid, and no performance deficiency or violation of regulatory requirements exists. This unresolved item is closed.
 
-05:  Concerns With The Methodology Used To Determine Suction Side Void Acceptance Criteria On January 11, 2008, the NRC requested each addressee of GL 2008
-01 to evaluate its emergency core cooling, decay heat removal, and containment spray systems licensing basis, design, testing, and corrective actions to ensure gas accumulation was maintained less than the amount which would challenge the operability of these systems, and take appropriate actions when conditions adverse to quality were identified.
 
In order to determine what amount of gas could challenge the operability of the subject systems, the licensee needed to develop appropriate acceptance criteria for evaluating identified voids.
 
As part of this effort, the licensee developed acceptance criteria for evaluating voids identified in the suction side of the subject systems' pumps.
 
During subsequent inspections the inspectors identified a concern with the methodology used by the licensee to develop acceptance criteria for suction side voids. At the time of the inspection the acceptance criteria was inconsistent with the 0.5
-second criterion recommended by the Office of Nuclear Reactor Regulation (NRR) in TI 2515/177 Inspection Guidance (ML111660749).
 
The NRR-recommended methodology was more conservative because it ensured there were no significant deviations exceeding the maximum recommended void fractions.
 
However, because the licensee's methodology averaged over the entire transient duration time, it allowed void volumes that could significantly exceed the recommended void fraction when the actual duration transient time was shorter than the maximum allowable duration time specified by the recommended void fraction acceptance criteria. This issue was originally captured in the licensee's CAP as CR
-HQN-2011-00853. Since then, and as result of other void related violation s, the licensee revised their procedures including their Gas Accumulation Management Program Document (EN
-DC-219, Revision 3). The revised Program Document incorporates, by reference, the Acceptance Criteria of NEI 09
-10, "Guidelines for Effective Prevention and Management of System Gas Accumulation
."  The NRC has issued a Safety Evaluation (SE) of the NEI 09-10, which discusses the Agency's position in regards to the use of NEI 09
-10. In addition, based on the information discussed in the NEI 09
-10 and the SE, the 0.5 second criterion discussed in the URI is no longer the recommended method proposed by NRR. Therefore, the inspectors concern is no longer valid, and no performance deficiency or violation of regulatory requirements exists. This unresolved item is closed.
 
{{a|4OA6}}
{{a|4OA6}}
==4OA6 Management Meeting(s)==
==4OA6 Management==


===.1 Exit Meeting Summary On November 4, 2014, the inspectors presented the inspection results to Mr. Vitale, and other members of the licensee staff.===
Meeting(s)
The licensee acknowledged the issues presented. The inspectors asked the licensee if the inspectors had proprietary materials that should be returned. The inspectors verified that no proprietary information was retained by the inspectors or documented in this report.


===.1 Exit Meeting Summary===
On November 4, 2014
, the inspector s presented the inspection results to Mr. Vitale, and other members of the licensee staff. The licensee acknowledged the issues presented. The inspector s asked the licensee if the inspectors had proprietary materials that should be returned. The inspectors verified that no proprietary information was retained by the inspectors or documented in this report
.
37
37


===.2 Followup Exit Meeting Summary On November 4, 2014, the inspectors conducted a follow-up exit by phone with Mr. Vitale, and other members of the licensee staff.===
===.2 Followup Exit Meeting Summary===
This meeting updated the status of two concerns that were open at the time of the on-site exit. The licensee acknowledged the issues presented.  
 
On November 4
, 2014, the inspector s conducted a follow
-up exit by phone with Mr. Vitale, and other members of the licensee staff. This meeting updated the status of two concerns that were open at the time of the on
-site exit.
 
The licensee acknowledged the issues presented
.  
{{a|4OA7}}
{{a|4OA7}}
==4OA7 Licensee-Identified Violations The following violation of very low safety significance (Green) was identified by the licensee and is a violation of NRC requirements which meets the criteria of the NRC Enforcement Policy, for being dispositioned as a Non-Cited Violation.==
==4OA7 Licensee-Identified Violations==
Technical Specification 5.4.1.a, requires written procedures shall be established, implemented, and maintained as recommended in Regulatory Guide 1.33, Item (b), Administrative Procedures implementing the "Authorities and Responsibilities for Safe Operation and Shutdown." Procedure 4.48, Revision 3, "Control of Time Critical Operator Actions." Requires that Time Critical Operator Actions (TCAs) revalidated every two years. Contrary to the above, on July 23, 2014, the licensee found no evidence that TCA revalidation was performed since 2011. The licensee determined timing information could not be found for the following TCA validations:  TCA 2:  Match PCS and S/G Pressure during a SGTR Event,  TCA 10:  Align Shutdown Cooling (SDC), and  TCA 46:  Station Battery Load Stripping. This issue was determined to be more than minor, because it impacted the Procedure Quality attribute of the Reactor Safety, Mitigating Systems Cornerstone and adversely affected the cornerstone objective to ensure the availability, reliability, and capability of systems that respond to initiating events to prevent undesirable consequences. The licensee documented this issue in CR-PLP-2014-03841, dated July 23, 2014. The finding was determined to be of very low safety significance (Green) because all questions were answered "no" for Exhibit 2 - Mitigating Systems Screening Questions in Inspection Manual Chapter (IMC) 0609, Appendix A, Significance Determination Process (SDP) For Findings At-Power. ATTACHMENT:   
 
The following violation of very low safety significance (Green) was identified by the licensee and is a violation of NRC requirements which meet s the criteria of the NRC Enforcement Policy, for being dispositioned as a Non
-Cited Violation.
 
Technical Specification 5.4.1.a, requires written procedures shall be established, implemented, and maintained as recommended in Regulatory Guide 1.33, Item (b), Administrative Procedures implementing the "Authorities and Responsibilities for Safe Operation and Shutdown."
 
Procedure 4.48, Revision 3, "Control of Time Critical Operator Actions."
 
Requires that Time Critical Operator Actions (TCAs) revalidated every two years.
 
Contrary to the above, on July 23, 2014, the licensee found no evidence that TCA revalidation was performed since 2011. The licensee determined timing information could not be found for the following TCA validations
:  TCA 2:  Match PCS and S/G Pressure during a SGTR Event
,  TCA 10:  Align Shutdown Cooling (SDC)
, and  TCA 46:  Station Battery Load Stripping
. This issue was determined to be more than minor, because it impacted the Procedure Quality attribute of the Reactor Safety, Mitigating Systems Cornerstone and adversely affected the cornerstone objective to ensure the availability, reliability, and capability of systems that respond to initiating events to prevent undesirable consequences.
 
The licensee documented this issue in CR-PLP-2014-03841, dated July 23, 2014. The finding was determined to be of very low safety significance (Green) because all questions were answered "
no" for Exhibit 2  
- Mitigating Systems Screening Questions in Inspection Manual Chapter (IMC) 0609, Appendix A, Significance Determination Process (SDP) For Findings At-Power. ATTACHMENT:   


=SUPPLEMENTAL INFORMATION=
=SUPPLEMENTAL INFORMATION=


==KEY POINTS OF CONTACT==
SUPPLEMENTAL INFORMATION
Licensee  
KEY POINTS OF CONTAC
: [[contact::T. Vitale]], Site Vice President  
T Licensee  
: [[contact::T. Williams]], General Manager, Plant Operations  
: [[contact::T. Vitale]],
: [[contact::B. Davis]], Engineering Director
Site Vice President
: [[contact::D. Corbin]], Operations Manager   
T. Williams
: [[contact::J. Borah]], System Engineering Manager  
, General Manager, Plant Operations
: [[contact::K. O'Connor]], Design Engineering Manager  
: [[contact::B. Davis]], Engineering Director
: [[contact::J. Hardy]], Regulatory Assurance Manager
D. Corbin
: [[contact::B. Sova]], Engineering Supervisor  
, Operations Manager   
: [[contact::T. Fouty]], Engineering Supervisor
: [[contact::J. Borah]],
: [[contact::L. Engelke]], Engineering Supervisor
System Engineering Manager
: [[contact::K. Yeager]], Engineering Supervisor  
: [[contact::K. O'Connor]],
: [[contact::D. MacMaster]], Engineering Supervisor  
Design Engineering Manager  
: [[contact::R. Scudder]], Operations Specialist
: [[contact::J. Hardy]],
: [[contact::B. Dotson]], Regulatory Assurance Specialist  
Regulatory Assurance Manager
: [[contact::T. Davis]], Regulatory Assurance Specialist U.S. Nuclear Regulatory Commission  
: [[contact::B. Sova]], Engineering Supervisor
==LIST OF ITEMS OPENED, CLOSED, AND DISCUSSED==
: [[contact::T. Fouty]],
Engineering Supervisor  
: [[contact::L. Engelke]],
Engineering Supervisor  
: [[contact::K. Yeager]],
Engineering Supervisor
: [[contact::D. MacMaster]], Engineering Supervisor
: [[contact::R. Scudder]], Operations Specialist
: [[contact::B. Dotson]], Regulatory Assurance Specialist
: [[contact::T. Davis]], Regulatory Assurance Specialist
U.S. Nuclear Regulatory Commission
LIST OF ITEMS OPENED, CLOSED, AND DISCUS
SED Opened 05000255/2014008
-01 NCV Failure to Ensure Engineered Safeguards Systems Aren't Adversely Affected By Air Entrainment
(Section 1R21.3.b(
1)) 05000255/201400
8-02 NCV Undersized Supply Cables from Startup Transformer to 2400V Buses
(Section 1R21.3.b(
2)) 05000255/201400
8-03 NCV Undersized Motors
(Section 1R21.3.b(
3)) 05000255/201400
8-04 NCV Failure to Ensure that 480V System Voltages do not Exceed Equipment Ratings
(Section 1R21.3.b(
4)) 05000255/2014008
-05 NCV Failure to Perform Comprehensive Pump Testing of Containment Spray Pump P
-54A in accordance with the Inservice Testing Program (Section 1R21.3.b(
5)) 05000255/2014008
-06 NCV Failure to Correctly Translate Valve Leakage Limits into Test Procedure
(Section 1R21.3.b(
6)) 05000255/2014008
-07 NCV Failure to Identify Non
-Safety-Related Sub-Components Improperly Supplied with Safety-Related Valves (Section 1R21.3.b(
7)) 05000255/2014008
-08 NCV Failure to Establish an Adequate
Test Program for the Shutdown Cooling Heat Exchangers
(Section 1R21.3.b(
8))
05000255/2014008
-09 NCV Failure To Include The Degraded Voltage Channel Time Delay In TS Surveillance Requirement 3.3.5.2.a
(Section 1R21.3.b(
9)) 05000255/201400
8-10 URI Lack of Analysis for Electrical Containment Penetration Protection
(Section 1R21.3.b(
10)) 05000255/201400
8-11 URI Classification of CCW Piping and Components Inside the Reactor Containment Building
(Section 1R21.3.b(
11)) 05000255/2014008
-12 URI Component Cooling Water System Licensing Bases
(Section 1R21.3.b(
2)) 05000255/2014008
-13 NCV Non-Conservative Surveillance
for Emergency Diesel Generator Largest Load Reject Test
(Section 4OA2.1.b(1)) Closed 05000255/2014008
-01 NCV Failure to Ensure Engineered Safeguards Systems Aren't Adversely Affected By Air Entrainment
(Section 1R21.3.b(
1)) 05000255/201400
8-02 NCV Undersized Supply Cables from Startup Transformer to 2400V Buses
(Section 1R21.3.b(
2)) 05000255/201400
8-03 NCV Undersized Motors
(Section 1R21.3.b(
3)) 05000255/201400
8-04 NCV Failure to Ensure that 480V System Voltages do not Exceed Equipment Ratings
(Section 1R21.3.b(
4)) 05000255/2014008
-06 NCV Failure to Perform Comprehensive Pump Testing of Containment Spray Pump P
-54A in accordance with the Inservice Testing Program
(Section 1R21.3.b(
6)) 05000255/2014008
-07 NCV Failure to Correctly Translate Valve Leakage Limits into Test Procedure
(Section 1R21.3.b(
7)) 05000255/2014008
-08 NCV Failure to Identify Non
-Safety-Related Sub-Components Improperly Supplied with Safety-Related Valves (Section 1R21.3.b(
8)) 05000255/2014008
-09 NCV Failure to Establish a
n Adequate Test Program for the Shutdown Cooling Heat Exchangers
(Section 1R21.3.b(
9)) 05000255/2014008
-10 NCV Failure To Include The Degraded Voltage Channel Time Delay In TS Surveillance Requirement 3.3.5.2.a
(Section 1R21.3.b(
10)) 05000255/2014008
-13 NCV Non-Conservative Surveillance for Emergency Diesel Generator Largest Load Reject Test
(Section 4OA2.1.b(1)) 05000255/2012005
-05 URI Concerns With The Methodology Used To Determine Suction Side Void Acceptance Criteria
(Section 4OA
5.1) Discussed
None
LIST OF DOCUMENTS REVIEWED The following is a list of documents reviewed during the inspection. Inclusion on this list does not imply that the NRC inspectors reviewed the documents in their entirety, but rather, that selected sections of portions of the documents were evaluated as part of the overall inspection effort. Inclusion of a document on this list does not imply NRC acceptance of the document or
any part of it, unless this is stated in the body of the inspection report
. CALCULATIONS
Number Description or Title
Revision 152-202 Installation of Replacement Siemens Breaker
152-203 Installation of Replacement Siemens Breaker
1D-208-150-151 Component Cooling Pump P
-52B 4 1D-210-150-151 Breaker Calculation for 152
-210 3 1D-210-150-151 Breaker Calculation for 152
-210 3 1D-210-150-151 Breaker Calculation for 152
-210 3 23-3E LPSI Valve MO
-3190 (52-2339) ESP
P 3 D11/04 4160V Switchgear Bus 1F DC Supply
DBD 5.01
Diesel Engine and Auxiliary Systems
DBD 5.03 Emergency Diesel Generator Performance Criteria
DCP-090188-1 Range of Station Power Voltages
EA-AOVCAP-GATE-ESS-01 Actuator Capacity Review for Air Operated Gate
Valves in
ESS 1 EA-AOVT/T-ESS-02 Stem Thrust Requirements for AOVs CV
-3027 and CV
-3056 2 EA-AOVT/T-ESS-03 Evaluation of Thrust Requirements for AOVs CV
-3029 and
CV-3030 1 EA-AOV-WKLINK-02 Weak Link Calculation for AOVs CV
-3027 and CV
-3056 1 EA-AOV-WKLINK-06 Weak Link Calculation for AOVs CV
-3029 and CV
-3030 from Crane Valve
EA-A-PAL-90-018-01 DBA Sequencer Timing Study
EA-A-PAL-92-037 Emergency Diesel Generators Loadings
--First Two Hours
EA-APR-95-001 Appendix R Safe Shutdown Equipment List and Logic Diagrams 4 EA-APR-95-002 10 CFR Part 50 Appendix R Safe Shutdown Associated Circuits Analysis and Cable Selection
EA-APR-95-004 10 CFR Part 50 Appendix R Safe Shutdown Associated Circuits Analysis for Common Power Supply and Common Enclosure
EA-APR-95-015 Diesel Generator Capability without Service Water
EA-CA024154-01 Containment Spray System Flow Rates and Timing During Injection Mode Using Pipe
-Flo 1
EA-CA025644-01 Evaluation of the Impact of 110
Percent  EDG Overload on Ambient Temperature
EA-CCW-DBD-89-01 Generation of Design Basis for Specific Relief Valve Sizes in the CCW System
EA-C-PAL-95-0877D Evaluation of the Potential for Excessive Air Entrainment Caused by Vortexing in the SIRW tank
During a LOCA
EA-C-PAL-97-1650A-01 Diesel Generator Hydraulic Inputs
EA-C-PAL-97-1650A-01 Revised Hydraulic Inputs for Emergency Diesel Generator Steady State Load
EA-C-PAL-01-03563-02 Containment Sump NPSH Evaluation
EA-EAR-97-0273 Evaluation of 4 November 1996 Shutdown Cooling Heat Exchanger Performance Test T
-365 0 EA-EAR-2001-0333-01 Generation of ESS Pump Performance Curves for use with the Pipe-Flo ESS Hydraulic Model
EA-EC157-01 345 KV System Voltage Drop with LOCA
- Replacement SUT
1- 2 0 EA-EC-235-01 Assessment of the High Pressure Air System's Capacity to Cycle Valves in the West Engineering Safeguards
EA-EC496-001 Evaluation
of Downcomer,
Floor Drain, and Sump Vent Screens for GSI
-191 Resolution
EA-EC496-04 SFS Surface Area, Flow
and Volume 1 EA-EC6432-01 Palisades Emergency Diesel Generator Fuel Oil Storage Requirements
EA-EC7107-01 Palisades GSI
-191 Downstream Effects Evaluation of ECCS Components
EA-EC-8349-04 Post LOCA Boric Acid Precipitation Analysis for Palisades in Support of Replacement of TSP with NaTB as the Containment Sump Buffer Agent
EA-EC9600-01 Functionality of Equipment in EDG Room at an Elevated Temperature of 121F
EA-EC-11464-01 Second Level Undervoltage Time Delay Relays 162
-153 and 62-154 Uncertainty Analysis
EA-EC-11464-02 First Level Undervoltage Relays 127
-1 and 127
-2 Drift Calculations
EA-EC-11464-03 First Level Inverse Time Undervoltage Relays 127
-1 and 127-2 Uncertainty Analysis
EA-EC19401-01 Uncertainty Calculation for 2400V Safety Bus Voltage Meters
EA-EC3181717
-01 Analysis
of the Low Flow Testing
of the Engineered Safeguards System Pumps
EA-ELEC08- 0008 SIRW Tank Level Switch Position Uncertainty Calculation
EA-ELEC-AMP-016 Calculate the Cable Ampacity for Containment Spray
EA-ELEC-AMP-030 Capability of the 2400V Feeder Cables to Buses 1C and 1D from the Startup Transformer 1
-2 2 EA-ELEC-CABLE-A1208-1 2.4KV Cable Ampacity for P
-52B 0 EA-ELEC-CABLE-A1210-1 2.4KV Cable Ampacity for P
-54A 0 EA-ELEC-EDSA-01 Auxiliary AC System EDSA Model Development and Verification
and Validation
EA-ELEC-EDSA-03 LOCA with Offsite Power Available
1,2 EA-ELEC-EDSA-04 Second Level Undervoltage Relay Setpoint Determination (SLUR) 0 EA-ELEC-EDSA-05 Fast Transfer Analysis
EA-ELEC-EDSA-06 AC Short Circuit Analysis
and EC 5000122058
EA-ELEC-LDTAB-005 Emergency Diesel Generators 1
-1 and 1-2 Steady State Loadings 9,10 EA-ELEC-LDTAB-013 Worst Case Cable Loading Between SUT 1
-2, and Buses 1C
and 1D 0 EA-ELEC-LDTAB-019 Auxiliary Power System Measured Load Analysis
EA-ELEC-VOLT-010 Maximum and Minimum Station Power Voltages
EA-ELEC-VOLT-01A Dynamic Response of Emergency Diesel Generators and ECCS Motor Acceleration Times
EA-ELEC-VOLT-006 Determine the Terminal Voltage at the 46 Safety-Related Motor Operated Valves
EA-ELEC-VOLT-033 Second Level Undervoltage Relay Setpoint
EA-ELEC-VOLT-034 Calculation of VT Burden and Ratio Correction Factor for 2400V Class 1E Buses
EA-ELEC-VOLT-036 Station Power Transformers No. 11, 12, 19, and 20 Tap Change -2.5 percent  0 EA-ELEC-VOLT-037 Degraded Voltage Calculation for the Safety
-Related MOVs
EA-ELEC-VOLT-039 Stuck SGT 1
-1 Tap Changer and Subsequent Station Power Voltages 0 EA-ELEC-VOLT-050 Motor Control Center Control Circuit Voltage Analysis
EA-ELEC-VOLT-051 MCC Power Circuit Minimum Required Voltage Analysis
EA-ELEC-VOLT-053 Preferred AC Voltage Analysis
EA-GL-8910-O1 Generic Letter 89
-10 MOV Thrust Window Calculations
EA-GOTHIC-04-05 Development of LOCA Containment Response Base Deck
EA-GOTHIC-04-06 Development of MSLB Containment Response Base Deck
EA-GOTHIC-04-08 Containment Response to LOCA Using GOTHIC 7.2a
EA-GOTHIC-04-09 Containment Response to a MSLB Using GOTHIC 7.2a
EA-MOD-2005-004-03 ESS Flow Rates and Pump NPSH During Recirc Mode with CSS Throttling
EA-PIPEFLO-ESS-02 Pipe-Flo Professional 2007a Integrated Hydraulic Model of the Containment Spray, High Pressure and Low Pressure Safety Injection Systems
EA-PLTB-04 Pressure Looking and Thermal Binding Review for Appendix R Safe Shutdown Power Operated Gate Valves
EE-EDG-01 Evaluation of Maximum Diesel Room Temperature
MPR-4105 Technical Evaluation of EDG Frequency and Voltage Variations in Support of Operability Determination for Palisades
NB-PSA-ETSC Mode 4 LOCA Load Recovery Period Basis.
NEI-1149-014 Palisades Design Basis AST MHA/LOCA Radiological Analysis 4 SUT1-2/SUT1-2/ALTC Startup Transformer 1
-2 Load Tap Changer Automatic Controls 0  CORRECTIVE ACTION DOCUMENTS GENERATED DUE TO THE INSPECTION
Number Description or Title
Date CR-PLP-2014-04385 Merlin Drawing Revision Conflict For M0265BC Sheet 5 9/8/14 CR-PLP-2014-04406 Conditions Identified During A Tour Of The West Engineered Safeguards Room
9/10/14 CR-PLP-2014-04445 Indications Of White, Dry Boric Acid Inside The Insulation Box For LT
-0332A, SIRW LEVEL TRANSMITTER, and LT
-0332B, SIRW LEVEL TRANSMITTER
9/11/14 CR-PLP-2014-04446 NRC Inspector Identified
a Degraded Jumper Connection On A Ground Cable
9/11/14 CR-PLP-2014-04450 Electrical Penetrations of Reactor Containment
9/11/14 CR-PLP-2014-04472 NRC Questions Whether it is Appropriate to Have a Design Basis Calculation Which States 3.6
Percent Air Entrainment Could Occur
9/12/14 CR-PLP-2014-04491 EA-ELEC-VOLT-39, Stuck SGT 1
-1 TAP Changer and Subsequent Station Power Voltages, has not been updated
9/15/14 CR-PLP-2014-04495 NRC Inspectors Involved With
the 2014 CDBI Questioned
the Worst Case Load Assumption
9/15/14 CR-PLP-2014-04496 NRC Inspectors Involved With
the 2014 CDBI Questioned
the Worst Case Load Assumption
9/15/14
CORRECTIVE ACTION DOCUMENTS GENERATED DUE TO THE INSPECTION
Number Description or Title
Date CR-PLP-2014-04413 Calculation EA
-ELEC-VOLT-018, Which is Referenced In Design Basis Document 3.04, Could
Not Be Found
9/10/14 CR-PLP-2014-04450 FSAR Unclear On Requirements for Electrical Protection
for Containment Penetrations
9/11/14 CR-PLP-2014-04491 Calculation EA
-ELEC-VOLT-039, Which Analyzes Maximum Voltage Change During Stuck Tap Condition
for a Load Tap Changing Transformer, Does Not Bound Minimum Allowable Switchyard Voltage
9/15/14 CR-PLP-2014-04495 Non-Conservative Transient Load Analysis
for 2.4kV
Supply Breaker to
Bus 1C 9/15/14 CR-PLP-2014-04496 Non-Conservative Transient Load Analysis
for 2.4kV
Supply Breaker to
Bus 1D 9/15/14 CR-PLP-2014-04665 Process a Revision to Calculation EA
-C-PAL-95-0877D to Address the Conditions Identified in Condition Reports CR
-PLP-2014-04472 and CR
-PLP-2014-04665, Includes Operability Evaluation
of ESS Pumps 10/9/14 CR-PLP-2014-04672 As Presently Designed, The Thermal Overload Relays (TOR) For Six Safety
-Related Motor Operated Valves Will Not Alarm Under Certain Overload Conditions
9/24/14 CR-PLP-2014-04679 The Current Range (325
-375kw) Within RE
-131 Doesn't Bound The Largest Calculation Load
of P-8A 9/25/14 CR-PLP-2014-04680 The Current Range (325
-375kw) Within RE
-131 Doesn't Bound The Largest Calculation Load
of P-66A 9/25/14 CR-PLP-2014-04681 Incorrect Acceptance Criteria Limits for Leak Testing of CV-3027 and CV
-3056 9/25/14 CR-PLP-2014-04682 Time delay Between a Degraded Voltage Condition and Actuation
of the Transfer
from Offsite Power to the Diesel Generators is Ambiguous in Calculation
EA-ELEC-EDSA-03 9/25/14 CR-PLP-2014-04696 Diesel Voltage
and Frequency Limits Unanalyzed
9/26/14 CR-PLP-2014-04755 Improper Quality Classifications for Valve Sub
-Components
9/30/14 CR-PLP-2014-04815 Segment of Non
-Safety-Related Tubing Installed in Safety-Related System 10/2/14 CR-PLP-2014-04858 Lack of a Calculation that Establishes Total Time Delay, Including Loop Uncertainties, Between a Degraded Voltage Condition And Actuation of the Transfer from Offsite Power to the Diesel Generators
10/7/14 CR-PLP-2014-04860 The Cables from Start
-Up Transformer 1
-2 (EX-04) to Buses 1C (EA-11) and 1D (EA
-12) are Undersized
10/7/14 CR-PLP-2014-04864 EC That Changed The 2400/480 Station Transformer Taps To A 2.5 Percent Boost Setting In 1995 Did Not Bound Worst Case High Voltage Conditions
10/8/14 CR-PLP-2014-04874 NRC Question on Flow Testing of Components in the Closed Cycle Cooling Water Program
10/8/14
CORRECTIVE ACTION DOCUMENTS GENERATED DUE TO THE INSPECTION
Number Description or Title
Date CR-PLP-2014-04881 Missed Surveillance For CS P
-54A Due to Instruments Being Out Of Calibration Per The Requirements Of The ASME Code 10/8/14 CR-PLP-2014-04897 AOP-30, Loss of Shutdown Cooling, Attachment 8, Align Idle LPSI Pump Suction to the SIRW Tank When on Shutdown Cooling, May Not Be Adequate
10/9/14 CR-PLP-2014-04901 Transmission Network Model that Predicts the Change In Switchyard Voltage as a Result of a LOCA Does Not Consider Change in Plant Loading Imposed On Switchyard
10/9/14 CR-PLP-2014-04902 Motors That Are Undersized With Respect To Their Mechanical Loads Have Not Been Analyzed For Thermal Effects 10/9/14 CR-PLP-2014-04903 Degraded Voltage Monitor
Total Delay
-Time not in TS 3.3.5.2 10/09/14 CR-PLP-2014-04912 NRC Questions the Adequacy of the Testing Performed to Ensure E-60A/B Remain Qualified to the Capability Assumed During Design Basis Events
10/10/14 CR-PLP-2014-04915 Motor Operated Valve Calculation
EA-GL-8910-01 Uses Obsolete Electrical Calculation
EA-ELEC-VOLT-037 for Input Data Regarding Minimum Voltages to Valve Motors
10/10/14  CORRECTIVE ACTION DOCUMENTS REVIEWED DURING THE INSPECTION
Number Description or Title
Date A-NL-92-079 NRC Inspection Report 91
-19 (EDSFI) Reply to Open Item
91-19-03, "Overloading of Buses 1C
and 1D Feeder Cables from Startup Transformer"
3/29/95 A-NL-92-111 Spurious Diesel Generator Starts Due To Degraded Voltage Relay Time Delay Setting
3/9/95 A-PAL-92-066 Shutdown Cooling Heat Exchanger Performance Testing
2/16/92 AR 00870121
Inadequate Guidance for Operations When Outside Air Temperature Exceeds 95F
7/26/05 AR 199978
Revise PMS To Replace RO
-98 Test Gauges With M&TE
4/28/14 CE 01066273
-01 Excluded Required Equipment in OPR 108
2/7/06 C-PAL-94-0728JJ No Heat Exchanger Performance Validation Testing is Performed on the Shutdown Cooling Heat Exchangers
2/9/96 C-PAL-94-0728W Complete Assessment of Performance of Key Safety Systems Against the Plant Design Basis
5/2/95 C-PAL-97-1521 Heat Balance Discrepancies Recorded in Special Test T
-365 12/8/97 CR-PLP-2006-05443 Level Switch LS
-0329 Instrument Uncertainties
11/15/06 CR-PLP-2006-05479 EDG Room Cooling Intake Louvre Screens Dirty
11/16/06
CORRECTIVE ACTION DOCUMENTS REVIEWED DURING THE INSPECTION
Number Description or Title
Date CR-PLP-2006-05805 OPR 000108 Failed to Consider Elevated Temperatures on Several Components
2/7/06 CR-PLP-2006-05854 EDC Cooling Fan V
-24C Discrepancies
2/11/06 CR-PLP-2006-05897 Design Calculation 01067491 Does Not Consider Frequency Variation in Calculating Load
2/31/06 CR-PLP-2007-02040 Level Switch LS
-0329 Setpoint
5/15/07 CR-PLP-2008-04580 D/G Load Calc Did Not Account For Worst Case Load from CAC Fan Motors 11/7/08 CR-PLP-2008-04707 CDBI Team Questioned Using a Water Level Only 1 Inch Below Fuel Oil Suction Height
11/19/08 CR-PLP-2009-00477 Containment Spray Pump, P
-54A, Has Very Little Clearance Between Shaft Coupling and Shaft Keyway
2/4/09 CR-PLP-2009-05533 CCW Pumps Lack Adequate Inservice Testing Margin
2/3/09 CR-PLP-2009-05534 Containment Spray Pumps (CSS) Lack Inservice Testing Margin 12/3/09 CR-PLP-2010-01331 NRC Resident Has Questions On QO
-15 3/31/10 CR-PLP-2010-01734 Plant Response to IN 2010
-09, Importance of Understanding Circuit Breaker Control Panel Indications
05/11/10 CR-PLP-2010-03083 Change in Gas Void Point/Size
7/27/10 CR-PLP-2010-05181 Technical Specification Test RO
-98 Pump Test Results Low in Their Acceptance
Band 10/17/10 CR-PLP-2010-06434 Transition of fire protection to NFPA 805
10/18/10 CR-PLP-2011-03087 Issue Identified During 2011 CDBI RFI 167
6/21/11 CR-PLP-2011-03221 Failure to Adequately Evaluate the Enclosure Installed Over the 1F/1G Buses
6/27/11 CR-PLP-2011-03419 Dripping Water in East Engineered Safeguards in the Vicinity of P-54A Containment Spray Pump
7/11/11 CR-PLP-2011-03835 Water Was Found Dripping from the Overhead East Engineered Safeguards Cooler in the Vicinity of P
-54 A Spray Pump
8/4/11 CR-PLP-2011-03858 LOCA Could Occur in Mode 4
8/5/11 CR-PLP-2011-04749 Boric Acid Residue Discovered on Several Components
9/21/11 CR-PLP-2011-06313 No Uncertainty Analysis for Back
-Leakage into SIRW Tank
11/17/11 CR-PLP-2012-02124 Extent of Condition for CR
-PLP-11-6818, EQ Submergence Values Outside Containment
4/2/12
CORRECTIVE ACTION DOCUMENTS REVIEWED DURING THE INSPECTION
Number Description or Title
Date CR-PLP-2012-02382 Leakage from the Primary Coolant System to the SIRW Tank
4/10/12 CR-PLP-2012-05054 Potential Impact of Foreign Material Identified in CR PLP
-2012-05049 on the ECCS Pumps
7/13/12 CR-PLP-2012-05553 Post-Accident Water Temperature in Containment Greater
Than Air Temperature, Equipment EQ Needs Evaluation
8/8/12 CR-PLP-2012-06148 Lack of Complete Electrical Protective Coordination
for Appendix R
9/11/12 CR-PLP-2012-06148 Electrical Coordination Will Not Support Transition to NFPA
805  9/11/12 CR-PLP-2012-06795 Shutdown Cooling Heat Exchanger (E
-60A and E
-60B) Inspections Removed from 1R23 Scope
10/18/12 CR-PLP-2013-00076 2014 CDBI Pre
-Inspection Self-Assessment
2/23/13 CR-PLP-2013-01213 Diesel Generator Loading Calculation Non
-Conservative
3/20/13 CR-PLP-2013-02674 RIS 2013-05; Relationship Between GDC and Tech Spec Operability
6/17/13 CR-PLP-2013-03894 AOV Calculations Not Revised
9/3/13 CR-PLP-2013-04003 Condensation from Room Cooler Dripping onto P
-54A, CSS Pump and other NRC Identified Issues
9/10/13 CR-PLP-2013-04799 P-52B CCW Pump Has Oil Leak
11/6/13 CR-PLP-2013-04843 Green OOZE on Relay 150
-1 Terminals
11/08/13 CR-PLP-2013-04940 As Found Thread Engagement Issues on Cooler for P
-54A Containment Spray Pump
11/19/13 CR-PLP-2014-00042 Additional K
-Line 480V Circuit Breakers Subject to ABB Part
1/03/14 CR-PLP-2014-00550 Air And Oil Leak
on FCV-3057A 1/24/14 CR-PLP-2014-01679 P-54A Containment Spray Pump Low Differential Pressure During Performance of RO
-98. 2/25/14 CR-PLP-2014-03841 No Evidence Found that Time Critical Operator Action Validation was Performed Since
2011. 7/23/14 CR-PLP-2014-04881 Missed Surveillance of CS Pump P-54A Risk-Evaluation
10/9/14  DRAWINGS Number Description or Title
Revision E-1 Sheet 1
Single Line Meter and Relay Diagram 480 Volt Motor Control Center Warehouse
DRAWINGS Number Description or Title
Revision E-11 Sheet 1
Schematic Meter and Relay Diagram 2.4 KV System
E-12 Sheet 1
Schematic Meter and Relay Diagram 2.4 KV and 480V Systems 40 E-12 Sheet 2
Schematic Meter and Relay Diagram 2.4 KV and 480V Systems 9 E-17 Sheet 10
Logic Diagram 2400 Volt Load Shed
E-17 Sheet 11
Logic Diagram Diesel Start
E-17 Sheet 13
Logic Diagram Diesel Generator Breakers
E-17 Sheet 14
Logic Diagram Bus 1C and 1D Incoming Breakers
E-17 Sheet 18A
Logic Diagram Safeguard Transformer 1
-1 3 E-17 Sheet 5A
Containment Spray Isolation Valves Logic
Diagram 0 E-17 Sheet 8
Logic Diagram Main Generator Protection
E-17 Sheet 9
Logic Diagram Turbine
-Generator Trips and Fast Transfer
E-129 Sheet 44 Schematic Diagram Circuit Breaker 152
-210 0 E-237 Sheet 1 Schematic Diagram Containment Spray Valves 17 E-237 Sheet 1A Schematic Diagram Containment Spray Valves
E-244 Sheet 8
Schematic Diagram Safety Injection Motor Operated Valves
E-244 Sheet 9
Schematic Diagram Safety Injection Motor Operated Valves
E-246 Schematic Diagram SIRW Tank And Containment Sump Valves - Circuit No. 2
E-246 Sheet 1 Schematic Diagram SIRW Tank and Containment Sump Valves - Circuit 1
E-246 Sheet 2 Schematic Diagram SIRW Tank and Containment Sump Valves - Circuit 1
E-246 Sheet 2A Schematic Diagram SIRW Tank and Containment Sump Valves - Circuit 2
E-251 Sheet 1
Schematic Diagram Containment Spray Pump P54A
E-251 Sheet 1A
Schematic Diagram Containment Spray Pump P54A
E-251 Sheet
Schematic Diagram Containment Spray Pump P54
C 2 E-259 Sheet 3A
Schematic Diagram Component Cooling Pump P52B
E-3 Sheet 1
Single Line Meter and Relay Diagram 2400 Volt System
E-5 Sheet 5B
Single Line Meter and Relay Diagram 480 Volt Motor Control Centers 12 M-1 Equipment Location Reactor Building Plan of El.
570'-0" 14 M-136 Penetrations and Inserts
M-202 Piping and Instrument Diagram Chemical
and Volume Control System
M-203 Safety Injection, Containment Spray,
and Shutdown Cooling System 27 M-203 Sht. 2
Piping and Instrument Diagram Safety Injection,
Containment Spray and Shutdown Cooling System
M-203 Sht. A
System Diagram Safety Injection, Containment Spray and Shutdown Cooling System
M-204 Safety Injection, Containment Spray,
and Shutdown Cooling System 8
DRAWINGS Number Description or Title
Revision M-204 Sht. 1
Piping and Instrument Diagram Safety Injection, Containment Spray and Shutdown Cooling System
M-204 Sht. 1A
Piping and Instrument Diagram Safety Injection, Containment Spray and Shutdown Cooling System
M-204 Sht. 1B
Piping and Instrument Diagram Safety Injection Containment Spray 41 M-204 Sht. A
System Diagram Safety Injection, Containment Spray
and Shutdown Cooling System
M-209 Sht. 1
Piping and Instrument Diagram Component Cooling System
M-209 Sht. 2
Piping and Instrument Diagram Component Cooling System
M-209 Sht. A
System Diagram Component Cooling System
M-211 Sht. 1
Piping and Instrument Diagram Dirty Waste
and Gaseous Waste 78 M-225 High Pressure Air Operated Valves
M-31 Piping Drawings Area 2
M-347 Sht. 14
Pressure Safety (Relief) Valve Data Sheet
M-7 Equipment Location
SOD_SI_02_r03
Safety Injection, Containment Spray System
VEN-C18 Sheet
SIRW Tank Erection Diagram
- Hold Down Detail
VEN-C18 Sheet
SIRW Tank Bottom Installation
VEN-M-107 Sheet 2278
Stress Isometric
VEN-M-107 Sheet 2281
Stress Isometric
VEN-M-107 Sheet 2282
Stress Isometric
VEN-M-241BC Sheet 33 Double Disc Gate Valve
VEN-M-241BC Sheet 35 Double Disc Gate Valve
VEN-M-255 Sheet 3 Drag Valve
VEN-M-255 Sheet 4 Drag Valve
VEN-M-255 Sheet 5 Drag Valve
WD 950 Single Line Meter
and Relay Diagram 125Vdc, 120V Instrument
and Preferred AC System
10 CFR 50.59 DOCUMENTS (SCREENINGS/SAFETY EVALUATIONS)
Number Description or Title
Date SDR-99-0884 Cancellation of TS Surveillance Procedures and Revision of FSAR  7/22/99  MISCELLANEOUS
Number Description or Title
Date or Revision  Letter from Dennis
: [[contact::M. Crutchfield]], NRC, to David
: [[contact::P. Hoffman]], Consumers Power Company, "SEP Topic VIII
-4, Electrical Penetrations of Reactor Containment" (ADAMS Accession No
. ML8104080152
) 3/26/81  Letter from Kerry
: [[contact::A. Toner]], Consumers Power Company, to Dennis
: [[contact::M. Crutchfield]], NRC, "SEP Topic VIII
-4, Electrical Penetrations of the Reactor Containment" (ADAMS Accession No. ML8210190459
) 10/12/82  Letter from Kerry
: [[contact::A. Toner]], Consumers Power Company, to Dennis
: [[contact::M. Crutchfield]], NRC, "SEP Topic VIII
-4, Status Update of Program to Evaluate the Adequacy of Penetration Protection from Overload and Short
-Circuit Conditions" (ADAMS Accession No. ML
8302240273
) 2/11/83  Letter from Robert
: [[contact::A. Vincent]], Consumers Power Company, to Dennis
: [[contact::M. Crutchfield]], NRC, "SEP Topic VIII
-4, Electrical Penetrations of Reactor Containment" (ADAMS Accession No.
ML8106180170
) 6/15/81  Letter from Robert
: [[contact::A. Vincent]], Consumers Power Company, to Dennis
: [[contact::M. Crutchfield]], NRC, "SEP Topic VIII
-4, Electrical Penetrations of the Reactor Containment" (ADAMS Accession No. ML8111200805
) 11/16/81  Letter from Thomas
: [[contact::V. Wambach]], NRC, to David
: [[contact::J. VandeWalle]], Consumers Power Company, "Integrated Plant Safety Assessment Report (IPSAR) Section 4.26, Electrical Penetrations of Reactor Containment
- Palisades Plant" (ADAMS Accession No. ML
8306160396
) 6/10/83  White Paper from Fauske
and Associates:
What Determines
the Condition Of Significant Air Intrusion
for the Draindown For Quiescent Water Inventories?
9/23/14 13-0327 Process Applicability Determination for EC 42422
1C-108-J9400-162-153 Protective Relay Setting
- Bus 1C Second Level Under Voltage Time Delay Relay 162
-153 4 1C-108-J9400-162-154 Protective Relay Setting
- Bus 1D Second Level Under Voltage Time Delay Relay 162
-154 3 70P-017 Engineering Specification for Shutdown Cooling Heat Exchanger
988055 P-54A Containment Spray Pump Oil Test Results
5/8/13
MISCELLANEOUS
Number Description or Title
Date or Revision 988059 P-54A Containment Spray Pump Motor Inboard Bearing Oil Test Results
5/8/13 988060 P-54A Containment Spray Pump Motor Outboard Bearing Oil Test Results
7/1/13 ASCO Catalog
2, 3 and 4 Way Solenoid Valves Vendor Manual
ASME OMb Code-2003 Addenda to ASME OM Code
-2001 Code for Operation
and Maintenance of Nuclear Power Plants
8/29/03 Attachment 9.16 SNAPSHOT Assessment of Time Critical Operator Actions.
5/27/11 Attachment 9.4
SNAPSHOT Assessment of Time Critical Operator Actions.
9/3/14 CMT95201002
Enforcement Conference
- Inoperable Diesel Generators
- Inspection Report 94020
4/30/95 CR-PLP-2014-04881 Missed Surveillance of CS Pump P
-54A Risk Evaluation
10/9/14 CV-3027 Diagnostic Testing Results
- WO 52325715
4/24/12 CV-3031 IST - Valve Component Information
CV-3057 IST - Valve Component Information
DBD-1.01 Component Cooling Water System
DBD-1.01 Design Basis Document for Component Cooling Water System 8 DBD-2.01 Low Pressure Safety Injection System
DBD-2.01 Design Basis Document for Low Pressure Safety Injection System 10 DBD-2.02 Design Basis Document for High
-Pressure Safety Injection System 9 DBD-2.03 Containment Spray System
DBD-2.03 Design Basis Document for Containment Spray System
DBD-3.04 Design Basis Document:
2400V AC System
DBD-3.05 Design Basis Document:
480V AC System
DBD-4.03 Design Basis Document:
Preferred AC System
DBD-4.04 Design Basis Document:
Uninterruptible Power Supply
DBD-5.03 Design Basis Document:
Emergency Diesel Generator Performance Criteria
DBD-5.04 Design Basis Document:
Load Shedding Circuits
DBD-5.05 Design Basis Document:
Design Basis Accident and Normal Shutdown Sequencer
DBD-6.01(TR) Design Basis Document:
Grid Interface Topical Report
DBD-6.02 Design Basis Document:
345KV Switchyard
DPR-20 Renewed Facility Operating License
251 DRN-08-01700 EOP Supplement 42, Not Tripping HPSI for Loss of Subcooling
9/5/08
MISCELLANEOUS
Number Description or Title
Date or Revision DRN-08-02217 Section 2.0 Post RAS Actions Step "N" Should be Identified as a Continuous Step (Circle C), so Operators can Continue to Perform Later Steps
2/2/08 DRN-12-01684 Commitments in Procedure do not Match Commitment List
5/14/12 DRN-14-01118 EOP Supplement 42
9/12/14 DRN-14-01222 SOP-3 Revision to Stage Equipment for Venting
LPSI Discharge Piping with
Valve MV-ES3420 per AOP
-30, Attachment 8, Align Idle LPSI Pump Suction to the SIRW Tank When on SDC.
10/7/14 DWG. No.
5935 M-347 Sheet 14 Pressure Safety (Relief) Valve Data Sheet
EAR-99-0081 CVCS Declassification
LER 80-003 Licensee Event Report 80
-003 - Containment Spray
5/13/80 Letter Response to NUREG
-0737 12/19/80 Letter (9002120116)
Response to Generic Letter 89
-13, Service Water System Problems Affecting Safety
-Related Equipment
1/29/90 Letter (ML052410206
) Supplementary Information for the Palisades Application for Renewed Operating License Resulting from Aging Management Programs Audit
8/25/05 LR-AMPBD-06-CCCW Closed Cycle Cooling Water Program
LTR-PSA-14-01 Mode 4 LOCA Analysis
10/7/14 M0001GD 0999 Fabricating Engineers Inc. Technical Manual for Shutdown Cooling Heat Exchanger
ML050940446
Palisades Nuclear Plant Application for Renewed Operating License 3/22/05 ML071800216
License Amendment Request:  Replacement of Containment Sump Buffer
6/28/07 NB-PSA-SY-CSS Palisades Nuclear Plant Probabilistic Safety Assessment System Notebook
- Containment Spray System
PL-CCW Component Cooling Water
PL-CSS Containment Spray System Lesson Plan
- CV3001, CV3002, and CV-3030 9 PL-CSS Containment Spray System 9 PLJPM-LOR-SI-14 JPM - PERFORM PRE
-RAS ACTIONS IAW EOP SUPPLEMENT 42
PLJPM-LOR-SI-15 JPM - PERFORM PRE
-RAS ACTIONS IAW EOP SUPPLEMENT 42
PLJPM-LOR-SI-16 JPM - PERFORM POST RAS ACTIONS
PLJPM-LOR-SI-17 JPM - PERFORM POST RAS ACTIONS
MISCELLANEOUS
Number Description or Title
Date or Revision PLJPM-LOR-SI-18 JPM - PERFORM POST RAS ACTIONS
PLJPM-LOR-SI-19 JPM - PERFORM POST RAS ACTIONS
PLSEG-LOR-13F-02 Scenario
- AOP 30 4 PLSEG-LOR-13G-02 Scenario
- EOP 4.0 0 PLSEG-LOR-14-CDBI-1 EOP-4.0 LBLOCA Scenario for 2014 CDBI.
9/25/14 PLSEG-LOR-14-CDBI-2 Mode 4 LOCA Scenario for 2014 CDBI.
10/7/14 PLSEG-LOR-LOCA Scenario
- EOP 4.0 Loss of Coolant Accident
PL-SIS Safety Injection System
QO-16 Basis Document for QO
-16:  Inservice Test Procedure
- Containment Spray Pumps
Reply EC 53093 Evaluation For Potential Air Entrainment
at the Lowest Levels of SIRW Tank Inventory Considering A Single Failure More limiting
than the One Considered
in EA-C-PAL-95-087DD 9/24/14 RI-38 Basis Basis Document for SIRW Tank Level Instrument Calibration 10 SDR-99-0884 Cancellation of TS Surveillance Procedures and Revision of FSAR  7/22/99 SEP-APJ-PLP-101 Mechanical Containment Penetration Basis
SEP-ISI-PLP-002 ASME Code Boundaries for ASME Section XI Inservice Inspection Program
SEP-ISI-PLP-002 ASME Code Boundaries For Section XI Inservice Inspection Program 1 SEP-PLP-IST-102 Inservice Testing of Selected Safety
-Related Pumps
SOP-15 Service Water System
USI A-46 Equipment Evaluation Report
5/3/95  MODIFICATIONS
Number Description or Title
Date or Revision FC-718 RAS Logic Seal
-In Circuit Addition
2/19/86
OPERABILITY EVALUATIONS  Number Description or Title
Date or Revision CR-PLP-2014-4696 CA-1 Operability for all SSCs Within Maximum
Variations of EDG Frequency and Voltage Allowed by Technical Specifications
10/22/14 OPR 000108
Operability Recommendation
- EDG Room Temperature
PROCEDURES
Number Description or Title
Revision 4.02 Control of Equipment
Administrative Procedure
10.41 Site Procedures Process
Administrative Procedure
10.51 Writer's Guideline for Site Procedures
Administrative Procedure
4.06 Emergency Operating Procedure Development and Implementation
Administrative Procedure
4.66 Abnormal Operating Procedure Development and Implementation
Administrative Procedure TCA
Control of Time Critical Operator Actions
AOP-23 Primary Coolant Leak
AOP-30 Loss of Shutdown Cooling
AOP-36 Loss Of Component Cooling
AOP-37 Loss of Instrument Air
ARP-4 Reactor Water Level Low Alarm Response Procedure
ARP-3 Electrical Auxiliaries and Diesel Generator Scheme EK
-05 (EC-11) 74 ARP-7 Auxiliary Systems Scheme EK
-11 (C-13) 92 CEN 152 Combustion Engineering LOCA Recovery Guideline
5.3 EM-09-16 Master Heat Exchanger Testing Plan
and 8 EN-DC-178 System Walkdowns
EN-DC-195 Margin Management
EN-DC-219 Gas Accumulation Management
EN-MA-145 Maintenance Standard for Torque Applications
EN-OP-104 Operability Determination Process
EOP 4.0 Loss of Coolant Accident Recovery
EOP 4.0 Basis Loss of Coolant Accident Recovery Basis
EOP Intro
Introduction to EOP System Basis
EOP Supplement 42
Pre and Post RAS Actions
EOP TCA EOP Time Critical Operator Action Basis
EOP-4 Loss of Coolant Accident Recovery
EOP-5.0 Steam Generator Tube Rupture Recovery
EOP-9.0, HR-3 Functional Recovery Procedure
ESSO-1 Containment Spray Header Fill
PROCEDURES
Number Description or Title
Revision GOP-14 Shutdown Cooling Operations
MO-7A-1 Emergency Diesel Generator 1
-1 86 MO-7A-2 Emergency Diesel Generator 1
-2 86 NB-PSA-SM Probabilistic Safety Assessment Model Summary System Notebook 2 NB-PSA-SSS SIRW Tank and Containment Sump Suction System Probabilistic Safety Assessment System Notebook
NPOA Nuclear Plant Operating Agreement
ONP-17 Loss of Shutdown Cooling (SDC)
QO-16 Inservice Test Procedure
- Containment Spray Pumps
QO-2 Recirculation Actuation System
QO-5 Valve Test Procedure (Includes Containment Isolation Valves) 89 RE-131 Diesel Generator 1
-1 Load Reject
RE-131/132 Technical Specification Surveillance Procedure Basis Document 1 RE-132 Diesel Generator 1
-2 Load Reject
RE-137 Calibration of Bus 1C Undervoltage and Time Delay Relays
RE-138 Calibration of Bus 1D Undervoltage and Time Delay Relays
RI-38 SIRW Tank Level Instrument Calibration
RO-119 Inservice Testing of Engineered Safeguards Valves CV
-3027 and CV-3056 14 RO-217 Technical Specification Leak Rate Testing of Engineered Safeguards Check Valves
RO-98 Technical Specification Surveillance Procedure Basis Document 3 RT-71K Class 2 System Functional Test for Shutdown Cooling System 10 RT-71L Technical Specification Admin 5.5.2 Pressure Test Of ESS Pump Suction Piping
SEP-HX-PLP-001 Master Heat Exchanger Testing Plan
SOP-3 Safety Injection and Shutdown Cooling System
SOP-3, Attachment 16
Engineered Safeguards System Checklist (Heat SDC)
SOP-4 Containment Spray System
SOP-16 Component Cooling Water System
SOP-19 Nitrogen/Air Backup Stations 60 SOP-30 Station Power
SPS-E-17 Temporary Installation and Removal of Spare Circuit Breakers 24 T-205-A East Engineering Safeguards High Pressure Air System Performance Verification
PROCEDURES
Number Description or Title
Revision T-205-B West Engineering Safeguards High Pressure Air System Performance Verification
T-278-3A Nitrogen Station 3A Performance Test
T-365 Determination of Heat Transfer Capability of Shutdown Cooling Heat Exchangers E
-60A and E-60B 1  SURVEILLANCES (COMPLETED) Number Description or Title
Date or Revision T-205-A East Engineering Safeguards High Pressure Air System Performance Verification
11/23/14 T-205-B West Engineering Safeguards High Pressure Air System Performance Verification
2/2/14 T-278-3A Nitrogen Station 3A Performance Test
2/19/14 WO-PLP-52435851
LPSI and Containment Spray Comprehensive Pump Test and Check Valves Test
2/25/14 WO-PLP-52547674
Inservice Test Procedure
- Containment Spray Pumps
5/29/14  WORK ORDERS  Number Description or Title
Date or Revision 178171-01 Clean EDG Room Cooling Air Inlet Louvre Screens
11/21/06 342334-01 Change SUT 1
-2 (EX-04) Tap Changer Setpoint
51521714-01 Clean Door Louvre Screens
11/21/06 51521714-02 Repair Door Louvre Screens
11/21/06 51521714-03 Clean Wall Louvre Screens
11/21/06 52325512-01 RI-14, SIRW Tank Level Switch Interlock Test 8/6/12 52430162-01 RI-14, SIRW Tank Level Switch Interlock Test
3/6/14 52432473-01 RT-92 - Inspect ECCS Train Cont Sump Suction Inlet
3/9/14 52435963-01 Containment Sump Clean
-Out and Inspection
2/26/14 WT-PLP-2010-00261 Update DBD 3.04 Table 3
-2: "2400V AC Supply Cables, Design Ratings, Loading and Margins
6/2/10 WT-PLP-2014-00216 WT Written to Document Actions Resulting from
CDBI Focused Area Self
-Assessment LO
-PLP-2013-00076  7/17/14
LIST OF ACRONYMS USE
D °C Celsius Degrees °F Fahrenheit Degrees AC Alternating Current
ADAMS Agencywide Document Access Management System
AOP Abnormal Operating Procedure
AOV Air-Operated Valve
AR Action Request
ARM Area Radiation Monitor
ASME American Society of Mechanical Engineers
BHP Brake Horsepower
CAP Corrective Action Program
CCW Component Cooling Water
CDBI Component Design Bases Inspection
CFR Code of Federal Regulations
CS Containment Spray
CVCS Chemical and Volume Control
DBD Design Basis Document
DC Direct Current
DRS Division of Reactor
Safety EC Engineering Change
ECCS Emergency Core Cooling System
EDG Emergency Diesel Generator
EPRI Electric Power Research Institute
EPU Extended Power Uprate
EQ Equipment Qualifications
ESS Engineered Safeguards System
FIN Finding FSAR Final Safety Analysis Repor
t GDC General Design Criteria
GL Generic Letter
gpm Gallons per Minute
HELB High Energy Line Break
HPSI High Pressure Safety Injection
HVAC  Heating, Ventilation and Air
-Conditioning
IEEE Institute of Electrical
and Electronic Engineers
IMC Inspection Manual Chapter
IN Information Notice
IP Inspection Procedure
IR Inspection Report
IR Issue Report
ISI Inservice Inspection
IST Inservice Testing kV Kilovolt
LCO Limiting Condition for Operation
LER Licensee Event Report
LOCA Loss of Coolant Accident
LPCI Low Pressure Coolant Injection
MCC  Motor Control Center
MOV Motor-Operated Valve
 
