{{#Wiki_filter:Perry Nuclear Power Plant 70 Center Road FirstEnergy Nuclear Operating Company Pe^ Ohio 44081 Ernest J. Harkness 440-280-5382 Vice President Fax: 440-280-8029 September 25, 2014 L-14-285 10 CFR 2.202 ATTN:

Document Control Desk U.S. Nuclear Regulatory Commission Washington, DC 20555-001

On March 12, 2012, the Nuclear Regulatory Commission (NRC or Commission) issued an order (Reference 1) to FENOC.

Reference 1 was immediately effective and directs FENOC to develop, implement, and maintain guidance and strategies to maintain or restore core cooling, containment, and spent fuel pool cooling capabilities in the event of a beyond-design-basis external event.

Specific requirements are outlined in of Reference 1.

Reference 1 required submission of an overall integrated plan pursuant to Section IV, Condition C.

The final interim staff guidance (Reference 2) endorses industry guidance document Nuclear Energy Institute (NEI) 12-06, Revision 0 (Reference 3) with clarifications and exceptions identified in Reference 2.

Reference 4 provided the FENOC overall integrated plan for Beaver Valley Power Station (BVPS), Unit Nos.

1 and 2, Davis-Besse Nuclear Power Station (DBNPS), and Perry Nuclear Power Plant (PNPP).

As indicated in the FENOC status report provided by {{letter dated|date=August 28, 2014|text=letter dated August 28, 2014}} (Reference 5), planned strategy changes for PNPP were being incorporated into a revision of the PNPP Overall Integrated Plan (OIP).

The purpose of this letter is to provide Revision 1 of the PNPP OIP (Enclosure).

The extent of changes made to the OIP as a result of the revised strategies preclude the use of revision bars; therefore, the document has been revised in its entirety.

Change from 480 volts alternating current (Vac) to 4160 Vac alternate power source Change from Suppression Pool "Feed and Bleed" to Suppression Pool Closed Loop Cooling Change from portable pumps at the barge slip to portable pumps in the Emergency Service Water Pumphouse (ESWPH)

This letter contains no new regulatory commitments.

If you have any questions regarding this report, please contact Mr. Thomas A. Lentz, Manager - Fleet Licensing, at 330-315-6810.

I declare under penalty of perjury that the foregoing is true and correct.

Executed on September J T

. 2014.

1.

NRC Order Number EA-12-049, Order Modifying Licenses with Regard to Requirements for Mitigation Strategies for Beyond-Design-Basis External Events, dated March 12, 2012 2.

NRC Interim Staff Guidance JLD-ISG-2012-01, Compliance with Order EA-12-049, Order Modifying Licenses with Regard to Requirements for Mitigation Strategies for Beyond-Design-Basis External Events, Revision 0, dated August 29, 2012 3.

NE112-06, Diverse and Flexible Coping Strategies (FLEX) Implementation Guide, Revision 0, dated August 2012 4.

FirstEnergy Nuclear Operating Company's (FENOC's) Overall Integrated Plan in Response to March 12, 2012 Commission Order Modifying Licenses with Regard to Requirements for Mitigation Strategies for Beyond-Design-Basis External Events (Order Number EA-12-049), dated February 27, 2013 5.

FirstEnergy Nuclear Operating Company's (FENOC's) Third Status Report in Response to March 12, 2012 Commission Order Modifying Licenses with Regard to Requirements for Mitigation Strategies for Beyond-Design-Basis External Events (Order Number EA-12-049), dated August 28, 2014

Perry Nuclear Power Plant L-14-285 Page 3 cc:

Director, Office of Nuclear Reactor Regulation (NRR)

ENCLOSURE L-14-285 Overall Integrated Plan for Perry Nuclear Power Plant, Revision 1 (82 pages follow)  

Overall Integrated Plan for Perry Nuclear Power Plant, Revision 1 General Integrated Plan Elements Determine Applicable Extreme External Hazard Ref: NEI 12-06 Sections 4.0 - 9.0 JLD-ISG -2012-01 Section 1.0 Input the hozards applicable to the site; seismic, externalflood, high winds, snow, ice, cold, high temps. Describe how NEI 12-06 Sections 5 - 9 were applied and the basis for why the plant screened out for certain hazards.

The Perry Nuclear Power Plant (PNPP) site has been evaluated and the following external hazards have been identified:

Seismic External Flooding Severe Storms With High Winds Snow, lce And Extreme Cold Extreme Heat The PNPP site has been reviewed against the Nuclear Energy Institute (NEI) Flexible and Diverse Coping Mitigation Strategies (FLEX) guidance (Reference 2) and it has been determined that the FLEX equipment should be protected from seismic, external flooding, severe storms with high winds, snow ice and extreme cold, and extreme high temperatures (Reference 9). PNPP has determined the functional threats from each of these hazards and identified FLEX equipment that may be affected.

The FLEX equipment is being purchased commercial grade and the storage locations will provide the protection required from these hazards. PNPP is also developing procedures and processes to further address plant strategies for responding to these various hazards.

Per the Updated Safety Analysis Report (USAR) (Reference 4, Secti on 2.5), Seismic Input, the seismic criteria for PNPP includes two design basis earthquake spectra: Operating Basis Earthquake (OBE) and the Safe Shutdown Earthquake (SSE). The site seismic design response spectra define the vibratory ground motion of the OBE and the SSE. The maximum horizontal acceleration for the SSE, is 0.159. The OBE has a maximum horizontal acceleration of 0.075g. The maximum vertical response spectra for SSE are 0.l59 and for OBE, is 0.0759. Design response spectra for the SSE and OBE comply with Regulatory Guide 1.60.

Based on the FLEX guidance in Reference 2, seismic impact must be considered for all nuclear plant sites. As a result, the credited FLEX equipment needs to be assessed based on the current PNPP seismic licensing basis to ensure that the equipment remains accessible and available after a Beyond Design Basis External Event (BDBEE), and that the FLEX equipment does not become a target or source of a seismic interaction from other systems, structures or components. This assessment needs to include documentation ensuring that any storage location and deployment routes meet the FLEX criteria.

The flood assessment for the PNPP site provided in Reference 4 considered four prospective sources of flooding: Lake Erie, intense local precipitation, and flooding by two small, nameless streams that border the site to the east and south. Flooding from Lake Erie is extremely improbable because the maximum monthly mean lake elevation is approxirnately 45 feet below plant final grade elevations (611 to 620 feet per United States Geological Survey). Localized flooding from the streams during a Probable Maximum Flood (PMF) will not affect plant buildings or equipment. The PMF reaches an elevation of 620'5"; however, the site buildirrg floor elevations are at an elevation of 620'6". Localized I of82

Overall Integrated Plan for Perry Nuclear Power Plant, Revision 1 ponding may occur but the resulting increase in surface elevation of water flowing over the surrounding roads and railroads (acting as weirs) would not exceed one inch.

In summary, safety-related equipment is protected from the PMF. Floor elevations of safety-related structures are above the PMF. Therefore, PNPP is considered a "dry" site and external flooding is NOT applicable to the PNPP site.

PNPP is developing procedures and strategies for delivery of offsite FLEX equipment during Phase 3 that considers regional impacts from flooding.

NEI l2-06 (Reference 2), Figures 7-l and 7-2 were used for this assessment. Figure 7-1 indicates that the high wind speed from a hurricane does not exceed 130 mph. Figure 7-2 indicates a maximum wind speed of 188 mph for PNPP. Therefore, high wind hazards are applicable to the PNPP site.

Per the FLEX guidelines (Reference 2) all sites should consider the temperature ranges and weather conditions for their site for storing and deploying their FLEX equipment. That is, FLEX equipment should be suitable for use in the anticipated range of conditions for the site, consistent with normal design practices.

NEI 12-06 (Reference 2) discusses the potential for blockage of the intake structure. In extreme low temperatures it is possible that the cooling lake will develop frazil ice on its surface; however, the intake structures to the Ultirnate Heat Sink (UHS) are approximately 2,600 feet offshore and well below the surface of the water. The possibility of floating ice sheets or frazil ice blocking the ports is very remote. For the very unlikely case where complete blockage of the intake structures would occur, water can be drawn from the discharge tunnel. Therefore, flow blockage from ice is NOT applicable to the PNPP site.

Applicability of snow and extreme cold:

The PNPP site is above the 35th parallel; therefore, the FLEX strategies must provide the capability to address the impedances caused by extreme snowfall with snow removal equipment, as well as the challenges that extreme cold temperatures may present. On Figure 8-l of Reference2, PNPP is located in the area identified as purple and pink, which indicates that 3-day snowfalls up to 36 inches should be anticipated. The maximum Z4-hour snowfall observed was 26.5 inches, which occurred at Erie, Pennsylvania in December 1944. The minimum-recorded temperature in the area around the PNPP site is -20oF and occurred in Geneva per Reference 4,Table2.3-4. Therefore, snow and extreme cold hazards are applicable to the PNPP site.

The PNPP site is a Level 3 region as defined by Figure 8-2 of the NEI FLEX Implementation Guide (Reference 2). Therefore, ice storms are applicable to the PNPP site.

In summary, based on the available local data and Figures 8-l and 8-2 of NE,l 12-06, the PNPP site experiences significant amounts of sno% ice,, and extreme cold temperatures.

Therefore, snow, ice, and extreme cold temperature hazards are applicable to the PNPP site.

Per NEI 12-06, all sites must address high ternperatures. Virtually every state in the lower 48 contiguous United States has experienced temperatures in excess of I10"F. Many states have experienced temperatures in excess of 120'F. Sites should consider the impacts of these conditions on the FLEX equipment and its deployment.

Overall Integrated Plan for Perry Nuclear Power Plant, Revision 1 The maximum-recorded temperature in the area around the PNPP site was 103"F and occurred in Cleveland per Reference 4, Table 2.3-4.

