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Initial Exam 2011-302 Draft SRO Written Exam
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76. 038 EG2.4.11 SRO 001 Given the following plant conditions:

- The plant is operating at 100% RTP.

- The crew is implementing AOP-035, SIG Tube Leak, due to an identified tube leak in B SIC.

- Two charging pumps are running at maximum output and all letdown flowpaths have been isolated.

- RO reports that PZR Level is at 22% and continuing to lower in an uncontrolled manner.

Which ONE (1) of the following is the proper procedural progression for the given conditions?

EPP-7, SI Termination EPP-12, Post-SGTR Cooldown Using Backfill EPP-12

/3/

A Trip the Reactor --> Manual SI --> PATH-i --> PATH-2 -->

V B. Trip the Reactor --> Manual SI --> PATH-i --> PATH-2 --> EPP-7 --> EPP-12 PZR level reaches C. Continue in AOP-035 --> Trip the Reactor and actuate SI when 10% --> PATH-i --> PATH-2 --> EPP-12 to D. Continue in AOP-035, start the remaining charging pump and raise speed maximum and monitor PZR level.

The correct answer is A.

A. Correct.

2 will provide B. Incorrect. EPP-7 is not entered for a tube rupture. PATH-2 and EPP-1 direction on when to secure SI pumps and resetting of ECCS components.

Level cannot C. Incorrect. Foldout A does contain requirements to actuate SI if PZR on. AOP-035 be maintained greater than 10%. AOP-035 does not provide this directi y with two requires that the reactor be tripped if RCS level is lowering uncontrollabl charging pumps at maximum speed and letdown isolated.

In the past the third D. Incorrect. This was the correct process up to a few years ago.

letdow n was isolated.

charging pump was started and taken to maximum speed after the reactor with This was removed during a recent revision as a prudent action to trip letdow n isolate d.

only two charging pumps running at maximum speed and 10/13/2011 Page: 135 of 187

Question 76 Tier/Group 1/1 K/A Importance Rating - RO 4.0 SRO 4.2 Steam Generator Tube Rupture: Knowledge of abnormal condition procedures.

Reference(s) Sim/Plant design, AOP-035, PATH-1/2, EPP-12, EPP-7 Proposed References to be provided to applicants during examination None Learning Objective AOP-035-004 Question Source NEW Question Cognitive Level H -

10 CFR Part 55 Content- 41.10 /43.5/45.13 Comments Discussed with P. Capehart on 6/15/11: Knowledge of abnormal condition procedures relative to a SGTR. At RNP a SGTR is mitigated utilizing the EOP network procedures. A S/G Tube Leak is mitigated using an AOP. Agreed that abnormal condition procedures also included the EOP network procedures SRO: Assessing plant conditions and then selecting a procedure or section of a procedure to mitigate, recover, or which to proceed.

Page: 136 of 187 10/13/2011

Rev. 23 AOP-035 S/G TUBE LEAK Page 5 of 64

-J-f INSTRUCTIONS I I RESPONSE NOT OBTAINED

5. Check RCS Level - LOWERING IN AN Go To Step 12.

UNCONTROLLED MANNER Adjust Charging Flow As Follows:

Check Charging Pump Status - a. Start one additional Charging AT LEAST TWO RUNNING Pump.

b Place running Charging Pumps Speed Controllers in MAN adjust output to maximum Check RCS Level - LOWERING IN AN Go To Step 12.

UNCONTROLLED MANNER Check Letdown - IN SERVICE Go To Step 11.

Verify All Letdown Flowpaths Isolated As Follows:

LGV-460A & B, LTDN LINE STOP Valves CLOSED HIC-137, EXCESS LTDN FLOW Controller - ADJUSTED TO 0%

CVC-387, EXCESS LTDN STOP -

CLOSED Check RCS Level - LOWERING IN AN Go To Step 12.

UNCONTROLLED MANNER Trip The Reactor AND Go To Path-i OR EOP-E-0. Reactor Trip or Safety Injection

12. Control Charging Flow To Maintain Desired RCS Level

13. Check RCS Leakage - GREATER THAN IF leakage exceeds Charging RUNNING CHARGING FLOW flow, THEN Go To Step 6.

Go To Step 15.