NCV Non-Cited Violation
NEI Nuclear Energy Institute
NFPA National Fire Protection Association
NPSH Net Positive Suction Head
NRC U.S. Nuclear Regulatory Commission
NRR Nuclear Reactor Regulation
PARS Publicly Available Records System
PCS Primary Coolant System
P&ID Piping and Instrumentation Drawing
PI&R Problem Identification and Resolution
PRA Probabilistic Risk Assessment
psi Pounds Per Square Inch
psid Pounds Per Square Inch Differential
psig Pounds Per Square Inch Gauge
RIS Regulatory Issue Summary
SDC Shutdown Cooling
SDP Significance Determination Process
SEP Systematic Evaluation Program
SG Steam Generator
SIRW Safety Injection Refueling Water SR Surveillance Requirement
SSC Systems, Structures, and Components
TI Temporary Instructions
TS Technical Specification
URI Unresolved Item
Vac Volts Alternating Current
VAC Volts Alternating Current
VDC Volts Direct Current
Vdc Volts Direct Current
WO Work Order


===Opened===
A. Vitale
: 05000255/2014008-01 NCV Failure to Ensure Engineered Safeguards Systems Aren't Adversely Affected By Air Entrainment (Section 1R21.3.b(1))
    -2- In accordance with Title 10, Code of Federal Regulations
: 05000255/2014008-02 NCV Undersized Supply Cables from Startup Transformer to 2400V Buses (Section 1R21.3.b(2))
  (CFR) "Rules of Practice," a copy of this letter and its enclosure will be available electronically for public inspection in the NRC Public
: 05000255/2014008-03 NCV Undersized Motors (Section 1R21.3.b(3))
Document Room or from the Publicly Available Records System (PARS) component of NRC's Agencywide Documents Access and Management System (ADAMS), accessible from the NRC Web site at http://www.nrc.gov/reading
: 05000255/2014008-04 NCV Failure to Ensure that 480V System Voltages do not Exceed Equipment Ratings (Section 1R21.3.b(4))
-rm/adams.html
: 05000255/2014008-05 NCV Failure to Perform Comprehensive Pump Testing of Containment Spray Pump P-54A in accordance with the Inservice Testing Program (Section 1R21.3.b(5))
(the Public Electronic Reading Room). Sincerely,
: 05000255/2014008-06 NCV Failure to Correctly Translate Valve Leakage Limits into Test Procedure (Section 1R21.3.b(6))
: 05000255/2014008-07 NCV Failure to Identify Non-Safety-Related Sub-Components Improperly Supplied with Safety-Related Valves (Section 1R21.3.b(7))
: 05000255/2014008-08 NCV Failure to Establish an Adequate Test Program for the Shutdown Cooling Heat Exchangers (Section 1R21.3.b(8))  
: 05000255/2014008-09 NCV Failure To Include The Degraded Voltage Channel Time Delay In TS Surveillance Requirement 3.3.5.2.a (Section 1R21.3.b(9))
: 05000255/2014008-10 URI Lack of Analysis for Electrical Containment Penetration Protection (Section 1R21.3.b(10))
: 05000255/2014008-11 URI Classification of CCW Piping and Components Inside the Reactor Containment Building (Section 1R21.3.b(11))
: 05000255/2014008-12 URI Component Cooling Water System Licensing Bases (Section 1R21.3.b(12))
: 05000255/2014008-13 NCV Non-Conservative Surveillance for Emergency Diesel Generator Largest Load Reject Test (Section 4OA2.1.b(1))
===Closed===
: [[Closes finding::05000255/FIN-2014008-01]] NCV Failure to Ensure Engineered Safeguards Systems Aren't Adversely Affected By Air Entrainment (Section 1R21.3.b(1))
: [[Closes finding::05000255/FIN-2014008-02]] NCV Undersized Supply Cables from Startup Transformer to 2400V Buses (Section 1R21.3.b(2))
: [[Closes finding::05000255/FIN-2014008-03]] NCV Undersized Motors (Section 1R21.3.b(3))
: [[Closes finding::05000255/FIN-2014008-04]] NCV Failure to Ensure that 480V System Voltages do not Exceed Equipment Ratings (Section 1R21.3.b(4))
: [[Closes finding::05000255/FIN-2014008-06]] NCV Failure to Perform Comprehensive Pump Testing of Containment Spray Pump P-54A in accordance with the Inservice Testing Program (Section 1R21.3.b(6))
: [[Closes finding::05000255/FIN-2014008-07]] NCV Failure to Correctly Translate Valve Leakage Limits into Test Procedure (Section 1R21.3.b(7))
: [[Closes finding::05000255/FIN-2014008-08]] NCV Failure to Identify Non-Safety-Related Sub-Components Improperly Supplied with Safety-Related Valves (Section 1R21.3.b(8))
: [[Closes finding::05000255/FIN-2014008-09]] NCV Failure to Establish an Adequate Test Program for the Shutdown Cooling Heat Exchangers (Section 1R21.3.b(9))
: [[Closes finding::05000255/FIN-2014008-10]] NCV Failure To Include The Degraded Voltage Channel Time Delay In TS Surveillance Requirement 3.3.5.2.a (Section 1R21.3.b(10))
: [[Closes finding::05000255/FIN-2014008-13]] NCV Non-Conservative Surveillance for Emergency Diesel Generator Largest Load Reject Test (Section 4OA2.1.b(1))
: [[Closes finding::05000255/FIN-2012005-05]] URI Concerns With The Methodology Used To Determine Suction Side Void Acceptance Criteria (Section 4OA5.1)
===Discussed===
None