In summary, based on the available local data and industry estimates, the PNPP site does not experience extreme high temperatures. However, per NEI I 2-06, all sites will address high temperatures.

Therefore, high temperatures are applicable to the PNPP site. Selection of FLEX equipment the PNPP site will consider the site maximum expected temperatures in their specification, storage, and deployment requirernents, including ensuring adequate ventilation or supplementary cooling, if required.

Key Site assumptions to implement NEI 12-06 strategies.

Ref: NEI 12-06 Section 3.2.1 Provide key assumptions associated with implementation of FLEX strategies:

NEI 12-06 Assumptions Section 3.2.1 of NEI 12-06 provides the following assumptions.

Initial Plant Conditions The initial plant conditions are assumed to be the following:

Al.

Prior to the event the reactor has been operating at 100 percent rated thermal power for at least 100 days or has just been shut down from such a power history as required by plant procedures in advance of the impending event.

At the time of the postulated event, the reactor and supporting systems are within normal operating ranges for pressure, temperature, and water level for the appropriate plant condition. All plant equipment is either normally operating or available from the standby state as described in the plant design and licensing basis.

No specific initiating event is used. The initial condition is assumed to be a loss of offsite power (LOOP) at a plant site resulting from an external event that affects the off-site power system either throughout the grid or at the plant with no prospect for recovery of off-site power for an extended period. The LOOP is assumed to affect all units at a plant site.

All installed sources of emergency on-site alternating current (AC) power and Station Blackout (SBO) Alternate AC power sources are assumed to be not available and not imminently recoverable.

Cooling and makeup water inventories contained in systems or structures with designs that are robust with respect to seismic events, floods, and high winds, and associated missiles are available.

Normal access to the UHS is lost, but the water inventory in the UHS remains available and robust piping connecting the UHS to plant systems remains intact. The motive force for UHS flow, i.e., pumps, is assurned lost with no prospect for recovery.

Fuel for FLEX equiprnent stored in structures with designs that are robust with respect to seismic events, floods and high winds and associated missiles, remains available.

Permanent plant equiprnent that is contained in structures with designs that are robust with respect to seismic events, floods, and high winds, and associated missiles, are available.

Overall Integrated Plan for Perry Nuclear Power Plant, Revision 1 A9. Other equipment, such as portable AC power sources, portable back up direct current (DC) power supplies, spare batteries, and equipment for 10 Code of Federal Regulations (CFR) 50.54(hh) (2), may be used provided it is reasonably protected from the applicable external hazards per Sections 5 through 9 and Section 11.3 of NEI 12-06 and has predetermined hookup strategies with appropriate procedures/guidance and the equipment is stored in a relative close vicinity of the site.

Al0. Installed electrical distribution system, including inverters and battery chargers, remain available provided they are protected consistent with current station design.

Al l. No additional events or failures are assumed to occur immediately prior to or during the event, including security events.

Al2. Reliance on the fire protection system ring header as a water source is acceptable only if the header meets the criteria to be considered robust with respect to seismic events, floods, and high winds, and associated missiles.

Reactor Transient The following additional boundary conditions are applied for the reactor transient:

Al3. Following the loss of all AC power, the reactor automatically trips, and all rods are inserted.

Al4. The main steam system valves (such as main steam isolation valves, turbine stops, atmospheric dumps, etc.), necessary to maintain decay heat removal functions operate as designed.

Al5. Safety/Relief Valves (SRVs) initially operate in a normal manner if conditions in the reactor pressure vessel (RPV) so require. Normal valve reseating is also assumed.

A16. No independent failures,, other than those causing the extended loss of all AC power/loss of normal access to the ultimate heat sink (ELAP/LUHS) event, are assumed to occur in the course of the transient.

Reactor Coolant Inventory Loss Sources of expected boiling water reactor (BWR) reactor coolant inventory loss include:

Al7. Normal system leakage.

A18. Losses from letdown unless automatically isolated or until isolation is procedurally directed.

A19. Losses due to BWR recirculation pump seal leakage.

A20. BWR inventory loss due to operation of steam-driven systems, Safety Relief Valve (SRV) cycling, and RPV depressurization.

Spent Fuel Pool (SFP) Conditions The initial SFP conditions are:

A21. All boundaries of the SFP are intact, including the liner, gates, transfer canals, etc.

A22. Although sloshing may occur during a seismic event, the initial loss of SFP inventory does not preclude access to the refueling deck around the pool.

1^23. SFP cooling system is intact, including affached piping.

A24. SFP heat load assumes the maximum design basis heat load for the site.

Containment Isolation Valves A25. It is assumed that the containment isolation actions delineated in current station blackout 4 o f 8 2

Overall Integrated Plan for Perry Nuclear Power Plant, Revision 1 coping capabilities is sufficient.

Site Snecific Assumptions:

The followins assumptions are specific to the PNPP site:

A26. PNPP will be able to identifo an ELAP condition within I hour in order to enable actions which place the plant outside of the current design and licensing basis.

A27. Considerations for exceptions to the site security plan or other license/site specific requirements will be included in the FLEX Support Guidelines (FSGs).

A28. Flood and seismic re-evaluations pursuant to the 10 CFR 50.54(f) letter of March 12,2Al2 are not completed and therefore not assumed in this submittal. As the re-evaluations are completed, appropriate issues will be entered into the corrective action system and addressed on a schedule commensurate with other licensing bases changes.

A29. To support time sensitive FLEX actions, it is assumed adequate staffing levels will be available. Required staffing levels will be determined consistent with guidance contained in NEI l2-06 for each of the site specific FLEX strategies. Assumed available staffing levels will be determined consistent with Guideline For Assessing Beyond Design Basis Accident Response Staffing And Communications Capabilities, NEI 12-01, as described below.

The event impedes site access as follows:

A.

Post event time: 6 hours - No site access. This duration reflects the time necessary to clear roadway obstructions, use different travel routes, mobilize alternate transportation capabilities (e.g., private resource providers or public sector support), etc.

B.

Post event time: 6 to 24 hours - Limited site access. Individuals may access the site by walking, personal vehicle or via alternate transportation capabilities (e.g., private resource providers or public sector support).

C.

Post event time: 24+ hours - Improved site access. Site access is restored to a near-normal status and/or augmented transportation resources are available to deliver equipment, supplies and large numbers of personnel.

These results will be compared to confirm this assumption, or adjustments will be made to plant staffing or FLEX design to meet this requirement.

A30. This plan defines strategies capable of mitigating a simultaneous loss of all AC power and loss of normal access to the ultimate heat sink resulting from a beyond-design-basis event by providing adequate capability to maintain or restore core cooling, containment, and SFP cooling capabilities at all units on a site. Though specific strategies are being developed, due to the inability to anticipate all possible scenarios, the strategies are also diverse and flexible to encompass a wide range of possible conditions. These pre-planned strategies developed to protect the public health and safety will be incorporated into the unit emergency operating procedures in accordance with established Emergency Operating Procedure (EOP) change processes, and their impact to the design basis capabilities of the unit evaluated under 10 CFR 50.59. The plant Technical Specifications contain the limiting conditions for normal unit operations to ensure that design safety features are available to respond to a design basis accident and direct the required actions to be taken when the limiting conditions are not met.

The result of the beyond-design-basis event may place the plant in a condition where it cannot comply with certain Technical Specifications, andlor its Security Plan, as such, may warrant invocation of 10 CFR 50.54(x) and/or 10 CFR 73.55(p).

A31. lnstrumentation of FLEX equipment will be used to confirm continual performance.

Overall Integrated Plan for Perry Nuclear Power Plant, Revision 1 Include a description of any alternatives to the guidance, and provide a milestone schedule of planned action Extent to which the guidance, JLD-ISG -2012-01 and NEI 12-06, are being followed. IdentiS any deviations to JLD-ISG-2012-01and NEI 12-06.

Ref: JLD-ISG-2O12-0t NEI 12-06 Section 13.l PNPP plans to fully comply with the guidance in JLD-ISG-2012-01, Reference 3, and NEI 12-06 Reference 2, in implementing FLEX strategies for the PNPP site. Milestone schedule updates are now reflected in the six-month status reports.

Strategies thot have a time constraint to be successful should be identified with o technical basis and a justification provided that the time can reosonably be met (for example, a walkthrough of deployment).

Describe in detail in this section the technical basis for the time constraint identified on the sequence of events timeline Attachment

]A See attached sequence of events timeline (Attachment IA).

Provide a sequence of events and identi$ any time constraint required for success including the technical basis for the time constraint.

Reft NEI 12-06 Section 3.2.1.7 JLD-ISG -2012-01 Section 2. I The sequence of events and any associated time constraints are identified for PNPP Modes I through 4 strategies for FLEX Phase I through Phase 3. These actions are bounding when compared to Mode 5, as they require the most personnel, actions, and time constraints. See attached sequence of events timeline (Attachrnent 1A) for a summary of this information. The times identified to initiate each action in this section and in Attachment lA are based on resource loading to allow completion of all actions prior to their individual time constraints. The time and resources required to complete these tasks have been developed using plant staff walkthroughs and tabletop evaluations. The times stated are taken to be the elapsed time after the loss of power due to the external event. Time sensitive completion times are included.

Discussion of tirne constraints identified in Attachment 1A table.

: l.

Within 30 minutes perform cross tie of Unit I to Unit 2 Batteries

: 2. Prior to t hour, declare ELAP (Table item 3). This declaration allows actions to be taken which place plant components outside of the current licensing basis. This action is required at this time so that the FLEX load shed actions can be initiated at one hour after the event. As soon as the ELAP is declared, operators will contact the National Safer Response Center (NSRC)

(formerly the Regional Response Center (RRC)) to request delivery of off-site equipment be initiated. Declaration of an ELAP is time critical.

