IR 05000277-11-007, 05000278-11-007; 02/14/2011 - 03/11/2011; Peach Bottom Atomic Power Station, Units 2 and 3; Component Design Bases Inspection

ML111150200
Person / Time
Site:	Peach Bottom
Issue date:	04/25/2011
From:	Doerflein L T Engineering Region 1 Branch 2
To:	Pacilio M J Exelon Generation Co
References
IR-11-007
Download: ML111150200 (36)
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Text

UNITED STATES NUCLEAR REGU LATORY COMMISSION REGION I 475 ALLENDALE ROAD KING OF PRUSSIA. PA 19406-1415 April 25, 20LL Mr. Michael Senior Vice President, Exelon Generation Company, LLC President and Chief Nuclear Officer, Exelon Nuclear 4300 Winfield Road Warrenville, lL 60555

SUBJECT: PEACH BOTTOM ATOMIC POWER STATION - NRC COMPONENT DESIGN BASES I NSPECTl ON REPORT 0500027 7 l 201 1 007 AND 05000 27 81 201 1 007

Dear Mr. Pacilio:

On March 11,2011, the U.S. Nuclear Regulatory Commission (NRC) completed an inspection at your Peach Bottom Atomic Power Station (PBAPS), Units 2 and 3. The enclosed inspection report documents the inspection results, which were discussed with Mr. Thomas Dougherty, Site Vice President, and other members of your staff on March 11, 2011.The inspection examined activities conducted under your license as they relate to safety and compliance with the Commission's rules and regulations and with the conditions of your license.In conducting the inspection, the team examined the adequacy of selected components and operator actions to mitigate postulated transients, initiating events, and design basis accidents'

T'he inspection involved field walkdowns, examination of selected procedures, calculations and records, and interviews with station personnel.

This report documents two NRC-identified findings that were of very low safety significance (Green). These findings were determined to involve violations of NRC requirements.

However, because of the very low safety significance and because they were entered into your corrective action program, the NRC is treating these as non-cited violations (NCV), consistent with Section 2.3.2 of the NRC's Enforcement Policy. lf you contest any NCV in this report, 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, D.C. 20555-0001, with copies to the RegionalAdministrator, Region l; the Director, Office of Enforcement, U.S. Nuclear Regulatory Commission, Washington, D.C.20555-0001; and the NRC Resident Inspector at PBAPS. In addition, if you disagree with the cross-cutting aspect assigned to one of the findings 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 I and the NRC Resident Inspector at PBAPS. ln accordance with 10 CFR 2.390 of the NRC's "Rules of Practice," a copy of this letter, its enclosure, and your response (if any) will be available electronically for the public inspection in the NRC Public Docket Room or from the Publicly Available Records component of NRC's document system (ADAMS). ADAMS is accessible from the NRC Web site at http://www.nrc.qov/readinq-rm/adams.html (the Public Electronic Reading Room).

Sincerely,Lawrence T. Doerflein, Chief /Engineering Branch 2 Division of Reactor Safety Docket Nos. 5A-277',50-278 License Nos. DPR-44, DPR-56

Enclosure:

Inspection Report 0500027712011007 and 0500027812011007

w/Attachment:

Supplemental lnformation cc Mencl: Distribution via ListServ

SUMMARY OF FINDINGS

1R 0500027712011007, 0500027812011007; 0211412011

-0311112011;

Peach Bottom Atomic Power Station, Units 2 and 3; Component Design Bases Inspection.

The report covers the Component Design Bases Inspection conducted by a team of four NRC inspectors and two NRC contractors.

Two findings of very low risk significance (Green) were identified, which were also considered to be non-cited violations.

The significance of most findings is indicated by their color (Green, White, Yellow, Red) using NRC Inspection Manual Chapter (lMC) 0609, "Significance Determination Process" (SDP). The cross-cutting aspects were determined using IMC 0310, "Components Within the Cross-Cutting Areas." Findings for which the SDP does not apply may be Green or be assigned a severity level after NRC management review. The NRC's program for overseeing the safe operation of commercial nuclear power reactors is described in NUREG-1649, "Reactor Oversight Process," Revision 4, dated December 2006.NRC-ldentified and Self-Revealinq Findinqs

Cornerstone: Mitigating

Systems.

Green.

The team identified a finding of very low safety significance involving a non-cited violation of 10 CFR 50, Appendix B, Criterion lll, "Design Control," in that, Exelon did not ensure the ability to transfer fuel oil between underground fuel oil storage tanks.Specifically, Exelon had not performed adequate analyses or testing to demonstrate adequate net positive suction head available (NPSHn) for the EDG fuel oil transfer pumps. In response, Exelon entered this issue into their corrective action program and performed an evaluation to assure the fuel oil transfer pump NPSHA was adequate.The finding was more than minor because it was associated with the design control attribute of the Mitigating Systems Cornerstone and adversely affected the cornerstone objective of ensuring the availability, reliability, and capability of systems that respond to initiating events to prevent undesirable consequences.

The team performed a Phase 1 SDP screening, in accordance with NRC IMC 0609, Attachment 4, "Phase 1 - Initial Screening and Characterization of Findings," and determined the finding was of very low safety significance (Green) because it was a design or qualification deficiency confirmed not to result in loss of operability or functionality.

This finding does not have a cross-cutting aspect because the most significant contributor of the performance deficiency is not reflective of current licensee performance.

(1R21 .2.1.1).

Green.

The team identified a finding of very low safety significance involving a non-cited violation of 10 CFR 50, Appendix B, Criterion lll, "Design Control," in that Exelon did not verify the adequacy of the seismic design for temporary battery cells that had been placed in-service in safety-related station batteries that were required to be operable.Specifically, Exelon did not evaluate whether mechanical stress could be transferred from one temporary battery cell to another via rigid bus bars attached to the cell terminal posts and, as a consequence, did not verify that damage to a cell post or cell case would not result during a seismic event. During the inspection period, the temporary battery cells were not in-service and were not required to be operable.

In response, Exelon entered this issue into the corrective action program and performed a preliminary calculation to verify seismic adequacy.This finding was more than minor because it was associated with the design control attribute of the Mitigating Systems Cornerstone and adversely affected the cornerstone objective of ensuring the availability, reliability, and capability of systems that respond to initiating events to prevent undesirable consequences.

The team performed a Phase 1 SDP screening, in accordance with NRC IMC 0609, Attachment 4, "Phase 1 - lnitial Screening and Characterization of Findings," and determined the finding was of very low safety significance (Green) because it was a design or qualification deficiency confirmed not to result in loss of operability or functionality.

This finding had a cross-cutting aspect in the area of Problem ldentification and Resolution, Corrective Action Program, because Exelon did not thoroughly evaluate the problem such that the resolution addressed the cause. Specifically, a 2009 issue report identified that the battery cells on the cart did not have seismic spacers between the cells and did not have steel tie-rods installed for a cell clamp assembly, similar to the station battery. The issue report incorrectly determined that plastic tubes in between the two cells would provide an adequate seismic restraint.

IMC 0310, Aspect P.1(c)(1R21.2.1.2)ill

REPORT DETAILS

1. REACTOR SAFEry Cornerstones:

Initiating Events, Mitigating Systems, Barrier lntegrity 1R21 Component Desiqn Bases Inspection (lP 71 111

.21 ).1 lnspection

Sample Selection Process The team selected risk significant components for review using information contained in the Peach Bottom Atomic Power Station (PBAPS) Units 2 and 3 Probabilistic Risk Assessment (PRA) and the U. S. Nuclear Regulatory Commission's (NRC) Standardized Plant Analysis Risk (SPAR) model. Additionally, the PBAPS Significance Determination Process (SDP) Phase 2 Risk-lnformed lnspection Notebook (Revision 2.1a)was referenced in the selection of potential components for review. In general, the selection process focused on components that had a Risk Achievement Worth (RAW) factor greater than 1.3 or a Risk Reduction Worth (RRW) factor greater than 1.005. The components selected were located within both safety-related and non-safety related systems, and included a variety of components such as pumps, breakers, heat exchangers, transformers, and valves.The team initially compiled a list of components based on the risk factors previously mentioned.

Additionally, the team reviewed the previous component design bases inspection report (0500027712008007 and 0500027812008007)and excluded the majority of those components previously inspected.

The team then performed a margin assessment to narrow the focus of the inspection to 19 components and 4 operating experience (OE) items. The team's evaluation of possible low design margin included consideration of original design issues, margin reductions due to modifications, or margin reductions identified as a result of material condition/equipment reliability issues.The assessment also included items such as failed performance test results, corrective action history, repeated maintenance, maintenance rule (aX1) status, operability reviews for degraded conditions, NRC resident inspector insights, system health reports, and industry OE. The team also selected some components for large early release frequency (LERF) considerations, including the core spray injection, high pressure coolant injection steam isolation, and hardened vent valves. Finally, consideration was also given to the uniqueness and complexity of the design and the available defense-in-depth margins.The inspection performed by the team was conducted as outlined in NRC Inspection Procedure (1P) 71111.21.

This inspection effort included walkdowns of selected components, interviews with operators, system engineers and design engineers, and reviews of associated design documents and calculations to assess the adequacy of the components to meet design basis, licensing basis, and risk-informed beyond design basis requirements.

Summaries of the reviews performed for each inspection sample and the specific inspection finding identified are discussed in the subsequent sections of this report. Documents reviewed for this inspection are listed in the Attachment.

,2.2.1 2 Results of Detailed Reviews Results of Detailed Component Reviews (19 samples).2.1.1 E2 Emeroencv Diesel Generator-Mechanical.

OBG12 a. lnspection Scope The team reviewed the adequacy and appropriateness of design assumptions and calculations related to emergency diesel generator (EDG) fuel oil consumption, air start system capability, and room ventilation.

The team reviewed design calculations to ensure underground fueloil tank capacities were sufficient to meet required fuel oil consumption rates. Hydraulic design requirements for fuel oil transfer pumps related to vortexing in the tank outlet piping and net positive suction head (NPSH) were reviewed to verify the design capability of the EDG fuel oil transfer pumps. The EDG fuel oil chemistry tests were reviewed to verify testing was conducted in accordance with facility procedures and license requirements; and that the results were consistent with the assumptions contained in the fuel oil consumption calculation.

The team performed a review of maintenance and surveillance test procedures to ensure that the thermal performance of EDG heat exchangers, cooled by emergency service water, was adequate.

The preventive maintenance program for lube oil and fuel oilfilters was reviewed to ensure filters were replaced when necessary.

Field walkdowns were performed of the EDG to independently assess the material condition of the EDG and associated equipment.