==LIST OF DOCUMENTS REVIEWED==
Ann Marie Stone, Chief
The following is a list of documents reviewed during the inspection.
Engineering Branch 2
: Inclusion on this list does not imply that the NRC inspectors reviewed the documents in their entirety, but rather, that selected sections of portions of the documents were evaluated as part of the overall inspection effort.
Division of Reactor Safety
: Inclusion of a document on this list does not imply NRC acceptance of the document or any part of it, unless this is stated in the body of the inspection report. CALCULATIONS Number Description or Title Revision 152-202 Installation of Replacement Siemens Breaker 1 152-203 Installation of Replacement Siemens Breaker 1 1D-208-150-151 Component Cooling Pump P-52B 4 1D-210-150-151 Breaker Calculation for 152-210 3 1D-210-150-151 Breaker Calculation for 152-210 3 1D-210-150-151 Breaker Calculation for 152-210 3 23-3E LPSI Valve
Docket No. 50
: MO-3190 (52-2339) ESPP 3 D11/04 4160V Switchgear Bus 1F DC Supply 1 DBD 5.01
-255 License No. DPR
: Diesel Engine and Auxiliary Systems 6 DBD 5.03 Emergency Diesel Generator Performance Criteria 8
-20  Enclosure:
: DCP-090188-1 Range of Station Power Voltages 0
Inspection Report 05000255/2014008
: EA-AOVCAP-GATE-ESS-01 Actuator Capacity Review for Air Operated Gate Valves in ESS 1
w/Attachment:  Supplemental Information
: EA-AOVT/T-ESS-02 Stem Thrust Requirements for AOVs
cc w/encl:
: CV-3027 and
Distribution via  
: CV-3056 2
: EA-AOVT/T-ESS-03 Evaluation of Thrust Requirements for AOVs
: CV-3029 and
: CV-3030 1
: EA-AOV-WKLINK-02 Weak Link Calculation for AOVs
: CV-3027 and
: CV-3056 1
: EA-AOV-WKLINK-06 Weak Link Calculation for AOVs
: CV-3029 and
: CV-3030 from Crane Valve 1
: EA-A-PAL-90-018-01 DBA Sequencer Timing Study 3
: EA-A-PAL-92-037 Emergency Diesel Generators Loadings--First Two Hours 1
: EA-APR-95-001 Appendix R Safe Shutdown Equipment List and Logic Diagrams 4
: EA-APR-95-002 10 CFR Part 50 Appendix R Safe Shutdown Associated Circuits Analysis and Cable Selection 1
: EA-APR-95-004 10 CFR Part 50 Appendix R Safe Shutdown Associated Circuits Analysis for Common Power Supply and Common Enclosure 5
: EA-APR-95-015 Diesel Generator Capability without Service Water 0
: EA-CA024154-01 Containment Spray System Flow Rates and Timing During Injection Mode Using Pipe-Flo 1
: EA-CA025644-01 Evaluation of the Impact of 110 Percent
: EDG Overload on Ambient Temperature 1
: EA-CCW-DBD-89-01 Generation of Design Basis for Specific Relief Valve Sizes in the CCW System 0
: EA-C-PAL-95-0877D Evaluation of the Potential for Excessive Air Entrainment Caused by Vortexing in the SIRW tank During a LOCA 1
: EA-C-PAL-97-1650A-01 Diesel Generator Hydraulic Inputs 2
: EA-C-PAL-97-1650A-01 Revised Hydraulic Inputs for Emergency Diesel Generator Steady State Load 2
: EA-C-PAL-01-03563-02 Containment Sump NPSH Evaluation 0
: EA-EAR-97-0273 Evaluation of 4 November 1996 Shutdown Cooling Heat Exchanger Performance Test T-365 0
: EA-EAR-2001-0333-01 Generation of ESS Pump Performance Curves for use with the Pipe-Flo ESS Hydraulic Model 5
: EA-EC157-01 345 KV System Voltage Drop with LOCA - Replacement SUT 1- 2 0
: EA-EC-235-01 Assessment of the High Pressure Air System's Capacity to Cycle Valves in the West Engineering Safeguards 0
: EA-EC496-001 Evaluation of Downcomer, Floor Drain, and Sump Vent Screens for
: GSI-191 Resolution 1
: EA-EC496-04 SFS Surface Area, Flow and Volume 1
: EA-EC6432-01 Palisades Emergency Diesel Generator Fuel Oil Storage Requirements 1
: EA-EC7107-01 Palisades
: GSI-191 Downstream Effects Evaluation of ECCS Components 2
: EA-EC-8349-04 Post LOCA Boric Acid Precipitation Analysis for Palisades in Support of Replacement of TSP with NaTB as the Containment Sump Buffer Agent 0
: EA-EC9600-01 Functionality of Equipment in EDG Room at an Elevated Temperature of 121F 1
: EA-EC-11464-01 Second Level Undervoltage Time Delay Relays 162-153 and 62-154 Uncertainty Analysis 0
: EA-EC-11464-02 First Level Undervoltage Relays 127-1 and 127-2 Drift Calculations 0
: EA-EC-11464-03 First Level Inverse Time Undervoltage Relays 127-1 and 127-2 Uncertainty Analysis 0
: EA-EC19401-01 Uncertainty Calculation for 2400V Safety Bus Voltage Meters 0
: EA-EC3181717-01 Analysis of the Low Flow Testing of the Engineered Safeguards System Pumps 0
: EA-ELEC08- 0008 SIRW Tank Level Switch Position Uncertainty Calculation 0
: EA-ELEC-AMP-016 Calculate the Cable Ampacity for Containment Spray 1
: EA-ELEC-AMP-030 Capability of the 2400V Feeder Cables to Buses 1C and 1D from the Startup Transformer 1-2 2
: EA-ELEC-CABLE-A1208-1 2.4KV Cable Ampacity for P-52B 0
: EA-ELEC-CABLE-A1210-1 2.4KV Cable Ampacity for P-54A 0
: EA-ELEC-EDSA-01 Auxiliary AC System EDSA Model Development and Verification and Validation 2
: EA-ELEC-EDSA-03 LOCA with Offsite Power Available 1,2
: EA-ELEC-EDSA-04 Second Level Undervoltage Relay Setpoint Determination (SLUR) 0
: EA-ELEC-EDSA-05 Fast Transfer Analysis 2
: EA-ELEC-EDSA-06 AC Short Circuit Analysis and
: EC 5000122058 2
: EA-ELEC-LDTAB-005 Emergency Diesel Generators 1-1 and 1-2 Steady State Loadings 9,10
: EA-ELEC-LDTAB-013 Worst Case Cable Loading Between SUT 1-2, and Buses 1C and 1D 0
: EA-ELEC-LDTAB-019 Auxiliary Power System Measured Load Analysis 0
: EA-ELEC-VOLT-010 Maximum and Minimum Station Power Voltages 0
: EA-ELEC-VOLT-01A Dynamic Response of Emergency Diesel Generators and ECCS Motor Acceleration Times 1
: EA-ELEC-VOLT-006 Determine the Terminal Voltage at the 46 Safety-Related Motor Operated Valves 1
: EA-ELEC-VOLT-033 Second Level Undervoltage Relay Setpoint 1
: EA-ELEC-VOLT-034 Calculation of VT Burden and Ratio Correction Factor for 2400V Class 1E Buses 0
: EA-ELEC-VOLT-036 Station Power Transformers No. 11, 12, 19, and 20 Tap Change -2.5 percent
: 0
: EA-ELEC-VOLT-037 Degraded Voltage Calculation for the Safety-Related MOVs 3
: EA-ELEC-VOLT-039 Stuck SGT 1-1 Tap Changer and Subsequent Station Power Voltages 0
: EA-ELEC-VOLT-050 Motor Control Center Control Circuit Voltage Analysis 3
: EA-ELEC-VOLT-051 MCC Power Circuit Minimum Required Voltage Analysis 1
: EA-ELEC-VOLT-053 Preferred AC Voltage Analysis 0
: EA-GL-8910-O1 Generic Letter 89-10 MOV Thrust Window Calculations 4
: EA-GOTHIC-04-05 Development of LOCA Containment Response Base Deck 2
: EA-GOTHIC-04-06 Development of MSLB Containment Response Base Deck 2
: EA-GOTHIC-04-08 Containment Response to LOCA Using GOTHIC 7.2a 3
: EA-GOTHIC-04-09 Containment Response to a MSLB Using GOTHIC 7.2a 3
: EA-MOD-2005-004-03 ESS Flow Rates and Pump NPSH During Recirc Mode with CSS Throttling 4
: EA-PIPEFLO-ESS-02 Pipe-Flo Professional 2007a Integrated Hydraulic Model of the Containment Spray, High Pressure and Low Pressure Safety Injection Systems 1
: EA-PLTB-04 Pressure Looking and Thermal Binding Review for Appendix R Safe Shutdown Power Operated Gate Valves 0
: EE-EDG-01 Evaluation of Maximum Diesel Room Temperature 0
: MPR-4105 Technical Evaluation of EDG Frequency and Voltage Variations in Support of Operability Determination for Palisades 1
: NB-PSA-ETSC Mode 4 LOCA Load Recovery Period Basis. 4
: NEI-1149-014 Palisades Design Basis AST MHA/LOCA Radiological Analysis 4
: SUT1-2/SUT1-2/ALTC Startup Transformer 1-2 Load Tap Changer Automatic Controls 0
: CORRECTIVE ACTION DOCUMENTS GENERATED DUE TO THE INSPECTION Number Description or Title Date
: CR-PLP-2014-04385 Merlin Drawing Revision Conflict For M0265BC Sheet 5 9/8/14
: CR-PLP-2014-04406 Conditions Identified During A Tour Of The West Engineered Safeguards Room 9/10/14
: CR-PLP-2014-04445 Indications Of White, Dry Boric Acid Inside The Insulation Box For
: LT-0332A, SIRW LEVEL TRANSMITTER, and
: LT-0332B, SIRW LEVEL TRANSMITTER 9/11/14
: CR-PLP-2014-04446 NRC Inspector Identified a Degraded Jumper Connection On A Ground Cable 9/11/14
: CR-PLP-2014-04450 Electrical Penetrations of Reactor Containment 9/11/14
: CR-PLP-2014-04472 NRC Questions Whether it is Appropriate to Have a Design Basis Calculation Which States 3.6 Percent Air Entrainment Could Occur 9/12/14
: CR-PLP-2014-04491
: EA-ELEC-VOLT-39, Stuck SGT 1-1 TAP Changer and Subsequent Station Power Voltages, has not been updated 9/15/14
: CR-PLP-2014-04495 NRC Inspectors Involved With the 2014 CDBI Questioned the Worst Case Load Assumption
: 9/15/14
: CR-PLP-2014-04496 NRC Inspectors Involved With the 2014 CDBI Questioned the Worst Case Load Assumption 9/15/14 
: CORRECTIVE ACTION DOCUMENTS GENERATED DUE TO THE INSPECTION Number Description or Title Date
: CR-PLP-2014-04413 Calculation
: EA-ELEC-VOLT-018, Which is Referenced In Design Basis Document 3.04, Could Not Be Found 9/10/14
: CR-PLP-2014-04450 FSAR Unclear On Requirements for Electrical Protection for Containment Penetrations 9/11/14
: CR-PLP-2014-04491 Calculation
: EA-ELEC-VOLT-039, Which Analyzes Maximum Voltage Change During Stuck Tap Condition for a Load Tap Changing Transformer, Does Not Bound Minimum Allowable Switchyard Voltage 9/15/14
: CR-PLP-2014-04495 Non-Conservative Transient Load Analysis for 2.4kV Supply Breaker to Bus 1C 9/15/14
: CR-PLP-2014-04496 Non-Conservative Transient Load Analysis for 2.4kV Supply Breaker to Bus 1D 9/15/14
: CR-PLP-2014-04665 Process a Revision to Calculation
: EA-C-PAL-95-0877D to Address the Conditions Identified in Condition Reports
: CR-PLP-2014-04472 and
: CR-PLP-2014-04665, Includes Operability Evaluation of ESS Pumps 10/9/14
: CR-PLP-2014-04672 As Presently Designed, The Thermal Overload Relays (TOR) For Six Safety-Related Motor Operated Valves Will Not Alarm Under Certain Overload Conditions 9/24/14
: CR-PLP-2014-04679 The Current Range (325-375kw) Within
: RE-131 Doesn't Bound The Largest Calculation Load of P-8A 9/25/14
: CR-PLP-2014-04680 The Current Range (325-375kw) Within
: RE-131 Doesn't Bound The Largest Calculation Load of P-66A 9/25/14
: CR-PLP-2014-04681 Incorrect Acceptance Criteria Limits for Leak Testing of
: CV-3027 and
: CV-3056 9/25/14
: CR-PLP-2014-04682 Time delay Between a Degraded Voltage Condition and Actuation of the Transfer from Offsite Power to the Diesel Generators is Ambiguous in Calculation
: EA-ELEC-EDSA-03 9/25/14
: CR-PLP-2014-04696 Diesel Voltage and Frequency Limits Unanalyzed 9/26/14
: CR-PLP-2014-04755 Improper Quality Classifications for Valve Sub-Components 9/30/14
: CR-PLP-2014-04815 Segment of Non-Safety-Related Tubing Installed in Safety-Related System 10/2/14
: CR-PLP-2014-04858 Lack of a Calculation that Establishes Total Time Delay, Including Loop Uncertainties, Between a Degraded Voltage Condition And Actuation of the Transfer from Offsite Power to the Diesel Generators 10/7/14
: CR-PLP-2014-04860 The Cables from Start-Up Transformer 1-2 (EX-04) to Buses 1C (EA-11) and 1D (EA-12) are Undersized 10/7/14
: CR-PLP-2014-04864 EC That Changed The 2400/480 Station Transformer Taps To A 2.5 Percent Boost Setting In 1995 Did Not Bound Worst Case High Voltage Conditions 10/8/14
: CR-PLP-2014-04874 NRC Question on Flow Testing of Components in the Closed Cycle Cooling Water Program 10/8/14 
: CORRECTIVE ACTION DOCUMENTS GENERATED DUE TO THE INSPECTION Number Description or Title Date
: CR-PLP-2014-04881 Missed Surveillance For CS P-54A Due to Instruments Being Out Of Calibration Per The Requirements Of The ASME Code 10/8/14
: CR-PLP-2014-04897
: AOP-30, Loss of Shutdown Cooling, Attachment 8, Align Idle LPSI Pump Suction to the SIRW Tank When on Shutdown Cooling, May Not Be Adequate 10/9/14
: CR-PLP-2014-04901 Transmission Network Model that Predicts the Change In Switchyard Voltage as a Result of a LOCA Does Not Consider Change in Plant Loading Imposed On Switchyard 10/9/14
: CR-PLP-2014-04902 Motors That Are Undersized With Respect To Their Mechanical Loads Have Not Been Analyzed For Thermal Effects 10/9/14
: CR-PLP-2014-04903 Degraded Voltage Monitor Total Delay-Time not in TS 3.3.5.2 10/09/14
: CR-PLP-2014-04912 NRC Questions the Adequacy of the Testing Performed to Ensure E-60A/B Remain Qualified to the Capability Assumed During Design Basis Events 10/10/14
: CR-PLP-2014-04915 Motor Operated Valve Calculation
: EA-GL-8910-01 Uses Obsolete Electrical Calculation
: EA-ELEC-VOLT-037 for Input Data Regarding Minimum Voltages to Valve Motors 10/10/14
: CORRECTIVE ACTION DOCUMENTS REVIEWED DURING THE INSPECTION Number Description or Title Date A-NL-92-079 NRC Inspection Report 91-19 (EDSFI) Reply to Open Item 91-19-03, "Overloading of Buses 1C and 1D Feeder Cables from Startup Transformer" 3/29/95 A-NL-92-111 Spurious Diesel Generator Starts Due To Degraded Voltage Relay Time Delay Setting 3/9/95 A-PAL-92-066 Shutdown Cooling Heat Exchanger Performance Testing 12/16/92
: AR 00870121 Inadequate Guidance for Operations When Outside Air Temperature Exceeds 95F 7/26/05
: AR 199978 Revise PMS To Replace
: RO-98 Test Gauges With M&TE 4/28/14
: CE 01066273-01 Excluded Required Equipment in
: OPR 108 12/7/06 C-PAL-94-0728JJ No Heat Exchanger Performance Validation Testing is Performed on the Shutdown Cooling Heat Exchangers 12/9/96 C-PAL-94-0728W Complete Assessment of Performance of Key Safety Systems Against the Plant Design Basis 5/2/95 C-PAL-97-1521 Heat Balance Discrepancies Recorded in Special Test T-365 12/8/97
: CR-PLP-2006-05443 Level Switch
: LS-0329 Instrument Uncertainties 11/15/06
: CR-PLP-2006-05479 EDG Room Cooling Intake Louvre Screens Dirty 11/16/06 
: CORRECTIVE ACTION DOCUMENTS REVIEWED DURING THE INSPECTION Number Description or Title Date
: CR-PLP-2006-05805
: OPR 000108 Failed to Consider Elevated Temperatures on Several Components 12/7/06
: CR-PLP-2006-05854 EDC Cooling Fan V-24C Discrepancies 12/11/06
: CR-PLP-2006-05897 Design Calculation
: 01067491 Does Not Consider Frequency Variation in Calculating Load 12/31/06
: CR-PLP-2007-02040 Level Switch
: LS-0329 Setpoint 5/15/07
: CR-PLP-2008-04580 D/G Load Calc Did Not Account For Worst Case Load from CAC Fan Motors 11/7/08
: CR-PLP-2008-04707 CDBI Team Questioned Using a Water Level Only 1 Inch Below Fuel Oil Suction Height 11/19/08
: CR-PLP-2009-00477 Containment Spray Pump, P-54A, Has Very Little Clearance Between Shaft Coupling and Shaft Keyway 2/4/09
: CR-PLP-2009-05533 CCW Pumps Lack Adequate Inservice Testing Margin 12/3/09
: CR-PLP-2009-05534 Containment Spray Pumps (CSS) Lack Inservice Testing Margin 12/3/09
: CR-PLP-2010-01331 NRC Resident Has Questions On
: QO-15 3/31/10
: CR-PLP-2010-01734 Plant Response to
: IN 2010-09, Importance of Understanding Circuit Breaker Control Panel Indications 05/11/10
: CR-PLP-2010-03083 Change in Gas Void Point/Size
: 7/27/10
: CR-PLP-2010-05181 Technical Specification Test
: RO-98 Pump Test Results Low in Their Acceptance Band 10/17/10
: CR-PLP-2010-06434 Transition of fire protection to NFPA 805 10/18/10
: CR-PLP-2011-03087 Issue Identified During 2011 CDBI
: RFI 167 6/21/11
: CR-PLP-2011-03221 Failure to Adequately Evaluate the Enclosure Installed Over the 1F/1G Buses 6/27/11
: CR-PLP-2011-03419 Dripping Water in East Engineered Safeguards in the Vicinity of P-54A Containment Spray Pump 7/11/11
: CR-PLP-2011-03835 Water Was Found Dripping from the Overhead East Engineered Safeguards Cooler in the Vicinity of P-54 A Spray Pump 8/4/11
: CR-PLP-2011-03858 LOCA Could Occur in Mode 4 8/5/11
: CR-PLP-2011-04749 Boric Acid Residue Discovered on Several Components 9/21/11
: CR-PLP-2011-06313 No Uncertainty Analysis for Back-Leakage into SIRW Tank 11/17/11
: CR-PLP-2012-02124 Extent of Condition for
: CR-PLP-11-6818, EQ Submergence Values Outside Containment 4/2/12 
: CORRECTIVE ACTION DOCUMENTS REVIEWED DURING THE INSPECTION Number Description or Title Date
: CR-PLP-2012-02382 Leakage from the Primary Coolant System to the SIRW Tank
: 4/10/12
: CR-PLP-2012-05054 Potential Impact of Foreign Material Identified in CR
: PLP-2012-05049 on the ECCS Pumps 7/13/12
: CR-PLP-2012-05553 Post-Accident Water Temperature in Containment Greater Than Air Temperature, Equipment EQ Needs Evaluation 8/8/12
: CR-PLP-2012-06148 Lack of Complete Electrical Protective Coordination for Appendix R 9/11/12
: CR-PLP-2012-06148 Electrical Coordination Will Not Support Transition to NFPA 805
: 9/11/12
: CR-PLP-2012-06795 Shutdown Cooling Heat Exchanger (E-60A and E-60B) Inspections Removed from 1R23 Scope 10/18/12
: CR-PLP-2013-00076 2014 CDBI Pre-Inspection Self-Assessment 12/23/13
: CR-PLP-2013-01213 Diesel Generator Loading Calculation Non-Conservative 3/20/13
: CR-PLP-2013-02674
: RIS 2013-05; Relationship Between GDC and Tech Spec Operability 6/17/13
: CR-PLP-2013-03894 AOV Calculations Not Revised 9/3/13
: CR-PLP-2013-04003 Condensation from Room Cooler Dripping onto P-54A, CSS Pump and other NRC Identified Issues 9/10/13
: CR-PLP-2013-04799 P-52B CCW Pump Has Oil Leak 11/6/13
: CR-PLP-2013-04843 Green OOZE on Relay 150-1 Terminals 11/08/13
: CR-PLP-2013-04940 As Found Thread Engagement Issues on Cooler for P-54A Containment Spray Pump 11/19/13
: CR-PLP-2014-00042 Additional K-Line 480V Circuit Breakers Subject to ABB Part 21 1/03/14
: CR-PLP-2014-00550 Air And Oil Leak on
: FCV-3057A 1/24/14
: CR-PLP-2014-01679 P-54A Containment Spray Pump Low Differential Pressure During Performance of
: RO-98.
: 2/25/14
: CR-PLP-2014-03841 No Evidence Found that Time Critical Operator Action Validation was Performed Since 2011. 7/23/14
: CR-PLP-2014-04881 Missed Surveillance of CS Pump P-54A Risk-Evaluation 10/9/14
: DRAWINGS Number Description or Title Revision E-1 Sheet 1 Single Line Meter and Relay Diagram 480 Volt Motor Control Center Warehouse 83 
: DRAWINGS Number Description or Title Revision E-11 Sheet 1 Schematic Meter and Relay Diagram 2.4 KV System 38 E-12 Sheet 1 Schematic Meter and Relay Diagram 2.4 KV and 480V Systems 40 E-12 Sheet 2 Schematic Meter and Relay Diagram 2.4 KV and 480V Systems 9 E-17 Sheet 10 Logic Diagram 2400 Volt Load Shed 10 E-17 Sheet 11 Logic Diagram Diesel Start 2 E-17 Sheet 13 Logic Diagram Diesel Generator Breakers 8 E-17 Sheet 14 Logic Diagram Bus 1C and 1D Incoming Breakers 9 E-17 Sheet 18A Logic Diagram Safeguard Transformer 1-1 3 E-17 Sheet 5A Containment Spray Isolation Valves Logic Diagram 0 E-17 Sheet 8 Logic Diagram Main Generator Protection 8 E-17 Sheet 9 Logic Diagram Turbine-Generator Trips and Fast Transfer 24 E-129 Sheet 44 Schematic Diagram Circuit Breaker 152-210 0 E-237 Sheet 1 Schematic Diagram Containment Spray Valves 17 E-237 Sheet 1A Schematic Diagram Containment Spray Valves 6 E-244 Sheet 8 Schematic Diagram Safety Injection Motor Operated Valves 13 E-244 Sheet 9 Schematic Diagram Safety Injection Motor Operated Valves 13 E-246 Schematic Diagram SIRW Tank And Containment Sump Valves - Circuit No. 2 7 E-246 Sheet 1 Schematic Diagram SIRW Tank and Containment Sump Valves - Circuit 1 24 E-246 Sheet 2 Schematic Diagram SIRW Tank and Containment Sump Valves - Circuit 1 29 E-246 Sheet 2A Schematic Diagram SIRW Tank and Containment Sump Valves - Circuit 2 3 E-251 Sheet 1 Schematic Diagram Containment Spray Pump P54A 17 E-251 Sheet 1A Schematic Diagram Containment Spray Pump P54A 7 E-251 Sheet 3 Schematic Diagram Containment Spray Pump P54C 2 E-259 Sheet 3A Schematic Diagram Component Cooling Pump P52B 2 E-3 Sheet 1 Single Line Meter and Relay Diagram 2400 Volt System 50 E-5 Sheet 5B Single Line Meter and Relay Diagram 480 Volt Motor Control Centers 12 M-1 Equipment Location Reactor Building Plan of El. 570'-0" 14 M-136 Penetrations and Inserts 5 M-202 Piping and Instrument Diagram Chemical and Volume Control System 76 M-203 Safety Injection, Containment Spray, and Shutdown Cooling System 27 M-203 Sht. 2 Piping and Instrument Diagram Safety Injection, Containment Spray and Shutdown Cooling System 26 M-203 Sht. A System Diagram Safety Injection, Containment Spray and Shutdown Cooling System 7 M-204 Safety Injection, Containment Spray, and Shutdown Cooling System 8 
: DRAWINGS Number Description or Title Revision M-204 Sht. 1 Piping and Instrument Diagram Safety Injection, Containment Spray and Shutdown Cooling System 84 M-204 Sht. 1A Piping and Instrument Diagram Safety Injection, Containment Spray and Shutdown Cooling System 43 M-204 Sht. 1B Piping and Instrument Diagram Safety Injection Containment Spray 41 M-204 Sht. A System Diagram Safety Injection, Containment Spray and Shutdown Cooling System 8 M-209 Sht. 1 Piping and Instrument Diagram Component Cooling System 67 M-209 Sht. 2 Piping and Instrument Diagram Component Cooling System 33 M-209 Sht. A System Diagram Component Cooling System 9 M-211 Sht. 1 Piping and Instrument Diagram Dirty Waste and Gaseous Waste 78 M-225 High Pressure Air Operated Valves 6 M-31 Piping Drawings Area 2 26 M-347 Sht. 14 Pressure Safety (Relief) Valve Data Sheet 2 M-7 Equipment Location 13 SOD_SI_02_r03 Safety Injection, Containment Spray System 3
: VEN-C18 Sheet 67 SIRW Tank Erection Diagram - Hold Down Detail 9
: VEN-C18 Sheet 96 SIRW Tank Bottom Installation 0
: VEN-M-107 Sheet 2278 Stress Isometric 10
: VEN-M-107 Sheet 2281 Stress Isometric 10
: VEN-M-107 Sheet 2282 Stress Isometric 4
: VEN-M-241BC Sheet 33 Double Disc Gate Valve 0
: VEN-M-241BC Sheet 35 Double Disc Gate Valve 0
: VEN-M-255 Sheet 3 Drag Valve 0
: VEN-M-255 Sheet 4 Drag Valve 0
: VEN-M-255 Sheet 5 Drag Valve 0
: WD 950 Single Line Meter and Relay Diagram 125Vdc, 120V Instrument and Preferred AC System 57   
: 10
: CFR 50.59 DOCUMENTS (SCREENINGS/SAFETY EVALUATIONS) Number Description or Title Date
: SDR-99-0884 Cancellation of TS Surveillance Procedures and Revision of FSAR
: 7/22/99
: MISCELLANEOUS
: Number Description or Title Date or Revision
: Letter from Dennis M. Crutchfield, NRC, to David P. Hoffman, Consumers Power Company, "SEP Topic
: VIII-4, Electrical Penetrations of Reactor Containment" (ADAMS Accession No. ML8104080152) 3/26/81
: Letter from Kerry A. Toner, Consumers Power Company, to Dennis M. Crutchfield, NRC, "SEP Topic
: VIII-4, Electrical Penetrations of the Reactor Containment" (ADAMS Accession No. ML8210190459) 10/12/82
: Letter from Kerry A. Toner, Consumers Power Company, to Dennis M. Crutchfield, NRC, "SEP Topic
: VIII-4, Status Update of Program to Evaluate the Adequacy of Penetration Protection from Overload and Short-Circuit Conditions" (ADAMS Accession No. ML8302240273) 2/11/83
: Letter from Robert A. Vincent, Consumers Power Company, to Dennis M. Crutchfield, NRC, "SEP Topic
: VIII-4, Electrical Penetrations of Reactor Containment" (ADAMS Accession No. ML8106180170) 6/15/81
: Letter from Robert A. Vincent, Consumers Power Company, to Dennis M. Crutchfield, NRC, "SEP Topic
: VIII-4, Electrical Penetrations of the Reactor Containment" (ADAMS Accession No. ML8111200805) 11/16/81
: Letter from Thomas V. Wambach, NRC, to David J. VandeWalle, Consumers Power Company, "Integrated Plant Safety Assessment Report (IPSAR) Section 4.26, Electrical Penetrations of Reactor Containment - Palisades Plant" (ADAMS Accession No. ML8306160396) 6/10/83
: White Paper from Fauske and Associates:
: What Determines the Condition Of Significant Air Intrusion for the Draindown For Quiescent Water Inventories? 9/23/14 13-0327 Process Applicability Determination for
: EC 42422 0 1C-108-J9400-162-153 Protective Relay Setting - Bus 1C Second Level Under Voltage Time Delay Relay 162-153 4 1C-108-J9400-162-154 Protective Relay Setting - Bus 1D Second Level Under Voltage Time Delay Relay 162-154 3 70P-017 Engineering Specification for Shutdown Cooling Heat Exchanger 3
: 988055 P-54A Containment Spray Pump Oil Test Results 5/8/13 
: MISCELLANEOUS
: Number Description or Title Date or Revision
: 988059 P-54A Containment Spray Pump Motor Inboard Bearing Oil Test Results 5/8/13
: 988060 P-54A Containment Spray Pump Motor Outboard Bearing Oil Test Results 7/1/13 ASCO Catalog 32 2, 3 and 4 Way Solenoid Valves Vendor Manual 0 ASME OMb Code-2003 Addenda to ASME OM Code-2001 Code for Operation and Maintenance of Nuclear Power Plants 8/29/03 Attachment 9.16 SNAPSHOT Assessment of Time Critical Operator Actions. 5/27/11 Attachment 9.4 SNAPSHOT Assessment of Time Critical Operator Actions. 9/3/14 CMT952010029 Enforcement Conference - Inoperable Diesel Generators - Inspection Report 94020 4/30/95
: CR-PLP-2014-04881 Missed Surveillance of CS Pump P-54A Risk Evaluation 10/9/14
: CV-3027 Diagnostic Testing Results -
: WO 52325715 4/24/12
: CV-3031 IST - Valve Component Information
: 0
: CV-3057 IST - Valve Component Information
: 0
: DBD-1.01 Component Cooling Water System 8
: DBD-1.01 Design Basis Document for Component Cooling Water System 8
: DBD-2.01 Low Pressure Safety Injection System 10
: DBD-2.01 Design Basis Document for Low Pressure Safety Injection System 10
: DBD-2.02 Design Basis Document for High-Pressure Safety Injection System 9
: DBD-2.03 Containment Spray System 8
: DBD-2.03 Design Basis Document for Containment Spray System 8
: DBD-3.04 Design Basis Document:
: 2400V AC System 7
: DBD-3.05 Design Basis Document:
: 480V AC System 6
: DBD-4.03 Design Basis Document:
: Preferred AC System 7
: DBD-4.04 Design Basis Document:
: Uninterruptible Power Supply 5
: DBD-5.03 Design Basis Document:
: Emergency Diesel Generator Performance Criteria 8
: DBD-5.04 Design Basis Document:
: Load Shedding Circuits 5
: DBD-5.05 Design Basis Document:
: Design Basis Accident and Normal Shutdown Sequencer 7
: DBD-6.01(TR) Design Basis Document:
: Grid Interface Topical Report 4
: DBD-6.02 Design Basis Document:
: 345KV Switchyard 4
: DPR-20 Renewed Facility Operating License 251
: DRN-08-01700 EOP Supplement 42, Not Tripping HPSI for Loss of Subcooling 9/5/08 
: MISCELLANEOUS
: Number Description or Title Date or Revision
: DRN-08-02217 Section 2.0 Post RAS Actions Step "N" Should be Identified as a Continuous Step (Circle C), so Operators can Continue to Perform Later Steps 12/2/08
: DRN-12-01684 Commitments in Procedure do not Match Commitment List 5/14/12
: DRN-14-01118 EOP Supplement 42 9/12/14
: DRN-14-01222
: SOP-3 Revision to Stage Equipment for Venting LPSI Discharge Piping with Valve
: MV-ES3420 per
: AOP-30, Attachment 8, Align Idle LPSI Pump Suction to the SIRW Tank When on SDC. 10/7/14 DWG. No. 5935 M-347 Sheet 14 Pressure Safety (Relief) Valve Data Sheet 2
: EAR-99-0081 CVCS Declassification 0
: LER 80-003 Licensee Event Report 80-003 - Containment Spray 5/13/80 Letter Response to
: NUREG-0737 12/19/80 Letter (9002120116) Response to Generic Letter 89-13, Service Water System Problems Affecting Safety-Related Equipment 1/29/90 Letter (ML052410206) Supplementary Information for the Palisades Application for Renewed Operating License Resulting from Aging Management Programs Audit 8/25/05
: LR-AMPBD-06-CCCW Closed Cycle Cooling Water Program 3
: LTR-PSA-14-01 Mode 4 LOCA Analysis 10/7/14 M0001GD 0999 Fabricating Engineers Inc. Technical Manual for Shutdown Cooling Heat Exchanger 0 ML050940446 Palisades Nuclear Plant Application for Renewed Operating License 3/22/05 ML071800216 License Amendment Request:
: Replacement of Containment Sump Buffer 6/28/07
: NB-PSA-SY-CSS Palisades Nuclear Plant Probabilistic Safety Assessment System Notebook - Containment Spray System 0
: PL-CCW Component Cooling Water 7
: PL-CSS Containment Spray System Lesson Plan - CV3001, CV3002, and
: CV-3030 9
: PL-CSS Containment Spray System 9
: PLJPM-LOR-SI-14 JPM - PERFORM
: PRE-RAS ACTIONS IAW EOP SUPPLEMENT 42 0
: PLJPM-LOR-SI-15 JPM - PERFORM
: PRE-RAS ACTIONS IAW EOP SUPPLEMENT 42 0
: PLJPM-LOR-SI-16 JPM - PERFORM POST RAS ACTIONS 2
: PLJPM-LOR-SI-17 JPM - PERFORM POST RAS ACTIONS 1 
: MISCELLANEOUS
: Number Description or Title Date or Revision
: PLJPM-LOR-SI-18 JPM - PERFORM POST RAS ACTIONS 2
: PLJPM-LOR-SI-19 JPM - PERFORM POST RAS ACTIONS 1
: PLSEG-LOR-13F-02 Scenario -
: AOP 30 4
: PLSEG-LOR-13G-02 Scenario - EOP 4.0 0
: PLSEG-LOR-14-CDBI-1
: EOP-4.0 LBLOCA Scenario for 2014 CDBI. 9/25/14
: PLSEG-LOR-14-CDBI-2 Mode 4 LOCA Scenario for 2014 CDBI. 10/7/14
: PLSEG-LOR-LOCA Scenario - EOP 4.0 Loss of Coolant Accident 0
: PL-SIS Safety Injection System 6
: QO-16 Basis Document for
: QO-16:
: Inservice Test Procedure - Containment Spray Pumps 16 Reply
: EC 53093 Evaluation For Potential Air Entrainment at the Lowest Levels of SIRW Tank Inventory Considering A Single Failure More limiting than the One Considered in
: EA-C-PAL-95-087DD 9/24/14
: RI-38 Basis Basis Document for SIRW Tank Level Instrument Calibration 10
: SDR-99-0884 Cancellation of TS Surveillance Procedures and Revision of FSAR
: 7/22/99
: SEP-APJ-PLP-101 Mechanical Containment Penetration Basis 0
: SEP-ISI-PLP-002 ASME Code Boundaries for ASME Section XI Inservice Inspection Program 1
: SEP-ISI-PLP-002 ASME Code Boundaries For Section XI Inservice Inspection Program 1
: SEP-PLP-IST-102 Inservice Testing of Selected Safety-Related Pumps 0
: SOP-15 Service Water System 0 USI A-46 Equipment Evaluation Report 5/3/95
: MODIFICATIONS
: Number Description or Title Date or Revision
: FC-718 RAS Logic Seal-In Circuit Addition 12/19/86 
: OPERABILITY EVALUATIONS
: Number Description or Title Date or Revision
: CR-PLP-2014-4696 CA-1 Operability for all SSCs Within Maximum Variations of EDG Frequency and Voltage Allowed by Technical Specifications 10/22/14
: OPR 000108 Operability Recommendation - EDG Room Temperature 2
: PROCEDURES
: Number Description or Title Revision 4.02 Control of Equipment 71 Administrative Procedure 10.41 Site Procedures Process 48 Administrative Procedure 10.51 Writer's Guideline for Site Procedures 21 Administrative Procedure 4.06 Emergency Operating Procedure Development and Implementation 21 Administrative Procedure 4.66 Abnormal Operating Procedure Development and Implementation 5 Administrative Procedure TCA Control of Time Critical Operator Actions 3
: AOP-23 Primary Coolant Leak 1
: AOP-30 Loss of Shutdown Cooling 1
: AOP-36 Loss Of Component Cooling 0
: AOP-37 Loss of Instrument Air 0
: ARP-4 Reactor Water Level Low Alarm Response Procedure 62
: ARP-3 Electrical Auxiliaries and Diesel Generator Scheme
: EK-05 (EC-11) 74
: ARP-7 Auxiliary Systems Scheme
: EK-11 (C-13) 92
: CEN 152 Combustion Engineering LOCA Recovery Guideline 5.3
: EM-09-16 Master Heat Exchanger Testing Plan 4 and 8
: EN-DC-178 System Walkdowns 7
: EN-DC-195 Margin Management 7
: EN-DC-219 Gas Accumulation Management 3
: EN-MA-145 Maintenance Standard for Torque Applications 3
: EN-OP-104 Operability Determination Process 7 EOP 4.0 Loss of Coolant Accident Recovery 23 EOP 4.0 Basis Loss of Coolant Accident Recovery Basis 14 EOP Intro Introduction to EOP System Basis
: 0 EOP Supplement 42 Pre and Post RAS Actions
: 7 EOP TCA EOP Time Critical Operator Action Basis 0
: EOP-4 Loss of Coolant Accident Recovery 23
: EOP-5.0 Steam Generator Tube Rupture Recovery 18
: EOP-9.0,
: HR-3 Functional Recovery Procedure 22
: ESSO-1 Containment Spray Header Fill 16 
: PROCEDURES
: Number Description or Title Revision
: GOP-14 Shutdown Cooling Operations 47
: MO-7A-1 Emergency Diesel Generator 1-1 86
: MO-7A-2 Emergency Diesel Generator 1-2 86
: NB-PSA-SM Probabilistic Safety Assessment Model Summary System Notebook 2
: NB-PSA-SSS SIRW Tank and Containment Sump Suction System Probabilistic Safety Assessment System Notebook 1 NPOA Nuclear Plant Operating Agreement 1
: ONP-17 Loss of Shutdown Cooling (SDC) 40
: QO-16 Inservice Test Procedure - Containment Spray Pumps 35
: QO-2 Recirculation Actuation System 44
: QO-5 Valve Test Procedure (Includes Containment Isolation Valves) 89
: RE-131 Diesel Generator 1-1 Load Reject 6
: RE-131/132 Technical Specification Surveillance Procedure Basis Document 1
: RE-132 Diesel Generator 1-2 Load Reject 6
: RE-137 Calibration of Bus 1C Undervoltage and Time Delay Relays 11
: RE-138 Calibration of Bus 1D Undervoltage and Time Delay Relays 11
: RI-38 SIRW Tank Level Instrument Calibration 9
: RO-119 Inservice Testing of Engineered Safeguards Valves
: CV-3027 and
: CV-3056 14
: RO-217 Technical Specification Leak Rate Testing of Engineered Safeguards Check Valves 7
: RO-98 Technical Specification Surveillance Procedure Basis Document 3
: RT-71K Class 2 System Functional Test for Shutdown Cooling System 10
: RT-71L Technical Specification Admin 5.5.2 Pressure Test Of ESS Pump Suction Piping 21
: SEP-HX-PLP-001 Master Heat Exchanger Testing Plan 11
: SOP-3 Safety Injection and Shutdown Cooling System 95
: SOP-3, Attachment 16 Engineered Safeguards System Checklist (Heat SDC) 95
: SOP-4 Containment Spray System 25
: SOP-16 Component Cooling Water System 44
: SOP-19 Nitrogen/Air Backup Stations 60
: SOP-30 Station Power 74
: SPS-E-17 Temporary Installation and Removal of Spare Circuit Breakers 24 T-205-A East Engineering Safeguards High Pressure Air System Performance Verification 9 
: PROCEDURES
: Number Description or Title Revision T-205-B West Engineering Safeguards High Pressure Air System Performance Verification 11 T-278-3A Nitrogen Station 3A Performance Test 8 T-365 Determination of Heat Transfer Capability of Shutdown Cooling Heat Exchangers E-60A and E-60B 1
: SURVEILLANCES (COMPLETED) Number Description or Title Date or Revision T-205-A East Engineering Safeguards High Pressure Air System Performance Verification 11/23/14 T-205-B West Engineering Safeguards High Pressure Air System Performance Verification 12/2/14 T-278-3A Nitrogen Station 3A Performance Test 2/19/14
: WO-PLP-52435851
: LPSI and Containment Spray Comprehensive Pump Test and Check Valves Test 2/25/14
: WO-PLP-52547674
: Inservice Test Procedure - Containment Spray Pumps 5/29/14
: WORK ORDERS
: Number Description or Title Date or Revision
: 178171-01 Clean EDG Room Cooling Air Inlet Louvre Screens 11/21/06
: 342334-01 Change SUT 1-2 (EX-04) Tap Changer Setpoint
: 51521714-01 Clean Door Louvre Screens 11/21/06
: 51521714-02 Repair Door Louvre Screens 11/21/06
: 51521714-03 Clean Wall Louvre Screens 11/21/06
: 52325512-01
: RI-14, SIRW Tank Level Switch Interlock Test 8/6/12
: 52430162-01
: RI-14, SIRW Tank Level Switch Interlock Test 3/6/14
: 52432473-01
: RT-92 - Inspect ECCS Train Cont Sump Suction Inlet 3/9/14
: 52435963-01 Containment Sump Clean-Out and Inspection 2/26/14
: WT-PLP-2010-00261 Update DBD 3.04 Table 3-2: "2400V AC Supply Cables, Design Ratings, Loading and Margins 6/2/10
: WT-PLP-2014-00216 WT Written to Document Actions Resulting from CDBI Focused Area Self-Assessment
: LO-PLP-2013-00076
: 7/17/14
==LIST OF ACRONYMS==
: [[USED]] [[°C Celsius Degrees °F Fahrenheit Degrees]]
: [[AC]] [[Alternating Current]]
: [[ADAMS]] [[Agencywide Document Access Management System]]
: [[AOP]] [[Abnormal Operating Procedure]]
: [[AOV]] [[Air-Operated Valve]]
: [[AR]] [[Action Request]]
: [[ARM]] [[Area Radiation Monitor]]
: [[ASME]] [[American Society of Mechanical Engineers]]
: [[BHP]] [[Brake Horsepower]]
: [[CAP]] [[Corrective Action Program]]
: [[CCW]] [[Component Cooling Water]]
: [[CDBI]] [[Component Design Bases Inspection]]
: [[CFR]] [[Code of Federal Regulations]]
: [[CS]] [[Containment Spray]]
: [[CVCS]] [[Chemical and Volume Control]]
: [[DBD]] [[Design Basis Document]]
: [[DC]] [[Direct Current]]
: [[DRS]] [[Division of Reactor Safety]]
: [[EC]] [[Engineering Change]]
: [[ECCS]] [[Emergency Core Cooling System]]
: [[EDG]] [[Emergency Diesel Generator]]
: [[EPRI]] [[Electric Power Research Institute]]
: [[EPU]] [[Extended Power Uprate]]
: [[EQ]] [[Equipment Qualifications]]
: [[ESS]] [[Engineered Safeguards System]]
: [[FIN]] [[Finding]]
: [[FSAR]] [[Final Safety Analysis Report]]
: [[GDC]] [[General Design Criteria]]
: [[GL]] [[Generic Letter gpm Gallons per Minute]]
: [[HELB]] [[High Energy Line Break]]
: [[HPSI]] [[High Pressure Safety Injection]]
: [[HVAC]] [[Heating, Ventilation and Air-Conditioning]]
: [[IEEE]] [[Institute of Electrical and Electronic Engineers]]
: [[IMC]] [[Inspection Manual Chapter]]
: [[IN]] [[Information Notice]]
: [[IP]] [[Inspection Procedure]]
: [[IR]] [[Inspection Report]]
: [[IR]] [[Issue Report]]
: [[ISI]] [[Inservice Inspection]]
: [[IST]] [[Inservice Testing kV Kilovolt]]
: [[LCO]] [[Limiting Condition for Operation]]
: [[LER]] [[Licensee Event Report]]
: [[LOCA]] [[Loss of Coolant Accident]]
: [[LPCI]] [[Low Pressure Coolant Injection]]
: [[MCC]] [[Motor Control Center]]
: [[MOV]] [[Motor-Operated Valve]]
: [[NCV]] [[Non-Cited Violation]]
: [[NEI]] [[Nuclear Energy Institute]]
: [[NFPA]] [[National Fire Protection Association]]
: [[NPSH]] [[Net Positive Suction Head]]
: [[NRC]] [[U.S. Nuclear Regulatory Commission]]
: [[NRR]] [[Nuclear Reactor Regulation]]
: [[PARS]] [[Publicly Available Records System]]
: [[PCS]] [[Primary Coolant System]]
: [[P&ID]] [[Piping and Instrumentation Drawing]]
: [[PI&R]] [[Problem Identification and Resolution]]
: [[PRA]] [[Probabilistic Risk Assessment psi Pounds Per Square Inch  psid Pounds Per Square Inch Differential psig Pounds Per Square Inch Gauge]]
: [[RIS]] [[Regulatory Issue Summary]]
: [[SDC]] [[Shutdown Cooling]]
: [[SDP]] [[Significance Determination Process]]
: [[SEP]] [[Systematic Evaluation Program]]
: [[SG]] [[Steam Generator]]
: [[SIRW]] [[Safety Injection Refueling Water]]
: [[SR]] [[Surveillance Requirement]]
: [[SSC]] [[Systems, Structures, and Components]]
: [[TI]] [[Temporary Instructions]]
: [[TS]] [[Technical Specification]]
: [[URI]] [[Unresolved Item Vac Volts Alternating Current]]
: [[VAC]] [[Volts Alternating Current]]
: [[VDC]] [[Volts Direct Current Vdc Volts Direct Current WO Work Order]]
: [[A.]] [[Vitale    -2-  In accordance with Title 10, Code of Federal Regulations (]]
: [[CFR]] [[) "Rules of Practice," a copy of this letter and its enclosure will be available electronically for public inspection in the]]
: [[NRC]] [[Public Document Room or from the Publicly Available Records System (]]
PARS) component of NRC's Agencywide Documents Access and Management System (ADAMS), accessible from the NRC Web site at http://www.nrc.gov/reading-rm/adams.html (the Public Electronic Reading Room). Sincerely,
Ann Marie Stone, Chief Engineering Branch 2 Division of Reactor Safety Docket No. 50-255 License No.
: [[DPR]] [[-20  Enclosure: Inspection Report 05000255/2014008   w/Attachment:  Supplemental Information cc w/encl: Distribution via]]
}}
}}