14. Go To Step (

15. Notify Chemistry Personnel To Periodically Sample All S/Os For Activity And Boron Concentration

8.3.2 (Continued)

7. While the immediate actions are being performed, the CRS should verify their completion prior to entering the Path or applicable procedure. Once this verification is completed, the CRS should enter the procedure to verify the immediate actions as discussed above.

8. The Operators should broadcast the performance of immediate actions as they are being performed and then use 3-way communications to verify that immediate actions have been performed when the CRS uses the procedure.

9. Broadcasting of the Reactor Trip function should include the following as applicable:

Reactor Trip and Bypass Breakers Open a Rod Position Indication at zero

Rod Bottom Lights Illuminated

Neutron Flux decreasing

10. Broadcasting of the Safety Injection function should include the following as applicable:

Pressurizer Pressure is greater than 1715 psig.

No high steam line DIP or high steam flow bistables

CV pressure is less than 4 psig

Pressurizer level is greater than 10%, stable or rising

Safety Injection is not initiated and not required.

OMM-022 Rev. 35 Page 30 of 56

8.3.5 Precisely Controlling the Plant A control band (upper and lower thresholds) is to be provided when a parameter is being controlled manually or is out of specification. The control band is established such that the plant is being controlled precisely. Supplemental monitoring and contingencies are to be established as required.

2. An actionable limit is to be set as a contingency.

3. The Shift Manager and Shift Technical Advisor are to provide oversight and ensure the CRS has established a control band with an actionable limit.

4. The CRS is to maintain Command and Control by establishing a control band with an actionable limit, supplemental monitoring, and contingencies.

5. The Reactor Operators are to operate equipment with established control bands with an actionable limit. The RO is to advise the CRS if the control band can NOT be maintained prior to exceeding the thresholds. Also, the RO is to provide input on what supplemental monitoring and contingencies are warranted to precisely control the plant.

8.3.6 Automatic Actions/Actuations (RAIL 94R0928)

1. During the course of an event, should the setpoint for an automatic protective system actuation be approached, the Operator should, if possible, manually initiate the actuation prior to the automatic actuation. If immediate actions are in progress they should be completed prior to initiating the signal, however this is not considered performance of steps early or out of order.

f I

Example: During an RCS leakage transient, after entry to the EOP Network, pressure is slowly decreasing and after observing the trend in RCS pressure it is apparent that RCS makeup can not keep up with leakage. As pressure approaches the low pressure SI setpoint of 1715 psig, the Operator should manually initiate Safety Injection prior to reaching the setpoint.

OMM-022 Rev. 35 Page 34 of 56

%% ... *ATTCMPT TO RESTORE I NO POWER TO CLOSE MSIV DE ENERGIZED BUS AND MSIV BYPASS I VALVES J

FDEOIcATEoSHUTDOWN(

I BUS IS DEENERGED. I PLACE DEDICATED SHUTDOWN I DIESEL GENERATOR IN I R-19S, R-31S RESET SPDS R-15 RAG NO INITIATE MONITORING OF LEVELS NORMAL CRITICAL SAFETY FUNCTION STATUS TREES YES OPEN FOLDOUT 8 R-2 R-32A, R-32B NO REQUEST PERIODIC RAG LEVELS ACTIVITY SAMPLES OF NORMAL ALL S/Gs YES AT NO CV LEAST ONE RCP NO RUNNING PRESS NORMAL YES YES AT LEAST ONE SI NO CV SUMP NO PUMP RUNNING LEVEL NORMAL YES YES RCS SUBCOOLING NO RCS ci IR(CiflI INr LESS THAN

NO LETDOWN NOT REOURIED FOR USE 0 YES YES I AUX SPRAY FOR I C IWIED S/C DEPRESSURIZATION

.REATER THAN AT LEAST ONE S PRESS NO YES PZR LEVEL CCW PUMP GREATER THAN RUNG AUX 715 [6051 YES SPRAY AVALARLE YES NO 1 LEVEL OPEN CVC-38t, SEAL PP WTR RTRN ISO TER THAN YES

[325] 19 RLBTURED S/G NO OPEN AUX SPRAY PRESS GREATER THAN TO DEPRESSURIZE PC RCS PRESS NO RUN RCPs RI TIC PRIORITY ORDER OF C. B. A LEVEL GREATER YES To PROViDE PZR SPRAY S [32Z3,5, HARGING FLOW INIMUM P2W LEVEL Y ES GREATER THAN 105 [3251 AT NO LEAST OE RCP RUM*4G NO E PC? SEAL COOLRIG DL INC PREVIOUSLY LOST. fliEs.