: 3. Within 3 hours complete DC load shed actions

: 4. Within 4 hours provide alternate cooling to Reactor Core Isolation Cooling (RCIC) pump room by deployment of portable generator and fan.

: 5. At 5.5 hours, begin connecting RCIC suction source to allow RCIC feed with an alternate source to the heated Suppression Pool Water (Table item 1 I and Figure A.3-1). This action provides an alternate water source for RCIC and core cooling.

Overall Integrated Plan for Perry Nuclear Power Plant, Revision 1 At 6 hours, start FLEX generator(s) to energize 41601480 Vac vital buses (Table item l4). This is a critical task to power the plant 480 Vac equipment required for Phase 2. This equipment includes powering the battery chargers to ensure the batteries do not deplete within their 24 hour capacity. This allows motor operated valves (MOVs) to be remotely operated including the valves for Suppression Pool Make Up (SPMU), and the Suppression Pool Clean Up (SPCU) or Alternate Decay Heat Removal (ADHR) pump to provide "closed loop" containment cooling (credited) or alternatively, to enable the bleed function from the Suppression Pool and remove decay heat (non-credited).

At 6 hours, after starting the FLEX generator(s), start and operate the FLEX Lake Water Pump(s) at the Emergency Service Water Pump House (ESWPH) (Table item 12). This is a critical activity to provide Emergency Service Water (ESW) flow through the Residual Heat Removal (RHR) heat exchanger as cooling water and/or establish an alternate water source for the RCIC. Modular Accident Analysis Program (MAAP) analyses (Reference l) have demonstrated that the Suppression Pool temperature will not exceed the value specified in Reference 11 for RCIC operability before 7.8 hrs. Establishing this water source ensures continued core cooling.

At 6 hours, initiate Suppression Pool Makeup with SPMU (Table item l6). The MAAP analysis of the coping strategies performed for PNPP credits SPMU at 6 hours to provide additional volume of water to the Suppression Pool.

At 6.5 hours, initiate the credited closed loop cooling strategy via the use of the ADHR/SPCU pumps.

At t hours, begin refueling for the small I l0 Vac portable generator if RCIC Pump Room cooling is being accomplished by providing air flow to the room using a portable fan powered by the portable generator.

At l6 hours, start and operate diesel-powered compressor (Table item 2l). Calculations have determined that instrument air receiver tanks can support operation of the SRV valves for at least 24 hours. This calculation is based on design leakage and air use for over 200 actuations.

The coping analysis estimates less than 200 actuations in24 hours.

At24 hours, transition from "closed loop" cooling using ADHR/SPCU to Shutdown Cooling using RHR (Table item23).

At24 hours, begin SFP makeup (Thble item 24) it needed. Calculations of the SFP heat up and boil offassuming inventory loss due to seismic sloshing and maximum heat load determined the time to lower water levels to l0 feet above the fuel is at least 29 hours. The SFP emergency makeup system can be initiated remotely from the Intermediate Building at any time after the FLEX Lake Water Pump(s) have initiated flow through the ESW system.

Technical Bases An analysis of the core cooling and containment cooling coping strategy has been performed using the MAAP 4.0.7 code. This analysis provides the basis for the core cooling and containment cooling actions and timing (Reference 7).

Additionally, an analysis of the spent fuel pool was performed to determine inventory loss due to seismically induced sloshing and the heat up and boil down of the inventory in the pool. The analysis was performed using the maxirnum heat load in the pool assuming a full core offload (Reference 8).

13.

Overall Integrated Plan for Perry Nuclear Power Plant, Revision 1 Describe how the strategies will be deployed in all modes Identify how strategies will be deployed in all modes.

Ref: NEI 12-06 section 13.1.6 Deployment of FLEX equipment is described for each FLEX function in the subsequent sections and covers all operating modes. The broad-spectrum deployment strategies do not change for the different operating modes. The deployment strategies from the storage areas to the Operations Areas are identical and include debris removal, equipment transport, fuel transport, and power sources and requirements. The only difference is the utilization of the RCIC as a high pressure core cooling source for events initiating during Modes I -4. The FLEX Lake Water Pump(s) will provide direct flow to the RPV in Mode 5 through the ESW', Low Pressure Core Spray (LPCS), and High Pressure Core Spray (HPCS) pipes when RPV makeup is needed. Fuel Pool Cooling and Cleanup (FPCC) alternate decay heat removal will be used to remove decay heat. Each of these strategies and the associated connection points are described in detail in the subsequent sections. The electrical coping strategies are the same for all modes.

PNPP will use deployment paths, which refer to the route from a storage location to the operations area(s) for generators and other equipment; and routing paths, which refer to the route from a staging location to the point of connection to existing plant equipment for hoses and cables. Deployment paths and routing paths are shown in Attachment 2 of this document for all strategies. Generator storage and operations areas are shown on Figure 43-I 7, Electrical Generator Storage and Operations Areas.

To ensure that the strategies can be implemented in all modes, areas adjacent to the equipment storage and Operations Areas, as well as the deployment and hose routing paths will be maintained clear at all times. These requirements will be included in an administrative program. See Reference 16.

The dates specifically required by the order are obligated or committed dates. Other dates are planned dates subject to change.

Updates will be provided in the periodic (six month) status reports.

Provide a milestone schedule.

Modifications timeline o

Phase 1 Modifications o

Phase 2 Modifications o

Phase 3 Modifications Procedure guidance development complete o

Strategies o

Maintenance Storage plan (reasonable protection) r Staffing analysis completion FLEX equipment acquisition timeline Training completion for the strategies Regional Response Centers operational

Overall Integrated Plan for Perry Nuclear Power Plant, Revision 1 Ret NEI l2-06 Section l3.l See Six Month Status Report updates.

Overall Integrated Plan for Perry Nuclear Power Plant, Revision 1 Provide a description of the programmatic controls equipment protection, storage and deployment and equipment quality. See section ll in Ir{EI I2-06. Storage of equipment, 11.3, will be documented in later sections of this template and need not be included in this section.

See section 6.0 of JLD-LSG-2}12-01.

Identify how the programmatic controls will be met.

Reft NEI 12-06 Section l1 JLD-ISG -2012-01 Section 6.0 Equipment associated with these strategies will be procured as commercial equipment with design, storage, maintenance, testing, and configuration control in accordance with NEI l2-06 Rev. 0, Section I l.

Programs and controls will be established to assure personnel proficiency in the mitigation of beyond-design-basis events is developed and maintained in accordance with NEI 12-06 Rev. 0, Section 11.6.

Procedure Guidance PNPP is a participant in the Boiling Water Reactor Owners Group (BWROG) and will implement FSGs in a timeline to support the implementation of FLEX by Spring 2015. The BWROG guidance is to assist utilities with the development of site-specific procedures to cope with an ELAP in compliance with the guidance and requirements of Reference 2. The strategies described for PNPP are consistent with the alternate means of heat removal strategies developed for the BWR 6 Mark III plants (Reference 10).

The proposed implementation strategy aligns with the procedure hierarchy described in NEI 12-06 (Reference 2) in that actions that maneuver the plant are contained within the controlling strategic procedures, and the tactical FSGs are implemented as necessary to maintain the key safety functions of Core Cooling, Spent Fuel Cooling, and Containment in parallel with the strategic procedure actions.

The overall approach is symptom-based, meaning that the controlling procedure actions and FSGs are implemented based upon actual plant conditions.

PNPP will continue participation in the BWROG and will update plant procedures based upon generic industry guidance. It is expected that the following FSGs will be incorporated into existing plant procedures in order to develop the FSG interface:

o Operation of RCIC during ELAP conditions Alternate RCIC Suction Source o

DC Load Shed Initial Assessment and FLEX Equiprnent Staging Loss of DC Power o

Long Term RPV Inventory and Temperature Control Alternate SFP Makeup and Cooling o

Alternate Containment Cooling o

Transition from FLEX Equipment Maintenance and Testing The FLEX mitigation equipment will be initially tested (or other reasonable means used) to verifl, performance conforms to the limiting FLEX requirements. It is expected'that the testing will include the equipment and the assembled sub-system to meet the planned FLEX performance. Additionally, First Energy Nuclear Operating Cornpany, FENOC, will implement the maintenance and testing ternplate upon issuance by the Electric Power Research Institute (EPRI). The template will be developed to meet the FLEX guidelines established in Section 11.5 of Reference 2.

Overall Integrated Plan for Perry Nuclear Power Plant, Revision 1 The unavailability of equipment and applicable connections that directly performs a FLEX mitigatron strategy will be managed using plant equipment control guidelines developed in accordance with NEI 12-06 Rev. 0, Section 11.5.

Staffing The FLEX strategies documented in the event sequence analysis (Reference 9) assume:

On-site staff are at administrative shift staffing levels No independent, concurrent events All personnel on-site are available to support site response PNPP will have to address staffing considerations in accordance with NEI 12-06 (Reference 2) to fully implement FLEX at the site.

Configuration Control Per NEI 12-06 (Reference 2) and the Interim Staff Guidance (Reference 3), the FLEX strategies must be maintained to ensure future plant changes do not adversely impact the FLEX strategies.

The FLEX strategies and basis will be maintained in an overall program document. Existing plant configuration control procedures will be modified to ensure that changes to the plant design, physical plant layout, roads, buildings, and miscellaneous structures will not adversely impact the approved FLEX strategies in accordance with NEI 12-06 Rev. 0 Section I 1.8.