Revision as of 07:08, 1 July 2018

IR 05000255-14-008, 9/8/2014 - 11/4/2014, Palisades Nuclear Plant Component Design Bases Inspection (CDBI)
ML14338A848
Person / Time
Site: Palisades Entergy icon.png
Issue date: 12/02/2014
From: Stone A M
NRC/RGN-III/DRS/EB2
To: Vitale A J
Entergy Nuclear Operations
Stuart Sheldon
References
IR 2014008
Download: ML14338A848 (62)


Text

UNITED STATES NUCLEAR REGULATORY COMMISSION REGION III 2443 WARRENVILLE RD. SUIT E 210 LISLE, IL 60532

-4352 December 2, 2014 Mr. Anthony Vitale Vice-President, Operations Entergy Nuclear Operations, Inc.

Palisades Nuclear Plant 27780 Blue Star Memorial Highway Covert, MI 49043

-9530

SUBJECT: PALISADES NUCLEAR PLANT COMPONENT DESIGN BASES INSPECTION 05000255/2 014008

Dear Mr. Vitale:

On November 4, 2014

, the U.S. Nuclear Regulatory Commission (NRC)

completed a Component Design Bases Inspection (CDBI)

inspection at your Palisades Nuclear Plant

. The enclosed report documents the results of this inspection, which were discussed on November 4, 2014

, with you, and other members of your staff.

Based on the results of this inspection, ten NRC-identified findings of very low safety significance were identified. The finding s involved violation s of NRC requirements. However, because of their very low safety significance, and because the issues were entered into your Corrective Action Program, the NRC is treating the issues as Non-Cited Violations (NCVs) in accordance with Section 2.3.2 of the NRC Enforcement Policy. Additionally, one licensee-identified violation is listed in Section 4OA7 of this report.

If you contest the subject or severity of these NCVs, you should provide a response within 30 days of the date of this inspection report, with the basis for your denial, to the U.S. Nuclear Regulatory Commission, ATTN: Document Control Desk, Washington, DC 20555-0001, with a copy to the Regional Administrator, U.S. Nuclear Regulatory Commission

- Region III, 2443 Warrenville Road, Suite 210, Lisle, IL 60532

-4352; the Director, Office of Enforcement, U.S. Nuclear Regulatory Commission, Washington, DC 20555

-0001; and the Resident Inspector Office at the Palisades Nuclear Plant. In addition, if you disagree with the cross

-cutting aspect assigned to any finding in this report, you should provide a response within 30 days of the date of this inspection report, with the basis for your disagreement, to the Regional Administrator, Region III, and the NRC Resident Inspector at the Palisades Nuclear Plant

. In accordance with Title 10, Code of Federal Regulations (CFR) "Rules of Practice," a copy of this letter and its enclosure a copy of this letter, its enclosure, and your response (if any),

will be available electronically for public inspection in the NRC Public Document Room or from the Publicly Available Records System (PARS) component of NRC's Agencywide Documents Access and Management System (ADAMS), accessible from the NRC Web site at http://www.nrc.gov/reading

-rm/adams.html (the Public Electronic Reading Room).

Sincerely,/RA/

Ann Marie Stone, Chief Engineering Branch 2 Division of Reactor Safety Docket No. 50

-255 License No. DPR

-20

Enclosure:

Inspection Report 05000 255/2014008

w/Attachment:

Supplemental Information cc w/encl:

Distribution via LISTSERV Enclosure U.S. NUCLEAR REGULATORY COMMISSION REGION III Docket No:

50-255 License N o: DPR-20 Report No:

05000255/2014008 Licensee:

Entergy Nuclear Operations, Inc.

Facility:

Palisades Nuclear Plant Location:

Covert, MI Dates: September 8, 2014 through November 4, 2014 Inspectors:

S. Sheldon, Senior Engineering Inspector, Lead J. Corujo

-Sandin, Engineering Inspector, Mechanical C. Brown, Engineering Inspector, Electrical C. Zoia, Operations Engineer L. Rodriguez, Engineering Inspector, Observer H. Leake, Electrical Contractor C. Baron, Mechanical Contractor Approved by:

Ann Marie Stone, Chief Engineering Branch 2 Division of Reactor Safety i

SUMMARY OF FINDINGS

Inspection Report 05000255/2014008, 9/8/2014

- 11/4/2014

, Palisades Nuclear Plant Component Design Bases Inspection (CDBI).

The inspection was a 3

-week onsite baseline inspection that focused on the design of components. The inspection was conducted by regional engineering inspectors and two consultants. Ten Green finding s were identified by the inspectors. The finding s were considered Non-Cited Violations (NCVs) of NRC regulations. The significance of inspection findings is indicated by their color (i.e., greater than Green, or Green, White, Yellow, Red)and determined using IMC 0609, "Significance Determination Process" dated June 2, 2011.

Cross-cutting aspect s are determined using IMC 0310, "Aspects Within the Cross-Cutting Areas" effective date January 1, 2014.

All violations of NRC requirements are dispositioned in accordance with the NRC's Enforcement Policy dated Jul y 9, 2013. The NRC's program for overseeing the safe operation of commercial nuclear power reactors is described in NUREG

-1649, "Reactor Oversight Process" Revision 5, dated February 2014

.

A. NRC-Identified and Self-Revealing Findings

Cornerstone: Initiating Events

Green.

The inspectors identified a finding having very low safety significance and an associated Non-Cited Violation (NCV) of 10 CFR Part 50.36(c)(3), "Surveillance Requirements," for the failure to ensure the channel time delay for the degraded-voltage monitor was included in Technical Specification (TS) Surveillance Requirement (SR) 3.3.5.2.a. Specifically, the licensee fail ed to include in the TS SR the required time delay after the voltage relay trips before the preferred source of power is isolated and 1E electrical loads transferred to the stand-by Emergency Diesel Generator s (EDGs). This finding was entered into the licensee's Corrective Action Program and the licensee

's preliminary verification determined the degraded voltage monitors were still operable but degraded or non-conforming.

The performance deficiency was determined to be more than minor because if left uncorrected, it would have the potential to lead to more significant safety concern. Specifically, by not incorporating the total time delay requirements into the Technical Specifications

, (TS) the time could be changed without going through the TS change process, possibly leading to spurious trips of offsite power sources or possibly exceeding the accident analysis time is the FSAR. The inspectors determined the finding was of very low safety significance (Green) because it did not cause a reactor trip and the loss of mitigation equipment relied upon to transition the plant from the onset of the trip to a stable shutdown condition. The inspectors did not identify a cross-cutting aspect associated with this finding because the finding was not representative of the licensee's present performance.

(Section 1R21.3.b(

9))

Cornerstone: Mitigating Syste

ms

Green.

The inspectors identified a finding of very low safety significance and associated Non-Cited Violation of 10 CFR Part 50, Appendix B, Criterion III, "Design Control" for the failure to ensure the safety-related Engineered Safeguard Systems trains would not be adversely affected by air entrainment when aligned to the Safety Injection and Refueling Water (SIRW) Tank. Specifically, calculation EA

-C-PAL-0877D, assumed incorrectly only one train of the Engineered Safeguards System (ESS) was in operation when evaluating if the SIRW Tank reaches the limit for critical submergence during a tank drawdow n. As part of their corrective actions, the licensee re-evaluated the scenario s of concern, performed an operability evaluation, and implemented compensatory actions.

The performance deficiency was determined to be more than minor because it impacted the Equipment Performance attribute of the Reactor Safety, Mitigating Systems Cornerstone and adversely affected the cornerstone objective to ensure the availability, reliability, and capability of systems that respond to initiating events to prevent undesirable consequences

. Specifically, air entrainment into the ESS systems could potentially impact the operability of the system by air binding the pumps, reduce discharge flow, discharge pressure and/or delay injection

. The inspectors determined the finding was of very low safety significance (Green) because the finding was a deficiency affecting the design or qualification of a mitigating structure system or component (SSC) but the SSC maintained its operability. The inspectors did not identify a cross-cutting aspect associated with this finding because the finding was not representative of the licensee's present performance.

(Section 1R21.3.b(1))

Green.

The inspectors identified a finding of very low safety significance and associated NCV of 10 CFR Part 50, Appendix B, Criterion III, "Design Control," for the licensee's failure to ensure the incoming feeder cables from startup transformer 1

-2 to 2400 V safety-related Buses 1C and 1D were sized in accordance with their design basis, as described in Palisades FSAR Section 8.5.2. Specifically, the licensee failed to ensure the ampacity of the cables was at least as high as their maximum steady-state current. The licensee entered this finding into their Correction Action Program and verified the operability of the cables.

The performance deficiency was determined to be more than minor, because it impacted the Design Control attribute of the Reactor Safety,

Mitigating Systems Cornerstone and adversely affected the cornerstone objective to ensure the availability, reliability, and capability of systems that respond to initiating events to prevent undesirable consequences. Specifically, cables were undersized with respect to the loading that would automatically occur as the result of a design basis accident. The inspectors determined the finding was of very low safety significance (Green) because the SSC maintained its operability and functionality. This finding had a crosscutting aspect in the area of Human Performance, associated with the Design Margin component, because the licensee did not ensure that equipment is operated and maintained within design margins, and margins are carefully guarded and changed only through a systematic and rigorous process

. [H.6] (Section 1R21.3.b(

2))

Green.

The inspectors identified a finding of very low safety significance and associated NCV of 10 CFR Part 50, Appendix B, Criterion III, "Design Control," for the licensee's failure to ensure electric motors are sized in accordance with the design basis, as discussed in Palisades FSAR Section 6.2.3.1. Specifically, the horsepower ratings of certain motors are less than power demands of their driven equipment, and they were not analyzed to ensure overheating would not occur. The licensee entered this finding into their Correction Action Program with a recommended action to analyze the effect of the condition, and has verified the operability of the motors.

This performance deficiency was determined to be more than minor, because it impacted the Design Control attribute of the Reactor Safety, Mitigating Systems Cornerstone and adversely affected the cornerstone objective to ensure the availability, reliability, and capability of systems that respond to initiating events to prevent undesirable consequences. Specifically, motors serving loads with power demands in excess of the motor horsepower ratings were not analyzed to ensure that motor damage would not occur. The inspectors determined the finding was of very low safety significance (Green) because the SSC maintained its operability and functionality. This finding had a crosscutting aspect in the area of Human Performance, associated with the Design Margin component, because the licensee failed to ensure that equipment is operated within design margins, and margins are carefully guarded and changed only through a systematic and rigorous process. [H.6]

(Section 1R21.3.b(

3))

Green.

The inspectors identified a finding of very low safety significance and associated NCV of 10 CFR Part 50, Appendix B, Criterion III, "Design Control," for the licensee's failure to ensure that voltages on the 480V system do not exceed equipment ratings. Specifically, the licensee increased the output voltage of the supply transformers to the 480V safety-related buses by 2.5 percent, but failed to ensure the resulting voltages would not exceed equipment ratings when the system is powered from the station power transformer or emergency diesel generator. The licensee entered this finding into their Correction Action Program and verified the operability of the affected equipment.

The performance deficiency was determined to be more than minor, because it impacted the Design Control attribute of the Reactor Safety, Mitigating Systems Cornerstone a nd adversely affected the cornerstone objective to ensure the availability, reliability, and capability of systems that respond to initiating events to prevent undesirable consequences. Specifically, the licensee failed to verify or check the voltage increase on the 480V system to ensure th e maximum allowable voltage would not exceed equipment ratings. The inspectors determined the finding was of very low safety significance (Green) because the affected SSCs maintained their operability and functionality.

The inspectors did not identify a cross-cutting aspect associated with this finding, because the finding was not representative of the licensee's present performance.

(Section 1R21.3.b(

4))

Green.

The inspectors identified a finding of very low safety significance and associated Non-Cited Violation of Technical Specifications 5.5.7, "Inservice Testing Program

," for the failure to perform comprehensive pump testing of Containment Spray Pump P-54A in accordance with the code of record.

Specifically, the licensee did not rerun a comprehensive pump test, as required by the code's ISTB

-6300 "Systematic Error" section. As part of their corrective actions, the licensee entered the issue into the Corrective Action Program, and determined the component remained operable.

The performance deficiency was determined to be more than minor because it impacted the Equipment Performance attribute of the Reactor Safety, Mitigating Systems Cornerstone and adversely affected the cornerstone objective to ensure the availability, reliability, and capability of systems that respond to initiating events to prevent undesirable consequences. Specifically, failing to perform testing as required could result in the degradation of the equipment being undetected. The finding screened as having very low safety significance because the finding was a deficiency affecting the design or qualification of a mitigating structure system or component (SSC) but the SSC maintained its operability.

The findings had a cross-cutting aspect in the area of Problem Identification and Resolution, Evaluation, because the licensee failed to thoroughly evaluate the issue to ensure that resolutions address causes and extents of conditions commensurate with their safety significance.

[P.2] (Section 1R21.3.b(

5))

5

Green.

The inspectors identified a finding of very low safety significance and associated NCV of 10 CFR Part 50, Appendix B, Criterion XI, "Test Control," for the licensee's failure to have adequate acceptance criteria in the emergency diesel generator surveillance procedures. Specifically, the licensee failed to ensure the surveillance test procedures for the emergency diesel generator largest load rejection test bounded the power demand o f the largest load, as required by Technical Specification SR 3.8.1.5. The licensee entered this finding into their Correction Action Program and verified the operability of the emergency diesel generators.

The performance deficiency was determined to be more than minor, because it impacted the Procedure Quality attribute of the Reactor Safety, Mitigating Systems Cornerstone and adversely affected the cornerstone objective of ensuring the availability, reliability, and capability of systems to respond to initiating events to prevent undesirable consequences. Specifically, the surveillance procedure error could result in acceptance of test results that did not satisfy Technical Specification SR 3.8.1.5 for rejection of a load greater than or equal to the emergency diesel generator's single largest predicted post-accident load. The inspectors determined the finding was of very low safety significance (Green) because the SSC maintained its operability and functionality. This finding had a cross-cutting aspect in the area of Human Performance, associated with the Resources component, because the licensee failed to ensure that personnel, equipment, procedures, and other resources are adequate to assure nuclear safety by maintaining long term plant safety. [H.1] (Section 4OA2.1.b(1))

Cornerstone: Barrier Integrity

Green.

The inspectors identified a finding of very low safety significance (Green) and associated NCV of 10 CFR Part 50, Appendix B, Criterion III, "Design Control," for the licensee's failure to correctly translate design valve leakage limits into the applicable test procedure. Specifically, the acceptance criterion for emergency core cooling system (ECCS)/containment spray (CS) recirculation isolation valves CV

-3027 and CV

-3056 had not been correctly adjusted to account for the higher differential pressure associated with ECCS operation under post-accident conditions.

The licensee entered this finding into their Corrective Action Program to correct the valve leakage limit.

The performance deficiency was determined to be more than minor because it impacted the Design Control attribute of the Barrier Integrity Cornerstone and adversely affected the associated cornerstone objective to provide reasonable assurance that containment could protect the public from radionuclide releases caused by accidents or events.

Specifically, leakage approaching the procedural values would exceed analyzed dose calculations

. The finding screened as of very low safety significance (Green) because the finding did not represent an actual open pathway in the physical integrity of reactor containment, containment isolation system, or heat removal components and did not involve an actual reduction in function of hydrogen igniters in the reactor containment.

The inspectors determined this finding did not have an associated cross-cutting aspect because it was not representative of present performance.

(Section 1R21.3.b(

6))

Green.

The inspectors identified a finding of very low safety significance (Green) and associated NCV of 10 CFR Part 50, Appendix B, Criterion VII, "Control of Purchased Material, Equipment, and Services," for the licensee's failure to identify non-safety-related sub-components improperly supplied with safety-related valves. Specifically, ECCS/CS recirculation isolation valves CV

-3027 and CV

-3056, which were installed in 2007, were supplied with non-safety-related sub-components. These components were identified as non-safety-related on the vendor drawings. In addition, the licensee later installed a section of non-safety-related tubing on valve CV

-3027 based on the incorrect vendor drawing.

The licensee entered this finding into their Corrective Action Program to correct the valve drawings and replace the non-safety-related parts

. The performance deficiency was determined to be more than minor because it impacted the Design Control attribute of the Barrier Integrity Cornerstone and adversely affected the associated cornerstone objective to provide reasonable assurance that containment could protect the public from radionuclide releases caused by accidents or events. Specifically, the licensee failed to identify non-safety-related sub-components improperly supplied with safety-related valves which would form part of the containment barrier under post-accident conditions.

The finding screened as of very low safety significance (Green) because the finding did not represent an actual open pathway in the physical integrity of reactor containment, containment isolation system, or heat removal components and did not involve an actual reduction in function of hydrogen igniters in the reactor containment.

The inspectors determined this finding did not have an associated cross-cutting aspect because it was not representative of the licensee's present performance.

(Section 1R21.3.b(7))

Green.

The inspectors identified a finding of very low safety significance and associated NCV of 10 CFR Part 50, Appendix B, Criterion XI, "Test Control," for the licensee's failure to establish an adequate test program for the Shutdown Cooling (SDC) Heat Exchangers (HXs) to demonstrate they can perform as designed. Specifically, the licensee failed to take actions to ensure the SDC HXs' heat transfer capability met its design bases, as assumed in design bases calculations.

The performance deficiency was determined to be more than minor because it impacted the Design Control attribute of the Barrier Integrity Cornerstone and adversely affected the associated cornerstone objective to provide reasonable assurance that containment could protect the public from radionuclide releases caused by accidents or events. Specifically, the licensee failed to verify the SDC HXs heat transfer capability met their design bases, as assumed in design bases calculations, to limit containment temperatures and pressures during an event.

The finding screened as of very low safety significance (Green) because the finding did not represent an actual open pathway in the physical integrity of reactor containment, containment isolation system, or heat removal components and did not involve an actual reduction in function of hydrogen igniters in the reactor containment. The inspectors determined this finding had an associated cross-cutting aspect, Conservative Bias, in the Human Performance cross-cutting area

. Specifically, on several occasions when the licensee identified the need to perform testing and/or inspection of the SDC HXs, the licensee did not take actions because they did not believe any regulatory requirements or technical issues existed that required the testing and/or inspections.

[H.14] (Section 1R21.3.b(

8))

B. Licensee-Identified Violations

Violations of very low safety or security significance or Severity Level IV that were identified by the licensee have been reviewed by the NRC. Corrective actions taken or planned by the licensee have been entered into the licensee's Corrective Action Program (CAP). These violations and CAP tracking numbers are listed in Section 4OA7 of this report.

7

REPORT DETAILS

REACTOR SAFETY

Cornerstone:

Initiating Events, Mitigating Systems, and Barrier Integrity

1R21 Component Design Bases Inspection

.1 Introduction

The objective of the component design bases inspection is to verify the design bases have been correctly implemented for the selected risk significant components and the operating procedures and operator actions are consistent with design and licensing bases. As plants age, their design bases may be difficult to determine and an important design feature may be altered or disabled during a modification. The Probabilistic Risk Assessment (PRA) model assumes the capability of safety systems and components to perform their intended safety function successfully. This inspectable area verifies aspects of the Initiating Events, Mitigating Systems, and Barrier Integrity cornerstones for which there are no indicators to measure performance.

Specific documents reviewed during the inspection are listed in the attachment to the report.

.2 Inspection Sample Selection Process

The inspectors used information contained in the licensee's PRA and the Palisades Standardized Plant Analysis Risk Model to identify a scenario to use as the bas is for component selection. The scenario selected was a Large Break Loss of Coolant Accident (LBLOCA)and subsequent transfer to recirculation. Based on this scenario, a number of risk significant components were selected for the inspection.

The inspectors also used additional component information such as a margin assessment in the selection process. This design margin assessment considered original design reductions caused by design modification, power uprates, or reductions due to degraded material condition. Equipment reliability issues were also considered in the selection of components for detailed review. These included items such as performance test results, significant corrective actions, repeated maintenance activities, Maintenance Rule (a)(1) status, components requiring an operability evaluation, NRC resident inspector input of problem areas/equipment, and system health reports. Consideration was also given to the uniqueness and complexity of the design, operating experience, and the available defense in depth margins. A summary of the reviews performed and the specific inspection findings identified are included in the following sections of the report.

The inspectors also identified procedures and modifications for review that were associated with the selected components. In addition, the inspectors selected operating experience issues associated with the selected components.

This inspection constituted 20 samples as defined in Inspection Procedure 71111.21-05.

8

.3 Component Design

a. Inspection Scope

The inspectors reviewed the Final Safety Analysis Report (FSAR), Technical Specifications (TS), design basis documents, drawings, calculations and other available design basis information, to determine the performance requirements of the selected components. The inspectors used applicable industry standards, such as the American Society of Mechanical Engineers (ASME) Code, Institute of Electrical and Electronics Engineers (IEEE) Standards and the National Electric Code, to evaluate acceptability of the systems' design. The NRC also evaluated licensee actions, if any, taken in response to NRC issued operating experience, such as Bulletins, Generic Letters (GLs), Regulatory Issue Summaries (RISs), and Information Notices (INs). The review was to verify the selected components would function as designed when required and support proper operation of the associated systems. The attributes that were needed for a component to perform its required function included process medium, energy sources, control systems, operator actions, and heat removal. The attributes to verify that the component condition and tested capability was consistent with the design bases and was appropriate may include installed configuration, system operation, detailed design, system testing, equipment and environmental qualification, equipment protection, component inputs and outputs, operating experience, and component degradation.

For each of the components selected, the inspectors reviewed the maintenance history, preventive maintenance activities, system health reports, operating experience

-related information, vendor manuals, electrical and mechanical drawings, and licensee Corrective Action Program documents.

Field walkdowns were conducted for all accessible components to assess material condition and to verify that the as

-built condition was consistent with the design. Other attributes reviewed are included as part of the scope for each individual component.

The following 14 components were reviewed:

Containment Spray Pump P

-54A: The inspectors reviewed calculations related to pump hydraulics to ensure the pump was capable of performing its design bases accident mitigation functions. The calculations included analysis of net positive suction head (NPSH), discharge head, flow, and management of potential air entrainment mechanisms. The inspectors also reviewed procedures and system diagrams to ensure the pump would be operated within its design parameters during an event. Recent Inservice Test (IST) reports and historical trends data were reviewed to assess compliance with Technical Specificatio n

surveillance requirements, compliance with the applicable code of record, review potential component degradation, and impact on design margins. The inspectors discussed the component's performance with the system engineer and reviewed recent corrective action documents related to the SSC in order to assess the overall health of the component. In addition, the inspectors performed a walkdown to assess material condition of the pump and supporting components.

2400V Switchgear 1D: In addition to the generic list of attributes listed above, the inspectors reviewed electrical diagrams, calculations, and procedures, including system short circuit and load flow calculations. Incoming breaker protective relay trip setpoints were reviewed to evaluate the adequacy of the switchgear bus and breakers to carry anticipated loads under limiting conditions and to withstand and interrupt maximum available faults. The inspectors also 9 reviewed the voltage profile of the offsite system, voltage drop calculations, and the undervoltage relay settings to assess adequacy of voltage at the terminals of the safety

-related loads and ability to remain connected to offsite power under worst operating and accident conditions. Sizing of the incoming feeder cables was reviewed to determine their capability under worst accident conditions.