XS THAN YES EVALUATE STATUS PRIOR x 10 STARTING AN RCP F [55 FJ WI1 PZR LEVEL GREATER THAN lox [3253. Ir STOP ALL OUT ONE RCP REDUCE CHARGRIG FLOW CV TO IFIIUu 12 SPRAY VALVES ESSIWIZE RCS.

1 SQIE HEAD VOIDRIG WILL CAUSE ERRATIC PZR LEVEL BEHAVIOR PRESS. HAS REMAINED BELOW 4 PSIG NO VALVES WILL CLOSE SPRAY VALVE

. THEN GO TO ASSOCIATED WITH IDLE NO RCS S1COOLG RCPCS) USB4G TABLE I YES POINT 1. GREATER THAN 35 F [55 F] RVLIS UPPER RANGE NO IIIOICATION x SInES BELOW 10 .10 AMPS. GREATER THAN YES his. EIERGIZE SOURCE lOOT RANGE DETECTORS IINMZE CYCLING OF P2W PZR LEVEL AND RCS TRANSFER RECORDER PZR SPRAY PORVs TO PREVENT YES SUBCOOLING WILL LOWER JJX SPRAY ADVERSE CV CONCOTIONS DUE TO HEAD VOID

[S CLOSED DUE TO PRT RUPTURES OLLAPSE ON PC? STAR

) SHUTDOWN UNICESSARY START OlC RCP USING PLANT IPMENT OPID1 PRAY VALVES RAISE PZR OPEN OlC PZR PORV LEVEL TO GREATER THAN CLOSE. fliEs TO DEPRESSURIZE RCS P SUPPLYING 745

[0 VALVE EPP YES AT LEAST ONE RCP RAISE RCS 12 SUBCOOLING TO GREATER AY VALVE FAILS RUNMNG THAN 59 *F E,.I5 CLOSE A AMi B OV-121 NO VERIFY NATURAL CRICULATION USING IN RCS AND SUPPLEMENT E 0 S/C PRESSs AN 1035_SIDD RIFYPRV CLOSED LWICOOL BIG TABLE 1 ER THAN

[55 F]

IDLE RCP SPRAY VALVE YES RCP B PCV-455A

.EVEL 7 LEAST ITACT S/G RCP C PCV-455B TER THAN

[18Z]

CONTINUOUS USE H. B. ROBINSON STEAM ELECTRIC PLANT, UNIT NO. 2 PLANT OPERATING MANUAL VOLUME 3 PART 4 END PATH PROCEDURE EPP- 12 POST-SGTR COOLDOWN USING BACKFILL REVISION 14 Page 1 of 23

Rev. 14 EPP-12 POST-SGTR COOLDOWN USING BACKFILL Page 4 of 23 Purpose and Entry Conditions (Page 1 of 1)

1. PURPOSE This procedure provides actions to cooldown and depressurize the plant to Cold Shutdown conditions following a Steam Generator Tube Rupture. This recovery method depressurizes the ruptured S/G by draining it through the ruptured tube into the RCS.

2. ENTRY CONDITIONS

b. EPP-l3, Post-SGTR Cooldown Using Blowdown, when S/C blowdown is not available and the backfill method of cooldown is selected.

- END -

77. 054 AG2.4.11 SRO 001 Given the following plant conditions:

c:: -

The plant is currently at 100% RTP with FWUFM in service.

A feedwater flow transient has occurred.

HCV-1459, LP Heaters Bypass Valve, is observed to be OPEN with its control switch in AUTO.

- Main Feedwater Pump suction pressure is currently 375 psig.

Which ONE (1) of the following completes the statements below?

The CRS will direct that Reactor Power be maintained less than 100% using (1) or OMM-001-2, Shift Routine and Operating Practices.

lAW OMM-001-2, Reactor Thermal Power is allowed to increase to a maximum of .;

(2) MWth briefly during power excursions.