Finally, the team reviewed corrective action documents to determine if there were any adverse trends associated with the EDG and to assess Exelon's capability to evaluate and correct problems.b. Findinqs lntroduction:

The team identified a finding of very low safety significance (Green)involving a non-cited violation of 10 CFR 50, Appendix B, Criterion lll, "Design Control," in that Exelon did not ensure the ability to transfer fuel oil between underground fuel oil storage tanks. Specifically, Exelon had not performed adequate analyses or testing to demonstrate adequate NPSH available (NPSHA) for the EDG fuel oil transfer pumps.Description:

The fuel oil transfer pumps transfer fuel from buried fuel oil tanks to the EDG day tanks or, when required, can be used to transfer fuel oil from one storage tank to another. Each of the four EDGs has an associated underground fuel oil tank that was originally designed to supply seven days of fuel, and a fuel oil transfer pump located in the EDG room. There are no automatic trips of the fuel oiltransfer pumps on low tank level. Fuel oil pump NPSHn and vortex calculations are important to ensure that the EDGs have adequate volume of fuel oil available following a design basis event and that adequate margin is available to prevent air entrainment when fuel tank levels approach the tank bottom.Enclosure 3 Calculation PM-0123, "Diesel Generator Fuel Oil Consumption for 6 Days and 7 Days Operation with LOCA Dependent Loads," Rev. 0, indicated that the totalvolume of all four EDG fuel oil storage tanks contain sufficient quantity of fuel oil for seven days of EDG operation.

However, fuel oilwould need to be transferred between the underground tanks using the fuel oil transfer pumps in order to support operation of the EDG that has a higher electrical load using procedure AO 52D.1, "Transferring Diesel Fuel Oil Between Storage Tanks," Rev. 7.The team reviewed procedure AO 52D.1 and underground fuel oil storage tank level alarm setpoints, and determined that no specific guidance existed in the procedure to atert operators when the fuel oil storage tank levels reach the vortex limit, or when there was insufficient NPSH1 at the pump impeller.

lssue Report (lR) 01185526 was written during the inspection to evaluate and correct the issue.The team reviewed calculations for potential vortex formation at the fuel oil transfer pump suction and for NPSHA Calculation PM-0046, "DieselGenerator FuelOil Storage Tank Volume Determinations," Rev. 1, determined the usable volume of the storage tanks based on a vortex limit of 14 inches above the tank bottom. The vortex limit was based on a pump suction flow rate of 10 gpm. In 2006, lR 00476280 was written to evaluate a pump flow rate of 10 gpm as potentially non-conservative because the pump in-service testing (lST) acceptance criterion was about 45 gpm. The 10 gpm flow rate was specified by the architect/engineer on the originalfuel oil pump data sheet as the design input for the minimum pump flow rate. This lR stated that the appropriate fuel oil flow rate that should be used in the vortex calculation was about 24 gpm, based on a 1991 test, which measured actualflow when the pump was providing fueloil to the day tank (i.e., the normalflow path). The lR preliminarily concluded that the present level of 14 inches was sufficient for pump suction flow rate of 24 gpm. The team performed an evaluation of the vortex limit of 24 gpm to 45 gpm pump suction flow rates, and determined that the present level of submergence was satisfactory for vortex prevention.

Regarding NPSH^, Exelon determined that they did not have a calculation for the fuel oil transfer pumps, and in response, initiated lR 011185519.

A preliminary evaluation performed by Exelon identified that the NPSHA at a pump flow rate oI24 gpm had a margin of less than one inch of suction lift when compared to the fuel oil tank level at which unusable volume is determined (14 inches above tank bottom). The team identified that the pump flow rate could potentially be greater than 24 gpm during the transfer from one tank to another tank due to the pumps' design capability of 45 gpm and the specific transfer pump and associated tank configuration.

Higher flow rates, such as those that might occur during fuel oil transfer from one underground tank to another, could result in not having adequate NPSHA at the pump suction. Insufficient NPSHA at the pump suction could lead to fluid cavitation at the pump impeller, leading to degradation of pump hydraulic performance, with subsequent pump failure. In response, Exelon demonstrated to the team that the 1991 flow test provided reasonable assurance that the existing piping, tank, and throttle valve configuration bounds the assumed fuel oil transfer pump flow rate at24 gpm.Enclosure 4 Analvsis:

The team determined that the failure to properly evaluate the NPSHn considerations for the EDG fuel oil transfer pumps for operation following a design basis event was a performance deficiency that was reasonably within Exelon's abitity to foresee and prevent. The finding was more than minor because it was associated with the design control attribute of the Mitigating Systems Cornerstone and adversely affected the cornerstone objective of ensuring the availability, reliability, and capability of systems that respond to initiating events to prevent undesirable consequences.

In addition, this issue was similar to Example 3.j of lnspection Manual Chapter (lMC) 0612, Appendix E, "Examples of Minor lssues," which determined that calculation errors would be more than minor if, as a result of the erors, there was reasonable doubt on the operability of the component.

For this issue, there was a reasonable doubt on the operability of the fuel oil transfer pumps at low fuel oil storage tank levels because the required NPSH was originally specified at flow rate of 10 gpm, but historical test results and design data indicated that the pump flow rate could have been between 24 gpm and 45 gpm. Higher pump flow rates require additional NPSHA because the dynamic pressure loss in the inlet piping is a function of the fluid velocity.

The higher flow rates would require additional submergence of the suction pipe in the tank, resulting in more unusable oil in the underground tanks. ln response to this issue, Exelon performed a preliminary calculation to demonstrate that the existing NPSHA with the pump operating at a flow rate of 24 gpm would result in acceptable pump performance.

Exelon also initiated actions to improve procedure guidance when transferring EDG fuel oil.Traditional enforcement does not apply because the issue did not have any actual safety consequences or potential for impacting the NRC's regulatory function, and was not the result of any willful violation of NRC requirements.

In accordance with NRC Inspection Manual Chapter 0609, Attachment 4, "Phase 1 -Initial Screening and Characterization of Findings," a Phase 1 SDP screening was performed and determined the finding was of very low safety significance (Green)because it was a design deficiency confirmed not to result in loss of operability or functionality.

This finding did not have a cross-cutting aspect because the most significant contributor of the performance deficiency was not reflective of current licensee performance.

Enforcement:

10 CFR 50, Appendix B, Criterion lll, "Design Control," requires, in part, that measures be provided 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. These measures shall include provisions to assure that appropriate quality standards are specified and included in design documents.

Contrary to the above, prior to March 11,2011, the measures established to verify the adequacy of the design of the EDG fuel oil transfer pumps were not adequate.

Specifically, Exelon did not verify design requirements (EDG fuel oil transfer pump NPSHA) were satisfied by either appropriate engineering calculations or in-situ testing. Because this violation is of very low safety significance (Green) and was entered into the licensee's corrective action program as lRs 01185519 and 01 185526, this violation is being treated as a non-cited violation consistent with Section 2.3.2 ol the NRC Enforcement Policy. (NCV 0500027712011007-01, 05000278t20110007-Ol, Failure to Demonstrate the Gapability of the EDG Fuel Oil Transfer Pumps to Fulfill Their Safety Functions Under all Gonditions)5.2.1.2 Unit 3'B' 125 Vdc Batterv. 38D01 a. lnspection Scooe The team reviewed the design, testing, and operation of the Unit 3'B' 125 Vdc battery (38D01), to verify it could perform its design basis function to provide direct current (DC)power to connected loads during normal, transient, and postulated accident conditions, including station blackout events. Specifically, the team reviewed design calculations, including battery sizing, load profile studies, voltage drop calculations, and battery terminal connection resistances, to evaluate whether the battery capacity was adequate for the equipment load and duration required by design and licensing bases, and to assess whether adequate voltage was available to meet minimum voltage specifications for connected loads during worst case loading conditions.

The team also reviewed the battery hydrogen generation analysis to determine whether hydrogen concentration levels would stay below acceptable levels during normal and postulated accident conditions.

The team reviewed battery tests, including modified performance and service discharge tests, and routine surveillance tests to assess whether the testing and maintenance was sufficient and performed in accordance with approved procedures, vendor recommendations, industry standards, and design and licensing requirements.

The team compared the service test and modified performance test load profiles to the load profile studies for the loss-of-coolant accident with a concurrent loss-of-offsite power and the station blackout design assumptions to verify the load testing enveloped the predicted worst case loading conditions.

The team interviewed design and system engineers regarding the design, operation, testing, and maintenance of the battery.Field walkdowns of the battery were performed to independently assess the material condition of the battery cells and associated electrical equipment.

Finally, the team reviewed corrective action documents to determine if there were any adverse trends associated with the battery and to assess Exelon's capability to evaluate and correct problems.b. Findinqs lntroduction:

The team identified a finding of very low safety significance (Green)involving a non-cited violation of 10 CFR 50, Appendix B, Criterion lll, "Design Control," in that Exelon did not verify the adequacy of the seismic design for temporary battery cells that had been placed in-service in safety-related station batteries that were required to be operable.

Specifically, Exelon did not evaluate whether mechanical stress could be transferred from one temporary battery cell to another via rigid bus bars attached to the cell terminal posts and, as a consequence, did not verify that damage to a cell post or cell case would not result during a seismic event. During the inspection period, the temporary battery cells were not in-service and were not required to be operable.Description:

In 1990, Exelon fabricated four steel battery carts to transport and support two battery cells per cart. As needed, Exelon moved the cells on the four carts into a battery room, connected the temporary cells to an in-service safety-related battery, and then removed a row of permanent cells from service (i.e., disconnected).

While the Enclosure 6 temporary cells were in-service and considered operable, they remained in the battery carts. This method allowed Exelon to replace an entire battery, a row at a time, while the reactor plant remained at power (i.e., on-line battery replacement).

Since 1990, Exelon has used this method to replace allfour station batteries in each unit twice (total of 16 full battery replacements), and also for corrective maintenance when an individual cell needed to be removed from service while maintaining the battery operable.The team identified that the two cells, in a single battery cart, did not have any seismic restraints or seismic spacer plates (e.9., Styrofoam sheets) between the cells, as required by the battery vendor for the seismically qualified station battery racks. The two cells were mechanically connected to each other via rigid bus bars attached to the cell posts. Calculation PS-028, "Design of Battery Cart to Transport and Support Temporary Batteries," Rev. 1, documented Exelon's seismic analysis for the temporary cells when installed in the battery carts. That analysis verifled that a cart with two cells (i.e., evaluated as a single unit) would not tip over during a seismic event, but did not evaluate independent movement, such as sliding, between the two cells (e.9., relative motion cell to cell). lf independent movement were to occur, then mechanical load and stress would be transferred from one cell to the other via the bus bars attached to the cell terminal posts, and could result in damage to a post or case.During the inspection period, the temporary battery cells were not in-service and not required to be operable.