SIRW Tank Suction Valve (CV

-3057): The inspectors reviewed procedures and system diagrams to ensure the component would be operated within its design parameters during a design basis event.

The inspectors discussed the component's performance with the system engineer, and reviewed recent corrective action documents related to the SSC in order to assess the overall health of the component.

Calculations related to the component

's safety-related air supply was also reviewed. The inspectors reviewed the circuit protection and the environmental qualification to confirm the circuit was adequately protected

, and the valve was capable of performing its intended safety function. Voltage drop calculations were reviewed to verify the associated control circuits had adequate voltage under degraded voltage conditions. The inspectors also reviewed surveillance test data, any operator control limitations, operating procedures, vendor and generic communications, recent CRs and operability evaluations for any anomalous indications or possible difficulties in system operation.

In addition, the inspectors performed a walkdown to assess material condition of the valve, supporting components, and identify any potential concerns related to adverse interaction with the surrounding equipment.

Containment Sump Outlet Valve CV

-3029: The inspectors reviewed the design basis of the air

-operated valve including thrust calculations, the basis for valve stroke time requirements, and the associated control logic. The inspectors reviewed test, and emergency procedures

, as well as the response of the system to the failure of the valve to operate under accident conditions. The inspectors reviewed the capacity of the high

-pressure air system to verify its capability to operate the valve with a loss of normal instrument air. The inspectors reviewed air system leak test procedures and results and performed a walkdown of the valve to verify its material condition.

The inspectors also reviewed the circuit protection, the environmental qualification of affected circuit components to confirm the circuit was adequately protected, and the valve was capable of performing its intended safety function during a design basis accident. Voltage drop calculations were reviewed to verify the associated control circuits had adequate voltage under degraded voltage conditions. The inspectors also reviewed operating procedures, vendor and generic communications, recent CRs and operability evaluations for any anomalous indications or possible difficulties in system operation.

SIRW Tank Level Switch LS-327: The inspectors reviewed installation drawings and vendor documentation to verify the switch was appropriate for its use. The inspectors review ed the Recirculation Actuation Signal (RAS) logic to verify the switch met its design basis. The inspectors also reviewed switch calibration and testing procedures.

In addition, the inspectors performed a walkdown of the SIRW tank to assess the level transmitters used for calibration of the switch

. Shutdown Cooling Heat Exchanger E

-60A: The inspectors reviewed heat exchanger design documents to verify assumptions made in design bases calculations.

The inspectors reviewed normal, test, and emergency procedures.

The inspectors also reviewed historical information to understand how heat 10 exchanger performance had been validated since original installation. A walkdown was performed to assess the material condition of the heat exchanger and supporting components. In addition, the inspectors reviewed aging management aspects related to the heat exchanger.

Component Cooling Water (CCW) Pump (P

-52B): The inspectors reviewed calculations related to pump hydraulics to ensure the pump was capable of performing its design bases accident mitigation functions.

Included in the review were cooling requirements for the component and the supplied loads. Also, reviewed were potential alternate sources for cooling the supplied load if CCW were to become unavailable during an accident. The inspectors also reviewed procedures and system diagrams to ensure the pump would be operated within its design parameters during an event.

The inspectors discussed the component's performance with the system engineer, and reviewed recent corrective action documents related to the SSC in order to assess the overall health of the component. In addition, the inspectors performed a walkdown to assess material condition of the pump, supporting components, and identify any potential concerns related to adverse interaction with the surrounding or nearby equipment.

Component Cooling Water (CCW) Relief Valve RV

-0956: The inspectors also reviewed procedures and system diagrams to ensure the pump would be operated within its design parameters during an event.

The inspectors discussed the component's performance with the system engineer, and reviewed recent corrective action documents related to the SSC in order to assess the overall health of the component. In addition, the inspectors reviewed vendor manuals and technical sheets for the component. The required licensing and design bases for the component were reviewed and discussed with NRR, and requires further evaluation.

Containment Sump Strainer: The inspectors reviewed results of sump inspections and ECCS pump NPSH analyses to verify the pressure drop across the screens under post

-accident conditions. The inspectors reviewed normal, test, and emergency procedures. The inspectors also reviewed the basis for the maximum particle size.

125 VDC Bus D10

The inspectors reviewed the circuit diagrams, the short circuit current calculation, and the coordination calculation to confirm the short circuit duty and the proper coordination between the panel fuses and branch circuit cabling with the upstream protective device. The inspectors also reviewed the panel electrical loading and voltage drop calculations, and the branch circuit cabling, to confirm bus and circuit cable ampacity was adequate and branch circuits had adequate voltage. The inspectors also reviewed recent CRs, operability evaluations, and operating procedures for any anomalous indications.

LPSI Pump Suction Crosstie Valve MO

-3090: The inspectors reviewed the design basis of the motor

-operated valve including thrust calculations, the basis for valve stroke time requirements, and the associated control logic. The inspectors reviewed normal, test, and emergency procedures including the response to the single failure of an electrical power supply to MO

-3090. The inspectors also reviewed the interface between the electrical system distribution calculations and the valve thrust calculation to verify adequate voltage to the 11 valve motor under the most limiting conditions.

The inspectors performed a walkdown of the valve to verify its material condition.

480V Motor Control Center (MCC) 23: In addition to the generic list of attributes listed above, the inspectors reviewed electrical diagrams, calculations, and procedures, including system short circuit calculations and main alternating current (AC) electrical distribution analysis. Voltage calculations were reviewed to verify minimum and maximum voltages were within equipment capabilities, including downstream power and control components. Thermal overload protection for motor operated valves was reviewed to assess the adequacy of valve motor overload protection.

ECCS/CS Minimum Flow Valve CV

-3027: The inspectors reviewed the design basis of the air

-operated valve including thrust calculations, the basis for valve stroke time requirements, and the associated control logic. The inspectors reviewed normal, test, and emergency procedures as well as the response of the system to the single failure of the valve to operate under accident conditions. The inspectors reviewed the basis for the valve leakage limits and reviewed leak test procedures and results. The inspectors also reviewed the safety classification of valve sub

-components. The inspectors performed a walkdown of the valve to verify its material condition.

125 VDC Bus D11

The inspectors reviewed the circuit diagrams, the short circuit current calculation, and the coordination calculation to confirm the short circuit duty and the proper coordination between the panel fuses and branch circuit cabling with the upstream protective device. The inspectors reviewed the degraded voltage protection design scheme to determine whether it afforded adequate voltage to safety

-related devices at all voltage distribution levels. The inspectors also reviewed the panel electrical loading and the branch circuit cabling, to confirm bus, circuit cable ampacity was adequate, and branch circuits had adequate voltage. The inspectors also reviewed recent CRs, operability evaluations, and operating procedures for any anomalous indications.

b. Findings

(1) Failure to Ensure Engineered Safeguards Systems (ESS) Are Not Adversely Affected By Air Entrainment Introduction

A finding of very low safety significance (Green) and associated Non

-Cited Violation of 10 CFR Part 50, Appendix B, Criterion III, "Design Control" was identified by the inspectors for the failure to ensure the safety

-related ESS Trains would not be adversely affected by air entrainment when the ESS trains are aligned to the SIRW tank under design bases accidents.

Description

During a postulated design bases accident, the licensee's ESS would be required to operate. At the beginning of the accident the two trains of ESS would begin to operate with their associated pumps

' suction lined up to the SIRW Tank. Train A includes:

one Low Pressure Safety Injection (LPSI) pump, one Containment Spray (CS) pump and one High Pressure Safety Injection (HPSI) pump. Train B includes one LPSI pump, two CS pumps and one HPSI pump. When the water level in the SIRW tank reaches a pre

-determined low level, a Recirculation Actuation Signal (RAS) is generated. Once the RAS occurs, the LPCI pumps are tripped off and the pumps' suctions begin to automatically re-aligned to the containment sump. Per the licensee's

12 design bases this process can take up to 70 seconds to occur. If the water level were to get too low on the SIRW tank before the automatic swap to the containment sump concludes, air could be drawn into the system. If enough air entrainment occurred, the operability of the downstream pumps could be affected. Air entrainment can degrade pump performance, causing the pumps to air bind, reduce discharge pressure/flow and/or cause delays in injection.

The inspectors reviewed design bases calculation EA

-C-PAL-0877D, "Evaluation of the Potential for Excessive Air Entrainment Caused by Vortexing in the SIRW tank During a LOCA," Revision 1. In the calculation the licensee establishe d the critical submergences needed before air entrainment mechanisms could develop (vortexing and radial inflow) and evaluate d the lowest water levels reached in the SIRW tank during a design bases accident. The calculation determined the critical submergence limit for vortexing would be exceeded. The licensee estimated the maximum credible air entrainment at the pumps' suctions as 3.6 percent by volume. This value was determined using the "enveloping line" correlation based on Knauss, Jost, "Swirling Flow Problems at Intakes," A. A. Balkema, Rotterdam, Netherlands, 1987 and the expected void compression using the Ideal Gas Law. However, the inspectors noted the configuration described in the referenced material did not match the licensee's SIRW tank outlet piping configuration. The referenced material was based on horizontal outlet pipes, not vertical as in the case of the licensee's SIRW tank

. Also, the expected void fraction at the pumps exceeded those considered acceptable per NEI 09

-10, "Guidelines for Effective Prevention and Management of System Gas Accumulation

." The NEI 09-10 provides the void fraction acceptance criteria used for operability calls in Palisades' Gas Accumulation Management Program Document. This is discussed in Attachment 9.5 of EN-DC-219, "Gas Accumulation Management

," Revision 3 (the licensee's Gas Management Program Document):

"These guidelines do not provide acceptance criteria to support permanent design bases or procedural changes.

These guidelines do provide a toolset for establishing a Reasonable Expectation of Operability based on industry standards for non

-conforming conditions associated with gas intrusion.

Other tools may be utilized by a specific site if properly supported by site evaluation."

Upon further review, the inspectors noticed that when determining the lowest level reached in the SIRW tank, calculation EA

-C-PAL-0877D did not assume both trains of ESS could be in operation and taking suction from the SIRW tank concurrently. In addition, the calculation did not identify that a postulated single failure could result in a failure of RAS to occur for one train. Under this condition, one train of ESS would not realign to the containment sump and the LPCI pump on the affected train would continue to operate. Both of these concerns would result in a SIRW tank level lower than that assumed in the calculation. The licensee documented the inspectors' concerns under CR-PLP-2014-04472 and CR

-PLP-2014-04665. An operability evaluation was also developed under CR

-PLP-2014-04665. In order to maintain operability, the licensee re

-evaluated the scenarios in Question (EC 53093) and adjusted their acceptance criteria for critical submergence. In addition, compensatory actions to ensure the system behaved as expected in their re

-valuation were needed. These actions included:

(1) revising the acceptance criteria in QO

-2 for the stroke times of the SIRW tank outlet isolation valves CV

-3031 and CV

-3057 (shortened the allowed stroke time), and (2)revising the acceptance criteria in RI

-14 for the SIRW tank low level switches LS

-0327, LS-0328, LS-0329 and LS

-0330.

13

Analysis:

The inspectors determined the licensee

's failure to ensure the safety

-related ESS Trains would not be adversely affected by air entrainment when aligned to the SIRW tank was a performance deficiency. Specifically, when evaluating if the SIRW tank reaches the limit for critical submergence (during a tank drawdown) calculation EA-C-PAL-0877D, assumed only one train of ESS was in operation instead of both trains. Additionally, the licensee did not evaluate the potential effects on the ESS system if both trains are assumed to be in operation, or if one train fails to receive its RAS signal. Both scenarios result in lower water levels in the SIRW tank, and potential air ingestion into the ESS trains.

The performance deficiency was determined to be more than minor because it impacted the Equipment Performance attribute of the Reactor Safety, Mitigating Systems Cornerstone and adversely affected the cornerstone objective to ensure the availability, reliability, and capability of systems that respond to initiating events to prevent undesirable consequences. Specifically, air entrainment into the ESS systems could potentially impact the operability of the system by air binding the pumps, reduce discharge flow, discharge pressure and/or delay injection. The licensee performed an operability evaluation, and re

-analyzed the SIRW tank drain down (EC 53093) in order to ensure the ESS systems remained Operable.

The inspectors determined the finding could be evaluated using the SDP in accordance with IMC 0609, "Significance Determination Process," Attachment 0609.04,"

"Initial Characterization of Findings." Specifically, the inspectors used IMC 0609 Appendix A "SDP for Findings At

-Power" Exhibit 2, "Mitigating Systems Screening Questions". The finding was a deficiency affecting the design or qualification of a mitigating structure system or component (SSC) but the SSC maintained its operability. Specifically, the licensee performed an operability evaluation CR

-PLP-2014-04665 and determined the performance deficiency would result in lower SIRW Tank levels but at least one train of ESS would remain operable during a design bases accident. As a result, the finding screened as having very low safety significance, i.e.

, Green.

The inspectors did not identify a cross

-cutting aspect associated with this finding because the finding was not representative of the licensee's present performance. Enforcement

Title 10 CFR Part 50, Appendix B, Criterion III, "Design Control" requires, in part, that measures shall be established to assure that applicable regulatory requirements and the design basis, as defined in 50.2 and as specified in the license application, for those structures, systems, and components to which this appendix applies are correctly translated into specifications, drawings, procedures, and instructions.

Contrary to the above, as of September 8, 2014, the licensee failed to ensure their ESS trains would not be adversely affected by air entrainment when these are aligned to the SIRW tank. Specifically, calculation EA

-C-PAL-0877D, "Evaluation of the Potential for Excessive Air Entrainment Caused by Vortexing in the SIRW tank During a LOCA

," Revision 1, failed to evaluate the potential effects on the ESS systems if both trains were assumed to be in operation, or if one train fail ed to receive its RAS signal. As part of their corrective actions, the licensee initiated CR-PLP-2014-04665, performed an operability evaluation

, and implemented compensatory measures needed to ensure the Engineered Safeguard Systems are able to perform their required safety functions during design bases conditions.

14 Because this violation was of very low safety significance, and it was entered into the licensee's Corrective Action Program as CR

-PLP-2014-04472 and CR

-PLP-2014-04665, this violation is being treated as an NCV, consistent with Section 2.3.2 of the NRC Enforcement Policy. [NCV 05000255/201 4008-01, Failure to Ensure Engineered Safeguards Systems Are Not Adversely Affected By Air Entrainment.]

(2) Undersized Supply Cables from Startup Transformer to 2400V Buses Introduction

A finding of very low safety significance and associated Non-Cited Violation of 10 CFR Part 50, Appendix B, Criterion III, "Design Control," was identified by the inspectors for the licensee's failure to ensure the incoming feeder cables from startup transformer 1

-2 to 2400 V safety

-related Buses 1C and 1D were sized in accordance with their design basis, as described in Palisades FSAR Section 8.5.2

. Specifically, the licensee failed to ensure the ampacity of the cables was at least as high as their maximum predicted steady-state current.

Description

On October 23, 2013, the licensee issued calculation EA-ELEC-EDSA-03, "LOCA with Offsite Power Available," Revision 2, which identified that the maximum steady-state load on Bus 1C during a LOCA would be 873 amps (Tables B2

-1C and SU-CD-1C-B2) and on Bus 1D would be 953 amps (Table SU

-1D-2355-B2). Palisades FSAR Section 8.5.2 states that "Cables installed in...underground ducts are thermally sized in accordance with NEC or IPCEA/ICEA ampacity values (depending on cable physical size) of concentric stranded insulated cable for the conductor operating temperature of the insulation."

According to Section 4.0 a of Engineering Analysis EA-ELEC-AMP-030, "Capability of the 2400V Feeder Cables to Buses 1C and 1D from the Startup Transformer 1

-2," Revision 2, the rated operating temperature of the cable insulation is 90°C.

According to Engineering Change EC 24546 to Design Basis Document DBD 3.04, "2400V AC System

," Revision 7, the ampacity is 636 amps (current that would raise the cable temperature to 90°C). Thus, the cable ampacity is exceeded by the loading levels calculated in EA-ELEC-EDSA-03, contrary to the requirement of FSAR Section 8.5.2. Although the licensee previously entered this issue into their Margin Management Program as Margin Issue 414, they failed to characterize it as a design basis deficiency.

Based on inspector concerns, the licensee entered this issue into the Corrective Action Program as CR

- CR-PLP-2014-4860 with a recommended action to provide additional procedural guidance for unloading the cables if an overload condition were to occur.

The licensee also verified current operability by confirming the cables would not fail as a result of the condition

.

Analysis:

The inspectors determined the failure to ensure the supply cables to Buses 1C and 1D are sized in accordance with the design basis was contrary to 10 CFR Part 50, Appendix B, Criterion III, "Design Control," and was a performance deficiency.

The finding was determined to be more than minor because the finding was associated with the Design Control attribute of the Reactor Safety, Mitigating Systems Cornerstone and adversely affected the cornerstone objective to ensure the availability, reliability, and capability of systems that respond to initiating events to prevent undesirable consequences.

Specifically, cables were undersized with respect to the loading that would automatically occur as the result of a design basis event.

The inspectors assessed this finding for significance in accordance with NRC Manual Chapter 0609, Appendix A, Exhibit 2

, The Significance Determination Process (SDP) for Findings At-Power, and determined that it was of very low safety significance (Green),

15 because the SSC maintained its operability and functionality

. This finding had a crosscutting aspect in the area of Human Performance, associated with the Design Margin component, because the licensee did not ensure that equipment is operated and maintained within design margins, and margins are carefully guarded and changed only through a systematic and rigorous process

. The licensee's margin management program had not corrected this know n condition.

[H.6] Enforcement

Title 10 CFR Part 50, Appendix B, Criterion III, "Design Control" requires, in part, "Measures shall be established to assure that applicable regulatory requirements and the design basis are correctly translated into specifications, drawings, procedures, and instructions. The design control measures shall provide for verifying or checking the adequacy of design, such as by the performance of design reviews, by the use of alternate or simplified calculational methods, or by the performance of a suitable testing program."

Contrary to the above, as of September 8, 2014, the licensee failed to assure that the design basis for cable sizing specified in FSAR Section 8.5.2 was translated into the design of the cables. Specifically, the design ampacity of the cables was less than their maximum predicted steady-state load.

Because this violation was of very low safety significance, and it was entered into the licensee's Corrective Action Program as CR

- CR-PLP-2014-4860 with a recommended action to provide additional procedural guidance for unloading the cables if an overload condition were to occur, this violation is being treated as an NCV, consistent with Section 2.3.2 of the NRC Enforcement Policy. The licensee also verified current operability by confirming the cables would not fail as a result of the condition

. [NCV 05000255/201400 8-02, Undersized Supply Cables from Startup Transformer to 2400V Buses

.] (3) Undersized Motors

Introduction:

A finding of very low safety significance and associated Non-Cited Violation of 10 CFR Part 50, Appendix B, Criterion III, "Design Control," was identified by the inspectors for the licensee's failure to ensure that electric motors are sized in accordance with the design basis, as discussed in Palisades FSAR Section 6.2.3.1. Specifically, the horsepower ratings of certain motors are less than power demands of their driven equipment, and they were not analyzed to ensure that overheating would not occur. Description

Palisades FSAR Section 6.2.3.1 states the containment spray "motor drivers have been selected to be non

-overloading over the entire pump operating range." To the contrary, on August 6, 2014, the licensee issued calculation EA

-ELEC-LDTAB-005, "Emergency Diesel Generators 1

-1 and 1-2 Steady State Loadings," Revision 10, which identifies, in Table C.1, that the motor for containment spray pump P

-54A is rated 250 HP, but the power demand of the pump is 278 BHP. The calculation also lists other motors having ratings less than the power demand of their associated driven equipment

. Power demands of the containment spray pumps and other motor driven equipment would be even higher than those listed in Calculation Tables A.1 through E.2 when the emergency diesel generator is operating at its maximum allowable frequency and voltage. The calculation identifies, in Section 4.24, that this operating condition would cause a 6.32 percent increase in the power demands. The inspectors noted calculation EA-ELEC-LDTAB-005 does not analyze or justify the undersized motor condition, nor is there any other analysis that justifies this condition. In the, "Quality Assurance Program Manual," Revision 26, the licensee is committed to Regulatory Guide 1.64, "Quality Assurance Requirements for the Design of Nuclear Power Plants," Revision 2, which 16 cites ANSI N45.2.11

-1974, "Quality Assurance Requirements for the Design of Nuclear Power Plants." ANSI N45.2.11 states, "Measures shall be applied to verify the adequacy of design. Design verification is the process of reviewing, confirming, or substantiating the design by one or more methods to provide assurance that the design meets the specified design inputs-. The results of design verification efforts shall be clearly documented." Contrary to this requirement, the licensee had not verified and documented the thermal capability of motors serving loads in excess of the motor horsepower rating.

The licensee entered this issue into their Corrective Action Program as CR-PLP-2014-4902 with a recommended action to analyze the effect of the condition.

The licensee subsequently verified operability of the motors.

Analysis:

The inspectors determined the failure to ensure that electric motors are sized in accordance with the design basis and verified to be within their thermal capability was contrary to 10 CFR Part 50, Appendix B, Criterion III, "Design Control," and was a performance deficiency. The finding was determined to be more than minor because the finding was associated with the Design Control attribute of the Reactor Safety, Mitigating Systems Cornerstone and adversely affected the cornerstone objective to ensure the availability, reliability, and capability of systems that respond to initiating events to prevent undesirable consequences

. Specifically, certain motors serv e loads with demands in excess of the motor horsepower ratings, and they were not analyzed to ensure that overheating would not occur

. The inspectors assessed this finding for significance in accordance with NRC Manual Chapter 0609, Appendix A, Exhibit 2, The Significance Determination Process (SDP) for Findings At

-Power, and determined that it was of very low safety significance (Green), because the SSC maintained its operability and functionality.

This finding had a crosscutting aspect in the area of Human Performance, associated with the Design Margin component, because the licensee did not ensure that equipment is operated and maintained within design margins, and margins are carefully guarded and changed only through a systematic and rigorous process

. [H.6] Enforcement

Title 10 CFR Part 50, Appendix B, Criterion III, "Design Control" requires, in part, that "Measures shall be established to assure that applicable regulatory requirements and the design basis are correctly translated into specifications, drawings, procedures, and instructions.

The design control measures shall provide for verifying or checking the adequacy of design, such as by the performance of design reviews, by the use of alternate or simplified calculational methods, or by the performance of a suitable testing program."

Contrary to the above, as of September 8, 2014, the licensee failed to verify the adequacy of design of certain motors.

Specifically, the horsepower ratings of those motors did not bound the power demands of their driven equipment, and they were not analyzed to ensure that the condition would not cause overheating

. Because this violation was of very low safety significance, and it was entered into the licensee's Corrective Action Program as CR-PLP-2014-4902, this violation is being treated as an NCV, consistent with Section 2.3.2 of the NRC Enforcement Policy

. [NCV 05000255/201400 8-03, Undersized Motors.

]

17 (4) Failure to Ensure that 480V System Voltages do not Exceed Equipment Ratings Introduction

A finding of very low safety significance and associated Non-Cited Violation of 10 CFR Part 50, Appendix B, Criterion III, "Design Control," was identified by the inspectors for the licensee's failure to ensure that voltages on the 480V system do not exceed equipment ratings.

Specifically, the licensee increased the output voltage of the supply transformers to the 480V safety-related buses by 2.5 percent, but failed to ensure that the resulting voltages would not exceed equipment ratings when the system is powered from the station power transformer or emergency diesel generator.

Description

On March 30, 1995, the licensee issued calculation EA

-ELEC-VOLT-036, "Station Power Transformers No. 11, 12, 19, and 20 Tap Change

- 2.5 percent," Revision 0, which states, in Section IV.2.1, "the maximum allowed voltage at 480 V Load Centers/MCC's is 1.058 pu (480 V base)."

On July 28, 1995, the licensee issued Specification Change document SC 102, Revision 0, to increase the output voltage of the supply transformers to the 480V safety

-related buses by 2.5 percent. The inspectors determined the licensee failed to recognize that this could result in voltages at the 480V buses in excess of the 1.058 per unit limit. In addition, calculation EA

-ELEC-VOLT-036,Section IV.4.3, postulated a non

-conservative maximum voltage on the 2400V buses of 1.0 per unit (2400V). However, voltages on the 2400V buses in excess of 1.0 per unit could occur due to 1) operation on the diesel generator supply within the diesel generator voltage range up to 1

.05 per unit, as allowed by Palisades

Technical Specification SR 3.8.1.2, or 2) operation on the non

-regulated Station Power Transformer 1-2 supply during shutdown conditions, as discussed in Palisades Technical Specification Basis 3.8.2.

The inspectors were concerned these higher voltages on the 2400V buses, in conjunction with the 2.5 percent increase in voltage to the 480V buses, could result in over voltages on the 480V buses. Voltages higher than the 1.058 per unit calculation limit could cause exposure of load equipment to voltages in excess of the manufacturers' ratings and diminished capability of electrical protective devices to interrupt short circuit currents.

The licensee entered this issue into their Corrective Action Program as CR-PLP-2014-4696 with a recommended action to further analyze emergency diesel generator operation at its maximum allowable voltage and CR-PLP-2014-4864 with an action to restrict switchyard maximum voltage when the safety

-related buses are powered from the station power transformer.

The licensee subsequently determined that all equipment was operable at the full range of diesel operation.

Analysis:

The inspectors determined the licensee's failure to verify or check the adequacy of Specification Change document SC 102, Revision 0, was contrary to 10 CFR Part 50, Appendix B, Criterion III, "Design Control,"

and was a performance deficiency.

The finding was determined to be more than minor because the finding was associated with the Design Control attribute of the Reactor Safety, Mitigating Systems Cornerstone and adversely affected the cornerstone objective to ensure the availability, reliability, and capability of systems that respond to initiating events to prevent undesirable consequences.

Specifically, the licensee failed to verify or check the adequacy of Engineering Assessment EA

-ELEC-VOLT-036, "Station Power Transformers Nos. 11, 12, 19, and 20 Tap Change

- 2.5 percent," Revision 0, to ensure that postulated maximum source voltages bounded allowable operating conditions and thus that the voltage increase would not result in overvoltage conditions

.

18 The inspectors assessed this finding for significance in accordance with NRC Manual Chapter 0609, Appendix A, Exhibit 2

. The Significance Determination Process (SDP) for Findings At-Power, and determined that it was of very low safety significance (Green), because the SSCs maintained their operability and functionality

. The inspectors did not identify a cross

-cutting aspect associated with this finding

, because the finding was not representative of the licensee's present performance.

Enforcement

Title 10 CFR Part 50, Appendix B, Criterion III, "Design Control" requires, in part, that "Measures shall be established to assure that applicable regulatory requirements and the design basis are correctly translated into specifications, drawings, procedures, and instructions.

The design control measures shall provide for verifying or checking the adequacy of design, such as by the performance of design reviews, by the use of alternate or simplified calculational methods, or by the performance of a suitable testing program." Contrary to the above, as of September 8, 2014, the licensee failed to verify the adequacy of the design of the transformer tap settings. Specifically, the 2.5 percent boost in voltages to the 480V buses could result in voltages in excess of equipment ratings under certain allowable operating conditions.

Because this violation was of very low safety significance, and it was entered into the licensee's Corrective Action Program as CR-PLP-2014-4696, and CR-PLP-2014-4864 this violation is being treated as an NCV, consistent with Section 2.3.2 of the Enforcement Policy

. [NCV 05000255/201400 8-04, Failure to Ensure that 480V System Voltages do not Exceed Equipment Ratings

.] (5) Failure To Perform Comprehensive Pump Testing Of Containment Spray Pump P

-54A In Accordance With The Inservice Testing Program.

Introduction

A finding of very low safety significance (Green) and associated Non

-Cited Violation of Technical Specifications 5.5.7, "Inservice Testing Program" was identified by the inspectors for the licensee's failure to perform comprehensive pump testing of Containment Spray pump P

-54A in accordance with the code of record.

Description

On February 25, 2014 the licensee performed WO 52435851 01, "RO-98 -LPSI PMP VIB, CONT SPRY PMP VIB, DIS CK

," which includes the comprehensive pump test of Containment Spray (CS) Pump P

-54A. The comprehensive pump test is performed every 18 months in accordance with the ASME OMb Code

-2001, through ASME OMb Code

-2003 Addenda, which according to FSAR Section 6.9.2.1, "Pump Testing Program

," and Site Engineering Program SEP

-PLP-IST-102, "Inservice Testing of Selected Safety-Related Pumps" is the code of record for Palisades. Comprehensive testing of pumps is performed in order to detect potential degradation of the equipment and helps ensure the SSC will be able to meet its design requirements. During the test, the recorded differential pressure (DP) was 142.0 psid as read on differential pressure indicator DPI-0319A (range 0 to 250 psid). This value was within the Alert Range established by the licensee's procedure. Procedure RO

-98 establishes the different criteria for P

-54A as follows:

The Acceptable Range was a 143.2 to 158.6 psid

The Alert Range was 138.6 to 143.2 psid
The Required Action Range was DP lower than 138.6 psid or greater than 158.6 psid; and The Acceptance Criteria was DP greater than 136.9 psid at 2250 +/

- 35 gpm 19 The licensee documented the test results in the Alert Range under CR

-PLP-2014-01679. The licensee suspected instrumentation issues may have been the cause of the deviation. Site personnel performed a historical search of RO

-98 testing and identified several CRs related to instrumentation issues including CR

-PLP-2010-05181 and CR-PLP-2010-06403. On January 13, 2014

, the DPI-0319A had been calibrated to ensure it was within the comprehensive test required accuracy. On February 26, 2014

, a post-test calibration was performed in accordance with WO 52435851 01. The result of the calibrations showed pressure indicator DPI

-0319A was outside of the test requirements. The results indicated the gauge was reading lower than actual DP. The licensee determined the deviation was approximately 8.75 psid lower and concluded this would indicate an actual DP of approximately 150 psid under RO

-98 conditions for pump P-54A. The licensee concluded this would result in a DP within the acceptable range. In addition to the above, the license performed an assessment of the vibration results obtained and evaluated various pump result trends (comprehensive and quarterly testing) associated with pump performance. Based on this review, documented on CR

-PLP-2014-01679, the licensee concluded pump P

-54A was actually operating within its acceptable range and no additional corrective actions were required.

However, the inspectors were concerned the comprehensive pump test performed on February 25, 2014

, was invalid because it did not meet the requirements specified by the ASME code. Specifically, the requirements for differential pressure instrument accuracy. Per ASME OMb Code

-2003, ISTB

-3510(a) "Accuracy" states:

"Instrument accuracy shall be within the limits of Table ISTB

-3500-1." Table ISTB

-3500-1, "Required Instrument Accuracy," requires the differential pressure instrument accuracy for differential pressure readings during a comprehensive test to be plus or minus 1/2 percent full scale. The post

-test calibration results showed DPI

-0319A did not meet the required accuracy. The ASME code, Section ISTB-6300 "Systematic Error" requires:

"When a test shows measured parameter values that fall outside of the acceptable range of Table ISTB

-5100-1, Table ISTB

-5200-1, Table ISTB

-5300-1, or Table ISTB

-5300-2, as applicable, that have resulted from an identified systematic error, such as improper system lineup or inaccurate instrumentation, the test shall be rerun after correcting the error."

Containment Spray Pump, P

-54A, acceptance values for testing fall under Table ISTB

-5100-1 "Centrifugal Pump Test Acceptance Criteria

." As such, the licensee should have rerun the comprehensive test once DPI

-0319A was shown to be out of calibration.

Failing to perform the IST comprehensive test as prescribe by the code was contrary to Technical Specifications (TS) 5.5.7, which requires an Inservice Testing Program be establish, implemented, and maintained. Section TS 5.5.7 a. establishes the required IST intervals as required by the code. Complete details for pumps IST are contained in Site Engineering Program SEP

-PLP-IST-102, "Inservice Testing of Selected Safety-Related Pumps." The licensee documented the inspectors' concerns and documented the basis of operability under CR

-PLP-2014-04881. The licensee determined the component remained operable based on the evaluation of the instruments calibration and the successful completion of the most recent quarterly IST

.

Analysis:

The inspectors determined the failure to perform comprehensive pump testing of CS pump P

-54A in accordance with the code of record was contrary to Technical Specification 5.5.7., "Inservice Testing

," and a performance deficiency. The performance deficiency was determined to be more than minor because it was associated with the mitigating system cornerstone attribute of equipment performance.

20 The PD adversely affected the associated cornerstone objective to ensure the availability, reliability, and capability of CS pump P

-54A to respond to initiating events to prevent undesirable consequences. Specifically, failing to perform testing as required could result in the degradation of the equipment being undetected.