A (1) AOP-0l0, Main Feedwater/Condensate Malfunction, Attachment 1 (2) 2346 MWth B. (1) OP-105, Maneuvering the Plant When Greater Than 25% Power (2) 2385 MWth C. (1) AOP-010, Main Feedwater/Condensate Malfunction, Attachment 1 (2) 2385 MWth D. (1) OP-I 05, Maneuvering the Plant When Greater Than 25% Power (2) 2346 MWth 10/13/2011 Page: 137 of 187

The correct answer is A.

A. Correct.

B. Incorrect. With HCV-1459 open the feedwater will become cooler due to bypassing the LP FW Heaters This will cause reactor power to increase The second part of the (afstractor is correct

/iO C. Incorrect. The first part of the distractor is correct. AOP-01 0 does direct the operators to control reactor power to less than 100%. Power will be lowered so that MFP suction pressure is greater than 400 psig. At 400 psig MFP suction pressure HCV-1459 should automatically open with the control switch in AUTO.

D. Incorrect. With HCV-1 459 open the feedwater will become cooler due to bypassing the LP FW Heaters. This will cause reactor power to increase. AOP-01 0 does direct the operators to control reactor power to less than 100%. Power will be lowered so that MFP suction pressure is greater than 400 psig. At 400 psig MFP suction pressure HCV-1459 should automatically open with the control switch in AUTO.

Question 77 Tier/Group 1/1 K/A Importance Rating - RD 4.0 SRO 4.2 Loss of Main Feedwater (MFW): Knowledge of abnormal condition procedures.

Reference(s) Sim/Plant design, AOP-010, OMM-001-2 Proposed References to be provided to applicants during examination - None Learning Objective AOP-010-006 Question Source NEW Question Cognitive Level H -

10CFRPart55Content- 41.10/43.5/45.13 Comments -

SRO: Assessing plant conditions and then selecting a section of a procedure to mitigate, recover, or with which to proceeth Also knowledge of maximum licensed N thermal power limitations.

I lj Page: 138 of 187 10/13/2011

Rev. 27 AOP-0l0 MAIN FEEDWATER/CONDENSATE MALFUNCTION Page 17 of 23 J STEP H INSTRUCTIONS I I RESPONSE NOT OBTAINED CAUTION Failure of HCV-1459. LP HEATERS BYP, will cause Reactor Power to rise.

Steady State operation above 100% is NQI permitted.

- - - - ** ****** *** **** ****** * ****** ***t**

t*t* * ** **** ** *** * * * ** * * *** **** ***

NOTE

HCV-1459, LP HEATERS BYP, is interlocked with QCV-10426, SECONDARY BYPASS. HCV-1459 failing open will also result in QCV-10426 opening.

Rapid power reductions may result in the axial flux difference exceeding the operating band values and require a power reduction to less than 50% to comply with ITS 3.2.3 Condition C.

35. Determine If HCV-1459 Has Failed As Follows:

a. Check HCV-1459, LP HEATERS a. Co To Step 38.

BYP - OPEN

b. aintain Reactor Power less than 100% using Attachment 1

c. Continue to reduce power using Attachment 1 until Feed Water Pump Suction pressures are greater than 400 psig.

(Local Indication)

P1-1433 - A FW PUMP SUCTION PRESSURE

P1-1434 - B FW PUMP SUCTION PRESSURE

d. Check Feed Water Pump d. WHEN Feed Water Pump suction suc Lion pressures - GREATER pressures arc greater than THAN 400 PSIG 400 psig, THEN Go To Step 35.e.

e. Verify HCV1459 - CLOSED e. Locally isolate HCV-1459 by closing C-52A, I-[CV-1459 INLET.

9.3 Continuous Calorimetric Program NOTE: Power level is limited to a maximum of 100.3% (2346 MWth) per LDCR 02-0012, Appendix K Power Uprate.