The most recent usage was in November 2006, when temporary cells were installed in the 28 Battery. Exelon entered this issue into their corrective action program as lR 1 182989, and performed a preliminary calculation to verify seismic adequacy.

The team reviewed the calculation and found it reasonable.

Analvsis:

The team determined that the failure to evaluate whether temporary battery cells would remain operable during a seismic event prior to substituting the cells into an in-service station battery during on-line battery replacement or maintenance was a performance deficiency that was reasonably within Exelon's ability to foresee and prevent. The finding was more than minor because it was associated with the design control attribute of the Mitigating Systems Cornerstone and adversely affected the cornerstone objective of ensuring the availability, reliability, and capability of systems that respond to initiating events to prevent undesirable consequences.

In addition, this issue was similar to example 3.k of IMC 0612, Appendix E, "Examples of Minor lssues," which determined that calculation errors would be more than minor if, as a result of the errors, there was reasonable doubt on the operability of the component.

For this issue, there was a reasonable doubt on the operability of the temporary battery cells during a seismic event, in that a knowledgeable seismic engineer could not determine the adequacy of design based on a review of the existing seismic analysis, design details, or available vendor information.

ln response to this issue, Exelon performed a preliminary calculation to assess past seismic adequacy, which utilized material properties, such as coefficient of friction, which were not available from typically utilized engineering reference sources or material properties handbooks.

Traditional enforcement does not apply because the issue did not have any actual safety consequences or potentialfor impacting the NRC's regulatory function, and was not the result of any willful violation of NRC requirements.

7 In accordance with NRC Inspection Manual Chapter 0609, Attachment 4, "Phase 1 -Initial Screening and Characterization of Findings," a Phase 1 SDP screening was performed and determined the finding was of very low safety significance (Green)because it was a design deficiency confirmed not to result in loss of operability or functionality.

This finding had a cross-cutting aspect in the area of Problem ldentification and Resolution, Corrective Action Program, because Exelon did not thoroughly evaluate the problem such that the resolution addressed the cause. Specifically, in 2009, ,R 844207 identified that the battery cells on the cart did not have Styrofoam (i.e., seismic) spacers between the cells and did not have steeltie-rods installed for a cell clamp assembly, similar to the station battery. The lR incorrectly determined that plastic tubes in-between the two cells would provide an adequate seismic restraint.

IMC 0310, Aspect P.1(c)]Enforcement:

10 CFR 50, Appendix B, Criterion lll, "Design Control," requires, in part, that design control measures shall provide for verifying the adequacy of design, such as by design reviews, or the use of alternate or simplified calculational methods. Contrary to the above, from 1990 until 2011, Exelon did not verify the adequacy of the seismic design for temporary battery cells that had been placed in-service in safety-related station batteries that were required to be operable.

Calculation PS-028, "Design of Battery Cart to Transport and Support Temporary Batteries," Rev. 1, verified seismic adequacy of the cart to support the total weight of two battery cells, but did not evaluate independent movement, such as sliding, between the two cells (i.e., relative motion cell to cell). Specifically, Exelon did not evaluate whether mechanical load and stress could be transferred from one temporary battery cell to another via rigid bus bars attached to the cell terminal posts and, as a consequence, did not verify that damage to a cell post or cell case would not result during a seismic event. The most recent usage was in November 2006, when the temporary cells were installed in the 28 Battery. Because this violation was of very low safety significance (Green) and was entered into Exelon's corrective action program (lR 1182989), this violation is being treated as a non-cited violation, consistent with Section 2.3.2 of the NRC's Enforcement Policy. (NCV O 500027 7 l 20 1 1 007 -02, 0 500027 8 I 20 1 1 007 -02, Tem po rary Battery Cart Se is m i c Configuration Deficiency)

.2.1.3 Unit 3 Core Sprav / Residual Heat Removal Room Coolers. 3DE057 / 3DE058

a. Inspection Scooe The core spray and residual heat removal (RHR) pump rooms are cooled by fan coil units that remove heat to the emergency service water (ESW) system during postulated accident conditions.

The team reviewed room heat load calculations and pump room cooler thermal performance calculations to verify the units were capable of supplying sufficient cooling to the rooms. Recent thermal performance test results were reviewed to determine whether the room coolers were capable of performing adequately during postulated accident conditions.

The team performed a walkdown of the room cooler areas to assess material condition and cleanliness of the fan coil fins. The team also Enclosure I reviewed corrective action documents and health reports to determine if there were any adverse trends associated with the room coolers and to assess Exelon's capability to evaluate and correct problems.b. Findinos No findings were identified.

.2.1.4 'B' Emerqencv

Service Water Pump. 08P57 a. lnspection Scope The team ensured river levels met vendor requirements associated with ESW pump suction submergence and NPSH design requirements to ensure the pump was capable of performing its safety function.

The team verified that appropriate seismic analysis was performed on the pump/motor assembly.

Hydraulic calculations were reviewed to ensure design requirements for flow, pressure, and vibration were appropriately translated into acceptance criteria in pump in-service testing (lST) procedures.

The team reviewed pump structure ventilation calculations to ensure environmental conditions were adequately maintained.

Design change history and IST results were reviewed to assess potential component degradation and impact on design margins; and an associated ESW pump replacement test was also reviewed to verify the pump's ability to perform its design safety function.

The team also conducted a walkdown of the ESW pump to assess the material condition and to verify the installed configuration was consistent with the plant drawings, and the design and licensing bases. Finally, the team reviewed corrective action documents to determine if there were any adverse trends associated with the pump and to assess Exelon's capability to evaluate and correct problems.b. Findinqs No findings were identified.

.2.1.5 Unit 2 Condensate

Storaqe Tank. 20T10

a. Inspection Scope

The condensate storage tank (CST) functions as the preferred source of water for the high pressure coolant injection (HPCI) pump and the reactor core isolation cooling (RCIC) pump. The team reviewed design documents, including the HPCI pump and RCiC pump vortex calculation when aligned to the CST, CST drawings, and tank level uncertainty calculations.

The team also reviewed results of recent visual inspections of the CST, and conducted a walkdown of the tank area to observe material condition.

Finally, the team reviewed corrective action documents to determine if there were any adverse trends associated with the CST and to assess Exelon's capability to evaluate and correct problems.Enclosure I I b. Findinqs No findings were identified.

.2.1.6 Unit 3 Hioh Pressure Service Water Pump. 3DP042

a. lnspection Scope The team inspected the 'D' high pressure service water (HPSW) pump (3DP042) to determine whether it could fulfill its design basis function of delivering cooling flow to the associated residual heat removal heat exchangers and to provide water to the residual heat removal system to flood the primary containment after a postulated accident.

The team reviewed applicable portions of the Updated Final Safety Analysis Report (UFSAR), the Technical Specifications, the Technical Requirements Manual, design basis documents, and calculations to identify the design basis requirements for the pump. The team interviewed the system engineer and reviewed pump testing results to assess pump performance.

The team walked down the HPSW pump, the pump motor, and the pump structure to independently assess Exelon's configuration control, the material condition, the pump's operating environment, and flood protection.

The pump submergence requirement was reviewed to ensure adequate NPSHn. The stress analysis of the pump and discharge piping restraints were reviewed to evaluate maximum loading. The team reviewed IST results to ensure that the pump operation was within the specified parameters.

In addition, pump cooling requirements and operating procedures were reviewed to ensure adequate pump operating temperatures.

Finally, the team reviewed corrective action documents and system health reports to determine if there were any adverse trends associated with the HPSW pump and to assess Exelon's capability to evaluate and correct problems'b. Findinqs No findings were identified.

.2.1.7 Service Water lntake

a. lnspection Scope The team inspected the service water intake to determine whether it could fulfill its design basis function of supplying cooling water to safety-related and nonsafety-related systems during normal and accident conditions.

The team reviewed applicable portions of the UFSAR, the Technical Specifications, the Technical Requirements Manual, design bases documents, and calculations to identify the design basis requirements for the service water intake structure.

Silting levels within the service water bay were reviewed to ensure proper HPSW and ESW pump operation.

The team reviewed procedures and instrumentation to ensure proper manual isolation of the service water bay portion of the intake structure in the event of a high or low water level in Conowingo Pond to ensure availability of cooling water to the supplied safety-related systems. Additionally, the team performed a walkdown of accessible areas on the intake structure to assess configuration control and the material condition of risk-significant structures, systems, Enclosure 10 and components.

Material condition of inaccessible areas was assessed by performing a review of periodic inspection reports performed by Exelon and independent contractors.

Finally, the team reviewed corrective action documents to determine if there were any adverse trends associated with the service water intake structure to assess Exelon's capability to evaluate and correct problems.b. Findinqs No findings were identified.

.2.1.8 Unit 2 Core Sprav Iniection

Valve. MO-2-14-012A.

and Hioh Pressure Coolant Iniection Steam lsolation Valve. MO-2-23-016 (2 samples)a. Inspection Scope The team inspected two Unit 2 motor-operated valves (MOVs), the loop'A'core spray (CS) injection valve (MO-2-14-0124)and the HPCI steam isolation valve (MO-2-23-016), to verify the valves were capable of performing their design basis functions.

Valve MO-2-14-012A is a normally closed valve with a safety function to open for CS injection and a safety function to close for primary containment isolation.

MO-2-23-016 is a normally open valve with a safety function to close on a HPCI isolation signal.The team reviewed the UFSAR, the Technical Specifications, design basis documents, drawings, and procedures to identify the design basis requirements of each valve. The team reviewed periodic MOV diagnostic test results, stroke-timing test data, and logic test results to verify acceptance criteria were met. The team verified the MOV safety functions, torque switch settings, performance capability, and design margins were adequately monitored and maintained for each MOV. The team verified that diagnostic testing results were used to trend stem nut wear to ensure an adequate stem nut replacement frequency.

The team reviewed MOV weak link calculations to ensure the ability of the MOVs to remain structurally functional while stroking under design basis conditions.

The team verified that the valve analysis used the maximum differential pressure expected across the valves during worst case operating conditions.

Thermal binding, pressure locking, and temperature induced pressure locking analyses were reviewed to determine susceptibility.

Additionally, the team reviewed degraded voltage conditions, thermal overload sizing, and voltage drop calculation results to confirm that the MOVs would have sufficient voltage and power available to perform their safety function at degraded voltage conditions.

The team discussed the design, operation, and maintenance of the MOVs with engineering staff to evaluate performance history, maintenance, and overall component health of the MOVs. The team also conducted a walkdown of MO-2-14-012A and remotely viewed MO-2-23-016 to assess the material condition and to verify the installed configurations were consistent with the plant drawings, and the design and licensing bases. Finally, the team reviewed corrective action documents to determine if there were any adverse trends associated with the valves and to assess Exelon's capability to evaluate and correct problems.Enclosure 11 b, Findinos No findings were identified.