The inspectors determined the finding could be evaluated using the SDP in accordance with IMC 0609, "Significance Determination Process," Attachment 0609.04," "Initial Characterization of Findings." Specifically, the inspectors used IMC 0609 Appendix A "SDP for Findings At

-Power" Exhibit 2, "Mitigating Systems Screening Questions". The finding was a deficiency affecting the design or qualification of a mitigating structure system or component (SSC) but the SSC maintained its operability. This was based on the licensee's evaluation of recent pump quarterly testing, the risk evaluation performed by the licensee, and allowance to defer performing the surveillance in according with the Technical Specifications. As a result, the finding screened as having a very low safety significance, i.e. Green.

The inspectors determined the findings had a cross

-cutting aspect in the area of Problem Identification and Resolution, Evaluation, because the licensee failed to thoroughly evaluate the issue to ensure that resolutions address causes and extents of conditions commensurate with their safety significance. Specifically, the licensee failed to identify that the out of calibration instrument would result in an invalid IST results, which would require rerunning the test per the code. [P.2]

Enforcement

Palisades Technical Specifications 5.5, "Programs and Manuals

," states: "The following programs shall be established, implemented, and maintained

," Technical Specifications 5.5.7, Inservice Testing Program, states:

"This program provides controls for inservice testing of ASME Code Class 1, 2, and 3 components."

Additionally, Site Engineering Program SEP

-PLP-IST-102, "Inservice Testing of Selected Safety-Related Pumps" provides the details for performing Inservice Testing at Palisades and lists ASME OMb Code

-2001, through ASME OMb Code

-2003 Addenda, as the code of record for Palisades.

Contrary to the above, on February 25, 2014, the licensee failed to rerun a comprehensive pump test of Containment Spray pump P

-54A in accordance with ASME code. Specifically, the licensee failed to meet the requirements of Section ISTB

-6300, "Systematic Error

," which requires licensees, after correcting the error, to rerun tests when the test shows the measured parameter falls outside the acceptable range as a result of a systematic error such as inaccurate instrumentation.

The licensee entered this issue into their Corrective Action Program and evaluated the operability of the component in accordance with their process.

Based on previously successful IST quarterly test the licensee determined the component remained operable.

Because this violation was of very low safety significance, and it was entered into the licensee's Corrective Action Program as CR

-PLP-2014-04881, this violation is being treated as a Green NCV, consistent with Section 2.3.2 of the NRC Enforcement Policy. [NCV 05000255/2014008

-06, Failure to Perform Comprehensive Pump Testing of Containment Spray Pump P

-54A in accordance with the Inservice Testing Program.]

(6) Failure to Correctly Translate Valve Leakage Limits into Test Procedure

Introduction:

The inspectors identified a finding of very low safety significance (Green) and associated NCV of 10 CFR Part 50, Appendix B, Criterion III, "Design Control

," for the licensee's failure to correctly translate design valve leakage limits into test procedures.

Specifically, the acceptance criterion for ECCS/CS recirculation isolation 21 valves CV

-3027 and CV

-3056 had not been correctly adjusted to account for the higher differential pressure associated with ECCS operation under post

-accident conditions.

Description

The inspectors reviewed the leak test procedure and acceptance criteria associated with ECCS/CS recirculation isolation valves CV

-3027 and CV

-3056. These valves were installed in series in the common minimum flow recirculation line from the ECCS and CS pumps to the SIRW tank. During post

-accident operation, these valves remain open during the ECCS injection phase to provide minimum flow protection for the low pressure safety injection (LPSI) and high pressure safety injection (HPSI) pumps. During the recirculation phase of post

-accident operation, these valves are required to be closed to limit the release of radiological material from the SIRW tank vent.

The inspectors observed the design basis alternate source term analysis, NAI

-1149-014, Revision 4 (dated 10/15/07), was based on a maximum allowable recirculation line leakage of 0.00625 gpm (23.7 ml/min).

Test procedure RO

-119, Inservice Testing o f Engineered Safeguards Valves CV

-3027 and CV

-3056, Revision 14 included a leakage acceptance criterion of 25.1 ml/min. The inspectors also observed test Procedure RO

-119 was performed with a LPSI pump in operation. The acceptance criterion had not been correctly adjusted to account for the higher differential pressure associated with HPSI pump operation under post

-accident conditions. The licensee performed an informal evaluation and determined that the correct leakage acceptance criterion would

be 6 ml/min. Condition Report CR-PLP-2014-04681 was initiated to address this issue.

The licensee determined that past leak test results for both CV

-3027 and CV-3056 had exceeded the corrected acceptance criterion of 6 ml/min. However, the most recent leak test results for both CV

-3027 and CV

-3056 were less than 6 ml/min. The licensee also reviewed the results in the context of total containment leakage and verified the past leak test results did not exceed operability limits.

Analysis:

The inspectors determined the failure to correctly translate design valve leakage limits into test procedures was contrary to 10 CFR Part 50, Appendix B, Criterion III, "Design Control," and was a performance deficiency. The performance deficiency was determined to be more than minor because it was associated with the Barrier Integrity Cornerstone attribute of Design Control and it adversely affected the associated cornerstone objective to provide reasonable assurance that containment could protect the public from radionuclide releases caused by accidents or events. Specifically, measured leakage exceed ed analyzed dose calculations

.

The inspectors determined the finding could be evaluated using the SDP in accordance with Inspection Manual Chapter (IMC) 0609, "Significance Determination Process,"

0609.04, "Initial Characterization of Findings," issued on June 19, 2012. Because the finding impacted the Barriers Cornerstone, the inspectors screened the finding through IMC 0609 Appendix A, "The Significance Determination Process for Findings At

-Power," issued June 19, 2012, using Exhibit 3, "Barrier Integrity Screening Questions." The finding screened as of very low safety significance (Green) because the inspectors answered "No" to all of the screening questions in Subsection B, "Reactor Containment," of Exhibit 3. Specifically, the finding did not represent an actual open pathway in the physical integrity of reactor containment, containment isolation system, or heat removal components and did not involve an actual reduction in function of hydrogen igniters in the reactor containment. The inspectors determined this finding did not have an associated cross

-cutting aspect because it was not representative of the licensee's present performance.

22

Enforcement:

Title 10 CFR Part 50, Appendix B, Criterion III, "Design Control," requires, in part, that measures shall be established to assure that applicable regulatory requirements and the design basis, as defined in §50.2 and as specified in the license application, for those structures, systems, and components to which this appendix applies are correctly translated into specifications, drawings, procedures, and instructions.

Contrary to the above, as of September 25, 2014, the licensee failed to correctly translated design leakage limits into the test procedure for valves CV-3027 and CV

-3056. Because this violation was of very low safety significance and was entered into the licensee's CAP as CR

-PLP-2014-04681, this violation is being treated as an NCV, consistent with Section 2.3.2 of the NRC Enforcement Policy. [NCV 05000255/2014008

-07, "Failure to Correctly Translate Valve Leakage Limits into Test Procedure

." (7) Failure to Identify Non

-Safety-Related Sub-Components Improperly Supplied with Safety-Related Valves Introduction

The inspectors identified a finding of very low safety significance (Green) and associated NCV of 10 CFR Part 50, Appendix B, Criterion VII, "Control of Purchased Material, Equipment, and Services," for the licensee's failure to identify non-safety-related sub

-components improperly supplied with safety

-related valves. Specifically, ECCS/CS recirculation isolation valves CV

-3027 and CV

-3056, which were installed in 2007, were supplied with non

-safety-related sub

-components. These components were identified as non

-safety- related on the vendor drawings. In addition, the licensee later installed a section of non

-safety-related tubing on valve CV

-3027 based on the incorrect vendor drawing.

Description

The inspectors reviewed the vendor drawings for safety

-related ECCS/CS recirculation isolation valves CV

-3027 and CV

-3056, which were installed in 2007. Drawings VEN

-M241BC, Sheet 33, Revision 0 and VEN

-M241BC, Sheet 35, Revision 0 listed the sub

-components associated with these valves and identified the quality classification of each sub

-component. The inspection team noted that some of the sub

-components appeared to be incorrectly classified as non

-safety-related. The licensee investigated and determined the drawings were incorrect and that some of these components were actually supplied as safety

-related; however, several cap screws were inappropriately supplied as non

-safety-related. Condition report CR

-PLP-2014-04755 was initiated to correct the drawings and replace the non-safety-related cap screws with safety-related material.

The licensee performed additional investigation and determined a section of non-safety-related tubing had been installed on valve CV

-3027 during maintenance activities; this error was based on the incorrect vendor drawing.

Condition report CR

-PLP-2014-04815 was initiated to correct the drawings and replace the tubing with safety-related material. The licensee performed an evaluation and determined both valves were operable in their current condition.

Analysis:

The inspectors determined the failure to identify non

-safety-related sub-components improperly supplied with safety-related valves was contrary to 10 CFR Part 50, Appendix B, Criterion VII, "Control of Purchased Material, Equipment, and Services," and was a performance deficiency. The performance deficiency was determined to be more than minor because it was associated with the Barrier Integrity Cornerstone attribute of Design Control and it adversely affected the associated cornerstone objective to provide reasonable assurance that containment could protect 23 the public from radionuclide releases caused by accidents or events. Specifically, the licensee failed to verify the sub

-components of valves CV

-3027 and CV

-3056 met their design requirements.

The inspectors determined the finding could be evaluated using the SDP in accordance with Inspection Manual Chapter (IMC) 0609, "Significance Determination Process," Attachment 0609.04, "Initial Characterization of Findings," issued on June 19, 2012. Because the finding impacted the Barriers Cornerstone, the inspectors screened the finding through IMC 0609 Appendix A, "The Significance Determination Process for Findings At

-Power," issued June 19, 2012, using Exhibit 3, "Barrier Integrity Screening Questions." The finding screened as of very low safety significance (Green) because the inspectors answered "No" to all of the screening questions in Subsection B, "Reactor Containment," of Exhibit 3. Specifically, the finding did not represent an actual open pathway in the physical integrity of reactor containment, containment isolation system, or heat removal components and did not involve an actual reduction in function of hydrogen igniters in the reactor containment. The inspectors determined this finding did not have an associated cross

-cutting aspect because it was not representative of current performance.

Enforcement

Title 10 CFR Part 50, Appendix B, Criterion VII, "Control of Purchased Material, Equipment, and Services," requires, in part, that measures shall be established to assure that purchased material, equipment, and services, whether purchased directly or through contractors and subcontractors, conform to the procurement documents.

Contrary to the above, as of September 25, 2007 and October 8, 2007, when these valves were installed, the licensee failed to assure that purchased material conformed to the procurement documents.

Because this violation was of very low safety significance and was entered into the licensee's CAP as CR

-PLP-2014-04755 and CR

-PLP-2014-04815, this violation is being treated as an NCV, consistent with Section 2.3.2 of the NRC Enforcement Policy. [NCV 05000255/2014008

-08, "Failure to Identify Non

-Safety-Related Sub-Components Improperly Supplied with Safety

-Related Valves."

] (8) Failure to Establish an Adequate Test Program for the Shutdown Cooling Heat Exchangers

Introduction:

The inspectors identified a finding of very low safety significance (Green) and associated NCV of 10 CFR Part 50, Appendix B, Criterion XI, "Test Control," for the licensee's failure to establish an adequate test program for the Shutdown Cooling (SDC) Heat Exchangers (HXs) to demonstrate they can perform as designed. Specifically, the licensee failed to take actions to ensure the SDC HXs' heat transfer capability met its design bases, as assumed in design bases calculations.

Description

The SDC HXs were designed for use during primary system cooldown, refueling, and emergency plant operation. During plant cooldowns and refueling outages, the HXs remove decay heat by directly cooling the primary coolant system. During emergency plant operations, the HXs form part of the containment cooling system by cooling the containment spray water. In addition, during the recirculation phase of a loss of coolant accident (LOCA), the SDC HXs cool the containment sump water that is injected by the High Pressure Safety Injection (HPSI) pumps to provide long term core cooling.

The SDC HXs are original plant equipment that has been intermittently operated since the beginning of plant operations in 1971. In over 40 years, they have never been 24 inspected, contrary to vendor recommendations. Section E

-4.1 of the vendor manual states that, "at intervals as experience indicates, an examination should be made of the interior and exterior condition of all tubes." Since the licensee has never inspected the interior of the SDC HXs, they have not established a frequency for performing the HX inspections as recommended by the vendor manual.

In addition, the SDC HXs have never been successfully thermal performance tested. In 1992, the licensee identified the need to thermal performance test the SDC HXs to verify they could perform as designed. However, because they were successfully performing their SDC function and because both water streams flowing through the HXs had chemistry controls in place, the licensee decided it was not necessary to perform the test. In 1996, the licensee completed a thermal performance test, but the analysis of the test results concluded the test did not achieve its goal of recording useful data. The test has never been repeated, and the licensee instead continues to credit the SDC function and the chemistry controls in place to provide assurance that the SDC HXs can perform as designed.

In 1989 the NRC issued Generic Letter (GL) 89

-13, "Service Water System Problems Affecting Safety

-Related Equipment." Although the GL was mostly related to open cycle cooling water systems, it did contain the following guidance related to closed cycle cooling water systems:

"Operating experience and studies indicate that closed

-cycle service water systems, such as component cooling water systems, have the potential for significant fouling as a consequence of aging

-related in

-leakage and erosion or corrosion. The need for testing of closed

-cycle system heat exchangers has not been considered necessary because of the assumed high quality of existing chemistry control programs. If the adequacy of these chemistry control programs cannot be confirmed over the total operating history of the plant

[emphasis added] or if during the conduct of the total testing program any unexplained downward trend in heat exchanger performance is identified that cannot be remedied by maintenance of an open

-cycle system, it may be necessary to selectively extend the test program and the routine inspection and maintenance program addressed in Action III, below, to the attached closed

-cycle systems.

" Therefore, the NRC recognized that testing of closed cycle system heat exchangers was not necessary if high quality chemistry control programs were in place. However, this was dependent on whether or not the adequacy of the chemistry control programs could be confirmed over the total operating history of the plant. Although Palisades has chemistry controls in place for both water streams (Primary Coolant System and Component Cooling Water) flowing through the SDC HXs, the licensee ha d not verified the effectiveness of these chemistry controls in preventing degradation of the SDC HXs heat transfer capability.

The chemistry controls, in themselves, are not enough to demonstrate the SDC HXs can perform as assumed in design bases calculations.

The licensee also credits the SDC function of the HXs to provide justification that they can perform as designed. However, during SDC, the water temperatures and flow rates through the HX are different than those during emergency plant operation, and the licensee does not monitor or trend the SDC performance of the HXs to detect degradation. Therefore, although the HXs are successfully performing the routine SDC function, the licensee does not gather nor analyze sufficient HX performance information to demonstrate the HXs can perform as assumed in design bases calculations.

25 The issue was entered into the licensee's Corrective Action Program as CR

-PLP-2014-04912 to review the adequacy of testing performed to ensure the SDC HXs remain qualified to the capability assumed during design bases events.

Based upon the available tube plugging margin and recent history of chemistry controls, the inspectors gained reasonable assurance of operability.

Analysis:

The inspectors determined the failure to establish an adequate test program for the SDC HXs to demonstrate they could perform as designed was contrary to 10 CFR Part 50, Appendix B, Criterion XI, "Test Control," and was a performance deficiency. The performance deficiency was determined to be more than minor because it was associated with the Barrier Integrity Cornerstone attribute of Design Control and it adversely affected the associated cornerstone objective to provide reasonable assurance that containment could protect the public from radionuclide releases caused by accidents or events. Specifically, the licensee failed to verify that the SDC HXs heat transfer capability met their design bases, as assumed in design bases calculations, to limit containment temperatures and pressures during an event.

The inspectors determined the finding could be evaluated using the SDP in accordance with Inspection Manual Chapter (IMC)0609, "Significance Determination Process," Attachment 0609.04, "Initial Characterization of Findings," issued on June 19, 2012. Because the finding impacted the Barriers Cornerstone, the inspectors screened the finding through IMC 0609 Appendix A, "The Significance Determination Process for Findings At

-Power," issued June 19, 2012, using Exhibit 3, "Barrier Integrity Screening Questions." The finding screened as of very low safety significance (Green) because the inspectors answered "No" to all of the screening questions in Subsection B, "Reactor Containment," of Exhibit 3. Specifically, the finding did not represent an actual open pathway in the physical integrity of reactor containment, containment isolation system, or heat removal components and did not involve an actual reduction in function of hydrogen igniters in the reactor containment.

The inspectors determined this finding had an associated cross

-cutting aspect, Conservative Bias, in the Human Performance cross

-cutting area

. Specifically, on several occasions and as recently as October 2012 when the licensee identified the need to perform testing and/or inspection of the SDC HX s, the licensee did not take actions because they did not believe any regulatory requirements or technical issues existed that required the testing and/or inspections. [H.14]

Enforcement:

Title 10 CFR Part 50, Appendix B, Criterion XI, "Test Control," requires, in part, that a test program shall be established to assure all testing required to demonstrate structures, systems, and components will perform satisfactorily in service is identified and performed in accordance with written test procedures which incorporate the requirements and acceptance limits contained in applicable design documents.

Contrary to the above, as of November 4, 2014

, the licensee failed to establish an adequate test program for the SDC HXs to demonstrate they could perform as designed. Specifically, the licensee failed to take actions to ensure the heat transfer capability of the SDC HXs met their design bases, as assumed in design bases calculations.

Because this violation was of very low safety significance and was entered into the licensee's CAP as CR

-PLP-2014-04912, this violation is being treated as an NCV, consistent with Section 2.3.2 of the NRC Enforcement Policy. [NCV 05000255/20 14008-09, "Failure to Establish an Adequate Test Program for the Shutdown Cooling Heat Exchangers

"]

(9) Failure To Include The Degraded Voltage Channel Time Delay In TS Surveillance Requirement 3.3.5.2.a Introduction

The inspectors identified a finding having very low safety significance and an associated Non-Cited Violation (NCV) of 10 CFR Part 50.36(c)(3), "Surveillance Requirements," for the failure to ensure the channel time delay for the degraded

-voltage monitor was included in TS SR 3.3.5.2.a. Specifically, the licensee had only included the timing requirements for the voltage sensing relay in the TS SR; failing to include the required time delay after the voltage sensing relay trips before the preferred source of power is isolated and 1E electrical loads transferred to the stand

-by EDGs. Description

The inspectors noted TS SR 3.3.5.2, Revision 189, requires the licensee to "Perform a CHANNEL CALIBRATION on each Loss of Voltage and Degraded Voltage channel with setpoints-:" Part a. of SR 3.3.5.2 gives the degraded voltage function setpoint but only gives the time delay associated with the sensing element of the degraded voltage monitor. However, a channel of the degraded voltage monitor contains both the voltage sensing relay and a nominal 6

-second delay timer which has to time out before the trip relay actuates and off-site power supply breaker is opened.

The inspectors reviewed an NRC letter to the licensee dated December 22, 1981

, with the Subject:

SEP Topic VIII

-1.A, "Potential Equipment Failures Associated With Degraded Grid Voltage." Enclosure 1 to this letter was the NRC staff's Safety Evaluation Report (SER) on degraded grid voltage protection for the Class 1E System. The SER conclusions were based on a detailed review and technical evaluation of the licensee's proposed modifications and changes to the Technical Specifications. This SER referenced EG&G Interim Report No. EGG

-EA-5321, Revision 3, Degraded Grid Protection for Class 1E Power Systems, Palisades Plant, Docket No. 50

-255, TAC No. 10043, Section 3.3, "Discussion," Paragraph 3, which states, in part, "The time delay selected shall be based on the following conditions:

a; The allowable time delay, including margin, shall not exceed the maximum time delay that is assumed in the FSAR accident analysis, and b

The time delay shall minimize the effect of short duration disturbances from reducing the unavailability of the offsite power source(s)." Paragraph 4 states, "The voltage monitors shall automatically initiate the disconnection of offsite power sources whenever the voltage setpoint and time

-delay limits have been exceeded." Paragraph 6 states

, "The Technical Specifications shall include limiting conditions for operations, surveillance requirements, setpoints with minimum and maximum limits, and allowable values for the second

-level voltage protection monitors." (Note that the degraded voltage setpoint is also known as the second

-level voltage relay setpoint.) The total time delay evaluated by EGG was a nominal 6 seconds added to the time for the voltage relay to activate. From these statements, it was clear that a degraded voltage monitor channel consisted of both the voltage sensing relay and the delay timer.

The licensee did not make a change to the custom TS but decided to enter the changes when implementing the standardized Combustion Engineering TS. The inspectors reviewed the Combustion Engineering STS Bases 3.3.7.3

, which states, in part, "SR 3.3.7.3 is the performance of a CHANNEL CALIBRATION. The CHANNEL CALIBRATION verifies the accuracy of each component within the instrument channel." Additionally, NRC Regulatory Issue Summary 2011

-12, Revision 1, "Adequacy of Station Electric Distribution System Voltages," again states, in part, "The voltage monitors (or DVRs) shall automatically initiate the disconnection of offsite power source(s) whenever the voltage and time delay limits have been exceeded," and "The Technical 27 Specifications shall include -

Allowable values for second

-level voltage protection DVRs." After the inspectors communicate d this concern as a non-conservative TS, the licensee initiated condition report CR

-PLP-2014-04903, "TS SR 3.3.5.2 is Non

-Conservative

," and implemented administrative controls in accordance with Administrative Letter 98

-10 for SR 3.3.5.2 degraded voltage time. The operability evaluation found the diesel generator under voltage start circuitry to be operable DNC [degraded non

-conforming] because the total time delay had been checked and calibrated to within acceptable values

.

Analysis:

The inspectors determined the failure to incorporate the total time delay in the 2400 V Class 1E bus degraded voltage monitor channel trip setpoints in the Technical Specification surveillance requirements was contrary to 10 CFR Part 50.36(c)(3), and was a performance deficiency. The performance deficiency was determined to be more than minor because if left uncorrected, it would have the potential to lead to more significant safety concern. Specifically, by not incorporating the total time delay requirements into the Technical Specifications, the time could be changed without going through the TS change process, possibly leading to spurious trips of offsite power sources or possibly exceeding the accident analysis time is the FSAR.

In accordance with Inspection Manual Chapter (IMC) 0609, "Significance Determination Process," Attachment 0609.04, "Initial Characterization of Findings," Table 2 the inspectors determined the finding affected the Initiating Events cornerstone due to the potential to initiate a loss of offsite power. As a result, the inspectors determined the finding could be evaluated using Appendix A, "The Significance Determination Process (SDP) for Findings At

-Power," Exhibit 1, "Initiating Events Screening Questions." The inspectors determined the finding was of very low safety significance (Green) because it did not cause a reactor trip and the loss of mitigation equipment relied upon to transition the plant from the onset of the trip to a stable shutdown condition.

The inspectors did not identify a cross

-cutting aspect associated with this finding because the finding was not representative of the licensee's present performance.

Enforcement

Title10 CFR Part 50.36(c) states, Technical Specifications will include minimum surveillance requirements.

Title10 CFR Part 50.36(c)(3) "Surveillance Requirements," states, in part, "are requirements relating to test, calibration, or inspection to assure that the necessary quality of systems and components is maintained, that facility operation will be within safety limits, and that the limiting conditions for operation will be met."

Contrary to the above, as of October 9, 2014, the licensee failed to include within TS SR the total time delay for all components in the degraded voltage

, which is required to maintain facility operation within safety limits. Specifically, the licensee failed to incorporate the total time delay for all of the components in a channel as required in a CHANNEL CALIBRATION. Because this violation was of very low safety significance, and it was entered into the licensee's Corrective Action Program as CR-PLP-2014-04903, this violation is being treated as an NCV, consistent with Section 2.3.2 of the NRC Enforcement Policy. [NCV 05000255/2014008

-10, Failure To Include The Degraded Voltage Channel Time Delay In TS Surveillance Requirement 3.3.5.2.a].

(10) Lack of Analysis for Electrical Containment Penetration Protection Introduction

The inspectors identified an unresolved item (URI) regarding lack of an analysis to demonstrate that circuit breakers and fuses provide adequate protection 28 against short circuits and overloads for electrical containment penetrations, as discussed in Regulatory Guide 1.63.

Resolution of this issue will be based on clarification of Palisade's licensing basis by NRC staff.

Description:

As part of the review of power supplies to components inside containment, the inspectors requested to review the analysis that demonstrates protection of the electrical penetrations against short circuits and overloads. The licensee responded that such an analysis does not exist, and stated their position that it is not required by their design and licensing bases.

Electrical protection of containment penetrations was the subject of the Palisades Systematic Evaluation Program (SEP) Topic VIII

-4. A letter from Dennis M. Crutchfield, NRC, to David P. Hoffman, Consumers Power Company, "SEP Topic VIII

-4, Electrical Penetrations of Reactor Containment," dated March 26, 1981

, (ADAMS Accession No. ML8104080152) included an enclosure entitled "Position on Protection of Containment Electrical Penetrations against Failures Caused by Fault and Overload Currents for SEP Plants." This position document states:

"-the staff requires compliance with the recommendations of Regulatory Guide 1.63 or an acceptable alternative method. For each containment electrical penetration, the protective systems provide primary and backup protection devices to prevent a single failure in conjunction with a circuit overload from impairing containment integrity."

The licensee responded in a letter from Robert A. Vincent, Consumers Power Company, to Dennis M. Crutchfield, NRC, "SEP Topic VIII

-4, Electrical Penetrations of Reactor Containment," dated June 15, 1981

, (ADAMS Accession No. ML8106180170), in which they stated:

"The secondary (backup) interrupt devices

(-) would fail to trip prior to the penetration reaching its limiting temperature of 302° C with the postulated combination of faults and failure of the primary interrupters." The licensee committed to perform more detailed evaluations of the capabilities of the protective devices, as well as "An evaluation of the adequacy of the Palisades Plant overcurrent protection surveillance testing program." In the following subsequent letters, the licensee reported on the progress of their further evaluations:

Letter from Robert A. Vincent, Consumers Power Company, to Dennis M. Crutchfield, NRC, "SEP Topic VIII

-4, Electrical Penetrations of the Reactor Containment," dated November 16, 1981

, (ADAMS Accession No. ML8111200805); Letter from Kerry A. Toner, Consumers Power Company, to Dennis M. Crutchfield, NRC, "SEP Topic VIII

-4, Electrical Penetrations of the Reactor Containment," dated October 12, 1982

, (ADAMS Accession No. ML8210190459); and letter from Kerry A. Toner, Consumers Power Company, to Dennis M. Crutchfield, NRC, "SEP Topic VIII

-4, Status Update of Program to Evaluate the Adequacy of Penetration Protection from Overload and Sho rt-Circuit Conditions," dated February 11, 1983

, (ADAMS Accession No. ML8302240273).

The NRC issued their Integrated Plant Safety Assessment Report on this SEP Topic in Letter from Thomas V. Wambach, NRC, to David J. VandeWalle, Consumers Power Company, "Integrated Plant Safety Assessment Report (IPSAR) Section 4.26, Electrical Penetrations of Reactor Containment

- Palisades Plant," dated June 10, 1983

, (ADAMS Accession No. ML8306160396). This IPSAR stated

, "The staff has evaluated this issue for other plants- and concluded that no further action was required for these plants

. Based upon the information contained in the licensee's letters dated June 15, 1981, October 12, 1982

, and February 11, 1983, the staff concludes that the design of the Palisades electrical penetrations are similar to other SEP plants, that the probability of electrical failure is low and that any leakage path due to penetration failure would be small. Therefore, we consider this issue to have been completed satisfactorily and 29 further action by the licensee is not required." This conclusion was reiterated in NUREG 0820, Supplement 1, "Integrated Plant Safety Assessment, Systematic Evaluation Program, Palisades Plant, Final Report," dated November 1983

, (ADAMS Accession No. ML8311290133). The inspectors requested that the licensee discuss their lack of an analysis for electrical penetration protection in light of Palisades FSAR Section 8.5.1.2, which states: "10 CFR Part 50, General Design Criterion 50, as implemented by Regulatory Guide 1.63 and IEEE Standard 317

-1972, requires that electrical penetrations be designed so that the containment structure can accommodate, without exceeding the design leakage rate, the calculated pressure, temperature and other environmental conditions resulting from any Loss of Coolant Accident (LOCA)." The licensee responded by initiating corrective action CR

-PLP-2014-04450, which states the licensee's position that Palisades is not committed to "the electrical circuit protection requirements of Regulatory Guide 1.63."

Due to complexity of establishing the appropriate design and licensing bases for this issue, the concern will be resolved using the NRC's Task Interface Agreement (TIA) process. Pending resolution, this item will be tracked as an unresolved item. [URI 05000255/201400 8-05, Lack of Analysis for Electrical Containment Penetration Protection].

(11) Classification of CCW Piping and Components Inside the Reactor Containment Building Introduction

The inspectors identified an unresolved issue (URI) regarding the Inservice Inspection (ISI) classification of component cooling water (CCW) piping and components inside the reactor containment building. This piping is currently classified as non

-safety-related. Resolution of this issue will be based on clarification of Palisade's licensing basis by NRC staff.

Description

The inspectors reviewed SEP

-ISI-PLP-002, ASME Code Boundaries for ASME Section XI Inservice Inspection Program, Revision 1. The purpose of this document was to establish classifications to ensure the proper scope of ASME Section XI system pressure tests, ASME Section V nondestructive examinations, ASME Section XI inspection of component supports, and ASME Section XI repairs, replacements and modifications. This program document stated that guidance for Class 2, 3, and non

-safety-related components is found in Regulatory Guide 1.26. The program referred to a set of color

-coded P&IDs.

The inspectors noted the CCW piping and components inside the reactor containment building were identified as non

-safety-related on the color

-coded P&IDs. The team also observed that Attachment 1 of SEP

-ISI-PLP-002 (page 45 of 75) identified the piping from the containment penetrations to the single containment isolation valve outside containment as class 2 (check valve CK

-CC910 for penetration MZ

-14, air-operated valve CV-0911 for penetration MZ

-15). This attachment referred to note H, which stated, in part: All containment penetration assemblies in Class 2, Class 3, and non

-class piping will be considered ASME Class 2 out to the second isolation valve where applicable.

In some cases, there is single isolation (e.g., MSS, FWS)- Where a Class 3 system penetrates containment, that portion will be considered Class 2 and treated as such (ie, ASME Section XI Interpretation BC84

-603). The basis for classification of containment penetrations is contained in EGAD

-EP-12, "Mechanical Containment Penetrations Basis Program".

30 The current Mechanical Containment Penetrations Basis document was SEP

-APJ-PLP-101, Revision 0. This document included a similar description for CCW penetrations MZ-14 and MZ

-15. It stated that FSAR Table 5.8

-4 classifies these penetrations as class C1. The FSAR table also identified these penetrations as Class C1 and indicated that they are not subject to 10 CFR Part 50, Appendix J testing requirements. The FSAR Section 6.7 included a description of Class C1 penetrations, it stated, in part:

Penetrations in this class include those systems that are not connected to either the containment atmosphere or to the Primary Coolant System and are normally open or may be opened during power operation.

These lines are protected from missiles originating inside the containment and the lines themselves form the boundary of the containment.

One remote manually operated valve, locked closed manual valve or automatic isolation valve is provided in each line.

Check valves are considered automatic.

In SEP-APJ-PLP-101 also stated

, that both Penetrations MZ

-14 and MZ

-15 were originally classified as C2 (closed system outside containment per FSAR Section 6.7), until FSAR Revision 22. These were reclassified by SDR 0884, dated July 22, 199

9. The basis for these changes included an evaluation that determined CCW piping inside

containment would not be damaged by internal missiles (as addressed by NRC's evaluation of SEP Topic III

-4,c, dated September 21, 1981)

, and the classification of CCW as a closed system inside containment. The associated 10 CFR 50.59 evaluation determined that NRC approval was not required for these changes.

The inspection team raised questions regarding the licensing basis classification of the CCW system inside containment:

1. FSAR Section 6.9 stated that Regulatory Guide 1.26 was used to select ASME Classes 2 and 3 systems and components for coverage by the inspection plan. Regulatory Guide 1.26, stated in part:

The Quality Group C standards given in Table 1 of this guide should be applied to water-, steam-, and radioactive

-waste-containing pressure vessels; heat exchangers (other than turbines and condensers); storage tanks; piping; pumps; and valves that are not part of the reactor coolant pressure boundary or included in Quality Group B but part of the following:

-(b) cooling water and seal water systems or portions of those systems important to safety that are designed for the functioning of components and systems important to safety, such as reactor coolant pumps, diesels, and the control room-The classification of the CCW system inside containment did not appear to be consistent with the guidance of Regulatory Guide 1.26. In addition, industry guidance provided by ANSI/ANS 51.1

- 1983 indicated that closed systems inside containment (with single active isolation valves) should be class 2 or class 3.

2. FSAR Section 6.7 addressed class C1 containment penetrations stating, "These lines are protected from missiles originating inside the containment and the lines themselves form the boundary of the containment." The inspectors questioned whether it was appropriate to classify a portion of the containment boundary as non

-safety-related for the purpose of inspection, testing, and repairs.