List training plans for affected organizations or describe the plan for training development Describe training plan Training plans will be developed for plant groups such as the Emergency Response Organization, Fire, Security, Emergency Preparedness, Operations, Engineering, Mechanical Maintenance, and Electrical Maintenance. The training plan development will be done in accordance with PNPP procedures using the Systematic Approach to Training, and will be implemented to ensure that the required PNPP staff is trained prior to implementation of FLEX. The training program will comply with the requirements outlined in Section I l.6 of NEI 12-06.

Discussion in this section may include the following information and will he.further developed as the Regional Response Center development is completed.

o Site-specific RRC plan o

ldentification of the primary and secondary RRC sites o

ldentification of any alternate equipment sites (i.e., another nearby site with compatible equipment that can be deployed)

Describe how delivery to the site is acceptable r

Describe how all requirements in NEI 12-06 are identified Describe Regional Response Center plan The industry will establish two NSRCs to support utilities during beyond design basis events. Each NSRC will hold five sets of equipment, four of which will be able to be fully deployed when requested, the fifth set will have equipment in a maintenance cycle. Equipment will be moved from an NSRC to the near site staging are1 established by the Strategic Alliance for FLEX Emergency Response (SAFER) team and the utility. Communications will be established between the affected nuclear site and the SAFER team and required equipment moved to the site as needed. First arriving equipment, as I I of82

Overall Integrated Plan for Perry Nuclear Power Plant, Revision 1 established during development of the nuclear site's playbook, will be delivered to the site within 24 hours from the initial request.

FENOC has signed a contract with SAFER to meet the requirements of NEI 12-06, Section 12.

Notes: None 12 of 82

Overall Integrated Plan for Perry Nuclear Power Plant, Revision 1 Maintain Core Cooling & Heat Removal BWR Installed Equipment Phase 1 Determine Baseline coping capabilify with installed coping modifications not including FLEX modifications, utilizing methods described in Table 3-1 of NEI 12-O6z Reft JLD-lSG-2012-01 Sections 2 and 3 Provide a general description of the coping strategies using installed equipment including station modffications that are proposed to maintain core cooling. Identifu methods (RCIC) and strategy(ies) utilized to achieve this coping time.

Modes l - 4 Phase I actions include those that can be performed using installed plant equipment to extend initial coping, building on the current station black out response. The key functions to protect are core cooling, containment integrity and spent fuel pool cooling. In some cases, actions are required in support of a safety function rather than directly serving a safety function.

Reactor core cooling and heat removal is provided during Phase 1 by using the turbine driven RCIC pump to supply water to the RPV and operation of SRVs to vent stream from the RPV to the Suppression Pool. The RCIC pump is powered by the steam generated in the RPV. The instrumentation and controls required to operate the RCIC turbine are powered by the Division 1 125 Vdc bus EDlA so the availability of the equipment for providing core cooling is unaffected by an ELAP.

The RCIC pump is located on elevation 574'6" of the Auxiliary (Aux) Building in a dedicated watertight room. The Aux Building structure is Seismic Category I, and protected against seismic events, floods, and high winds. The RCIC turbine, pump and supporting valves and piping are also seismically qualified. The RCIC pump and associated piping is expected to be available for all hazards addressed by FLEX.

The RCIC throttle valve and SRVs are required to support this function. The RCIC throttle valve is powered by an attached hydraulic system with control provided by 125 Vdc and will be used to balance makeup flow to the RPV with the loss of inventory due to steam discharge through the SRVs to maintain the water level in the RPV. This will minimize cycling of the RCIC system valves and maintain the RCIC pump operating during the event. As RPV pressure increases, the SRVs (electrically controlled) will be used to maintain RPV pressure by releasing steam from the RPV to the Suppression Pool.

The RCIC pump is designed to automatically start in the event of an initiation signal for RPV Low Level 2 (Reference 4, Section 5.4.6). If the automatic start does not occur, plant procedures provide the operator actions required to start the pump from the Control Room or locally from the RCIC room.

The normal water source for the RCIC pump is the Condensate Storage Tank (CST). However, the CST is not considered "robust" as defined in NEI l2-06 for protection from seismic and tornado events.

Therefore, the Suppression Pool is credited as the source for the RCIC pump. Suction will be aligned to the Suppression Pool if the CST is unavailable during Phase 1 per existing operations procedure(s)

(FSG 10.1). Makeup to the RPV is provided by the Suppression Pool inventory and makeup water to the Suppression Pool is not required during Phase 1 coping.

During Phase 1, all of the energy from the core decay heat and RPV sensible heat would be deposited in the Suppression Pool. This would result in a temperature increase in the pool that could challenge the continued operation of the RCIC with respect to current design basis limits. A BWROG task has qualified the ooeration of the RCIC up to a suction temperature of 230'F (Reference I l). In order to l3 of82

Overall Integrated Plan for Perry Nuclear Power Plant, Revision 1 Maintain Core Cooling & Heat Removal BWR Installed Equipment Phase 1 maintain the operation of the RCIC to provide core cooling, equipment will be deployed for use in Phase 2 to provide an alternate cold water suction supply to the RCIC pump.

If an ELAP occurs during Mode 4, water in the vessel will heat up. When temperature reaches 2l2oF, the vessel will begin to pressurize. The turbine driven systems are generally available for emergency use, thus during the pressure rise, RCIC can be returned to service with suction from the CST or Suppression Pool to provide injection flow to the vessel. When pressure rises, the operators will control pressure using an SRV to support RCIC operation. The primary and secondary strategies for Mode 4 are the same as those for Modes I - 3 as discussed above for core cooling. Once AC electrical power is restored, the Standby Liquid Control, SPCU, ADHR, and FLEX Lake Water Pump(s) are available to provide for RPV makeup in the event the RCIC is not available.

An estimation of time to core uncovery was performed with the vessel flooded to the vessel flange (Reference 5) to bound the time available if the ELAP event initiates in mode 5 where RCIC is not available. This calculation showed that more than I I hours were required to boil down to Top of Fuel.

This allows adequate time to arrange low pressure core cooling/injection and other responses as Phase 2 or Phase 3 actions using FLEX equipment.

Provide a brief description of Procedures / Strategies /

Guidelines Confirm that procedure/guidance exists or will be developed to s upport i mpl e m ent at i on.

The following OffNormal Instruction (ONIs) and FSGs currently exist and would be used during the initial phase of the ELAP o

ONI-RI0-2 Total Loss of AC Power ONI-SPI D-3 Cross Tying Unit I and Unit 2 Batteries ONI-SPI D-I Maintaining System Availability ONI-SPI-D-2 Non-essential DC Loads o

ONI-SPI H-3, Instrumentation Available During Station Blackout.

ONI-EI2-2 Loss of Decay Heat Removal FSG 10.1 RCIC FLEX Operation PNPP will continue participation in the BWROG and will update plant procedures upon changes to generic industry guidance. The BWROG Emergency Procedures Committee has developed changes to the Emergency Procedure Guides and Severe Accident Guidance (EPG/SAGs, References l2 and 13) to support continued operation of RCIC during an ELAP. These changes were completed in EPG/SAGs Rev 3.

These changes rnodify RPV pressure control guidance to maintain RCIC operation. PNPP's response to the ELAP assumes that the operators follow ONI-Rl0-2 Total Loss OfAC Power guidance in the initiaf phase of the event to extend the l25Ydc battery life, establish ventilation to rooms with vital equipment and to depressurize and control the RPV pressure and level.

Overall Integrated Plan for Perry Nuclear Power Plant, Revision 1 Maintain Core Cooling & Heat Removal BWR Installed Equipment Phase I It is expected the following FSGs will be incorporated into plant procedures in order to develop the FSG interface for Phase l:

FSG 10.3 RCIC Suction Alternate Supply ONI-SPI D-3 Division 3 To Division 2 480 Volt Crosstie ONI-SPI D-3 Nonessential DC Loads FSG 80.1 Establishing FLEX Travel Paths Identify modifications List modifications and describe how they support coping time.

There are no modifications required to support Phase l.

Key Reactor Parameters List instrumentation creditedfor this coping evaluation phase.

o RPV Level o

RPV Pressure RPV Temperature RCIC Flow Rate Suppression Pool Temperature Suppression Pool Level Containment Pressure PNPP will develop procedures to read this instrumentation locally, where applicable, using a portable instrument, as required by Section 5.3.3 of NEI 12-06.

Overall Integrated Plan for Perry Nuclear Power Plant, Revision 1 Maintain Core Cooling & Heat Removal BWR Portable Equipment Phase 2 Provide a generol description of the coping strategies using on-site portable equipment including station modffications that ore proposed to maintain core cooling. Identify methods and strategy(ies) utilized to achieve this coping time.

The preferred coping strategy for Phase 2 consists of maintaining RCIC operation versus depressurizingthe RPV and injecting water with low pressure pumps to maintain RPV level. A connection point is provided from the discharge piping of the RHR heat exchangers that can be connected to the connection point on the RCIC suction line to allow Suppression Pool water that is being cooled by "Closed Loop Suppression Pool Cooling" to supply the RCIC system. The expected temperature of the RHR heat exchanger outlet during "Closed Loop Suppression Pool Cooling" has been evaluated to be less than 140"F (RCIC suction design basis temperature). A secondary alternate source of water to the RCIC system is provided by a connection point on the ESW system that can be aligned to the RCIC pump suction to allow the FLEX Lake Water Pump(s) to provide an indefinite injectable volume (via Lake Water) to the RCIC system. With an alternative suction source aligned, RCIC system operation is not challenged by high temperatures of the process flow and RCIC operation continues until Shutdown Cooling can be established in Phase 3. Should RCIC fail during Phase 2, depressurizingthe RPV and using low pressure injection of Suppression Pool or lake water into the RPV using the SPCU, ADHR, or FLEX Lake Water pump(s) is the secondary method of RPV injection. The actions and modifications required to continue injecting to the RPV are discussed below. The Suppression Pool heat removal actions and rnodifications will be discussed under the Maintain Containment Function. Establishing FLEX equipment to supply 41601480 Vac power to support these functions is discussed in the Safety Function Support section.