.2.1.9 'B' Emeroencv

Service Water Pump Motor. 08P57

a. Inspection Scope

The team inspected the'B' ESW pump (08P57) motor to determine whether it could fulfill its design basis function of providing adequate horsepower for the pump to deliver cooling flow to the associated EDG heat exchangers and room coolers. The team interviewed the system engineer and reviewed lRs that had been written for the ESW pump motor to assess its performance.

The team walked down the ESW pump, the pump motor, and the pump structure to independently assess Exelon's configuration control, the pump motor's operating environment, and its material condition.

The team reviewed ESW system sizing calculations and a design modification that replaced the'B'pump to determine and evaluate the required capacity for the break horsepower required by the pump motor during design basis conditions.

The UFSAR and Technical Specifications were reviewed to ensure consistency between the pump parameters and the design basis flow requirements.

The team reviewed the 4160 Vac system load flow calculation and motor nameplate data to confirm that adequate voltage would be available at the motor terminals for design basis conditions.

The team also reviewed the motor overcurrent relay setting calculation , relay settings, and recent overcurrent relay calibration tests to evaluate whether the protective relays would provide for reliable motor operation at design basis minimum voltage conditions.

Finally, the team reviewed corrective action documents and system health reports to determine if there were any adverse trends associated with the ESW pump motor and to assess Exelon's capability to evaluate and correct problems.b. Findinqs No findings were identified.

.2.1.1 0 E2 Emerqencv

Diesel Generator-Electrical.OBGl2

a. Inspection Scope

The team inspected the E2 EDG to confirm that it was capable of meeting its design basis accident load requirements.

The EDG was designed to provide standby power to safety-related 4160 Vac emergency auxiliary switchgear E22 (Unit 2) and E23 (Unit 3)when the preferred power supply is not available.

The team reviewed the UFSAR, station single line diagrams, EDG vendor rating documentation, station operating procedures, and the generator nameplate data to confirm consistency in the load ratings.The team reviewed the brake horsepower basis for selected pump motors to ensure loads were adequately considered in the loading study at worse case motor load conditions.

The team reviewed the EDG load study for the worse case design basis Enclosure 12 loading conditions and the periodic surveillance testing to confirm the EDG load capability.

The team walked down the EDGs to independently assess Exelon's configuration control, the generator's operating environment, and its material condition.

The team also reviewed the design basis and periodic testing for the components that could trip the EDG during a design basis postulated accident to ensure that they would operate reliably.

Finally, the team reviewed corrective action documents and system health reports to determine if there were any adverse trends associated with the generator and to assess Exelon's capability to evaluate and correct problems.b. Findinqs No findings were identified.

.2.1.1 14160

Volt Emeroencv Auxiliarv Switchqear E22. 20416 a. Insoection Scope The team inspected 4160 Vac emergency auxiliary switchgear E22to confirm that it was capable of meeting its design basis requirements.

Switchgear E22 was designed to distribute power to safety-related pump motors and load centers during design basis conditions.

The team reviewed design basis load flow and short circuit current calculations to determine the design basis for maximum load, momentary and interrupting duty, and bus bracing requirements, and reviewed switchgear equipment vendor ratings for conformance with the design basis. The team also reviewed design basis inputs for conservatism and reviewed vendor equipment data to confirm adequate margin in breaker momentary and interrupting duty. The team reviewed protective relaying calculations for breaker coordination for incoming line and load center feeder breakeis, preventive maintenance for selected breakers, component replacements, and the results of inspections/tests to confirm the reliability of the equipment.

The team performed a walk down of the switchgear to independently assess Exelon's configuration control, the operating environment, and its material condition.

Finally, the team reviewed corrective action documents and system health reports to determine if there were any adverse trends associated with the switchgear, to confirm that the switchgear and breakers were properly maintained, and to assess Exelon's capability to evaluate and correct problems.b. Findinqs No findings were identified.

.2.1.1 2 Unit 2 'A' Reactor Protection

Svstem Motor-Generator Set / Scram Solenoid Pilot Valves a. lnspection Scope The team reviewed the Technical Specifications and Bases, other design and licensing bases documentation, and surveillance requirements for the reactor protection system electric power monitoring assemblies for motor generator set undervoltage to confirm the design basis voltage at the scram solenoid pilot valves (SSPV). The team reviewed the Enclosure 13 results of recent plant testing that determined maximum voltage drop to hydraulic control unit (HCU) fuses and the results of testing that was conducted by Exelon to determine vendor (Automatic Switch Company (ASCO) and Automatic Valve Company (AVCO))solenoid electrical data, including pickup and dropout voltages.

The team reviewed the vendor drawings and rating data for the originalASCO and the replacement AVCO solenoids to confirm the capability of the solenoids to operate over the range of voltage expected at the solenoid valves. The team reviewed the engineering change request that implemented the design change for AVCO valves to replace the ASCO valves for the SSPVs, and vendor solenoid operator rating data for the replacement AVCO valves, to confirm that the Technical Specification undervoltage trip value supported continuous operation of the AVCO solenoid valves. The team performed a walk down of the HCU SSPVs to independently assess Exelon's configuration control, the operating environment, and the material condition.

Finally, the team reviewed corrective action documents and system health reports to determine if there were any adverse trends associated with the SSPVs, to confirm that the HCUs were properly maintained, and to assess Exelon's capability to evaluate and correct problems.b. Findinqs No findings were identified.

.2.1.1 3 Unit 3'B' 125 Vdc Batterv Bus. 3BD17

a. Inspection Scope

The team reviewed the design and operation of the 'B' 125 Vdc battery bus (38D17), and associated distribution panels to evaluate whether the loading of the DC bus was within equipment ratings and to determine whether the bus could perform its design basis function to reliably power the associated loads under worst case conditions.

Specifically, the team reviewed calculations and drawings, including voltage drop calculations, short circuit analysis, and load study profiles, to evaluate the adequacy and appropriateness of design assumptions.

The team also reviewed the DC overcurrent protective coordination studies to verify there was adequate protection for postulated faults in the DC system.The team interviewed system and design engineers, and walked down the 125Vdc battery bus and distribution panels to independently assess the material condition and determine whether the system alignment and operating environment was consistent with design basis assumptions.

Finally, the team reviewed corrective action documents and system health reports to determine whether there were any adverse operating trends and to assess Exelon's capability to evaluate and correct problems.b. Findinqs No findings were identified.

14.2.1.14 Unit 3'B' 125 Vdc Batterv Charqers.

38D003-1 and 38D003-2 a. Inspection Scooe The team reviewed the design, testing, and operation of the 125 Vdc battery chargers 38D003-1 and 38D003-2, to verify they could perform their design basis function to provide DC power to connected loads during normal, transient, and postulated accident conditions.

The team reviewed design calculations, drawings, and vendor specifications as related to battery charger sizing, short circuit fault current, load profile studies, and voltage drop to evaluate battery charger capability.

Maintenance and test procedures were reviewed to determine whether maintenance and testing was adequate to ensure reliable operation; and that they were performed in accordance with regulatory requirements, industry standards, and vendor recommendations.

The team compared as-found and as-left inspection and test results to established acceptance criteria to verify the charger's capability conformed to design basis assumptions and requirements.

In addition, the team interviewed system and design engineers, and walked down the battery chargers to independently assess the material condition, and determine whether the system alignment and operating environment were consistent with the design basis assumptions.

Finally, the team reviewed corrective action documents and system health reports to determine if there were any adverse trends associated with the chargers and to assess Exelon's capability to evaluate and correct problems.b. Findinqs No findings were identified.

.2.1.1 5 Unit 2 Hioh Pressure Coolant lniection

Valves. MO-2-23-019 and MO-2-23-020 a. lnspection Scope The team reviewed the design, testing, and operation of the HPCI system injection valves (MO-2-23-019 and MO-2-23-020)to verify they could perform their design basis functions during normal, transient, and postulated accident conditions.

Both valves were included in Exelon's safety-related MOV program. Valve MO-2-23-019 is a normally closed valve with a safety function to open for HPCI injection and a safety function to close for primary containment isolation.

Valve MO-2-23-020 is a normally open valve, with a safety function to open (if closed) for HPCI injection.

The team reviewed Exelon's MOV program procedures, MOV design specifications, torque switch settings, and MOV calculations to assess thrust and torque limits and actuator settings.

The team compared those values to applicable design conditions, such as maximum expected differential pressures, predicted stem nut wear, and weak link analysis, to verify worst case system conditions were adequately incorporated into test procedure acceptance criteria and component design. The team reviewed periodic tST and MOV diagnostic test results, and stem lubrication and operator grease inspection results to verify the MOV performance conformed to design Enclosure 15 and regulatory requirements, predicted expectations and assumed margins. In addition, the team reviewed motor data, degraded voltage conditions, thermal overload configuration, and voltage drop calculations to verify the MOVs would have sufficient power available to perform their safety function at worst case degraded voltage conditions.

Exelon's analyses for valve thermal binding, pressure locking, and temperature induced pressure locking were also reviewed to determine susceptibility to these phenomena.

The team reviewed HPCI logic functional test results to verify valve controls were appropriately tested and would function as required.In addition, the team interviewed system and design engineers, and walked down the MOVs to independently assess the material condition and determine whether the operating environment was consistent with the design basis assumptions.

Finally, the team reviewed corrective action documents and system health reports to determine if there were any adverse trends associated with the M.OVs and to assess Exelon's capability to evaluate and correct problems.b. Findinqs No findings were identified.

.2.1.1 6 Unit 2 Torus Hardened Vent Valve. AO-2511 and Containment

Emeroencv Vent Outboard lsolation Valve, AO-80290 a. lnspection Scope The Unit 2 torus hardened vent valve (AO-251 1) and the associated containment emergency vent outboard isolation valve (AO-80290)were reviewed to verify their ability to operate if called upon in the event of an emergency.

These vent valves are manually operated valves that were designed to allow operators to vent primary containment during a postulated accident that involved the loss of decay heat removal. The team reviewed the design basis document, maintenance history, design changes, drawings, and associated surveillance testing for the valves to ensure they were capable of performing their intended safety function.

The team also interviewed operators and the system engineer, and walked down associated equipment to assess the material condition of the valves, related piping, associated pipe support structures, and air and backup nitrogen supply lines.The team reviewed the associated emergency operating procedure and assessed the manual operator actions required to operate the valves to ensure the operators were provided with clear guidance to perform the actions as credited in the design and licensing bases. Finally, the team reviewed corrective action documents and system health reports to determine if there were any adverse trends associated with the valves and to assess Exelon's capability to evaluate and correct problems.b. Findinqs No findings were identified.