31 The licensee has stated that the CCW system classification is in accordance with their current licensing basis. This position is primarily based on the NRC's evaluation of SEP Topic III

-4,c, dated September 21, 1981, the CCW system being protected from internal missiles, and seismic events not being postulated to occur coincidently with a LOCA.

Resolution of this issue will be based on clarification of Palisade's licensing basis.

Pending resolution, this item will be tracked as an URI. [URI 05000255/201400 8-11, Classification of CCW Piping and Components Inside the Reactor Containment Building.] (12) Component Cooling Water System Licensing Bases Introduction

The inspectors identified an Unresolved Item (URI) regarding the licensing bases for the Component Cooling Water (CCW) system. Specifically, the inspectors require clarification as to what failures of the CCW system the licensee needs to postulate and evaluate. The NRC will conduct further inspection to determine when these changes to the licensing bases occurred.

Description

As part of the 2014 Component Design Bases Inspection (CDBI), the inspectors selected CCW pump P

-52B and relief valve RV

-0956 for review. Both of these components were part of the CCW system. The CCW system was designed as a closed cycle system, where both trains share a common suction and common discharge header. This means that although there were redundant pumps and heat exchangers, the system's piping was not designed to be redundant and a single pipe break or failure of the pressure boundary could result in the complete loss of CCW. One of CCW's safety functions was to transfer heat from the reactor and containment (post

-Design Bases Events/Accidents) to the ultimate heat sink. Another important safety function for CCW was to provide cooling to the Engineered Safeguard Systems' (ESS) and containment spray (CS) pumps. Per the licensee's design bases, cooling to the ESS pumps was required to maintain their operability.

When reviewing the licensing bases for the plant, it was not clear what type of failures needed to postulated for the CCW system under post

-accident conditions. The licensee's position was postulating a passive failure of CCW concurrent with a design bases accident (DBA) was not within their licensing bases. The licensee's position was that no active single failure, according to their definition in FSAR Section 1.4.16, would render CCW inoperable. They also considered a postulated failure of the non-safety-related portion of the CCW system inside containment as beyond design bases, except as result of a seismic event which was not postulated to occur in conjunction with an accident.

Currently, the licensee credits post-accident heat being removed from containment by a combination of containment air coolers (CAC) and the containment spray (CS) system. The CAC are supplied by service water and are independent of the CCW system. Per the current design, the licensee needs either two CS pumps or one CS pump and three CACs. Both alternatives require the CCW system to remove heat from the CS system. However, the original design took credit for the CS and the CAC as independent and redundant in their capability to remove heat from the containment. In other words, originally the licensee needed either two CS pumps or three CACs.

Additionally, the original design allowed for the capability to swap cooling water to the ESS pumps from CCW to service water remotely from the main control room (MCR). Both of these design flexibilities have been either lost or eliminated due to subsequent design changes

.

32 The inspectors noted the agency staff had previously evaluated the susceptibility of CCW to loss of function following certain assumed CCW pipe breaks during the Systematic Evaluation Program(SEP). This was documented on SEP Topic IX

-3, Station Service and Cooling Water Systems Palisades, February 22, 1982.

The agency staff had concluded the CCW design was not in conformance with GDC 44, regarding capability and redundancy of essential functions of the system. However, the staff noted the essential functions of CCW could be performed by other systems under all operating conditions. The SEP evaluation explicitly addressed a passive failure of the CCW system under post

-accident conditions and concluded that the CACs would be capable of removing heat from containment.

The inspectors were concerned that if the CCW system became inoperable as the result of non-safety-related component failures, the plant would no longer have the redundant capability to remove heat from the containment during a DBA, or provide alternate cooling to the ESS pumps from the MCR. In addition, the inspectors needed to clarify the licensing bases regarding a postulated loss of CCW concurrent with a design bases accident.

This issue is unresolved pending further inspection to determine when these changes to the licensing bases occurred. [URI 05000255/2014008

-12, Component Cooling Water System Licensing Bases]

.4 Operating Experience

a. Inspection Scope

The inspectors reviewed six operating experience issues to ensure that NRC generic concerns had been adequately evaluated and addressed by the licensee. The operating experience issues listed below were reviewed as part of this inspection:

Information Notice 1988

-45, "Problems in Protective Relay and Circuit Breaker Coordination

" Information Notice 2010

-09, "Importance of Understanding Circuit Breaker Control Panel Indications"

Information Notice 2010

- 11, "Potential for Steam Voiding Causing Residual Heat Removal System Inoperability

"; Regulatory Issue Summary 2013

-05, "NRC Position On The Relationship Between General Design Criteria and Technical Specification Operability

"; NRC-21-2013-60-00 and -01, "K-Line Circuit Breaker Primary Close Latch

"; and IER-L4-13-54, "Unprotected DC Ammeters Result in Unanalyzed Condition."

b. Findings

No findings of significance were identified.

.5 Modifications

a. Inspection Scope

The inspectors reviewed one permanent plant modification related to selected risk significant components to verify that the design bases, licensing bases, and performance capability of the components had not been degraded through modifications. The modification listed below was reviewed as part of this inspection effort:

FC-718,RAS Logic Seal

-In Circuit Addition

b. Findings

No findings of significance were identified.

.6 Operating Procedure Accident Scenario

s

a. Inspection Scope

The inspectors performed a detailed review of the operator actions and the procedures listed below associated with the selected components and associated with risk important operator actions. For the procedures listed, simulator scenarios were observed as applicable, and in

-plant actions were walked down with a non

-licensed operator or a licensed operator as appropriate. These activities were performed to determine whether there was sufficient information to perform the procedure, whether the steps could reasonably be performed in the available time, and whether the necessary tools and equipment were available. The procedures were compared to FSAR and design assumptions. In addition, the procedures were reviewed to ensure the procedure steps would accomplish the desired results.

The following Time Critical Operator Actions (TCAs) and accidents were reviewed:

TCA 1: "Enable Closure of the ESS recirculation valves on RAS,"

TCA 6: "Align hot leg injection,"

TCA 44: "Switch CR HVAC to Emergency Mode,"

TCA 47: "ESS Suction Header Cross

-Tie," Large Break Loss of Coolant Accident (LBLOCA),

Mode 4 Loss of Coolant Accident (LOCA).

The following procedures were reviewed:

Administrative Procedure TCA, "Control of Time Critical Operator Actions," Revision 3; Emergency Operating Procedure Basis EOP TCA, "EOP Time Critical Operator Action Basis," Revision 0; Emergency Operating Procedure EOP

-4.0, "Loss of Coolant Accident Recovery," Revision 23; Emergency Operating Procedure Supplement 42, "Pre and Post RAS Actions," Revision 7 Abnormal Operating Procedure AOP

-30, Loss of Shutdown Cooling," Revision 1.

b. Findings

No findings of significance were identified.

OTHER ACTIVITIES

4OA2 Identification and Resolution of Problems

.1 Review of

Items Entered Into the Corrective Action Program

a. Inspection Scope

The inspectors reviewed a sample of the selected component problems that were identified by the licensee and entered into the Corrective Action Program. The inspectors reviewed these issues to verify an appropriate threshold for identifying issues and to evaluate the effectiveness of corrective actions related to design issues. In addition, corrective action documents written on issues identified during the inspection were reviewed to verify adequate problem identification and incorporation of the problem into the Corrective Action Program. The specific corrective action documents that were sampled and reviewed by the inspectors are listed in the attachment to this report.

The inspectors also selected six issues that were identified during previous CDBIs to verify the concern was adequately evaluated and corrective actions were identified and implemented to resolve the concern, as necessary. The following issues were reviewed:

NCV 05000255/2006009

-08, "Emergency Diesel Generator Fuel Transfer System Temperature Ratings"

NCV 05000255/2006009

-10, "Potential for Safety Injection and Refueling Water Tank Level Switch Setpoints to be Outside Technical Specification Limit

"; NCV 05000255/2008009

-01, "Inadequate Analysis of Emergency Diesel Generator 1-2 Loading During Design Basis Events

"; NCV 05000255/2008009

-02, Failure to Establish Correct Technical Specification Limits"; NCV 05000255/2011009

-01, Failure to Adequately Evaluate the Enclosure Installed Over the 1F/1G Buses

"; and NCV 05000255/2011009

-03, "Procedures Were Not Appropriate To Address Gas Accumulation Issues"

b. Findings

(1) Non-Conservative Surveillance for Emergency Diesel Generator Largest Load Reject Test Introduction

A finding of very low safety significance and associated Non-Cited Violation of 10 CFR Part 50, Appendix B, Criterion XI, "Test Control,"

was identified by the inspectors for the licensee's failure to have adequate acceptance criteria in the emergency diesel generator surveillance procedures.

Specifically, the licensee failed to ensure the surveillance test procedures for the emergency diesel generator largest load reject test bounded the power demand of the largest load, as required by Technical Specification SR 3.8.1.

5 based upon full load reject testing

. Description

Palisades Technical Specification Surveillance Requirement SR 3.8.1.5 requires verification of the emergency diesel generator response following rejection of "a load greater than or equal to its associated single largest post

-accident load." On June 20, 2013, the licensee issued Technical Specification Surveillance Procedure RE

-132, "Diesel Generator 1

-2 Load Reject," Revision 6. This procedure specifies, in Step 5.3.11, that the emergency diesel generator be loaded to "325 to 375 kw" in preparation 35 for the load reject test. On August 6, 2014, the licensee issued calculation EA

-ELEC-LDTAB-005, "Emergency Diesel Generators 1

-1 and 1-2 Steady State Loadings," Revision 10, which includes documentation of the magnitudes of the emergency diesel generator loads. The inspectors asked the licensee to compare the calculation data with the procedure criterion for a minimum test load of 325kW. The licensee concluded that, according to the calculation, the largest single emergency diesel generator load is High Pressure Safety Injection Pump P

-66A, which has a power demand of 360.25kW. Thus, surveillance Procedure RE

-132 allows an emergency diesel generator load test value (325kW) that does not bound the magnitude of the generator's single largest load (360.25kW).

The licensee entered this issue into their Corrective Action Program as CR-PLP-2014-4679 and CR-PLP-2014-4680 for Emergency Diesel Generators 1

-1 and 1-2, respectively, with recommended actions to revise the surveillance procedure minimum load limit for the load reject test to bound the magnitudes of the single largest loads.

The licensee also verified current operability by confirming the emergency diesel generators are capable of performing as required by SR 3.8.1.5

.

Analysis:

The inspectors determined the failure to have adequate acceptance criteria in the emergency diesel generator surveillance procedure was contrary to 10 CFR Part 50, Appendix B, Criterion XI, "Test Control," and was a performance deficiency. The finding was determined to be more than minor because the finding was associated with the Procedure Quality attribute of the Reactor Safety, Mitigating Systems Cornerstone and adversely affected the cornerstone objective to ensure the availability, reliability, and capability of systems that respond to initiating events to prevent undesirable consequences

. Specifically, the surveillance procedure error could result in acceptance of test results that did not satisfy Technical Specification SR 3.8.1.5 for rejection of a load greater than or equal to the emergency diesel generator's single largest post

-accident load.

The inspectors assessed this finding for significance in accordance with NRC Manual Chapter 0609, Appendix A, Exhibit 2

, The Significance Determination Process (SDP) for Findings At-Power, and determined that it was of very low safety significance (Green), because the SSC maintained its operability and functionality

. This finding has a cross

-cutting aspect in the area of Human Performance, associated with the Resources component, because the licensee did not ensure that personnel, equipment, procedures, and other resources are adequate to assure nuclear safety by maintaining long term plant safety. [H.1]

Enforcement:

Title 10 CFR Part 50, Appendix B, Criterion XI, "Test Control," requires, in part, "A test program shall be established to assure that all testing required to demonstrate that structures, systems, and components will perform satisfactorily in service is identified and performed in accordance with written test procedures which incorporate the requirements and acceptance limits contained in applicable design documents." Contrary to the above, on June 20, 2013, the licensee failed to assure that written test procedures incorporate requirements contained in applicable design documents. Specifically, the licensee revised Technical Specification Surveillance Procedure RE

-132, "Diesel Generator 1

-2 Load Reject

," but failed to identify that the specified kW level for the largest load rejection test did not bound the largest predicted post-accident load

. Because this violation was of very low safety significance, and it was entered into the licensee's Corrective Action Program as CR-PLP-2014-4679 and CR-PLP-2014-4680, 36 this violation is being treated as an NCV, consistent with Section 2.3.2 of the NRC Enforcement Policy. [NCV 05000255/2014008

-13, Non-Conservative Surveillance for Emergency Diesel Generator Largest Load Reject Test

.]

4OA5 Other Activities

.1 (Closed) Unresolved Item (URI) 05000255/2012005

-05: Concerns With The Methodology Used To Determine Suction Side Void Acceptance Criteria On January 11, 2008, the NRC requested each addressee of GL 2008

-01 to evaluate its emergency core cooling, decay heat removal, and containment spray systems licensing basis, design, testing, and corrective actions to ensure gas accumulation was maintained less than the amount which would challenge the operability of these systems, and take appropriate actions when conditions adverse to quality were identified.

In order to determine what amount of gas could challenge the operability of the subject systems, the licensee needed to develop appropriate acceptance criteria for evaluating identified voids.

As part of this effort, the licensee developed acceptance criteria for evaluating voids identified in the suction side of the subject systems' pumps.

During subsequent inspections the inspectors identified a concern with the methodology used by the licensee to develop acceptance criteria for suction side voids. At the time of the inspection the acceptance criteria was inconsistent with the 0.5

-second criterion recommended by the Office of Nuclear Reactor Regulation (NRR) in TI 2515/177 Inspection Guidance (ML111660749).

The NRR-recommended methodology was more conservative because it ensured there were no significant deviations exceeding the maximum recommended void fractions.

However, because the licensee's methodology averaged over the entire transient duration time, it allowed void volumes that could significantly exceed the recommended void fraction when the actual duration transient time was shorter than the maximum allowable duration time specified by the recommended void fraction acceptance criteria. This issue was originally captured in the licensee's CAP as CR

-HQN-2011-00853. Since then, and as result of other void related violation s, the licensee revised their procedures including their Gas Accumulation Management Program Document (EN

-DC-219, Revision 3). The revised Program Document incorporates, by reference, the Acceptance Criteria of NEI 09

-10, "Guidelines for Effective Prevention and Management of System Gas Accumulation

." The NRC has issued a Safety Evaluation (SE) of the NEI 09-10, which discusses the Agency's position in regards to the use of NEI 09

-10. In addition, based on the information discussed in the NEI 09

-10 and the SE, the 0.5 second criterion discussed in the URI is no longer the recommended method proposed by NRR. Therefore, the inspectors concern is no longer valid, and no performance deficiency or violation of regulatory requirements exists. This unresolved item is closed.

4OA6 Management

Meeting(s)

.1 Exit Meeting Summary

On November 4, 2014

, the inspector s presented the inspection results to Mr. Vitale, and other members of the licensee staff. The licensee acknowledged the issues presented. The inspector s asked the licensee if the inspectors had proprietary materials that should be returned. The inspectors verified that no proprietary information was retained by the inspectors or documented in this report

.

37

.2 Followup Exit Meeting Summary

On November 4

, 2014, the inspector s conducted a follow

-up exit by phone with Mr. Vitale, and other members of the licensee staff. This meeting updated the status of two concerns that were open at the time of the on

-site exit.

The licensee acknowledged the issues presented

.

4OA7 Licensee-Identified Violations

The following violation of very low safety significance (Green) was identified by the licensee and is a violation of NRC requirements which meet s the criteria of the NRC Enforcement Policy, for being dispositioned as a Non

-Cited Violation.

Technical Specification 5.4.1.a, requires written procedures shall be established, implemented, and maintained as recommended in Regulatory Guide 1.33, Item (b), Administrative Procedures implementing the "Authorities and Responsibilities for Safe Operation and Shutdown."

Procedure 4.48, Revision 3, "Control of Time Critical Operator Actions."

Requires that Time Critical Operator Actions (TCAs) revalidated every two years.

Contrary to the above, on July 23, 2014, the licensee found no evidence that TCA revalidation was performed since 2011. The licensee determined timing information could not be found for the following TCA validations

TCA 2: Match PCS and S/G Pressure during a SGTR Event

, TCA 10: Align Shutdown Cooling (SDC)

, and TCA 46: Station Battery Load Stripping

. This issue was determined to be more than minor, because it impacted the Procedure Quality attribute of the Reactor Safety, Mitigating Systems Cornerstone and adversely affected the cornerstone objective to ensure the availability, reliability, and capability of systems that respond to initiating events to prevent undesirable consequences.

The licensee documented this issue in CR-PLP-2014-03841, dated July 23, 2014. The finding was determined to be of very low safety significance (Green) because all questions were answered "

no" for Exhibit 2

- Mitigating Systems Screening Questions in Inspection Manual Chapter (IMC) 0609, Appendix A, Significance Determination Process (SDP) For Findings At-Power. ATTACHMENT:

SUPPLEMENTAL INFORMATION

SUPPLEMENTAL INFORMATION

KEY POINTS OF CONTAC

T Licensee

T. Vitale,

Site Vice President

T. Williams

, General Manager, Plant Operations

B. Davis, Engineering Director

D. Corbin

, Operations Manager

J. Borah,

System Engineering Manager

K. O'Connor,

Design Engineering Manager

J. Hardy,

Regulatory Assurance Manager

B. Sova, Engineering Supervisor
T. Fouty,

Engineering Supervisor

L. Engelke,

Engineering Supervisor

K. Yeager,

Engineering Supervisor

D. MacMaster, Engineering Supervisor
R. Scudder, Operations Specialist
B. Dotson, Regulatory Assurance Specialist
T. Davis, Regulatory Assurance Specialist

U.S. Nuclear Regulatory Commission

LIST OF ITEMS OPENED, CLOSED, AND DISCUS

SED Opened 05000255/2014008

-01 NCV Failure to Ensure Engineered Safeguards Systems Aren't Adversely Affected By Air Entrainment

(Section 1R21.3.b(

1)) 05000255/201400

8-02 NCV Undersized Supply Cables from Startup Transformer to 2400V Buses

(Section 1R21.3.b(

2)) 05000255/201400

8-03 NCV Undersized Motors

(Section 1R21.3.b(

3)) 05000255/201400

8-04 NCV Failure to Ensure that 480V System Voltages do not Exceed Equipment Ratings

(Section 1R21.3.b(

4)) 05000255/2014008

-05 NCV Failure to Perform Comprehensive Pump Testing of Containment Spray Pump P

-54A in accordance with the Inservice Testing Program (Section 1R21.3.b(

5)) 05000255/2014008

-06 NCV Failure to Correctly Translate Valve Leakage Limits into Test Procedure

(Section 1R21.3.b(

6)) 05000255/2014008

-07 NCV Failure to Identify Non

-Safety-Related Sub-Components Improperly Supplied with Safety-Related Valves (Section 1R21.3.b(

7)) 05000255/2014008

-08 NCV Failure to Establish an Adequate

Test Program for the Shutdown Cooling Heat Exchangers

(Section 1R21.3.b(

8))

05000255/2014008

-09 NCV Failure To Include The Degraded Voltage Channel Time Delay In TS Surveillance Requirement 3.3.5.2.a

(Section 1R21.3.b(

9)) 05000255/201400

8-10 URI Lack of Analysis for Electrical Containment Penetration Protection

(Section 1R21.3.b(

10)) 05000255/201400

8-11 URI Classification of CCW Piping and Components Inside the Reactor Containment Building

(Section 1R21.3.b(

11)) 05000255/2014008

-12 URI Component Cooling Water System Licensing Bases

(Section 1R21.3.b(

2)) 05000255/2014008

-13 NCV Non-Conservative Surveillance

for Emergency Diesel Generator Largest Load Reject Test

(Section 4OA2.1.b(1)) Closed 05000255/2014008

-01 NCV Failure to Ensure Engineered Safeguards Systems Aren't Adversely Affected By Air Entrainment

(Section 1R21.3.b(

1)) 05000255/201400

8-02 NCV Undersized Supply Cables from Startup Transformer to 2400V Buses

(Section 1R21.3.b(

2)) 05000255/201400

8-03 NCV Undersized Motors

(Section 1R21.3.b(

3)) 05000255/201400

8-04 NCV Failure to Ensure that 480V System Voltages do not Exceed Equipment Ratings

(Section 1R21.3.b(

4)) 05000255/2014008

-06 NCV Failure to Perform Comprehensive Pump Testing of Containment Spray Pump P

-54A in accordance with the Inservice Testing Program

(Section 1R21.3.b(

6)) 05000255/2014008

-07 NCV Failure to Correctly Translate Valve Leakage Limits into Test Procedure

(Section 1R21.3.b(

7)) 05000255/2014008

-08 NCV Failure to Identify Non

-Safety-Related Sub-Components Improperly Supplied with Safety-Related Valves (Section 1R21.3.b(

8)) 05000255/2014008

-09 NCV Failure to Establish a

n Adequate Test Program for the Shutdown Cooling Heat Exchangers

(Section 1R21.3.b(

9)) 05000255/2014008

-10 NCV Failure To Include The Degraded Voltage Channel Time Delay In TS Surveillance Requirement 3.3.5.2.a

(Section 1R21.3.b(

10)) 05000255/2014008

-13 NCV Non-Conservative Surveillance for Emergency Diesel Generator Largest Load Reject Test

(Section 4OA2.1.b(1)) 05000255/2012005

-05 URI Concerns With The Methodology Used To Determine Suction Side Void Acceptance Criteria

(Section 4OA

5.1) Discussed

None

LIST OF DOCUMENTS REVIEWED The following is a list of documents reviewed during the inspection. Inclusion on this list does not imply that the NRC inspectors reviewed the documents in their entirety, but rather, that selected sections of portions of the documents were evaluated as part of the overall inspection effort. Inclusion of a document on this list does not imply NRC acceptance of the document or

any part of it, unless this is stated in the body of the inspection report

. CALCULATIONS

Number Description or Title

Revision 152-202 Installation of Replacement Siemens Breaker

152-203 Installation of Replacement Siemens Breaker

1D-208-150-151 Component Cooling Pump P

-52B 4 1D-210-150-151 Breaker Calculation for 152

-210 3 1D-210-150-151 Breaker Calculation for 152

-210 3 1D-210-150-151 Breaker Calculation for 152

-210 3 23-3E LPSI Valve MO

-3190 (52-2339) ESP

P 3 D11/04 4160V Switchgear Bus 1F DC Supply

DBD 5.01

Diesel Engine and Auxiliary Systems

DBD 5.03 Emergency Diesel Generator Performance Criteria

DCP-090188-1 Range of Station Power Voltages

EA-AOVCAP-GATE-ESS-01 Actuator Capacity Review for Air Operated Gate

Valves in

ESS 1 EA-AOVT/T-ESS-02 Stem Thrust Requirements for AOVs CV

-3027 and CV

-3056 2 EA-AOVT/T-ESS-03 Evaluation of Thrust Requirements for AOVs CV

-3029 and

CV-3030 1 EA-AOV-WKLINK-02 Weak Link Calculation for AOVs CV

-3027 and CV

-3056 1 EA-AOV-WKLINK-06 Weak Link Calculation for AOVs CV

-3029 and CV

-3030 from Crane Valve

EA-A-PAL-90-018-01 DBA Sequencer Timing Study

EA-A-PAL-92-037 Emergency Diesel Generators Loadings

--First Two Hours

EA-APR-95-001 Appendix R Safe Shutdown Equipment List and Logic Diagrams 4 EA-APR-95-002 10 CFR Part 50 Appendix R Safe Shutdown Associated Circuits Analysis and Cable Selection

EA-APR-95-004 10 CFR Part 50 Appendix R Safe Shutdown Associated Circuits Analysis for Common Power Supply and Common Enclosure

EA-APR-95-015 Diesel Generator Capability without Service Water

EA-CA024154-01 Containment Spray System Flow Rates and Timing During Injection Mode Using Pipe

-Flo 1

EA-CA025644-01 Evaluation of the Impact of 110

Percent EDG Overload on Ambient Temperature

EA-CCW-DBD-89-01 Generation of Design Basis for Specific Relief Valve Sizes in the CCW System

EA-C-PAL-95-0877D Evaluation of the Potential for Excessive Air Entrainment Caused by Vortexing in the SIRW tank

During a LOCA

EA-C-PAL-97-1650A-01 Diesel Generator Hydraulic Inputs

EA-C-PAL-97-1650A-01 Revised Hydraulic Inputs for Emergency Diesel Generator Steady State Load

EA-C-PAL-01-03563-02 Containment Sump NPSH Evaluation

EA-EAR-97-0273 Evaluation of 4 November 1996 Shutdown Cooling Heat Exchanger Performance Test T

-365 0 EA-EAR-2001-0333-01 Generation of ESS Pump Performance Curves for use with the Pipe-Flo ESS Hydraulic Model

EA-EC157-01 345 KV System Voltage Drop with LOCA

- Replacement SUT

1- 2 0 EA-EC-235-01 Assessment of the High Pressure Air System's Capacity to Cycle Valves in the West Engineering Safeguards

EA-EC496-001 Evaluation

of Downcomer,

Floor Drain, and Sump Vent Screens for GSI

-191 Resolution

EA-EC496-04 SFS Surface Area, Flow

and Volume 1 EA-EC6432-01 Palisades Emergency Diesel Generator Fuel Oil Storage Requirements

EA-EC7107-01 Palisades GSI

-191 Downstream Effects Evaluation of ECCS Components

EA-EC-8349-04 Post LOCA Boric Acid Precipitation Analysis for Palisades in Support of Replacement of TSP with NaTB as the Containment Sump Buffer Agent

EA-EC9600-01 Functionality of Equipment in EDG Room at an Elevated Temperature of 121F

EA-EC-11464-01 Second Level Undervoltage Time Delay Relays 162

-153 and 62-154 Uncertainty Analysis

EA-EC-11464-02 First Level Undervoltage Relays 127

-1 and 127

-2 Drift Calculations

EA-EC-11464-03 First Level Inverse Time Undervoltage Relays 127

-1 and 127-2 Uncertainty Analysis

EA-EC19401-01 Uncertainty Calculation for 2400V Safety Bus Voltage Meters

EA-EC3181717

-01 Analysis

of the Low Flow Testing

of the Engineered Safeguards System Pumps

EA-ELEC08- 0008 SIRW Tank Level Switch Position Uncertainty Calculation

EA-ELEC-AMP-016 Calculate the Cable Ampacity for Containment Spray

EA-ELEC-AMP-030 Capability of the 2400V Feeder Cables to Buses 1C and 1D from the Startup Transformer 1

-2 2 EA-ELEC-CABLE-A1208-1 2.4KV Cable Ampacity for P

-52B 0 EA-ELEC-CABLE-A1210-1 2.4KV Cable Ampacity for P

-54A 0 EA-ELEC-EDSA-01 Auxiliary AC System EDSA Model Development and Verification

and Validation

EA-ELEC-EDSA-03 LOCA with Offsite Power Available

1,2 EA-ELEC-EDSA-04 Second Level Undervoltage Relay Setpoint Determination (SLUR) 0 EA-ELEC-EDSA-05 Fast Transfer Analysis

EA-ELEC-EDSA-06 AC Short Circuit Analysis

and EC 5000122058

EA-ELEC-LDTAB-005 Emergency Diesel Generators 1

-1 and 1-2 Steady State Loadings 9,10 EA-ELEC-LDTAB-013 Worst Case Cable Loading Between SUT 1

-2, and Buses 1C

and 1D 0 EA-ELEC-LDTAB-019 Auxiliary Power System Measured Load Analysis

EA-ELEC-VOLT-010 Maximum and Minimum Station Power Voltages

EA-ELEC-VOLT-01A Dynamic Response of Emergency Diesel Generators and ECCS Motor Acceleration Times

EA-ELEC-VOLT-006 Determine the Terminal Voltage at the 46 Safety-Related Motor Operated Valves

EA-ELEC-VOLT-033 Second Level Undervoltage Relay Setpoint

EA-ELEC-VOLT-034 Calculation of VT Burden and Ratio Correction Factor for 2400V Class 1E Buses

EA-ELEC-VOLT-036 Station Power Transformers No. 11, 12, 19, and 20 Tap Change -2.5 percent 0 EA-ELEC-VOLT-037 Degraded Voltage Calculation for the Safety

-Related MOVs

EA-ELEC-VOLT-039 Stuck SGT 1

-1 Tap Changer and Subsequent Station Power Voltages 0 EA-ELEC-VOLT-050 Motor Control Center Control Circuit Voltage Analysis

EA-ELEC-VOLT-051 MCC Power Circuit Minimum Required Voltage Analysis

EA-ELEC-VOLT-053 Preferred AC Voltage Analysis

EA-GL-8910-O1 Generic Letter 89

-10 MOV Thrust Window Calculations

EA-GOTHIC-04-05 Development of LOCA Containment Response Base Deck

EA-GOTHIC-04-06 Development of MSLB Containment Response Base Deck

EA-GOTHIC-04-08 Containment Response to LOCA Using GOTHIC 7.2a

EA-GOTHIC-04-09 Containment Response to a MSLB Using GOTHIC 7.2a

EA-MOD-2005-004-03 ESS Flow Rates and Pump NPSH During Recirc Mode with CSS Throttling

EA-PIPEFLO-ESS-02 Pipe-Flo Professional 2007a Integrated Hydraulic Model of the Containment Spray, High Pressure and Low Pressure Safety Injection Systems

EA-PLTB-04 Pressure Looking and Thermal Binding Review for Appendix R Safe Shutdown Power Operated Gate Valves

EE-EDG-01 Evaluation of Maximum Diesel Room Temperature

MPR-4105 Technical Evaluation of EDG Frequency and Voltage Variations in Support of Operability Determination for Palisades

NB-PSA-ETSC Mode 4 LOCA Load Recovery Period Basis.