5. During Steady State Operations, reactor power may indicate greater than the allowed RTP for brief periods of time with no operator action required. It is NOT intended that this flexibility be used to make up for lost generation when the Period Average falls significantly below Target Power level for extended periods. These periods should be limited as follows:

a. The allowed thermal power with FWUFM in service is 2339MWth. With FWUFM out of service for longer than allowed by TRM 3.25, thermal power will be limited to 2300 MWth. The setpoints at which a power limit warning will be received are aiios:NP2 6004-CALO-SRS-001

The 8 hour9.259259e-5 days 0.00222 hours 1.322751e-5 weeks 3.044e-6 months average power is >2339 MWt and less than 1 hour1.157407e-5 days 2.777778e-4 hours 1.653439e-6 weeks 3.805e-7 months remains in the 8 hour9.259259e-5 days 0.00222 hours 1.322751e-5 weeks 3.044e-6 months period

The 1 minute average power is >2339.35 MWt (100.015%) for 290 minutes continuously.

The 1 minute average power is >2340.75 MWt (100.075%) for 50 minutes continuously.

The 1 minute average power is >2342.50 MWt (100.150%) for 20 minutes continuously.

The 1 minute average power is >2346.00 MWt (100.299%) for 5 minutes continuously

The 4 minute average power is >2346.00 MWt (100.299%)

instantaneously

b. The 4 minute average thermal power indication should not be allowed to consistently exceed the allowed RTP without taking operator action to reduce power. Small fluctuations above and below the allowed thermal power limit are expected for short durations and are part of steady state operations. The magnitude, trend and average of the fluctuations must be evaluated to determine if a power reduction is required.

c. The one hour average thermal power indication should not be allowed to exceed the allowed thermal power. It is recognized that the one hour average thermal power could exceed the allowed thermal power at the beginning of a new 8 hour9.259259e-5 days 0.00222 hours 1.322751e-5 weeks 3.044e-6 months period. It is not intended that a power reduction be initiated immediately in this condition. The trend should be evaluated and power reductions initiated if required.

6. During Planned Evolutions, operators should consider reducing power in advance of planned plant evolutions that have a potentially high likelihood of causing power to increase above the licensed power limit. IF during the evolution, power increases above the licensed power limit, THEN operators should take action to restore power to or below the licensed limit.

OMM-001-2 Rev. 70 Page 16 of 50

9.3 Continuous Calorimetric Program

7. Upon receiving any valid calorimetric Power Alarm, Reactor power shall be reduced to less than 2339 MWth, or until the calorimetric Power Alarm is cleared using the Valve Position Limiter. A time/power target will be given. Power must be reduced to less than the target power by the time given to prevent exceeding the limits. The cause of the Time / Power alarm may be determined by clicking on the ALARM INFORMATION button. [R5] [R6]

8. No information will be displayed for periods in which values cannot be calculated. For example, IF ERFIS is OOS for greater than thirty minutes, THEN no Period Average, Projected Power, or Recommended Power will be calculated. For periods in which ERFIS data is unavailable for less than thirty minutes AND the power change for the period ERFIS was OOS is less than 1%, the CCP will generate missing data using linear interpolation. IF it is anticipated that the Period Average will NOT be calculated, THEN the Reactor should be operated at less than 2339 MW Thermal. WHEN the CCP is 003, THEN Reactor power shall be maintained less than or equal to 100% as indicated by other diverse indications to ensure Time I Power limits are not exceeded.

9. Other conditions may exist which effect the validity of the CCP calculation. WHEN these conditions exist, THEN other indications of Reactor power shall be used.

Conditions which affect the validity of the CCP calculation include:

Operation at less than 15% power will cause some inputs to the COP calculation to be outside reasonability limits.

IF Charging temperature or Letdown flow data is unavailable, THEN the CCP calculation will default to data for operation with only the 60 gpm orifice in service.

Operation with greater than 60 gpm letdown flow will cause the calculation to be non-conservative.

Feeding any SIG with a MDAFW Pump will result in non-conservative results.

10. FWUFM measures feed flow and assumes all that flow (minus steam generator blowdown) is converted to steam flow, it instantly responds to changes in feed flow.

Evolutions/events that perturb feed flow or temperature, such as manual FRV control, SDAFW Pump flow, placing/removing Condensate Polishers in/from service, removing SIG Blowdown from service, or sudden changes in ambient temperature particularly associated with heavy rain will cause FWUFM to indicate power has increased, when in fact steam demand (which reactor power follows) hasnt changed.