16.2.1.17 Unit 3 'C' Residual Heat Removal Pump. CP35 a. lnspection Scope The team inspected the'C' RHR pump (CP35) to determine whether it could futfill its design basis function of taking suction from the torus (suppression pool) and delivering low pressure, high volume, cooling water flow to the associated heat exchangers and the reactor vessel. The team reviewed NPSH and differential pressure calculations to ensure consistency with design basis requirements and IST results. The team interviewed the system engineer, and reviewed pump test results and completed lRs associated with the RHR pump to assess the pump's performance.

The team walked down the four Unit 3 RHR pumps and motors, and other accessible portions of the RHR system to independently assess Exelon's configuration control, the pumps' operating environment, and the RHR system material condition.

In addition, the team reviewed system flow calculations, the UFSAR, and the Technical Specifications to ensure the pump parameters were consistent with design basis assumptions.

b. Findinqs No findings were identified.

.2.1.1 8 Emersencv

Coolinq Water Pump Discharqe Valve. MO-0-48-0841.

and Emerqencv Coolino Water Pump Discharqe Check Valve. CKV-CC-V506 a. Inspection Scopq The team inspected the emergency cooling water pump discharge MOV, MO-0-48-0841, and its associated pump discharge check valve, CKV-CC-V506, to verify the valves were capable of performing their design basis function.

These normally closed valves were designed to open to provide a flow path for pump discharge flow during emergency cooling water (ECW) pump operation.

The ECW system provides a reliable backup source of cooling water in the event both ESW pumps fail to achieve adequate discharge pressure.The team reviewed the UFSAR, the Technical Specifications, design basis documents, drawings, and procedures to identify the design basis requirements of each valve. The team reviewed the check valve inspection results, and periodic MOV diagnostic test results and stroke-timing test data to verify acceptance criteria were met. The team verified the MOV safety function, performance capability, torque switch configuration, and design margins were adequately monitored and maintained in accordance with Exelon's MOV program. The team reviewed MOV weak link calculations to ensure the ability of the MOV to remain structurally functional while stroking under design basis conditions.

The team verified that the MOV valve analysis used the maximum differential pressure expected across the valve during worst case operating conditions.

Additionally, the motor data, degraded voltage conditions, and voltage drop calculation results were reviewed to confirm that the MOVs would have sufficient voltage and power available to perform their safety function at degraded voltage conditions.

17 The team discussed the design, operation, and maintenance of the valves with engineering staff to evaluate component performance history, maintenance, and overall component health. The team also conducted walkdowns of the valves and associated equipment to assess the material condition and to verify the installed configurations were consistent with the plant drawings, and the design and licensing bases. Finally, the team reviewed corrective action documents to determine if there were any adverse trends associated with the valves and to assess Exelon's capability to evaluate and correct problems.b. Findinqs No findings were identified.

.2.2 Review of Industrv Operatinq

Experience and Generic lssues (4 samples)The team reviewed selected OE issues for applicability at PBAPS Units 2 and 3. The team performed a detailed review of the OE issues listed below to verify that Exelon had appropriately assessed potential applicability to site equipment and initiated corrective actions when necessary.

.2.2.1 10 CFR 21 Report. Linear lndications

on Opposed Piston EDG Bearinqs a. lnspection Scooe The team reviewed Exelon's applicability review and disposition of a Fairbanks Morse 10 CFR 21 Notification (Log No.2011-05-00)related to a bearing defect. The nature of the identified defect was linear indications (hot tears) that were observed by a Fairbanks Morse production inspector on an EDG main bearing. The indications went across the entire edge and extended about one inch deep into the bearing'The team verified that Exelon reviewed the 10 CFR 21 notification, which concluded that none of the suspected bearings were currently installed in the Peach Bottom EDGs, but two cam bearings from the vendor were in the warehouse, and were similarly subject to the notification.

The team reviewed Exelon's actions, which included quarantining the bearings so that they would not be used, to ensure the 10 CFR 21 report was appropriately addressed.

b. Findinos No findings were identified.

.2.2.2 NRC lnformation

Notice 2010-03. Failures of Motor-Operated Valves Due to Deqraded Stem Lubricant a. lnsoection Scope The team evaluated Exelon's applicability review and disposition of NRC Information Notice (lN) 2010-03. The lN was issued to inform licensees of recent failures and Enclosure 18 corrective actions for MOVs due to degraded lubricant on the valve stem and actuator stem nut threaded area. The team assessed the adequacy of Exelon's evaluation of lN 2010-03 by reviewing specific lRs, results of MOV inspections and diagnostic testing results, and by conducting interviews with engineering personnel.

Findinqs No findings were identified.

.2.2.3 NRC Information

Notice 2007-01. Recent Operatinq Experience Concerninq Hydrostatic Barriers

a. Inspection Scope

The team performed a detailed review of Exelon's evaluation of NRC lN 2007-01. This lN discussed events involving water leaking into areas containing safety-related equipment due to deficient hydrostatic (water tight) barriers.

The barriers were either degraded, missing, or composed of non-watertight materials such as fire stops (e.9., silicone foam). The team reviewed the UFSAR, the Technical Specifications, design basis documents, vendor specifications, drawings, and procedures to identify the design basis requirements for external flood seals. The team discussed the design, operation, and maintenance of the external flood seals with engineering staff to evaluate their performance history, maintenance, and overall component health. The team also walked down portions of safety-related buildings such as the EDGs, pump structure, and RHR to assess the material condition of visibly accessible external and internalflood protection seals.The team verified that Exelon had appropriately evaluated the OE and had completed engineering evaluations, modifications, and repairs for identified deficiencies to minimize and limit the impact of potential externalflood events. The team also reviewed Exelon's corrective actions to address previously identified leaking electric conduit seals leading to the bottom of a safety-related pump structure motor control center (MCC-E224-P-A).

b. Findinos No findings were identified.

.2 -2.4 NRC lnformation

Notice 2006-29. Potential Common Cause Failure of Motor-Operated Valves as a Result of Stem Nut Wear a. lnspection Scope The team assessed Exelon's review and follow-up actions to address the issue described in NRC lN 2006-29. This lN detailed ineffective maintenance practices which resulted in undetected excessive stem nut wear that had the potential for common cause failure of multiple MOVs. Specifically, the team reviewed Exelon's maintenance procedures, engineering program documents, and completed MOV diagnostic test results which evaluated stem nut wear, and interviewed engineering personnel that Enclosure b.implemented the MOV diagnostic program at PBAPS to determine whether Exelon was appropriately monitoring MOVs for excessive stem nut wear issues.Findinqs No findings were identified.

OTHER ACTIVITIES

ldentification and Resolution of Problems (lP 71152)lnspection Scope The team reviewed a sample of problems that Exelon had previously identified and entered into the corrective action program. The team reviewed these issues to verify an appropriate threshold for identifying issues and to evaluate the effectiveness of corrective actions. In addition, lRs written on issues identified during the inspection were reviewed to verify adequate problem identification and incorporation of the problem into the corrective action system. The specific corrective action program documents that were sampled and reviewed by the team are listed in the Attachment.

Findinos No findings were identified.

Meetinqs.

Includino Exit The team presented the inspection results to Mr. Thomas Dougherty, Site Vice President, and other members of Exelon staff at an exit meeting on March 11,2Q11.The team reviewed proprietary information, which was returned to Exelon at the end of the inspection.

The team verified that none of the information in this report is proprietary.

4.4c.A2 a.4046 b.Enclosure A-1 ATTACHMENT

=SUPPLEMENTAL

INFORMATION=

KEY POINTS OF CONTACT

Licensee Personnel

W. Bennett, Mechanical

Maintenance

R. Bogar, Senior Engineer

R. Brower, Design Engineering

Manager

J. Chizever, Design Engineering

Manager

H. Coleman, Design Engineer

J. Coyle, Design Engineer

C. Dye, System Engineer

T. Fleischmann, Mechanical

Maintenance

W. Ford, System Engineer

T. Grimme, System Engineer

X. Haro, System Engineer

E. Haupin, Program Engineer

C. Howell, Design Engineering

K. Kaufman, System Engineer

P. Kester, Design Engineer

R. Lack, System Engineer

M. Long, Programs Branch Manager

J. Lyter, Operations

Support Engineer

L. Nace, System Engineer

T. Purcell, Design Engineer

M. Ruff, Program Engineer

R. Smith, Regulatory

Assurance

Engineer

D. Tyson, Design Engineer

T. Veale, Design Engineer

R. Wagner, Design Engineer

D. Wheeler, Maintenance

Rule Coordinator

LIST OF ITEMS

OPENED, CLOSED AND DISCUSSED Opened and Closed NCV

0500027712011007-o1

05000278t2Q11007-01

0500027712011007-02

05000278/2011007-02

Failure to Demonstrate

the Capability

of the EDG Fuel OilTransfer

Pumps to FulfillTheir

Safety Functions

Under all Postulated

Conditions (Section 1R21.2.1.1)

Temporary

Battery Cart Seismic Configuration

Deficiency (Section 1R21 .2.1 .2)Attachment

LIST OF DOCUMENTS

REVIEWED Calculations and Evaluations:

1187-M-003, RHR System - Orifice Design, Rev. 0 1187-M-004, HPSW System - RHR Modification

MO-89, New Internals, Rev. 1 1187-M-008, RHR Mode B and C Nozzle Pressure Drop and Adjustment, Rev. 0 1187-M-010, HPSW - RHR System Modification, Rev. 0 1 187-M-01 1, RHR System Orifice, Rev. 0 18247-EC-104

(102), ECCS Pump Room Cooling Parametric Study, Rev. 1 18247-M-A35, CST Minimum Water Level to Prevent Vortex Formation, Rev. 1 22.33, ESW System Network Analysis, Rev. 0 32-1H, Design of Support 2-32G8-S67

and 3-32GB-S-67

for Stress Calc 32-1, Rev. 0 33-03C, Analysis of ESW Pump Anchor Bolts and Supports, Design of New Supports, Rev. 1 6280-M11-55-3, Seismic Analysis, HPSW Pumps, Rev. 0

40004660, Silt Level Effects on the Circulating and Intake Bay Components,

11112190

41486268, Evaluate for Replacement

200 Parts for 2DB-R-B on the 250VDC Bus,12112/10

A1607566, ESW/HPSW Bay Mud Level Measurements,

2118192 A1695348 Eval-01, Determine Whether Spacers are Needed for 00D452 Batteries,2126110

BLP-12,012, HPSW Technical Specification, 1Ql28l7 4

ECR 10-308, Minor revision to

PE-17, Battery Capacity Analysis, Rev. 0

ECR 96-00990-0, Pressure LockinglThermal Binding Design Analysis for PBAPS, Rev. 2