Phase 2 actions include those which can be performed using on-site FLEX equipment to further extend coping until external support becomes available. It should be noted that precursor tasks may be required to enable application of required FLEX strategies. For example, in order to deploy FLEX equipment, debris removal activities may need to be initiated and partially completed, in order to effectively deploy equipment to the appropriate Operations Area.

Establishing the FLEX water source In order to establish the FLEX water source from the UHS for various applications (component cooling and/or system injection), FLEX Lake Water Pump(s) will be "stored in a location near the point of deployment" in the ESWPH. The ESWPH structure and associated equipment are Seismic Category I, and protected against seismic events, floods, and high winds and robust for all FLEX events. The FLEX Lake Water Pump(s) ('N'pump and 'N + I'pump) will be able to supply the required flow to either ESW A(B) loop (or both can be used if no equipment failures occur). The FLEX Lake Water Pump(s) will be electrically connected and have a suction hose(s) attached and lowered to the ESWPH suction bay and three discharge hoses connected from the FLEX Lake Water Pump(s) to the selected ESW loop to supply approximately 3000 gallons per minute (gpm) in the ESW Loop. Note that a portion of the discharge of the FLEX Lake Water Pump(s) can also be used intermittently via a dedicated hose connection to spray debris off the traveling screens if blockage occurs. The ESW system normally discharges back to the lake but is designed with return lines from the discharge of ESW A and ESW B to return water that has absorbed heat from heat exchangers loads cooled by the ESW system, back to the ESW forebay during periods of cold later water temperatures, where icing rnay be experienced, to prevent buildup of ice in the Forebay and Suction Bay of the ESWPH.

TWo motor-driven FLEX Lake Water Pump(s) will be "stored in a location near the point of deployment" in the ESWPH ('N'pump and 'N + I'pump). The storage location will be the floor space which would have been occupied by the lJnit 2 ESW pump discharge piping. The FLEX Lake Water inins which will utilize four hose connections (three connections for Pump(s) will have disch l6 of82

Overall Integrated Plan for Perry Nuclear Power Plant, Revision 1 Maintain Core Cooling & Heat Removal BWR Portable Equipment Phase 2 ESW Supply and one hose connection for auxiliary use). Additionally, corresponding hose connections will be provided to allow connection of the FLEX Lake Water Pump(s) to the "A" and "B" trains of ESW. The receiving hose connections will tie into the ESW Loop at the ESW Pump discharge piping between the pump discharge check valve and discharge strainer. Three separate connection points will be installed with system boundary valves, and associated piping (routing to convenient locations) to each ESW Loop. Each connection point will terminate with a 5" hose connection.

TWo new connection points will be installed on ESW Supply header piping in the Auxiliary Building 599' 6" elevation. These hose connections will originate from 24" ESW System Supply header piping in the overhead of Auxiliary Building 599'6" elevation which supplies cooling water to the RHR Heat Exchangers and other ESW system loads. One set of two connection points will be installed on ESW A Loop, and another set on ESW B Loop.

Additionally, two new dry standpipes will be installed which vertically run through all elevations of the Auxiliary Building. The standpipes will penetrate the 620' 6" floor slab and terminate on this elevation with an isolation valve and a hose connection. The standpipes will have two hose connections and a mid-pipe isolation valve located on the 599' 6" elevation. Finally, the standpipes will have isolation valves and hose connections on the 574'6" for the West dry standpipe and 568'' 6" elevation for the East dry standpipe of the Auxiliary Building. One dry standpipe will be provided at the east and west end of the Auxiliary Building. Both dry standpipes will be designed and installed Seismic Category I, and protected against seismic events, floods, and high winds.

Emergency battery-backed lighting will be provided in the ESWPH. The lighting will be strategically placed to support operator actions in the ESWPH and will be capable of providing at least 24 hours of emergency lighting within the ESWPH. The cable and lighting boxes will be designed and installed Seismic Category l, and protected against seismic events, floods, and high winds. This installation will utilize the existing structural steel that supports the ESWPH south staircase.

Modes l - 4 In Phase 2, core cooling is performed by maintaining RPV water level with high pressure injection from RCIC. The robust water supply is from the Suppression Pool to the suction of the RCIC pump to maintain RPV water level. The SRV system will be used to control RPV pressure and to discharge steam to the suppression pool. RCIC and the SRVs are controlled with Division 1 125Vdc power.

An alternate robust water source for core cooling is the RHR system at the outlet of the RHR Heat Exchangers. The SPCU / ADHR pump will be placed into Closed Loop Suppression Pool Cooling flowing water from the Suppression Pool to the Suppression pool via the RHR Heat Exchangers. The RHR system can be aligned to the RHR to FPCC Return header via installed plant equipment. A new connection point on the RHR to FPCC Return header at Aux Building elevation 599' 6" will be connected to the suction of the RCIC pump for core cooling (Figures A3-2,A3-3) with a hose (via the dry standpipe discussed above).

A second robust alternate water source for core cooling is the lake water supplied through the ESW system. A connector point on the ESW A or E,SW B Supply Header pipe at Aux Building elevation 599' 6-will be connected to the suction of the RCIC pump for core cooling (Figures A3-2,A3-3) with a hose (via the dry standpipe discussed above).

Other, non-robust, water sources can be used to supply RCIC for core cooling if available. These include the CST, the Mixed Bed Storage Tank or the Two Bed Storage Tank on the west side of the If these tanks are not available or become depleted, the lake water supplied lant at el620' 6" 17 of82

Overall Integrated Plan for Perry Nuclear Power Plant, Revision 1 Maintain Core Cooling & Heat Removal BWR Portable Equipment Phase 2 by the FLEX Lake Water Pump(s) through the ESW system would be aligned and provides an indefinite injectable volume.

Low Pressure Core Cooling Core cooling can be maintained after the RPV has been depressurizedto less than approximately 50 psig with continued core boiling via low pressure injection. This RPV pressure can be achieved from deliberate pressure reduction by using the controlled opening of an SRV (within the lO0oF/hr.

cooldown rate), or by rapid depressurization using a full division Automatic Depressurization System (ADS) initiation. The Emergency Operating Procedures provide guidance for use of the SPCU and ADHR pumps to provide RPV injection. The SPCU / ADHR pumps can be aligned to inject Suppression Pool water directly to the RPV as Alternate Injection Subsystems. The SPCU /ADHR pumps can also be used to inject to the RPV during Closed Loop Suppression Pool Cooling by operation of the RHR to RPV injection valve and RHR to Suppression pool test return valves to align flow from the outlet of the RHR heat exchangers back to the RPV vice the Suppression Pool. If SPCU and ADHR pumps cannot be used for RPV injection; the FLEX Lake Water Pump(s) (rated to supply 3000 gpm each at 150 psig) can provide RPV injection to the RPV at once the RPV is depressurized to 50 psig. In this strategy SRVs would be opened to maintain a low pressure condition. SRVs are controlled using DC power from the Control Room.

For SPCU / ADHR injection no modifications are required. Injection flow paths are via installed piping systems.

For the FLEX Lake Water Pump(s) a flush connection blanked flange is available on the LPCS that will be converted to a have a 5 inch hose Storz connector. The ESW A or ESW B system will be connected to the new LPCS Storz connector via a hose. After the manual valve FLUSH WTR TO LPCS PUMP DISCH LINE is opened and the LPCS INJECTION VALVE, is opened electrically or manually, the ESW water will be injected through the LPCS into the RPV.

An additional method for low pressure core cooling (or suppression pool inventory addition) is similar to the primary method but injects through the HPCS. Water would be supplied from Lake Erie as the robust alternate water supply via ESW B. The hose connection to the RPV is via an existing flush point. ESW water will be provided by opening the manual valve HPCS PUMP DISCH LINE FLUSH CONN, then opening HPCS INJECTION VALVE. HPCS TEST VALVE TO SUPR POOL would be opened to supply the Suppression Pool. Both MOVs can be opened or closed via local manual action and are in accessible locations. Note that this HPCS connection point requires no modifications and currently serves as the plant's "Fast Fire Water" injection point.

Core cooling will be re-established in Phase 2 by restoration of the FPCC system flow with the systems heat exchangers in service to the Containment Upper Pools. This is the normal alternate decay heat removal method used during Refueling operations. If pool makeup is required, or FPCC system cannot be placed into service, core cooling will be re-established using the low pressure core cooling method described above. This alignment of the FLEX Lake Water Pump(s) supplying water through the ESW system to either the LPCS or HPCS can provide at least 250 gpm to the vessel which is sufficient to remove decay heat. A flow rate of at least 1000 gpm will suppress boiling. The heated water can then be directed back to the Suppressiorr Pool through the steam line and an SRV or up through the reactor cavity to the upper pool depending on the level of the water in the cavity. (Reference 9) 18 of82

Overall Integrated Plan for Perry Nuclear Power Plant, Revision 1 Maintain Core Cooling & Heat Removal BWR Portable Equipment Phase 2 Details:

Provide a brief description of Procedures / Strategies /

Guidelines PNPP will continue participation in the BWROG and will update plant procedures based upon generic industry guidance. It is expected the following FSGs (in addition to Phase 1 FSGs) will be incorporated into existing plant procedures in order to develop the FSG interface for Phase 2:

Establishing Water Source from Lake Erie to ESW in the ESWPH Aligning Alternate RCIC Suction Source Establishing Closed Loop Suppression Pool Cooling Low Pressure Core Cooling Identifv modifications Install six inch isolation valve(s) and Storz hose connection on the RCIC pump suction pipe (Figure A'3-l)

Install Pipe connections on ESW A and ESW B pipes in ESWPH Install Storz hose connections on ESW A and ESW B pipes in Auxiliary Building (Figures A3-2, A.3-3)

Install hose connections on Demin Water Source Tanks o

Two Bed Storage Tank o

Mixed Bed Storage Tank Modifo LPCS Flange to install 5" Storz Connection (Figure A3-7)

Key Reactor Parameters List instrumentation creditedfo, this coping evaluation phase.

o RPV Level RPV Pressure RPV Temperature r

RCIC Flow Rate Containment Pressure PNPP will develop procedures to read this instrumentation locally, where applicable,,

using a portable instrument, as required by Section 5.3.3 ofNEl 12-06.