11. Temporary conditions that affect OR known to cause power as calculated by LEFM to increase above 2339 MWth should be monitored by diverse redundant indications with no action for up to 5 minutes to allow LEFM to stabilize. IF at any time a diverse redundant power indication shows an actual transient, OR changes in Steam Flow, Steam Pressure, OR unexplained secondary annunciators, THEN action should be taken to maintain reactor power 2339 MWth using the Valve Position Limiter. Steam Flow Calorimetric is an effective tool to validate LEFM response. LEFM increases that are solely a result of increases in feed flow would not be seen as a power increase using Steam Flow Calorimetric. [R5] [R6]

12. IF questions arise concerning the validity of the COP calculation OR reactor power has exceeded the licensed power maximum of 2346 MWt, THEN contact Engineering AND initiate an NCR.[R11]

OMM-001-2 Rev. 70 Page 17 of 50

78. 055 EA2.O1 SRO 001 Given the following plant conditions:

- The plant is in MODE 5 with RHR Pump A in service.

- The SUT has failed and both EDGs have tripped.

Which ONE (1) of the following completes the statement below?

FCV-605 and HCV-758 will fail (2) and the conditions are required to be mitigated by implementing AOP-017, Loss of Instrument Air, Section C, RHR Aligned for Core Cooling, AND (1)

A. (1) SHUT (2) EPP-1, Loss of All AC Power B. (1) OPEN (2) EPP-1, Loss of All AC Power C. (1) OPEN (2) AOP-020, Loss of Residual Heat Removal (Shutdown Cooling)

Dv (1) SHUT (2) AOP-020, Loss of Residual Heat Removal (Shutdown Cooling)

J 10/13/2011 Page: 139 of 187

REVISE The correct answer is D.

A: Incorrect - Both FCV-605 and HCV-758 fail SHUT on loss of IA. AOP-017 will be entered for a loss of instrument air, which will eventually occur during a station blackout.

AOP-017 is a concurrent AOP, however, EPP-1 contains a note that explicitly states that Foldouts and concurrent AOP5 should not be implemented during EPP-1. Also, lAW OMM-022, Emergency Operating Procedures Users Guide, Attachment 10.1, EOP Applicability Table, EPP-1 is not applicable when RHR is in service.

B: Incorrect - Both FCV-605 and HCV-758 fail SHUT on loss of IA. AOP-017 would be entered for a loss of instrument air, which will eventually occur during a station blackout. AOP-017 is a concurrent AOP, however, EPP-1 contains a note that explicitly states that Foldouts and concurrent AOPs should not be implemented during EPP-1. Also, lAW OMM-022, Emergency Operating Procedures Users Guide, Attachment 10.1, EOP Applicability Table, EPP-1 is not applicable when RHR is in service.

C: Incorrect - Both FCV-605 and HCV-758 fail SHUT on loss of IA. Second part of distractor is correct.

D: Correct - Both FCV-605 and HCV-758 fail SHUT on loss of IA. AOP-017 would be entered for a loss of instrument air, which will eventually occur during a station blackout.

AOP-01 7 is a concurrent AOP, however, EPP-1 contains a note that explicitly states that Foldouts and concurrent AOPs should not be implemented during EPP-1. Also, lAW OMM-022, Emergency Operating Procedures Users Guide, Attachment 10.1, EOP Applicability Table, EPP-1 is not applicable when RHR is in service.

10/13/2011 Page: 140 of 187

Question 78 Tier/Group 1/1 K/A Importance Rating - RO 3.4 SRO 3.7 Ability to determine or interpret the following as they apply to a Station Blackout:

Existing valve positioning on a loss of instrument air system.

Reference(s) Sim/Plant design, AOP-017, Pages 3 and 36; SD-003, RHR, Figure 3.,

OMM-022.

Proposed References to be provided to applicants during examination None -

Learning Objective AOP-017-006 Question Source BANK (Similar question used on 2008 NRC Exam. The question format and distractors have been significantly modified.)

Question Cognitive Level H -

10 CFR Part 55 Content 43.5/45.13 Comments -

SRO: The candidate must have knowledge of administrative procedures that specify hierarchy, implementation, and/or coordination of plant normal, abnormal, and emergency procedures. OMM-022, Emergency Operating Procedures Users Guide, contains the instructions for the use of Emergency and Abnormal Operating Procedures.