EWR 40036401, Temporary Battery Cable Torque Requirements, 5/3i91 EWR A0158039, Battery Cell Change-out with One or Two Units at Power,

1017194 EWR P-51694, lntercell Gonnection Resistance, 5/9/90 G-080-VC-146, Safe and Alternate Shutdown Analysis, Rev. 0

LIS-0401A

Manual Calculation, EDG Fuel Oil Storage Tank Level, Rev. 0

MDE-86-0786, Safe and Alternate Shutdown Analysis, Rev. 1

ME-02371-01, Minimum Acceptable Flow Rate for ESW Flow to RHR Room Coolers, Rev. 0

ME-0538, Primary Containment Venting Flow Rates for Various Vent Paths, Rev. 0

ME-171,

MOD 1788, Determine

RHR Pump Required Discharge Pressure,

1018185

ME-3, RHR Heat Exchanger lnlet Pressures for All Modes of RHR/HPSW Operation, Rev. 1

ME-507, Acceptance Criteria for IST of RHR Pumps (LPCI Mode), Rev. 3

OTC-50, Operating Thrust Calculations, Rev. 1

PE-0087, Determine

CST Working Volume for New Settings of CST Level Switches, Rev. 0

PE-0121, PBAPS Voltage Regulation Study, Rev.7

PE-0166, Emergency Diesel Generator Loading for Cases Defined by UFSAR 8.5.2C1L, Rev. 7

PE-017,

1251250 Vdc Battery Capacity Analysis, Rev. 12

PE-0192, AC System Fault Study, Rev. 1J

PE-O194, Coordination for 4kV 1E Switchgear, Rev. 4

PE-088, 4160 Emergency Aux. Switchgear

20A17 Bus 32 Protective Relay Settings, Rev. 8

PE-090, Cable Withstand Current Rating, Rev. 2

PE-140,1251250

Vdc System What lf Cases, Rev. 10

PE-181 ,125Vdc Voltage Analysis, Rev. 3

PE-191 ,1251250 Vdc System Fault Current, Rev. 2

PE-196,

1251250 Vdc System Coordination, Rev. 2

PEAM-0004, HPCI and RCIC Loads During Fire Safe Shutdown Event, Rev. 0

PEAM-0008, Station Blackout Time Line for HPCI and RCIC Loads, Rev. 0 Attachment Pl-00034, Level Uncertainty Calculation for

LT-3-23-074 (CST Level Trip), Rev. 1 Pl-00089, Level Uncertainty Calculation for

LT-3-13-170 (CST Level), Rev. 1

PM-0046, EDG Fuel Oil Storage Tank Volume Determinations, Rev. 1

PM-0047, EDG Fuel Oil Consumption for 7 Days Continuous Operation at Full Load, Rev. 0

PM-0123, Diesel Generator Fuel Oil Consumption for 6 Days andT Days Operation with LOCA Dependent Loads, Rev. 0

PM-034, Required BHP (Mechanical)

RHR Pump(s) for Different Modes of Operation, 10/11/89

PM-0410, ldentify Licensing Requirements for Diesel Generator Air Start System, Rev. 0

PM-0533, EDG Operability Curves with Reduced ESW Flow Rates, Rev. 1

PM-0589, RHR Heat Exchanger Performance Evaluation, Rev. 4

PM-0620, Determine Upstream and Downstream Line Pressures for

GL 89-13 MOVs, Rev. 16

PM-0760, Power Rerate Evaluation - SBO Analysis, Rev. 1

PM-0958, RHR/Core Spray Pump Room Temperatures Post-LOCA

with 95' River Water, Rev.2

PM-1010, RHR Pump NPSH, Rev.6A

PM-104, Emergency Heat Sink TemperatureslRevised Flow Rates and Heat Loads, Rev. 3

PM-1048, Design Basis for Internal Flood Protection, HPSWESW Pump Structure, Rev. 0

PM-391, Determine Minimum Water Level in Emergency Cooling Tower Reservoir, Rev. 13

PM-589, RHR Heat Exchanger Performance Evaluation, Rev. 4

PM-620, Determine Differential Pressures for MOVs, Rev. 16

PM-736, Battery Room Hydrogen Concentration, Rev. 2

PM-824, Maximum Anticipated Bearing Oil Temperature of the HPSW Pumps, Rev. 1

PS-028, Design of Battery Cart to Transport and Support Temporary Batteries, Rev. 1

PS-155, Seismic Evaluation of Battery Racks for Cell Change-out Activity, Rev. 1

SR-124, Seismic Weak Link Report, Rev. 4

VO-00182

OTe-46, Grane-Aloyco Operating Thrust Calculations, Rev. 1 Completed Surveillance.

Maintenance.

and Modification Testinq: Daily Operator Rounds Logs for 38 Battery (2117111)Mf DAS Calculation and Diagnostic Trace Results for MO-2-14-012A(9121106,9128110)

MO-2-23-019

MIDACALC As-left Test Setup Review, Rev. 1

MO-2-23-019

MIDACALC Results, Rev. 1

MO-2-23-020

MIDACALC As-left Test Setup Review, Rev. 1

MO-2-23-020

MIDACALC Results, Rev. 1 MOV Post-Test Data Review Worksheet for MO-2-14-012A(9l21lOO)

MOV Post-Test Data Review Worksheet for

MO-2-23-016

(9128110)RCM 072, Trash Rack Inspection

(6/26109)RT-0-1 00-505-2, Emergency Operating

Procedure

Tool Inventory

g 1812010)RT-f-033-631-3, RHR Room Cooler ESW Heat Transfer Test(1124111)

RT-f-033-632-3, Core Spray Room Cooler ESW Heat Transfer TesI (212109, 212111)RT-M-033-675-2, Unit 2 Pump lntake Structure Inspection and Cleaning (9/25/10)RT-O-032-310-3, HPSW Oil Cooler Heat Transfer Capability Test (8127110)RT-O-033-600-2, Full Flow Test of ESW to ECCS Coolers and EDG Coolers (1102111)RT-O-052-252-2, E2 EDG lnspection Post Maintenance Functional Test (5/8/1 0)Sl2F-23-76-XXCQ, Calibration Check of HPCI Steam Line High Flow DPIS 2-23-76 (12115110)

Sf 2M-54-E22-XXC4, Calibration Check and Functional Test of E22 Bus and E224 Bus Meters and Overcurrent Relays (1/9/08)Attachmenl Sl2T-MlS'8547-C1CQ, Calibration/Functional Check of Channel C Group 1, 4 and 5 of PCIS Logic for

TI5-80547C

(1115111)SP-1472, Diesel Generator Air Start Capacity and Full Load Reject Test (12130192)

ST/LLRT 20.078J0, Torus Purge Exhaust (9121 108, 1015110)ST/LLRT 30.078.10, Torus Purge Exhaust (1019107, l0l2l0g)ST-0-33-310-2, ESW Booster and ECW Pump and Valve Functional

lST (12122108, 3/5/09, 12t22t09, 3t5t10)ST-8.1.9, Diesel Fuel Oil Transfer Pump Functional Test (1/16i91 )ST-C-095-884-2, Sampling Diesel Fuel Prior to Delivery to On-Site Storage Tanks (215111)ST-C-095-885-2, Diesel Generator Main FuelTank Sampling and Analysis (215111)ST-l-014-100-2, Core Spray'A' Logic System FunctionalTest(2121108, 3/10/10)ST-l-023-100-2, HPCI Logic System Functional Test (9/2/10)ST-LLRT-2Ol.06.01, 'A' Feedwater Local Leak Rate Test (9/17l10)ST-M-168-250-2, Safety Grade Instrument Gas System Functional and IST (1013108, 1016110)ST-M-168-250-3, Safety Grade lnstrument Gas System Functional and IST (10111107,10/4/09)

ST-M-57 B-7 32-3, 38 Mod ified Battery Discha rge Performa nce Test (9 I 281 09)ST-M-578-7

2-3, 38 1 25 1 250 Vdc Battery Service Test ( 1 0/05/07)ST-M-578-750-3,

1251250 Vdc Battery Weekly Inspection

(2112111)ST-M-57B-752-3, 38D001 Battery Yearly Inspection

(11 l1 1 110)ST-M-578-7

2-3, 38D003 - I 12 Battery Charger Capability Test ( 1 1 l05l 10)ST-O-007-410-2, PCIS Valves Cold Shutdown IST (10/9/08, 10/6/10)ST-O-007-410-3, PCIS Valves Gold Shutdown IST (10/111A7, U27109, 10/08/09)ST-O-007-510-2, PCIS Valves Remote Position Indication Verification

(1019108, 1016110)ST-O-007-510-3, PCIS Valves Remote Position Indication Verification

(101111Q7, 10/4109)ST-O-01 0-301 -3,'A' RHR Functional and IST (7 l8l 10, 1 1 l 1 l 10, 1 l 1 1 l 1 1)ST-O-010-306-2, 'B' RHR Pump, Valve, Flow, and Cooler Functional and IST (8125110,2127111)

ST-O-023-301-2, HPCI Pump, Valve, Flow and Cooler Functional and IST (1114110,

319110, 61 1 1 l 10, 1 0/8/1 0, 121 121 10)ST-O-023-5Q1-2, HPCIValves Remote Position Indication Verification

(10/15/08, 10/6/10)ST-O-032-301-3, HPSW Functional and IST (12128109,3130110,719110,

1019110, 12131110,)

ST-O-033-300-2, ESW Valve, Cooler, ECT Fans FunctionalTest

(7/31/10, 10123110,1129111)

ST-0-033-635-2, ESW Piping Pressure Test Examination

(7l25lOO)ST-O-052-212-2, E2 EDG Slow Start Full Load and IST Test, Rev. 28 (215111)ST-O-052-7

O2-2, E2

EDG 24 Hour End urance Test, Rev. 17 (1 1 l 1 61 09)ST-O-52D-202-2, EDG Fuel OilTransfer Pump 08P060/Suction Check Valve IST (11127111)

ST-O-578-7

20-3, 38D00 1 /3DD00 1 Battery Quarterly

I nspectio n (21051 1 1 )TC No.00-179,

RT-O-033-600-2, Flow Test of ESW to ECCS/EDG Coolers (4120100)Gorrective Action Documents:

1080382

1484451

1084973 1 1 05880 1

106382

1106815 1

107538 1

108049

1108114 1 1 15030

1119887

1120123 1

120916

1120923

1126992 1

139681 1

161618

1164992

1166272

1173818

1174102

1175594*1 1 76959.1177549 05641 08

0844207

0867814

0879701

1010281

1050043

1071130 1 071 343 1179128.1179679.1180126.1 1 81 305*1 1 82989*1

183169 1 1 83364 .1184319" Attachment

1184761*1184834*1185240" 1185791.1

187639 "

060051

189814

307815

322722

384941

469346

476280

495197

504642

660310

668388

772999

820382

822488 85901 5

879701

883424

914639

940062

941208

965488

974218

987344 A-5 A00452577

400894291 A01023025

401107323 A01 1351 18 A01

135676 A01

141508 A01

150893 A01 1 59574 A01181771.

401184771*

A01186152.