Storage / Protection of Equipment :

Describe storage / protection plan or schedule to determine storage requirements Seismic PNPP plans to store the FLEX Lake Water Pump(s) and hoses and other FLEX equipment in existing robust buildings meeting the requirements for storage of FLEX equipment. The electric pumps will be stored in the ESWPH utilizing space originally designated for the Unit 2 ESW pumps (Figure A3-4). The ESWPH is Seismic Category l, and protected against seismic events, floods, and high winds. Both the Unit 2 EDG building and the Unit 2 Aux building were constructed to meet the site seismic requirements. Other satellite equipment locations will also be in safety related structures. FLEX equipmetrt will be secured as appropriate during SSE and will be l9 of82

Overall Integrated Plan for Perry Nuclear Power Plant, Revision 1 Maintain Core Cooling & Heat Removal BWR Portable Equipment Phase 2 protected from seismic interactions from other components. No components will be stacked or at a raised elevation as to cause interference with the deployment of any FLEX equipment. A SSE having a peak horizontal ground acceleration of 0.1 5 g has been selected for design (USAR Section 2.5.2.6). The design basis values from the USAR will be used for PNPP's FLEX strategies. See Figure

,A3-16 (l thru 5) for storage and deployment information.

Flooding Note: if stored below current flood level, then ensure procedures exist to move equipment prior to exceeding flood level.

Storage for the FLEX lake Water pumps will be in the ESWPH. The ESWPH floor elevation is 580' 6." Maximum suction bay water height based upon maximum lake levels and surge heights is 580'0" based upon the location of the intake structures approximately l/2 mile off shore. The ESWPH is designed to preclude ground water in-leakage with sealed penetrations. The normal access to the ESWPH is 620' 6" and is above the maximum site flood level of 620' 5".

Incidental in-leakage from ground water or system failures would be drained below the 580'6" floor level by grating openings above the suction bay of the pump house and back to the lake via the intake structure. Storage for other equipment will be in the Unit 2 Emergency Diesel Generator Buildin g andlor the Auxiliary Building at el. 620'6". The buildings are sited in a location above the PMF grade (620'5" for PNPP). Other satellite equipment locations will also be in safety related structures. See Figure A.3-16 (l thru 5) for storage and deployment information.

Severe Storms with High Winds The ESWPH, the lJnit2 Emergency Diesel Generator Building and the Auxiliary Building are designed as Seismic Category I structures that meets the plant's design basis for the SSE (e.g., existing safety-related structure Snow, Iceo and Extreme Cold PNPP site is subject to significant amounts of snoq extreme low temperatures and existence of large amount of ice. PNPP storage locations will ensure that all FLEX equipment is provided general protection from the elements at the site.

FLEX equipment is stored within buildings that will be maintained within a temperature range to ensure its function when called upon.

High Temperatures The FLEX storage buildings will include adequate ventilation to ensure that high temperatures do not affect the functionality of FLEX equiprnent.

Overall Integrated Plan for Perry Nuclear Power Plant, Revision 1 Maintain Core Cooling & Heat Removal BWR Portable Equipment Phase 2 Deployment Conceptual Design (Attachment 2 contains Conceptual Sketches)

Upon declaration of the ELAP, personnel will be dispatched to connect the FLEX Lake Water Pump(s) at their staging location in the ESWPH. The FLEX Lake Water Pump(s) do not need to be deployed from their storage location; however, alternate strategies require deployment of electrical support equipment. The site has been evaluated for soil liquefaction due to a seismic event and found to not be susceptible. Therefore, the routes will be available. No significant debris is expected, however the FLEX equipment includes debris removal vehicles that can be used to clear the route. In addition, the site area is very open allowing blockages to be avoided. Hoses and other equipment required in the Unit I Aux Building will be deployed the short distance between the Unit I and FLEX Equipment Bay 2 (Unit 2 Auxiliary Building) (Figure,A3-18) or will be stored in the Unit 1 Auxiliary Building.

Strategy Modifications Protection of connections Identify Strategy including how the equipment will be deployed to the point of use.

Identify modifications Identify how the connection is protected Core Cooling using RCIC and Alternate Water Source.

Two installed pumps (SPCU/ADHR) will be used to establish flow though the RHR heat exchanges. The water exiting the RHR Heat Exchanger will be cooled and aligned to the RCIC pump suction to provide a clean water source to the RCIC system.

Two electric powered pumps will be staged in the ESWPH. The pumps will take suction from the ESWPH Suction Bay (from Lake Erie) and discharge through three 5" lines into corresponding hose connections that connect to the ESW A and/or B pump discharge pipe in the ESWPH between the pump discharge check valve and the strainers.

In the Unit 1 Aux. building, hoses will be affached from ESW A to the RCIC suction pipe. The alternate path is from the E,SW B to the RCIC suction pipe.

Two Bed Storage Tanks Install ESW Dry Standpipes (Figures A.3-5,

Modify LPCS Flange to install 5" Storz Connection Electrical Modifications are described in the Safety Function Support section Connections within Auxiliary Building (ESW and RCIC) are protected by a robust structure Connections in the E,SWPH are protected by a robust structure Mixed Bed and Two Bed Storage Tank connections are not robustly protected but mav be available 2l of 82

Overall Integrated Plan for Perry Nuclear Power Plant, Revision 1 Maintain Core Cooling & Heat Removal BWR Portable Equipment Phase 2 Core Cooling using Low Pressure Method Two installed pumps (SPCU/ADHR) will be used to provide RPV injection using the Suppression Pool as the water source using installed system piping.

The connections for the two electric pumps to provide lake water to the ESW system was previously discussed. Within the Unit I Auxiliary Building the ESW A would be connected with a hose to the LPCS. The alternate connection would be from the ESW B to the HPCS in order to provide lake water directly to the RPV.

Overall Integrated Plan for Perry Nuclear Power Plant, Revision 1 Maintain Core Cooling & Heat Removal BWR Portable Equipment Phase 3 Provide a general description of the coping strategies using phase 3 equipment including modificattons that are proposed to maintain core cooling. Identify methods and strategy(ies) utilized to achieve this coping time.

By Phase 3, additional 4160Vac generator(s) will have arrived from the NSRC and connected to a Unit I 4160 Vac vital bus, (Figure 43-13). If not previously initiated in Phase 2, direct decay heat removal via the Shutdown Cooling (SDC) mode of RHR operation can now be initiated. One RHR heat exchanger is required with 3000 gpm of cooling water provided by the ESW system from Lake Erie.

Once SDC is established, the RPV will stop steaming and makeup to the vessel can be terminated. In most cases, the most desirable strategy in Phase 3 will be to promptly proceed to cold shutdown.

Operators will align and start an RHR pump, A or B. The associated RHR heat exchanger will have the lake water aligned to it through the corresponding ESW train. Normal plant line-ups (other than FLEX Lake Water Pump(s) at the ESWPH) can be followed with due consideration to the NSRC generator loading constraints.

A secondary core cooling path is to use the RHR system in Suppression Pool Cooling mode (cooled by the ESW supplied by the FLEX Lake Water Pump(s) at the ESWPH). RCIC can be aligned to take suction from the Suppression Pool or alternatively, from the connection to the ESW system. Also, the low pressure core cooling path can be used to directly feed the RPV. This essentially extends the Phase 2 strategies into Phase 3, with the distinct difference being the utilization of the RHR System is a design basis al ignment/confi guration.

Provide a brief description of Procedures / Strategies /

Guidelines Confirm that procedure/guidance exists or will be developed to support implementation with a description of the procedure / strategy /

guideline.

PNPP will utilize industry developed guidance from the BWROG, EPRI, and NEI to develop site specific guidelines for the deployment and implementation of FLEX strategies, as well as the interfaces for FLEX strategies with existing plant procedures.

r Transition from High or Low Pressure Core Cooling to RHR Cooling o FLEX alignment of ESW flow through the RHR Heat Exchangers.

Identify modifications List modifications and describe how they support coping time.

No additional modifications are required for Phase 3 Core Cooling.

Key Reactor Parameters List instrumentation creditedft, this coping evaluation phase.

. RPV Level o RPV Pressure

. RPV Temperature

. RHR flow rate

. Suppression Pool Temperature

. Suppression Pool Level o ESW flow rate 23 of 82

Overall Integrated Plan for Perry Nuclear Power Plant, Revision 1 Maintain Core Cooling & Heat Removal BWR Portable Equipment Phase 3 Deployment Conceptual Design (Attachment 2 contains Conceptual Sketches)

No additional deployment of FLEX equipment is required in Phase 3 for Core Cooling.

Protection of connections Modifications Identify how the connection is protected Identifu Strategy including how the equipment will be deployed to the point of use.

Identify modifications FLEX Lake Water Pump(s) to ESW connections are described in Phase 2 section Deployment of the NSRC Generator(s) is described in the Safety Function Support Section Initiate RPV Cooling Using RHR pump The ESW train providing lake water will be redirected to provide cooling to the RHR A or B Heat Exchangers using normal lineups.

The discharge of ESW from the Heat Exchanger will be directed back to the lake through its normal flow path.