10/13/2011 Page: 141 of 187

Rev. 32 AOP-020 LOSS OF RESIDUAL HEAT REMOVAL (SHUTDOWN COOLING)

Page 9 of 130 H STEP H INSTRUCTIONS I RESPONSE NOT OBTAINED

1. PURPOSE This procedure provides the instructions necessary to mitigate the loss of RHR in all conditions for which RHR can be aligned to provide shutdown cooling. This includes loss of RHR cooling for reasons such as RCS leakage, loss of power, loss of Service Water or Component Cooling Water, RHR pump cavitation, and inadequate RHR flow or abnormal reductions in RHR cooling.

This procedure is applicable in Modes 4, 5, and 6 when fuel is in the vessel. --

2. ENTRY CONDITIONS Direct entry from any condition resulting in a loss of RHR pump(s), RHR pump cavitatiDn, abnormal RHR flow or temperature control, loss of instrument bus, or excessive loss of RCS inventory while RHR is aligned for shutdown cooling.

As directed by the following other procedures:

AOP-005, Radiation Monitoring System, when a low level in the SFP exists due to an RCS leak with the SFP GATE VALVE open.

AOP-014, Component Cooling Water System Malfunction, resulting in stopping of the RHR Pumps while in CSD.

AOP-016, Excessive Primary Plant Leakage, if less than 200°F and leakage exceeds Charging Capacity.

AOP-0l7, Loss Of Instrument Air, if the loss of Instrument Air has affected core cooling while on RHR.

- END -

Rev. 40 AOP-017 LOSS OF INSTRUMENT AIR Page 28 of 68

STEP H INSTRUCTIONS SECTION C RESPONSE NOT OBTAINED IGNED F OR C O CO OL ING (Page 1 of 6)

Determine If IA Capacity Has Been Restored As Follows:

a. Check IA Header pressure: a. LE IA capacity is restored, THEN Go To Step 1.b.

GREATER THAN 85 PSIG Go To Step 2.

AND

STABLE DR RISING

b. Go To Attachment 4, Restoration From Loss Of Instrument Air Check RHR Flow Temperature LE RHR flow temperature Control - ADVERSELY AFFECTED BY control is affected, THEN LOSS OF IA perform Steps 3 and 4.

Go To Step 5.

Check RCS Temperature - LESS Control RCS temperature by THAN 212°F dumping steam using one of the following methods listed in order of preference:

a. Steam Dump to Condenser

b. Steam Line PORVs controlled by IA

c. Steam Line PORVs controlled by nitrogen using Attachment 2

d. Manually steam each intact

. S/C using Attachment 3 Perform AOP-O20, Loss Of Residual Heat Removal (Shutdown Cooling) While Continuing With This Procedure

5. Check RCS Status - SOLID PLANT Go To Step 8.

Rev. 40 AOP-017 LOSS OF INSTRUMENT AIR Page 36 of 68 ATTACHMENT 1 MAJOR COMPONENTS AFFECTED BY LOSS OF IA (Page 3 of 5)

6. Isolation Valve Seal Water System Components FAIL POSITION

a. PCV-1922 A & B, IVSW AUTO HEADER ISOLs - OPEN

7. Main Steam System Components FAIL POSITION

a. MAIN STEAM ISOLATION VALVES - CLOSED

b. STEAM LINE PORVs - CLOSED

8. Primary Sample System Components FAIL POSITION

a. PS-956 A through H, PRIMARY SAMPLE ISOLATIONS - CLOSED

9. Radiation Monitoring System Components FAIL POSITION

a. RMS-1,2.3 & 4, R-11/R-12 ISOL VALVES - CLOSED

10. Reactor Coolant System Components FAIL POSITION

a. PCV-455 A & B, PZR SPRAYS - CLOSED

b. RC-516 & 553, PRT TO GAS ANALYZER - CLOSED

c. RC-519 A & B, PW TO CV ISOs - CLOSED

d. RC-544, RV FLANGE LEAKOFF - OPEN

e. RC-550, PRT NITROGEN SUPPLY - CLOSED

11. Residual Heat Removal System Components FAIL POSITION

a. HCV-142, PURIFICATION FLOW - CLOSED

...._. b. HCV-758. RHR FIX DISCH FLOW - CLOSED

c. FCV-605. RHR FIX BYPASS FLOW - CLOSED

ATTACHMENT 10.1 Page 1 of 3 EOP APPLICABILITY TABLE PROCEDURE COMMENTS WHEN APPLICABLE PATH I > 350°F Assumes RHR System not in PATH 2 service and SI operable.