A1113462 p.1127431 A1167100 A1249047 A1355640 A1397382 A1410253 A1412800 A1423232 A1468210 A.1534762

41534763 A1534764

41534786 A1535069 A1646532 A1659013 A1701061 A1716992

41762647

41777591 A1777593

41777856

41777857 A1778747 A1784851* Document written as a result of inspection effort.Drawings: 6280-4-62, CW Pump Structure Plan Elev. Unit 3, Rev. 2 6280-C-24-54-3, Details, Condensate Storage Tank, Rev. 0 6280-E-1004, Raceway & Grounding Layout Pump Structure - Unit 2, Sh. 2, Rev. 32 6280-E-1004, Raceway & Grounding Layout Pump Structure - Unit 2, Sh. 3, Rev. 30 6280-E-1008, Raceway & Grounding Layout Pump Structure - Unit 3, Sh. 1, Rev. 32 6280-E-1079, Lighting, Communications Layout Circ Water Pump Structure, Sh. 1, Rev. 23 6280-E-1400, Conduit and Cable Trays Symbols, Notes and Details, Rev.O 6280-E-1615, Single Line Meter/Relay Diagram E124andE224, Sh.1, Rev. 76 6280-E-1621, Single Line Meter/Relay Diagram Pump Structure, Sh.1, Rev. 65 628A-E-47, Schematic Meter/Relay Diagram 4160 Vac Emer Aux Power Sys Unit 2, Rev. 27 6280-E-5254, Electrical Protective Relay Index, Rev. 44 6280-E-8, Single Line Meter/Relay Diagram EDG/4160 Vac, Sh. 1, Rev. 17 6280-E8-12-4, Motors for HPSW Pumps, Sh. 1, Rev.3 6280-M-11, Layne and Bowler Pump, Sh. 1, Rev. 2 6280-M-1 1-29, 18 FXH Pump Assembly, Sh. 1, Rev. 10 6280-M-1-DD-7-9, Core Spray Process Diagram, Sh. 1, Rev. 9 6280-M-1-DD-9-9, Residual Heat Removal Process Diagram, Sh. 1, Rev.9 6280-M1JJ-49, Core Spray Pump Curves, Sh. 1, Rev.0 6280-M-1-S-54-64, Electrical Schematic Diagram Reactor Protection System, Sh. 15, Rev.64 6280-M-1-S-54-64, Electrical Schematic Diagram Reactor Protection System, Sh. 16, Rev. 64 6280-M-309, Condensate and Refueling Water Storage and Transfer System, Rev. 64 6280-M-315, ESW and High Pressure Service Water Systems, Sh.3, Rev. 53 6280-M-330, Emergency Cooling System, Sh. 1, Rev. 35 6280-M-361, Residual Heat Removal System, Sh.3, Rev.67 6280-M-362, Core Spray Cooling System, Sh. 1, Rev. 35 6280-M-365, High Pressure Coolant Injection System, Sh. 1, Rev. 63 6280-M-366, High Pressure Coolant Injection Pump Turbine Details, Sh. 1, Rev. 57 6280-M-377, Diesel Generator Auxiliary Systems, Sh. 1 through 3, Rev. 44 6280-M-377, Diesel Generator Auxiliary Systems, Sh. 4, Rev. 40 Attachment

6280-M-377, Diesel Generator Auxiliary Systems, Sh. 44, Rev. 1 6280-M-377, Diesel Generator Auxiliary Systems, Sh. 5, Rev. 8 6280-M-46-24, Cardox System Control Logic/Schematic Diagram EDG Building, Sh. 2, Rev.25 682A-C-128, Misc. Details, ESW Pump and HPSW Pump, Rev. 3 6820-C-64, Underground Storage Tanks, Foundation and Manhole Details, Rev. 9 6820-M-77, Cooling Coils, Rev. 1 6820-M81-2-4, Diesel Generator Fuel OilTransfer Pump, Rev. 0 E-1, Single Line Diagram Station, Rev. 47 E-187, Electrical Schematic Diagram, ESW Pumps 4.16 kV Circuit Breaker, Sh. 3, Rev. 28 E-187, Electrical Schematic Diagram, ESW Pumps 4.16 kV Circuit Breaker, Sh. 4, Rev. 28 E-2365, Electrical Schematic Diagram RPS Power Distribution Protective Devices, Sh. 1, Rev. 7 E-26, Unit 2 125125A Vdc Single Line Diagram, Sh. 1, Rev. 79 E-27 , Unit 3

1251250 Vdc Single Line Diagram, Sh. 1 , Rev. 74 E-27,Unit31251250

Vdc Single Line Diagram, Sh. 2,Rev.41 E-27,Unit31251250

Vdc Single Line Diagram, Sh.3, Rev.5 E-5-7, Electrical Schematic Diagram, Standby Diesel Generator, Sh. 6, Rev. 50 E-8, Single Line Meter/Relay Diagram EDG & 4160 Vac Emer Power System - Unit 2, Rev. 17 GE Drawing 992C558AD, Outline ESW Pump Motor PBAPS Units 2 & 3, Rev. 3 2301, HPCI Steam Supply, Sh. 1, Rev.6 ISO 2-14, Core Spray, Sh. 12, Rev. 3 Johnston Pump Curve, J.O. 00JC1 4045, Rev. 0 M-102-B-235, Gate Valve Assembly with

SMB-2-80 Motor Operator, Sh.1, Rev. 3 M-11-28, SK Assembly Drawing for ESW Pumps OAP57 and OBP57, Rev. 4 M-11-61, HPSW Pump Curve, Sh. 1, Rev.0 M-1-K-11, Walworth Cast Steel 12-in Valve, Limitorque

SMB-2 Operator, Sh. 1, Rev. F M-1-5-36, HPCI Elementary Diagram, Sh. 2 Rev. 73 M-1-5-36, HPCI Elementary Diagram, Sh. 24 Rev. 73 M-1-5-36, HPCI Elementary Diagram, Sh. 3 Rev. 75 M-1-5-36, HPCI Elementary Diagram, Sh. 5 Rev. 74 M-1-S-36, HPCI Elementary Diagram, Sh. 6 Rev. 74 M-1-3-36, HPCI Elementary Diagram, Sh. 7, Rev. 75 M-1-S-36, HPCI Elementary Diagram, Sh. 8, Rev. 73 M-1-S-36, HPCI Elementary Diagram, Sh. 9, Rev. 74 M-1-5-36, HPCI Elementary Diagram, Sh. 10, Rev. 74 M-1-5-36, HPCI Elementary Diagram, Sh. 11 Rev. 76 M-1-5-36, HPCI Elementary Diagram, Sh. 12 Rev. 81 M-1-5-36, HPCI Elementary Diagram, Sh. 13 Rev. 83 M-1-5-36, HPCI Elementary Diagram, Sh. 14 Rev. 75 M-1-5-36, HPCI Elementary Diagram, Sh. 15, Rev. 79 M-1-S-40, Electrical Schematic Diagram Core Spray, Sh. 8, Rev. 57 M-1-S-70, Electrical Schematic Diagram RPS MG Set Control, Sh. 2, Rev. 14 Desiqn Basis Documents:

P-S-01A,

1251125 Vdc and 24148 Vdc System, Rev.14 P-S-02, Emergency Service Water System, Rev. 12 P-S-03, High Pressure Coolant Injection, Rev.21 P-S-04, High Pressure Service Water System, Rev. 10 Attachment

P-S-07, Diesel Generator and Auxiliaries, Rev. 7 P-S-08C, Reactor Building HVAC System, Rev. 11 P-S-08D, Miscellaneous

HVAC Systems, Rev. 9 P-S-09, Residual Heat Removal System, Rev. 17 P-S-27, Emergency Cooling Water System, Rev. 10 P-S-35, Intake Water System, Rev. 7 P-S-44, Core Spray System, Rev. 11 P-T-01, Structural, Rev. 8 P-T-13, Station Blackout Event, Rev.7 P-T-15, Motor-Operated Valves, Rev. 8 Miscellaneous:

0103111-08, Evaluation for NRC lN 2010-03, Failures of MOVs due to Degraded Stem Lubricant,

411110 6280-E-7, Specification for Medium Voltage Metal-Clad Switchgear/Bus Duct, Rev. 4 6280-M561-20-1, AGASTAT Control Relays, Rev. 0 AITL A1208913, Document and Control GL95-07 PLTB Design Changes,

3125104

ER-AA-2030, Attachment

4, System Walkdown Standards, RHR, 9/30/10 ISBN 0-444-87445-3, Tribology of Plastic Materials Table 1.10, 1990 Letter, EnerSys to PBAPS, Re:White Material in DX Batteries,

5107104 Letter, PBAPS to NRC, Response to NRC

GL 89-13, SW System Problems,

1129190 Letter, Response to

GL 96-05, Performance Verification of Design Bases Capability of Safety-Related Valves, 311 4197

LS-AA-126-1001, FASA, Preparation for the 201 1 NRC CDBI, Rev. 5 M-1-JJ-53-1, Residual Heat Removal Exchangers, Rev. 3,

3112108 M-f-U-435-1, RHR Pump Curve,

2118178

MO-0-48-841, AC Motor Operated Gate Valve Control Parameters, Rev. 2

MO-2-23-019

Data Sheet, Rev. 1

MO-2-23-020

Data Sheet, Rev. 1

NCR-PB-92-389-001, External Flood Barrier Penetration Seal Evaluations,

216195

NCR-PB-g2-39A-002, External Flood Barrier Penetration Seal Evaluations-Non Rx Bldg, 5i5l95

NE-075, Specification for Penetration Seals in Hazard Barriers at PBAPS and Limerick, Rev. 4 NEDC 31322, BWROG Design Basis of Selected Safety Related MOVs, 9186 NEDC 31871, BWROG Phase-ll Operational Basis of Selected Safety-Related

MOVs, 3/91 NEDC 31890, BWROG Phase-l Operational Basis of Selected Safety-Related

MOVs, 3/91

OP-AA-1 02-1 03, Operator Work-Arounds and Challenges, 212/1 1 Passport AR#

322722 Assignment

1. 3: Diesel Vulnerability to Tornado Missiles,

4121105 PBAPS Performance Monitoring Summary 10-1 RHR -LPCI Mode, 3/11 PBAPS Performance Monitoring Summary 10-2 RHR SDC/Torus Cooling, 3i11