RHR will be aligned for SDC using FSG procedures.

Initiate Suppression Pool cooling using RHR pump The ESW train providing lake water will be aligned to provide cooling to the RHR A or B Heat Exchangers using normal lineups.

The discharge of ESW from the Heat Exchanger will be directed back to the lake throush its normal flow path.

RHR will be aligned for Suppression Pool (SP) cooling using FSG procedures.

None for Core Cooling Electrical Modifications are described in the Safety Function Support section Notes: None 24 of 82

Overall Integrated Plan for Perry Nuclear Power Plant, Maintain Containment Determine Baseline coping capability with installed coping modifications not including FLEX modificationso utilizing methods described in Table 3-2 of NEI 12-06:

BWR Installed Equipment Phase 1:

Provide a generol description of the coping strategies using installed equipment including modifications that are proposed to maintain containment. Identi.fy methods (containment spray/Hydrogen igniter) and strategy(ies) utilized to achieve this coping time.

Containment integrity is rnaintained by keeping containment atmospheric pressure less than the design limit of l5 psig. Containment integrity will be established under total loss of AC conditions by manually closing three valves: CNTMT POOLS RTN OTBD ISOL, DW B/U PURGE OTBD ISOL, and MSL DM & MS IV BYP OTBD ISOL VALVE, per current plant procedures.

During Phase l, the Containment pressure and Suppression Pool temperature would increase to -1 I psig and213oF, respectively. This is due to the Suppression Pool water absorbing the reactor's decay heat as the operators partially depressurize the RPV to -200 psig (Reference l4). This is within the containment design pressure of l5 psig, but exceeds the Suppression Pool temperature limit of 185"F.

The containment design temperature of 185'F for the Suppression Pool will likely be exceeded within 5 hours regardless of actions that can be taken. This limit normally comprises part of the consideration in maintaining Containment integrity; however, industry consensus is that this limit should not be inviolable at the conditions and limited time period contemplated for FLEX.

Containment function is not challenged early in the event; therefore, no actions are required in Phase 1 in support of containment function.

Mode 5 / Refueling Containment function may be challenged throughout the event due to moderate steam release rate from the vessel. Action may be required to prevent pressurization of the containment. Control of Containment Pressure is addressed per the Emergency Operating procedures.

Provide a brief description of Procedures / Strategies /

Guidelines The following procedures cumently exist and would be used during the initial phase of the ELAP o ONI-Rl0-2 Total Loss of AC Power

. ONI-SPI D-3, Cross Tying Unit I and UnitZ Batteries r ONI-SPI D-1, Maintaining System Availability

. ONI-SPl-D-2, Non-essential DC Loads

. ONI-SPI H-3, Instrumentation Available During Station Blackout

. ONI-El 2-2,Loss of Decay Heat Removal PNPP will continue participation in the BWROG and will update plant procedures based upon generic industry guidance. It is expected the following FSGs will be incorporated into existing plant procedures in order to develop the FSG interface for Phase 1:

. Initial Assessment and FLEX Equiprnent Staging Identify modifications List modifications and describe how they support coping time.

There are no modifications required to support Phase 1.

Overall Integrated Plan for Perry Nuclear Power Plant, Revision 1 Maintain Containment Key Containment Parameters List instrumentation credited ft, this coping evaluation phase.

Suppression Pool Temperature

. Suppression Pool Level o Drywell Pressure

. Drywell Temperature

. Containment Pressure Notes: None 26 of82

Overall Integrated Plan for Perry Nuclear Power Plant, Revision Maintain Containment BWR Portable Equipment Phase 2:

Provide a generol description of the coping strategies using on-site portable equipment including modifications that are proposed to maintain core cooling. Identifi methods (containment spray/hydrogen igniters) and strategy(ies) utilized to achieve this coping time.

Modes 1-4 Decay heat is removed from the RPV via steam through one or more SRVs to the Suppression Pool.

The primary method of heat removal from the Containment during Phase 2 is "Suppression Pool Closed Loop Cooling" with cooling water sourced from ESWPH via FLEX Lake Water Pump(s); electrical power provided for process flow through the ADHR/SPCU systems via FLEX on-site generators. See Figure A3-12 Closed Loop Cooling During Phases 2 and 3 for flowpath details.

Large 41 60Vac 1. 1 megawatt (MW) generators will be deployed in Phase 2. A new generator "docking station" will be installed in a Unit 2 Diesel Generator Bay (curently the Diesel Maintenance Shop). The 4160Vac generators will be connected to the docking station via single phase cables. From the docking station a new cable/conduit run will be installed and will connect into Bus EH-21. A'Jumper" will be installed to support the FLEX strategy so that Bus EH-21 will be able to power buses EH-11/12/13 during a postulated event. See Reference l5 for details.

A new Manual Transfer Switch will be installed for the SPCU Pump and provide dedicated power supplies to the ADHR and SPCU pumps from bus EF-2-B.

Unit 2 ESW power cables running out to the ESWPH will be utilized, including the installation of a pump "docking station."

The docking station installed in the Diesel Generator Bay will also serve as the connection point for the NSRC (Phase 3) generator(s). The 4l60Vac generators procured for Phase 2 will be of the same makeimodel as the NSRC equipment. These generators are capable of automatically synchronizingand load sharing (i.e., running in parallel). The docking station and cable runs will be capable of supporting multiple generator outputs.

The use of 4l60Vac generators will allow electrical power to be provided to a large contingent of equipment offering versatility and flexibility during a beyond design bases event.

Early in Phase 2, when 480 Vac power becomes available from a FLEX generator, the Upper Containment pool will be dumped into the lower Suppression Pool by initiating SPMU. This requires manipulation of 480 Vac MOVs, and requires re-energizingone of the vital 480 Vac buses.

If needed later in Phase 2 at about 7 hours, Lake Erie water will be transferred to the Suppression Pool via the LPCS (primary) or HPCS (secondary) systems and new ESW hose connections in the Auxiliary Building. Cool water from the Lake Erie can also be added to the Suppression Pool to increase inventory and reduce overall bulk temperature. See Figure A3-8: LPCS Suppression Pool Inventory Addition Flowpath and Figure,A3-9: HPCS Suppression Pool Inventory Addition Flowpath for flow paths.

As described above the primary method of containment heat removal will be "suppression Pool Closed Loop Cooling" with cool water sourced from ESWPH via FLEX Lake Water Pump(s); electrical power provided for process flow through the ADHR/SPCU systems via FLEX on-site generators (Figure 43-ll). Several (three to four) six inch risers will be installed off of the ADHR Pump discharge piping in the LPCS Purnp Room. The piping configuration will originate at a tee installed in the ADHR pump discharge piping and will consist of a I 0" system boundary valve, with riser connection piping runs containing one riser isolation valve per riser. Each riser will terminate at a ftre hose connection.

Portions of the ADHR System will be evaluated/upgraded to establish a seismic pedigree in accordance with the requirements for FLEX event cooins eouioment (document-onlv changes) and new pipine will 27 of82

Overall Integrated Plan for Perry Nuclear Power Plant, Revision 1 Maintain Containment be installed seismically. See Figure A3-10, ADHR Piping Modification Location for details of the modification.

Mode 5 / Refueling Containment function will not normally be challenged during the event due to containment integrity being relaxed and the containment open during Mode 5 / Refueling.

There may be brief periods during Mode 5 / Refueling when containment integrity might be required, such as during an operation with a potential to drain the reactor vessel. If a BDBEE occurred during these times the containment function would not be challenged based on containment response analysis performed for Modes I through 4 which uses cases bounding for Mode 5 due to the decrease in decay heat rate.

Containment Hydrogen Control The PNPP Mark III containment atmosphere is not inerted and contains free oxygen during normal operation. An event that overheats the fuel can generate free hydrogen gas that could cause a violent hydrogen/oxygen reaction when within certain concentration ranges in the presence of an ignition source. To preclude damage to equipment inside the Containment, hydrogen igniters are energized to stimulate early, non-violent reactions of hydrogen and oxygen at low hydrogen concentrations outside the explosive ranges.

During the postulated FLEX event and response, no fuel damage will occur but NEI 12-06 requires consideration of hydrogen control during FLEX events.

Primary Method Installed Division I hydrogen igniters would be repowered to suppress hydrogen buildup in case of zirconium/water reaction from an overheated core. Normal power sources are from the Division I vital 480 Vac bus. Either division is adequate for control of hydrogen. With the onsite FLEX generator(s) connected in Phase 2, the current draw from the igniters is considered in the FLEX generator load assessment (Reference 9). Current plant procedures would be used for initiating hydrogen igniter operation. Portable small generators are also available for local 120 Vac operation of the igniters.

Secondary Method Division 2 hydrogen igniters are also adequate for control hydrogen concentrations. Like Division l, these are powered from the 480 Vac vital bus but small portable generators are available for backup use.

Provide a brief description of Procedures / Strategies /

Guidelines Confirm that procedure/guidance exists or will be developed to s upp or t imp I e m ent at i on PNPP will continue participation in the BWROG and will update plant procedures based upon generic industry guidance. It is expected the following FSGs will be incorporated into existing plant procedures in order to develop the FSG interface for Phase 2:

r The use of ADHR/SPCU, powered by onsite FLEX generators to perform "closed loop cooling" of the Unit 1 suppression pool

. Feeding Suppression Pool from ESW A or B

. Operation of Containment Hydrogen Igniters during an ELAP Identifv modifications List modifications and describe how they support coping time.