NEI-1149-014 Palisades Design Basis AST MHA/LOCA Radiological Analysis 4 SUT1-2/SUT1-2/ALTC Startup Transformer 1

-2 Load Tap Changer Automatic Controls 0 CORRECTIVE ACTION DOCUMENTS GENERATED DUE TO THE INSPECTION

Number Description or Title

Date CR-PLP-2014-04385 Merlin Drawing Revision Conflict For M0265BC Sheet 5 9/8/14 CR-PLP-2014-04406 Conditions Identified During A Tour Of The West Engineered Safeguards Room

9/10/14 CR-PLP-2014-04445 Indications Of White, Dry Boric Acid Inside The Insulation Box For LT

-0332A, SIRW LEVEL TRANSMITTER, and LT

-0332B, SIRW LEVEL TRANSMITTER

9/11/14 CR-PLP-2014-04446 NRC Inspector Identified

a Degraded Jumper Connection On A Ground Cable

9/11/14 CR-PLP-2014-04450 Electrical Penetrations of Reactor Containment

9/11/14 CR-PLP-2014-04472 NRC Questions Whether it is Appropriate to Have a Design Basis Calculation Which States 3.6

Percent Air Entrainment Could Occur

9/12/14 CR-PLP-2014-04491 EA-ELEC-VOLT-39, Stuck SGT 1

-1 TAP Changer and Subsequent Station Power Voltages, has not been updated

9/15/14 CR-PLP-2014-04495 NRC Inspectors Involved With

the 2014 CDBI Questioned

the Worst Case Load Assumption

9/15/14 CR-PLP-2014-04496 NRC Inspectors Involved With

the 2014 CDBI Questioned

the Worst Case Load Assumption

9/15/14

CORRECTIVE ACTION DOCUMENTS GENERATED DUE TO THE INSPECTION

Number Description or Title

Date CR-PLP-2014-04413 Calculation EA

-ELEC-VOLT-018, Which is Referenced In Design Basis Document 3.04, Could

Not Be Found

9/10/14 CR-PLP-2014-04450 FSAR Unclear On Requirements for Electrical Protection

for Containment Penetrations

9/11/14 CR-PLP-2014-04491 Calculation EA

-ELEC-VOLT-039, Which Analyzes Maximum Voltage Change During Stuck Tap Condition

for a Load Tap Changing Transformer, Does Not Bound Minimum Allowable Switchyard Voltage

9/15/14 CR-PLP-2014-04495 Non-Conservative Transient Load Analysis

for 2.4kV

Supply Breaker to

Bus 1C 9/15/14 CR-PLP-2014-04496 Non-Conservative Transient Load Analysis

for 2.4kV

Supply Breaker to

Bus 1D 9/15/14 CR-PLP-2014-04665 Process a Revision to Calculation EA

-C-PAL-95-0877D to Address the Conditions Identified in Condition Reports CR

-PLP-2014-04472 and CR

-PLP-2014-04665, Includes Operability Evaluation

of ESS Pumps 10/9/14 CR-PLP-2014-04672 As Presently Designed, The Thermal Overload Relays (TOR) For Six Safety

-Related Motor Operated Valves Will Not Alarm Under Certain Overload Conditions

9/24/14 CR-PLP-2014-04679 The Current Range (325

-375kw) Within RE

-131 Doesn't Bound The Largest Calculation Load

of P-8A 9/25/14 CR-PLP-2014-04680 The Current Range (325

-375kw) Within RE

-131 Doesn't Bound The Largest Calculation Load

of P-66A 9/25/14 CR-PLP-2014-04681 Incorrect Acceptance Criteria Limits for Leak Testing of CV-3027 and CV

-3056 9/25/14 CR-PLP-2014-04682 Time delay Between a Degraded Voltage Condition and Actuation

of the Transfer

from Offsite Power to the Diesel Generators is Ambiguous in Calculation

EA-ELEC-EDSA-03 9/25/14 CR-PLP-2014-04696 Diesel Voltage

and Frequency Limits Unanalyzed

9/26/14 CR-PLP-2014-04755 Improper Quality Classifications for Valve Sub

-Components

9/30/14 CR-PLP-2014-04815 Segment of Non

-Safety-Related Tubing Installed in Safety-Related System 10/2/14 CR-PLP-2014-04858 Lack of a Calculation that Establishes Total Time Delay, Including Loop Uncertainties, Between a Degraded Voltage Condition And Actuation of the Transfer from Offsite Power to the Diesel Generators

10/7/14 CR-PLP-2014-04860 The Cables from Start

-Up Transformer 1

-2 (EX-04) to Buses 1C (EA-11) and 1D (EA

-12) are Undersized

10/7/14 CR-PLP-2014-04864 EC That Changed The 2400/480 Station Transformer Taps To A 2.5 Percent Boost Setting In 1995 Did Not Bound Worst Case High Voltage Conditions

10/8/14 CR-PLP-2014-04874 NRC Question on Flow Testing of Components in the Closed Cycle Cooling Water Program

10/8/14

CORRECTIVE ACTION DOCUMENTS GENERATED DUE TO THE INSPECTION

Number Description or Title

Date CR-PLP-2014-04881 Missed Surveillance For CS P

-54A Due to Instruments Being Out Of Calibration Per The Requirements Of The ASME Code 10/8/14 CR-PLP-2014-04897 AOP-30, Loss of Shutdown Cooling, Attachment 8, Align Idle LPSI Pump Suction to the SIRW Tank When on Shutdown Cooling, May Not Be Adequate

10/9/14 CR-PLP-2014-04901 Transmission Network Model that Predicts the Change In Switchyard Voltage as a Result of a LOCA Does Not Consider Change in Plant Loading Imposed On Switchyard

10/9/14 CR-PLP-2014-04902 Motors That Are Undersized With Respect To Their Mechanical Loads Have Not Been Analyzed For Thermal Effects 10/9/14 CR-PLP-2014-04903 Degraded Voltage Monitor

Total Delay

-Time not in TS 3.3.5.2 10/09/14 CR-PLP-2014-04912 NRC Questions the Adequacy of the Testing Performed to Ensure E-60A/B Remain Qualified to the Capability Assumed During Design Basis Events

10/10/14 CR-PLP-2014-04915 Motor Operated Valve Calculation

EA-GL-8910-01 Uses Obsolete Electrical Calculation

EA-ELEC-VOLT-037 for Input Data Regarding Minimum Voltages to Valve Motors

10/10/14 CORRECTIVE ACTION DOCUMENTS REVIEWED DURING THE INSPECTION

Number Description or Title

Date A-NL-92-079 NRC Inspection Report 91

-19 (EDSFI) Reply to Open Item

91-19-03, "Overloading of Buses 1C

and 1D Feeder Cables from Startup Transformer"

3/29/95 A-NL-92-111 Spurious Diesel Generator Starts Due To Degraded Voltage Relay Time Delay Setting

3/9/95 A-PAL-92-066 Shutdown Cooling Heat Exchanger Performance Testing

2/16/92 AR 00870121

Inadequate Guidance for Operations When Outside Air Temperature Exceeds 95F

7/26/05 AR 199978199978Revise PMS To Replace RO

-98 Test Gauges With M&TE

4/28/14 CE 01066273

-01 Excluded Required Equipment in OPR 108

2/7/06 C-PAL-94-0728JJ No Heat Exchanger Performance Validation Testing is Performed on the Shutdown Cooling Heat Exchangers

2/9/96 C-PAL-94-0728W Complete Assessment of Performance of Key Safety Systems Against the Plant Design Basis

5/2/95 C-PAL-97-1521 Heat Balance Discrepancies Recorded in Special Test T

-365 12/8/97 CR-PLP-2006-05443 Level Switch LS

-0329 Instrument Uncertainties

11/15/06 CR-PLP-2006-05479 EDG Room Cooling Intake Louvre Screens Dirty

11/16/06

CORRECTIVE ACTION DOCUMENTS REVIEWED DURING THE INSPECTION

Number Description or Title

Date CR-PLP-2006-05805 OPR 000108 Failed to Consider Elevated Temperatures on Several Components

2/7/06 CR-PLP-2006-05854 EDC Cooling Fan V

-24C Discrepancies

2/11/06 CR-PLP-2006-05897 Design Calculation 01067491 Does Not Consider Frequency Variation in Calculating Load

2/31/06 CR-PLP-2007-02040 Level Switch LS

-0329 Setpoint

5/15/07 CR-PLP-2008-04580 D/G Load Calc Did Not Account For Worst Case Load from CAC Fan Motors 11/7/08 CR-PLP-2008-04707 CDBI Team Questioned Using a Water Level Only 1 Inch Below Fuel Oil Suction Height

11/19/08 CR-PLP-2009-00477 Containment Spray Pump, P

-54A, Has Very Little Clearance Between Shaft Coupling and Shaft Keyway

2/4/09 CR-PLP-2009-05533 CCW Pumps Lack Adequate Inservice Testing Margin

2/3/09 CR-PLP-2009-05534 Containment Spray Pumps (CSS) Lack Inservice Testing Margin 12/3/09 CR-PLP-2010-01331 NRC Resident Has Questions On QO

-15 3/31/10 CR-PLP-2010-01734 Plant Response to IN 2010

-09, Importance of Understanding Circuit Breaker Control Panel Indications

05/11/10 CR-PLP-2010-03083 Change in Gas Void Point/Size

7/27/10 CR-PLP-2010-05181 Technical Specification Test RO

-98 Pump Test Results Low in Their Acceptance

Band 10/17/10 CR-PLP-2010-06434 Transition of fire protection to NFPA 805

10/18/10 CR-PLP-2011-03087 Issue Identified During 2011 CDBI RFI 167

6/21/11 CR-PLP-2011-03221 Failure to Adequately Evaluate the Enclosure Installed Over the 1F/1G Buses

6/27/11 CR-PLP-2011-03419 Dripping Water in East Engineered Safeguards in the Vicinity of P-54A Containment Spray Pump

7/11/11 CR-PLP-2011-03835 Water Was Found Dripping from the Overhead East Engineered Safeguards Cooler in the Vicinity of P

-54 A Spray Pump

8/4/11 CR-PLP-2011-03858 LOCA Could Occur in Mode 4

8/5/11 CR-PLP-2011-04749 Boric Acid Residue Discovered on Several Components

9/21/11 CR-PLP-2011-06313 No Uncertainty Analysis for Back

-Leakage into SIRW Tank

11/17/11 CR-PLP-2012-02124 Extent of Condition for CR

-PLP-11-6818, EQ Submergence Values Outside Containment

4/2/12

CORRECTIVE ACTION DOCUMENTS REVIEWED DURING THE INSPECTION

Number Description or Title

Date CR-PLP-2012-02382 Leakage from the Primary Coolant System to the SIRW Tank

4/10/12 CR-PLP-2012-05054 Potential Impact of Foreign Material Identified in CR PLP

-2012-05049 on the ECCS Pumps

7/13/12 CR-PLP-2012-05553 Post-Accident Water Temperature in Containment Greater

Than Air Temperature, Equipment EQ Needs Evaluation

8/8/12 CR-PLP-2012-06148 Lack of Complete Electrical Protective Coordination

for Appendix R

9/11/12 CR-PLP-2012-06148 Electrical Coordination Will Not Support Transition to NFPA

805 9/11/12 CR-PLP-2012-06795 Shutdown Cooling Heat Exchanger (E

-60A and E

-60B) Inspections Removed from 1R23 Scope

10/18/12 CR-PLP-2013-00076 2014 CDBI Pre

-Inspection Self-Assessment

2/23/13 CR-PLP-2013-01213 Diesel Generator Loading Calculation Non

-Conservative

3/20/13 CR-PLP-2013-02674 RIS 2013-05; Relationship Between GDC and Tech Spec Operability

6/17/13 CR-PLP-2013-03894 AOV Calculations Not Revised

9/3/13 CR-PLP-2013-04003 Condensation from Room Cooler Dripping onto P

-54A, CSS Pump and other NRC Identified Issues

9/10/13 CR-PLP-2013-04799 P-52B CCW Pump Has Oil Leak

11/6/13 CR-PLP-2013-04843 Green OOZE on Relay 150

-1 Terminals

11/08/13 CR-PLP-2013-04940 As Found Thread Engagement Issues on Cooler for P

-54A Containment Spray Pump

11/19/13 CR-PLP-2014-00042 Additional K

-Line 480V Circuit Breakers Subject to ABB Part

1/03/14 CR-PLP-2014-00550 Air And Oil Leak

on FCV-3057A 1/24/14 CR-PLP-2014-01679 P-54A Containment Spray Pump Low Differential Pressure During Performance of RO

-98. 2/25/14 CR-PLP-2014-03841 No Evidence Found that Time Critical Operator Action Validation was Performed Since

2011. 7/23/14 CR-PLP-2014-04881 Missed Surveillance of CS Pump P-54A Risk-Evaluation

10/9/14 DRAWINGS Number Description or Title

Revision E-1 Sheet 1

Single Line Meter and Relay Diagram 480 Volt Motor Control Center Warehouse

DRAWINGS Number Description or Title

Revision E-11 Sheet 1

Schematic Meter and Relay Diagram 2.4 KV System

E-12 Sheet 1

Schematic Meter and Relay Diagram 2.4 KV and 480V Systems 40 E-12 Sheet 2

Schematic Meter and Relay Diagram 2.4 KV and 480V Systems 9 E-17 Sheet 10

Logic Diagram 2400 Volt Load Shed

E-17 Sheet 11

Logic Diagram Diesel Start

E-17 Sheet 13

Logic Diagram Diesel Generator Breakers

E-17 Sheet 14

Logic Diagram Bus 1C and 1D Incoming Breakers

E-17 Sheet 18A

Logic Diagram Safeguard Transformer 1

-1 3 E-17 Sheet 5A

Containment Spray Isolation Valves Logic

Diagram 0 E-17 Sheet 8

Logic Diagram Main Generator Protection

E-17 Sheet 9

Logic Diagram Turbine

-Generator Trips and Fast Transfer

E-129 Sheet 44 Schematic Diagram Circuit Breaker 152

-210 0 E-237 Sheet 1 Schematic Diagram Containment Spray Valves 17 E-237 Sheet 1A Schematic Diagram Containment Spray Valves

E-244 Sheet 8

Schematic Diagram Safety Injection Motor Operated Valves

E-244 Sheet 9

Schematic Diagram Safety Injection Motor Operated Valves

E-246 Schematic Diagram SIRW Tank And Containment Sump Valves - Circuit No. 2

E-246 Sheet 1 Schematic Diagram SIRW Tank and Containment Sump Valves - Circuit 1

E-246 Sheet 2 Schematic Diagram SIRW Tank and Containment Sump Valves - Circuit 1

E-246 Sheet 2A Schematic Diagram SIRW Tank and Containment Sump Valves - Circuit 2

E-251 Sheet 1

Schematic Diagram Containment Spray Pump P54A

E-251 Sheet 1A

Schematic Diagram Containment Spray Pump P54A

E-251 Sheet

Schematic Diagram Containment Spray Pump P54

C 2 E-259 Sheet 3A

Schematic Diagram Component Cooling Pump P52B

E-3 Sheet 1

Single Line Meter and Relay Diagram 2400 Volt System

E-5 Sheet 5B

Single Line Meter and Relay Diagram 480 Volt Motor Control Centers 12 M-1 Equipment Location Reactor Building Plan of El.

570'-0" 14 M-136 Penetrations and Inserts

M-202 Piping and Instrument Diagram Chemical

and Volume Control System

M-203 Safety Injection, Containment Spray,

and Shutdown Cooling System 27 M-203 Sht. 2

Piping and Instrument Diagram Safety Injection,

Containment Spray and Shutdown Cooling System

M-203 Sht. A

System Diagram Safety Injection, Containment Spray and Shutdown Cooling System

M-204 Safety Injection, Containment Spray,

and Shutdown Cooling System 8

DRAWINGS Number Description or Title

Revision M-204 Sht. 1

Piping and Instrument Diagram Safety Injection, Containment Spray and Shutdown Cooling System

M-204 Sht. 1A

Piping and Instrument Diagram Safety Injection, Containment Spray and Shutdown Cooling System

M-204 Sht. 1B

Piping and Instrument Diagram Safety Injection Containment Spray 41 M-204 Sht. A

System Diagram Safety Injection, Containment Spray

and Shutdown Cooling System

M-209 Sht. 1

Piping and Instrument Diagram Component Cooling System

M-209 Sht. 2

Piping and Instrument Diagram Component Cooling System

M-209 Sht. A

System Diagram Component Cooling System

M-211 Sht. 1

Piping and Instrument Diagram Dirty Waste

and Gaseous Waste 78 M-225 High Pressure Air Operated Valves

M-31 Piping Drawings Area 2

M-347 Sht. 14

Pressure Safety (Relief) Valve Data Sheet

M-7 Equipment Location

SOD_SI_02_r03

Safety Injection, Containment Spray System

VEN-C18 Sheet

SIRW Tank Erection Diagram

- Hold Down Detail

VEN-C18 Sheet

SIRW Tank Bottom Installation

VEN-M-107 Sheet 2278

Stress Isometric

VEN-M-107 Sheet 2281

Stress Isometric

VEN-M-107 Sheet 2282

Stress Isometric

VEN-M-241BC Sheet 33 Double Disc Gate Valve

VEN-M-241BC Sheet 35 Double Disc Gate Valve

VEN-M-255 Sheet 3 Drag Valve

VEN-M-255 Sheet 4 Drag Valve

VEN-M-255 Sheet 5 Drag Valve

WD 950 Single Line Meter

and Relay Diagram 125Vdc, 120V Instrument

and Preferred AC System

10 CFR 50.59 DOCUMENTS (SCREENINGS/SAFETY EVALUATIONS)

Number Description or Title

Date SDR-99-0884 Cancellation of TS Surveillance Procedures and Revision of FSAR 7/22/99 MISCELLANEOUS

Number Description or Title

Date or Revision Letter from Dennis

M. Crutchfield, NRC, to David
P. Hoffman, Consumers Power Company, "SEP Topic VIII

-4, Electrical Penetrations of Reactor Containment" (ADAMS Accession No

. ML8104080152

) 3/26/81 Letter from Kerry

A. Toner, Consumers Power Company, to Dennis
M. Crutchfield, NRC, "SEP Topic VIII

-4, Electrical Penetrations of the Reactor Containment" (ADAMS Accession No. ML8210190459

) 10/12/82 Letter from Kerry

A. Toner, Consumers Power Company, to Dennis
M. Crutchfield, NRC, "SEP Topic VIII

-4, Status Update of Program to Evaluate the Adequacy of Penetration Protection from Overload and Short

-Circuit Conditions" (ADAMS Accession No. ML 8302240273

) 2/11/83 Letter from Robert

A. Vincent, Consumers Power Company, to Dennis
M. Crutchfield, NRC, "SEP Topic VIII

-4, Electrical Penetrations of Reactor Containment" (ADAMS Accession No.

ML8106180170

) 6/15/81 Letter from Robert

A. Vincent, Consumers Power Company, to Dennis
M. Crutchfield, NRC, "SEP Topic VIII

-4, Electrical Penetrations of the Reactor Containment" (ADAMS Accession No. ML8111200805

) 11/16/81 Letter from Thomas

V. Wambach, NRC, to David
J. VandeWalle, Consumers Power Company, "Integrated Plant Safety Assessment Report (IPSAR) Section 4.26, Electrical Penetrations of Reactor Containment

- Palisades Plant" (ADAMS Accession No. ML 8306160396

) 6/10/83 White Paper from Fauske

and Associates:

What Determines

the Condition Of Significant Air Intrusion

for the Draindown For Quiescent Water Inventories?

9/23/14 13-0327 Process Applicability Determination for EC 42422

1C-108-J9400-162-153 Protective Relay Setting

- Bus 1C Second Level Under Voltage Time Delay Relay 162

-153 4 1C-108-J9400-162-154 Protective Relay Setting

- Bus 1D Second Level Under Voltage Time Delay Relay 162

-154 3 70P-017 Engineering Specification for Shutdown Cooling Heat Exchanger

988055 P-54A Containment Spray Pump Oil Test Results

5/8/13

MISCELLANEOUS

Number Description or Title

Date or Revision 988059 P-54A Containment Spray Pump Motor Inboard Bearing Oil Test Results

5/8/13 988060 P-54A Containment Spray Pump Motor Outboard Bearing Oil Test Results

7/1/13 ASCO Catalog

2, 3 and 4 Way Solenoid Valves Vendor Manual

ASME OMb Code-2003 Addenda to ASME OM Code

-2001 Code for Operation

and Maintenance of Nuclear Power Plants

8/29/03 Attachment 9.16 SNAPSHOT Assessment of Time Critical Operator Actions.

5/27/11 Attachment 9.4

SNAPSHOT Assessment of Time Critical Operator Actions.

9/3/14 CMT95201002

Enforcement Conference

- Inoperable Diesel Generators

- Inspection Report 94020

4/30/95 CR-PLP-2014-04881 Missed Surveillance of CS Pump P

-54A Risk Evaluation

10/9/14 CV-3027 Diagnostic Testing Results

- WO 52325715

4/24/12 CV-3031 IST - Valve Component Information

CV-3057 IST - Valve Component Information

DBD-1.01 Component Cooling Water System

DBD-1.01 Design Basis Document for Component Cooling Water System 8 DBD-2.01 Low Pressure Safety Injection System

DBD-2.01 Design Basis Document for Low Pressure Safety Injection System 10 DBD-2.02 Design Basis Document for High

-Pressure Safety Injection System 9 DBD-2.03 Containment Spray System

DBD-2.03 Design Basis Document for Containment Spray System

DBD-3.04 Design Basis Document:

2400V AC System

DBD-3.05 Design Basis Document:

480V AC System

DBD-4.03 Design Basis Document:

Preferred AC System

DBD-4.04 Design Basis Document:

Uninterruptible Power Supply

DBD-5.03 Design Basis Document:

Emergency Diesel Generator Performance Criteria

DBD-5.04 Design Basis Document:

Load Shedding Circuits

DBD-5.05 Design Basis Document:

Design Basis Accident and Normal Shutdown Sequencer

DBD-6.01(TR) Design Basis Document:

Grid Interface Topical Report

DBD-6.02 Design Basis Document:

345KV Switchyard

DPR-20 Renewed Facility Operating License

251 DRN-08-01700 EOP Supplement 42, Not Tripping HPSI for Loss of Subcooling

9/5/08

MISCELLANEOUS

Number Description or Title

Date or Revision DRN-08-02217 Section 2.0 Post RAS Actions Step "N" Should be Identified as a Continuous Step (Circle C), so Operators can Continue to Perform Later Steps

2/2/08 DRN-12-01684 Commitments in Procedure do not Match Commitment List

5/14/12 DRN-14-01118 EOP Supplement 42

9/12/14 DRN-14-01222 SOP-3 Revision to Stage Equipment for Venting

LPSI Discharge Piping with

Valve MV-ES3420 per AOP

-30, Attachment 8, Align Idle LPSI Pump Suction to the SIRW Tank When on SDC.

10/7/14 DWG. No.

5935 M-347 Sheet 14 Pressure Safety (Relief) Valve Data Sheet

EAR-99-0081 CVCS Declassification

LER 80-003 Licensee Event Report 80

-003 - Containment Spray

5/13/80 Letter Response to NUREG

-0737 12/19/80 Letter (9002120116)

Response to Generic Letter 89

-13, Service Water System Problems Affecting Safety

-Related Equipment

1/29/90 Letter (ML052410206

) Supplementary Information for the Palisades Application for Renewed Operating License Resulting from Aging Management Programs Audit

8/25/05 LR-AMPBD-06-CCCW Closed Cycle Cooling Water Program

LTR-PSA-14-01 Mode 4 LOCA Analysis

10/7/14 M0001GD 0999 Fabricating Engineers Inc. Technical Manual for Shutdown Cooling Heat Exchanger

ML050940446

Palisades Nuclear Plant Application for Renewed Operating License 3/22/05 ML071800216

License Amendment Request: Replacement of Containment Sump Buffer

6/28/07 NB-PSA-SY-CSS Palisades Nuclear Plant Probabilistic Safety Assessment System Notebook

- Containment Spray System

PL-CCW Component Cooling Water

PL-CSS Containment Spray System Lesson Plan

- CV3001, CV3002, and CV-3030 9 PL-CSS Containment Spray System 9 PLJPM-LOR-SI-14 JPM - PERFORM PRE

-RAS ACTIONS IAW EOP SUPPLEMENT 42

PLJPM-LOR-SI-15 JPM - PERFORM PRE

-RAS ACTIONS IAW EOP SUPPLEMENT 42

PLJPM-LOR-SI-16 JPM - PERFORM POST RAS ACTIONS

PLJPM-LOR-SI-17 JPM - PERFORM POST RAS ACTIONS

MISCELLANEOUS

Number Description or Title

Date or Revision PLJPM-LOR-SI-18 JPM - PERFORM POST RAS ACTIONS

PLJPM-LOR-SI-19 JPM - PERFORM POST RAS ACTIONS

PLSEG-LOR-13F-02 Scenario

- AOP 30 4 PLSEG-LOR-13G-02 Scenario

- EOP 4.0 0 PLSEG-LOR-14-CDBI-1 EOP-4.0 LBLOCA Scenario for 2014 CDBI.

9/25/14 PLSEG-LOR-14-CDBI-2 Mode 4 LOCA Scenario for 2014 CDBI.

10/7/14 PLSEG-LOR-LOCA Scenario

- EOP 4.0 Loss of Coolant Accident

PL-SIS Safety Injection System

QO-16 Basis Document for QO

-16: Inservice Test Procedure

- Containment Spray Pumps

Reply EC 53093 Evaluation For Potential Air Entrainment

at the Lowest Levels of SIRW Tank Inventory Considering A Single Failure More limiting

than the One Considered

in EA-C-PAL-95-087DD 9/24/14 RI-38 Basis Basis Document for SIRW Tank Level Instrument Calibration 10 SDR-99-0884 Cancellation of TS Surveillance Procedures and Revision of FSAR 7/22/99 SEP-APJ-PLP-101 Mechanical Containment Penetration Basis

SEP-ISI-PLP-002 ASME Code Boundaries for ASME Section XI Inservice Inspection Program

SEP-ISI-PLP-002 ASME Code Boundaries For Section XI Inservice Inspection Program 1 SEP-PLP-IST-102 Inservice Testing of Selected Safety

-Related Pumps

SOP-15 Service Water System

USI A-46 Equipment Evaluation Report

5/3/95 MODIFICATIONS

Number Description or Title

Date or Revision FC-718 RAS Logic Seal

-In Circuit Addition

2/19/86

OPERABILITY EVALUATIONS Number Description or Title

Date or Revision CR-PLP-2014-4696 CA-1 Operability for all SSCs Within Maximum

Variations of EDG Frequency and Voltage Allowed by Technical Specifications

10/22/14 OPR 000108

Operability Recommendation

- EDG Room Temperature

PROCEDURES

Number Description or Title

Revision 4.02 Control of Equipment

Administrative Procedure

10.41 Site Procedures Process

Administrative Procedure

10.51 Writer's Guideline for Site Procedures

Administrative Procedure

4.06 Emergency Operating Procedure Development and Implementation

Administrative Procedure

4.66 Abnormal Operating Procedure Development and Implementation

Administrative Procedure TCA

Control of Time Critical Operator Actions

AOP-23 Primary Coolant Leak

AOP-30 Loss of Shutdown Cooling

AOP-36 Loss Of Component Cooling

AOP-37 Loss of Instrument Air

ARP-4 Reactor Water Level Low Alarm Response Procedure

ARP-3 Electrical Auxiliaries and Diesel Generator Scheme EK

-05 (EC-11) 74 ARP-7 Auxiliary Systems Scheme EK

-11 (C-13) 92 CEN 152 Combustion Engineering LOCA Recovery Guideline

5.3 EM-09-16 Master Heat Exchanger Testing Plan

and 8 EN-DC-178 System Walkdowns

EN-DC-195 Margin Management

EN-DC-219 Gas Accumulation Management

EN-MA-145 Maintenance Standard for Torque Applications

EN-OP-104 Operability Determination Process

EOP 4.0 Loss of Coolant Accident Recovery

EOP 4.0 Basis Loss of Coolant Accident Recovery Basis

EOP Intro

Introduction to EOP System Basis

EOP Supplement 42

Pre and Post RAS Actions

EOP TCA EOP Time Critical Operator Action Basis

EOP-4 Loss of Coolant Accident Recovery

EOP-5.0 Steam Generator Tube Rupture Recovery

EOP-9.0, HR-3 Functional Recovery Procedure

ESSO-1 Containment Spray Header Fill

PROCEDURES

Number Description or Title

Revision GOP-14 Shutdown Cooling Operations

MO-7A-1 Emergency Diesel Generator 1

-1 86 MO-7A-2 Emergency Diesel Generator 1

-2 86 NB-PSA-SM Probabilistic Safety Assessment Model Summary System Notebook 2 NB-PSA-SSS SIRW Tank and Containment Sump Suction System Probabilistic Safety Assessment System Notebook

NPOA Nuclear Plant Operating Agreement

ONP-17 Loss of Shutdown Cooling (SDC)

QO-16 Inservice Test Procedure

- Containment Spray Pumps

QO-2 Recirculation Actuation System

QO-5 Valve Test Procedure (Includes Containment Isolation Valves) 89 RE-131 Diesel Generator 1

-1 Load Reject

RE-131/132 Technical Specification Surveillance Procedure Basis Document 1 RE-132 Diesel Generator 1

-2 Load Reject

RE-137 Calibration of Bus 1C Undervoltage and Time Delay Relays

RE-138 Calibration of Bus 1D Undervoltage and Time Delay Relays

RI-38 SIRW Tank Level Instrument Calibration

RO-119 Inservice Testing of Engineered Safeguards Valves CV

-3027 and CV-3056 14 RO-217 Technical Specification Leak Rate Testing of Engineered Safeguards Check Valves

RO-98 Technical Specification Surveillance Procedure Basis Document 3 RT-71K Class 2 System Functional Test for Shutdown Cooling System 10 RT-71L Technical Specification Admin 5.5.2 Pressure Test Of ESS Pump Suction Piping

SEP-HX-PLP-001 Master Heat Exchanger Testing Plan

SOP-3 Safety Injection and Shutdown Cooling System

SOP-3, Attachment 16

Engineered Safeguards System Checklist (Heat SDC)

SOP-4 Containment Spray System

SOP-16 Component Cooling Water System

SOP-19 Nitrogen/Air Backup Stations 60 SOP-30 Station Power

SPS-E-17 Temporary Installation and Removal of Spare Circuit Breakers 24 T-205-A East Engineering Safeguards High Pressure Air System Performance Verification

PROCEDURES

Number Description or Title

Revision T-205-B West Engineering Safeguards High Pressure Air System Performance Verification

T-278-3A Nitrogen Station 3A Performance Test

T-365 Determination of Heat Transfer Capability of Shutdown Cooling Heat Exchangers E

-60A and E-60B 1 SURVEILLANCES (COMPLETED) Number Description or Title

Date or Revision T-205-A East Engineering Safeguards High Pressure Air System Performance Verification

11/23/14 T-205-B West Engineering Safeguards High Pressure Air System Performance Verification

2/2/14 T-278-3A Nitrogen Station 3A Performance Test

2/19/14 WO-PLP-52435851

LPSI and Containment Spray Comprehensive Pump Test and Check Valves Test

2/25/14 WO-PLP-52547674

Inservice Test Procedure

- Containment Spray Pumps

5/29/14 WORK ORDERS Number Description or Title

Date or Revision 178171-01 Clean EDG Room Cooling Air Inlet Louvre Screens

11/21/06 342334-01 Change SUT 1

-2 (EX-04) Tap Changer Setpoint

51521714-01 Clean Door Louvre Screens

11/21/06 51521714-02 Repair Door Louvre Screens

11/21/06 51521714-03 Clean Wall Louvre Screens

11/21/06 52325512-01 RI-14, SIRW Tank Level Switch Interlock Test 8/6/12 52430162-01 RI-14, SIRW Tank Level Switch Interlock Test

3/6/14 52432473-01 RT-92 - Inspect ECCS Train Cont Sump Suction Inlet

3/9/14 52435963-01 Containment Sump Clean

-Out and Inspection

2/26/14 WT-PLP-2010-00261 Update DBD 3.04 Table 3

-2: "2400V AC Supply Cables, Design Ratings, Loading and Margins

6/2/10 WT-PLP-2014-00216 WT Written to Document Actions Resulting from

CDBI Focused Area Self

-Assessment LO

-PLP-2013-00076 7/17/14

LIST OF ACRONYMS USE

D °C Celsius Degrees °F Fahrenheit Degrees AC Alternating Current

ADAMS Agencywide Document Access Management System

AOP Abnormal Operating Procedure

AOV Air-Operated Valve

AR Action Request

ARM Area Radiation Monitor

ASME American Society of Mechanical Engineers

BHP Brake Horsepower

CAP Corrective Action Program

CCW Component Cooling Water

CDBI Component Design Bases Inspection

CFR Code of Federal Regulations

CS Containment Spray

CVCS Chemical and Volume Control

DBD Design Basis Document

DC Direct Current

DRS Division of Reactor

Safety EC Engineering Change

ECCS Emergency Core Cooling System

EDG Emergency Diesel Generator

EPRI Electric Power Research Institute

EPU Extended Power Uprate

EQ Equipment Qualifications

ESS Engineered Safeguards System

FIN Finding FSAR Final Safety Analysis Repor

t GDC General Design Criteria

GL Generic Letter

gpm Gallons per Minute

HELB High Energy Line Break

HPSI High Pressure Safety Injection

HVAC Heating, Ventilation and Air

-Conditioning

IEEE Institute of Electrical

and Electronic Engineers

IMC Inspection Manual Chapter

IN Information Notice

IP Inspection Procedure

IR Inspection Report

IR Issue Report

ISI Inservice Inspection

IST Inservice Testing kV Kilovolt

LCO Limiting Condition for Operation

LER Licensee Event Report

LOCA Loss of Coolant Accident

LPCI Low Pressure Coolant Injection

MCC Motor Control Center

MOV Motor-Operated Valve

NCV Non-Cited Violation

NEI Nuclear Energy Institute

NFPA National Fire Protection Association

NPSH Net Positive Suction Head

NRC U.S. Nuclear Regulatory Commission

NRR Nuclear Reactor Regulation

PARS Publicly Available Records System

PCS Primary Coolant System

P&ID Piping and Instrumentation Drawing

PI&R Problem Identification and Resolution

PRA Probabilistic Risk Assessment

psi Pounds Per Square Inch

psid Pounds Per Square Inch Differential

psig Pounds Per Square Inch Gauge

RIS Regulatory Issue Summary

SDC Shutdown Cooling

SDP Significance Determination Process

SEP Systematic Evaluation Program

SG Steam Generator

SIRW Safety Injection Refueling Water SR Surveillance Requirement

SSC Systems, Structures, and Components

TI Temporary Instructions

TS Technical Specification

URI Unresolved Item

Vac Volts Alternating Current

VAC Volts Alternating Current

VDC Volts Direct Current

Vdc Volts Direct Current

WO Work Order

A. Vitale

-2- In accordance with Title 10, Code of Federal Regulations

(CFR) "Rules of Practice," a copy of this letter and its enclosure will be available electronically for public inspection in the NRC Public

Document Room or from the Publicly Available Records System (PARS) component of NRC's Agencywide Documents Access and Management System (ADAMS), accessible from the NRC Web site at http://www.nrc.gov/reading

-rm/adams.html

(the Public Electronic Reading Room). Sincerely,

Ann Marie Stone, Chief

Engineering Branch 2

Division of Reactor Safety

Docket No. 50

-255 License No. DPR

-20 Enclosure:

Inspection Report 05000255/2014008

w/Attachment: Supplemental Information

cc w/encl:

Distribution via