PEA-91 134, Testing of ASCO and AVCO SV Assemblies, 4l9l1O Peach Bottom Operational and Technical Decision Making Review Matrix, Q2lQ3lQ4-2010

Periodic Assessment of Maintenance Rule Program, April 2007 - March 2009 R105-94-08.01, PBAPS

GL 89-10 Test Program Completion Report, Rev. 1

ST-O-33-310-2, Yearly ECW Pump (P186) Vibration Data, 2001'2011 Stock Code 116-85068

Procurement Clause M-121375, Battery Design Requirements, 5113/03 System Health Report, Emergency Cooling Water and Tower, Q3-2010 System Health Report, DC Systems, Q3-2010 Attachment System Health Report, HPCI Systems, Q3-2010 System Health Report, RHR and RHR Sample, Q3-2010 System Health Report, Unit 2 Core Spray, Q2-2010 System Health Report, Primary Containment, Q2-2010 System Health Report, Service Water and Service Bay, Q3-2010 System Health Report, Unit 3 High Pressure Service Water, Q3-2010 TRT No. 11-2,Voltages Obtained in Support of

ECR 09-00158,

1112111 Modifications

& 10

GFR 50.59 Reviews:

ECR 06-00428, HPSW Pumps Obsolete and Require Replacement Evaluation,

1017106

ECR 95-01703, Replacement

HPSW Motor Evaluation

2(3) A-DP042,413195

PB 05-00385 002, ConverUUpgrade

EDG Cardox System to Manual System, Rev. 2

PB 09-00157 000, U2 SSPVs: Design Change from ASCO to AVCO, Rev. 0

PB 99-02596 004, Procure Replacement Discharge Head for ESW Pumps, Rev. 4 Procedures:

Alarm Response Card Window F5, 'B' Diesel Fuel Storage Tank Level Hi-Lo, Rev. 12

AO 29.3, Discharge Canal - lntake Pond Crosstie Gate Operation/Frazil lce Mitigation, Rev. 16

AO 52D.1, Transferring Diesel Fuel Oil Between Storage Tanks, Rev. 7

ARC 204 20C207R D-4, Outer Screen Structure Screen Stopped, Rev. 2

ARC 212 20C205RR C-5, Unit 3 High Pressure Service Water Bay Level High-Low, Rev. 5

ARC 317 3OC212R K-4, HPSW Pump Room High-Lo Temp, Rev. 3

ARC 326 30C03D E-3, D High Press Service Water Pump Overcurrent, Rev. 3

CC-AA-309, Controlof Design Analysis, Rev. 10

CC-AA-309-1001, Guidelines for Preparation and Processing of Design Analysis, Rev. 6

CC-PB-201 , Hazard Barrier Control Program, Rev. 0

COL 30.1 .A-2, Emergency Service Water System (Unit 2 and Common), Rev. 31

COL 33.1.A-2, Emergency Service Water System (Unit 2 and Common), Rev. 23

COL 33.1.A-3, Emergency Service Water System (Unit 3 and Common), Rev. 21

ER-M-2030, Conduct of Plant Engineering Manual, Rev. 9

ER-AA-300, MOV Program Administrative Procedure, Rev. 6

ER-AA-300-1001, MOV Program Performance lndicators, Rev. 5

ER-M-302, MOV Program Engineering Procedure, Rev. 5

ER-AA-302-1001, MOV Thrust/Torque Sizing and Setup Determination Methodology, Rev. 6

ER-AA-302-1003, MOV Margin Analysis and Periodic Verification Test lntervals, Rev. 7

ER-AA-302-1004, MOV Performance Trending, Rev. 5

ER-AA-302-1005, MOV Design Database Control, Rev. 6

ER-AA-302-1006,

GL 96-05 Program MOV Maintenance and Testing Guidelines, Rev. 10

ER-AA-302

-1007 , MOV Limitorque Actuator Capability Determination Methodology, Rev. 6

ER-AA-302-1008, MOV Diagnostic Test Preparation lnstructions, Rev. 8

ER-AA-302-1009, Final JOG MOV Periodic Verification Program lmplementation, Rev. 1

ER-AA-520, Instrument Performance Trending, Rev. 3

ER-PB-310-1010, Peach Bottom Maintenance Rule Structural Monitoring Program, Rev. 4 M-057-013, 125 Volt Battery Replacement and Cell Post Cleaning, Rev. 12 M-057-014, Cyberex 125 Volt Battery Charger Maintenance, Rev. 13 M-057-017, Installation of Maintenance Battery 00D452, Rev. 1 Attachment

M-511-120, Motor Inspection/Replacement for Motor Operators

SMB-000 to

SMB-S, Rev. 12

MA-AA-723-300, Diagnostic Testing of Motor-Operated Valves, Rev. 4

MA-AA-723-301, Periodic Inspection of Limitorque Model SMB/SB/SBD-000

to 5 MOVs, Rev. 6

NE-119, MOV Thrust & Torque Determination Methodology, Rev. 12

OP-PB-108-103-2, Locked Valve List - PBAPS Unit 2, Rev. 3

RT-M-033-675-2, Unit 2 Pump Intake Structure lnspection and Cleaning, Rev. 4

SE-1 1, Loss-of-Offsite Power, Rev. 13

SE-11.1, Operating

SBO Line during a Loss-of-Offsite Power Event, Rev.7

SE-3, Loss of Conowingo Pond-Procedure, Rev. 19

SE-4, Flood Procedure, Rev. 24

SO 28A.7.A-3, Removalof One Circulating Water Pump from Service, Rev. 13

SO 32.1.A-3, High Pressure Service Water System Startup and Normal Operations, Rev. 15

SO 32.8.A-3, High Pressure Water System Routine Inspection, Rev. 6

SO 48.1.B, Emergency Cooling Water System Startup, Rev. 13

SO 52A.1.B, Diesel Generator Operations, Rev. 45

SO-578.1-3,125125Q

Volt Battery Charger Operations, Rev. 5 ST-l-023-100-2, HPCI Logic System FunctionalTest, Rev. 17 ST-l-052-252-2, E2 EDG lnspection Post Maintenance lnstrumentation and Logic Test, Rev. 9 ST-l-37G-392-2, E-2 EDG Cardox System Simulated Actuation and Air Flow Test, Rev. 7

ST-M-578-732-3,38

Modified Battery Discharge Performance Test, Rev. 13

ST-M-578-742-3,38

251250 Vdc Battery Service Test, Rev. 13

ST-M-578-750-3,

1251250 Vdc Battery Weekly Inspection, Rev. 30

ST-M-578-752-3,38D001

Battery Yearly Inspection, Rev. 5

ST-M-57B-762-3, 3BD003 - 112 Bathery Charger Capability Test, Rev. 4

ST-O-010-501-3, RHR Loop'A'Valves Remote Position lndication Verification, Rev. 4

ST-O-578-7

20-3, 38D001 /3DD001 Battery Quarterly Inspection, Rev. 1 6 T-200-2, Primary Containment Venting, Rev. 10 T-2OOJ-2, Containment Venting via the Torus Hardened Vent, Rev.'1

WC-PB-430-1001, Operation and Maintenance of Surveillance Testing Program, Rev. 2 Vendor Manuals & Specifications:

Crane-Aloyco Report No.

OTC-156, Rev. 0

MO-0-48-841, Diagnostic Test,

1125105 6280-M1

1-4902, Lanye and Bowler Vertical Turbine Pump, Rev. 5 6280-M1308-4, Type SMB Instruction and Maintenance Manual, 9i90 Coltec lndustries Letter to PECO, Contract

205700 Reference

85782 EDG Load Rating,

7111191

GEI-88761J, GE lnstructions/Parts for Maintenance Magne-Blast Circuit Breaker, Rev. J E-5-51-2, Emergency DieselGenerator, Rev. 0 E-5-166, Emergency Diesel Generator, Rev. 10 E-5-167, Emergency Diesel Generator, Rev. 3 E-5-168, Emergency Diesel Generator, Rev. 10 11 905 551(Colt lndustries) - Emergency Diesel Generator Flow, Rev. 3 E-13-55-2, Assembling

& Maintaining Standard Racks for Exide Batteries, Rev. 2 E-13-123, EnerSys 2GN-23 Battery, Rev. 6

NE-102-3, Cyberex 130/200R3-S

Battery Charger, Rev. 2 Proposed IEEE Criteria for Class 1E Electrical Systems for Nuclear Power, IEEE Transactions on Nuclear Science, Volume

NS-16, No. 4, 8/69 Attachment

IEEE 450, Maintenance, Testing, and Replacement of Lead-Acid Batteries, 1995 Edition IEEE 485, Sizing Lead Storage Batteries, 1983 Edition

C-00028, Specification for Underground Tanks for PBAPS, Units 2 and 3, Rev. 0 Work Orders: c0191657 c0191657 c0210254 c0213000 c0215360 R091 1947 R0912314 R0920651 R0956479 R0956510 R0968698 R0969299 R0980854 R0987536 R0990551 R1014319 R1031820 R1031825 R1032672 R1034765 R1056501 R1087604 R1092779 R1

103855 R1107243 R1107824 R1

108074 R1

108326 R1

108326 R1114222 R1114653 R1 1 17400 R1

138376 R1140365 R1

153965 R1174864 R1

179055 R1

179056 R1

179058 R1

180981 R1

182719 R1 1 861 31 R849482 R889540 R922217 Attachment

AC CFR CS CST DC ECW EDG ESW HCU HPCI HPSW rMc IN IP IR IST KV MOV NCV NPSH NPSHA NRC OE PBAPS PRA RAW RCIC RHR RRW SDP SPAR SSPV UFSAR Vac Vdc A-11

LIST OF ACRONYMS

Alternating

Current Code of Federal Regulations

Core Spray Condensate

Storage Tank Direct Current Emergency

Cooling Water Emergency

Diesel Generator Emergency

Service Water Hydraulic

Control Unit High Pressure Coolant lnjection High Pressure Service Water Inspection

Manual Chapter lnformation

Notice Inspection

Procedure lssue Report In-service

Testing kilo-Volts

Motor-Operated

Valve Non-cited

Violation Net Positive Suction Head Net Positive Suction Head Available Nuclear Regulatory

Commission

Operating

Experience

Peach Bottom Atomic Power Station Probabilistic

Risk Assessment

Risk Achievement

Worth Reactor Core lsolation

Cooling Residual Heat Removal Risk Reduction

Worth Significance

Determination

Process Standardized

Plant Analysis Risk Scram Solenoid Pilot Valve Updated Final Safety Analysis Report Volts, Alternating

Current Volts, Direct Current Attachment