Overall Integrated Plan for Perry Nuclear Power Plant, Revision 1 Maintain Containment Create Hose connections and hose path for ESW A to LPCS (Via Dry Stand Pipe)

Create Hose connections and hose path for ESW B to HPCS (Via Dry Stand Pipe)

Install Storz hose connection to LPCS in Auxiliary Building (Figure A3-7)

Install hose connections on ADHR Pump Discharge Install hose connections on FPCC System Piping Modification of ADHR pumps decontamination connection from 2" to 3-5" Storz connections for FLEX Evaluate/Upgrade SPCU to seismically robust for FLEX Evaluate/Upgrade ADHR to seismically robust for FLEX Lisl instrumentation credited or recovered for this coping evaluation.

. U I Suppression Pool Level o Ul Suppression Pool Temperature o SPCU flow rate

. ADHR flow rate o Containment Pressure Key Containment Parameters Storage / Protection of Equipment:

Describe storage / protection plan or schedule to determine storage requirements PNPP plans to store the FLEX Lake Water Pump(s) and hoses and other FLEX equipment in existing robust buildings meeting the requirements for storage of FLEX equipment. The electric pumps will be stored in the ESWPH utilizing space originally designated for the Unit 2 ESW pumps (Figure A3-4). The ESWPH is Seismic Category l, and protected against seismic events, floods, and high winds. Both the Unit 2 EDG building and the Unit 2 Aux building were constructed to meet the site seismic requirements. Other satellite equipment locations will also be in safety related structures. FLEX equipment will be secured as appropriate during SSE and will be protected from seismic interactions from other components. No components will be stacked or at a raised elevation as to cause interference with the deployment of any FLEX equipment. A SSE having a peak horizontal ground acceleration of 0.15 g has been selected for design (USAR Section 2.5.2.6). The design basis values from the USAR will be used for PNPP's FLEX strategies. See Figure 43-16 (1 thru 5) for storage and deployment information.

Storage for the FLEX lake Water pumps will be in the ESWPH. The ESWPH floor elevation is 580'6." Maximum suction bay water height based upon maximum lake levels and surge heights is 580'0" based upon the location of the intake structures approximately ll2 mlle off shore. The ESWPH is designed to preclude ground water in-leakage with sealed penetrations. The normal access to the ESWPH is 620' 6" and is above the maximum site flood level of 620' 5".

Overall Integrated Plan for Perry Nuclear Power Plant, Revision 1 Maintain Containment lncidental in-leakage from ground water or system failures would be drained below the 580'6" floor level by grating openings above the suction bay of the pump house and back to the lake via the intake structure. Storage for other equipment will be in the Unit 2 Emergency D iese I Generator Bui ldin g and/ or the Auxi I iary Bui ld ing at el. 620'6". The buildings are sited in a location above the PMF grade (620'5" for PNPP). Other satellite equipment locations will also be in safety related structures. See Figure 43-16 (1 thru 5) for storage and deployment information.

Severe Storms with High Winds The ESWPH, the Unit 2 Emergency Diesel Generator Building and the Auxiliary Building are designed as Seismic Category I structures that meets the plant's design basis for the SSE (e.g., existing safety-related structure Snow, Ice, and Extreme Cold PNPP site is subject to significant amounts of snow extreme low temperatures and existence of large amount of ice. PNPP storage locations will ensure that all FLEX equipment is provided general protection from the elements at the site.

FLEX equipment is stored within buildings that will be maintained within a temperature range to ensure its function when called upon.

High Temperatures The FLEX storage buildings will include adequate ventilation to ensure that high temperatures do not affect the functionality of FLEX equipment.

Hoses and other equipment required in the Unit I Aux Building will be deployed the short distance between the Unit 1 and FLEX Equipment Bay 2 (Unit 2 Auxiliary Building) (Figure,{3-18) or will be stored in the Unit 1 Aux Buildins.

Strategy Modifications Protection of connections Identify Strategy including how the equipment will be deployed to the point of use.

Identifu modifications Identify how the connection is protected Two electric powered pumps will be staged in the ESWPH. The pumps will take suction from the ESWPH Suction Bay (from Lake Erie) and discharge through three 5" lines into a corresponding hose connections that connects to the ESW A and/or B pump discharge pipe in the ESWPH between the pump discharge check valve and the strainers.

Maintain Containment Within the Unit I Auxiliary Building the ESW A would be connected with a hose to the LPCS. The alternate connection would be from the ESW B to the HPCS. These connections are to provide lake water directly to the SP.

Notes: None Overall Integrated Plan for Perry Nuclear Power Plant, Revision 1 3l of82

Overall Integrated Plan for Perry Nuclear Power Plant, Revision 1 Maintain Containment BWR Portable Equipment Phase 3:

Provide a generol description of the coping strategies using phase 3 equipment including modifications that are proposed to maintain core cooling. Identify methods (containment spray/hydrogen igniters) and strategt(ies) utilized to achieve this coping time.

Mode 5 / Refueling Containment function may be challenged throughout the event due to moderate steam release rate from the vessel. Action may be required to prevent pressurizationof the containment. Control of Containment Pressure is addressed per the Emergency Operating procedures.

Provide a brief description of Procedures / Strategies /

Guidelines Confirm that procedure/guidance exists or will be developed to s upp or t impl em ent at i on PNPP will continue participation in the BWROG and will update plant procedures based upon generic industry guidance. It is expected the following FSGs will be incorporated into existing plant procedures in order to develop the FSG interface for Phase 3:

. Alternate Water Source from Lake Erie to ESWPH

. Connecting Lake Erie Alternate Water Source to ESW A or B

. Operation of Containment Hydrogen Igniters during an ELAP Identify modifications List modificalions and describe how they support coping time.

No additional modifications are required to maintain Containment in Phase 3.

Key Containment Parameters List instrumentation credited or recovered for this coping evaluation.

o Suppression Pool Level

. Suppression Pool Temperature r RHR flow rate

. ESW flow rate to RHR heat exchanger Deployment Conceptual Modification (Attachm ent 2 contains Conceptual Sketches)

Strategy Modifications Protection of connections Identify Strategy including how the equipment will be deployed to the point of use.

Identfu modffications Identify how the connection is protected Shutdown Cooling using RHR and FLEX cooling of Heat Exchanger.

No additional modifications required.

Connections for RHR and ESW A use existing piping within a robust structure (Auxiliary Building) 32 of 82

Overall Integrated Plan for Perry Nuclear Power Plant, Revision 1 Maintain Containment Suppression Pool Cooling using RHR and FLEX coolins of Heat Exchanger No additional modifications required.

Connections for RHR and ESW A use existing piping within a robust structure (Auxiliary Building)

Notes: Deployment of the NSRC 4160Vac generator is described in the Safety Function Support Section.

Overall Integrated Plan for Perry Nuclear Power Plant, Revision 1 Maintain Spent Fuel Pool Cooling Determine Baseline coping capability with installed coping modifications not including FLEX modifications, utilizing methods described in Table3-2 of NEI 12-06:

BWR Installed Equipment Phase 1:

Provtde a general description of the coping strategies using installed equipment including modifications that are proposed to maintain spent fuel pool cooling. Identify methods (makeup via portable iniection source) and strateg,t(ies) utilized to achieve this coping time.

Spent Fuel Pool cooling is not challenged early in the event; however, access to the SFP area as a part of Phase I response could be challenged due to environmental conditions local to the pool and/or radiation levels from stored spent control rod blades.

Provide a brief description of Procedures / Strategies /

Guidelines The following procedures currently exist and would be used during the initial phase of the ELAP o ONI-RI0-2, Total Loss of AC Power

. ONI-SPI D-3, Cross Tying Unit I and Unit 2 Batteries

. ONI-SPI D-1, Maintaining System Availability o ONI-SPI -D-2, Non-essential DC Loads

. ONI-SPI H-3, Instrumentation Available During Station Blackout

. ONI-El2-2, Loss of Decay Heat Removal PNPP will continue participation in the BWROG and will update plant procedures based upon generic industry guidance. lt is expected the following FSGs will be incorporated into existing plant procedures in order to develop the FSG interface for Phase 1:

. Initial Assessment and FLEX Equipment Staging r Alternate SFP Makeup and Cooling Identify modifications List modifications and describe how they support coping time.

Develop and install an SFP Level Monitoring system Key SFP Parameter List instrumentation credited or recovered for this coping evaluation.

SFP Level Per Order EA 12-051 PNPP will develop procedures to read this instrumentation locally, where applicable, using a portable instrument, as required by Section 5.3.3 of NEI 12-06.

Notes: None 34 of82

Overall Integrated Plan for Perry Nuclear Power Plant, Revision Maintain Spent Fuel Pool Cooling BWR Portable Equipment Phase 2:

Provide a general description of the coping strategies using on-site portable equipment including modifications that are proposed to maintain spent fuel pool cooling. Identifu methods (makeup via portable injection source) and strategy(ies) utilized to achieve this coping time.

In Phase 2, the Spent Fuel Pool will heat to the boiling point and the level in the pool will continue to reduce. Calculations have been performed to determine the time to heat up the SFP and boil down to 10 ft. above the fuel using the maximum heat load associated with a full core offload. After reducing the pool inventory due to seismically induced sloshing, the time to reach 10 feet above the fuel was over 29 hours (Reference 9).

A new emergency inventory make-up system for the SFP (called the Spent Fuel Pool Emergency Makeup System) will be installed. The system will essentially consist of a dump line to the SFP with an individually isolable hose connection point. New piping will be installed seismically. The system will consist of a new piping riser that will originate from Unit 2 Emergency Closed Cooling piping (the safety related cooling water source for the FPCC Heat Exchangers). The riser will penetrate the Intermediate Building (lB) 620'6" floor slab (in the Unit 2 Annulus Exhaust Gas Treatment System "8" Fan Room) and Fuel Handling Building west wall. The piping will run along the pool deck and terminate near the edge of the pool. Prior to entering the Fuel Handling Building an individually isolatable hose connection point will be provided to permit the connection temporary oscillating monitor nozzles for pool spray application.