Modifications necessary if otherwise.

EPP-1

-2 EPP-3 EPP-22 EPP-25 EZ Modes including full power until RHR in service All modes Assumes RCS partly hot and pressurized. Problems with RCP seals are minimal if RCS is cold and depressurized.

EPP-25 can be used at any time desired to power equipment from the DSDG or to initiate backfeed.

EPP-4 Reactor Critical or at power Assumes trip from power.

Modifications necessary if otherwise.

EPP-5 >350° F Assumes hot (near no load)

EPP-6 conditions. Slight modification required if already in cooldown.

EPP-7 >350°F Assumes RHR System not in service. Modifications necessary if otherwise.

EPP-8 >350°F Assumes RHR System not in EPP-9 service; entry is limited by EPP-10 stated conditions.

EPP-Supplements Modifications necessary if otherwise.

EPP-11 >200°F Assu 0 212 mesT °F. h S/Gs will not steam if below boiling point.

EPP-Foldouts >200°F Applicability dependent upon procedures that provide entry conditions.

Condition at time of initiating event.

Rev. 35 Page 48 of 56 OMM-022

79. 058 AA2.03 SRO 001 The plant was operating at 100% RTP when the following indications are received:

- B RCP Red and Green lights extinguished.

- Reactor Trip Breaker B Red and Green lights extinguished.

- Channel #3 Reactor Protection Bistables illuminated.

- B MDAFW Pump Red and Green lights extinguished.

- Tave is being maintained at No-Load Value.

Which ONE (1) of the following identifies (1)the correct procedural progression and (2) the correct actions to be taken?

Enter PATH-I --> (1)

Request a crew to locally trip OCBs 52/8 AND 52/9, (2)

A (1) EPP-4, Reactor Trip Response --> EPP-27, Loss of DC Bus B (2) Isolate Letdown, Reduce charging to minimum, control pressurizer pressure using control and backup heaters and PCV-456, PZR PORV B. (1) EPP-4, Reactor Trip Response --> EPP-27, Loss of DC Bus B (2) Verify FCV-626 is open and then secure all charging pumps, control pressurizer pressure using control and backup heaters and normal spray flow C. (1) EPP-7, SI Termination --> EPP-27, Loss of DC Bus B (2) Isolate Letdown, Reduce charging to minimum, control pressurizer pressure using control and backup heaters and PCV-456, PZR PORV D. (1) EPP-7, SI Termination --> EPP-27, Loss of DC Bus B (2) Verify FCV-626 is open and then secure all charging pumps, control pressurizer pressure using control and backup heaters and normal spray flow Page: 142 of 187 10/13/2011

The correct answer is A.

A. Correct. The indications given indicate that a loss of DC Bus B has occurred.

When on normal plant electric plant lineup, a safety injection will not occur just due a loss of DC Bus B. EPP-4 will be performed until it directs the crew to transition to EPP-7. EPP-27 will direct the crew to isolate letdown, reduce charging flow and control pressure using heaters and PORV. Spray will be lost due to IA being isolated to the CV on a loss of DC Bus B.

B. Incorrect The first half of answer is correct. The second half is incorrect. Isolation of letdown has been omitted. Charging pumps will only be secured once PZR is greater than 71%. Also, normal spray flow is not available since PCV-1716 has failed closed isolating instrument air to containment.

C. Incorrect The first half is incorrect. A Safety Injection signal is not received on a loss of DC Bus B from a normal electric plant lineup. EPP-7, SI Termination, is an entry condition to EPP-27 if an SI had occurred. The second part of the distractor is correct.

D. Incorrect. The first half is incorrect. A Safety Injection signal is not received on a loss of DC Bus B from a normal electric plant lineup. EPP-7, SI Termination, is an entry condition to EPP-27 if an SI had occurred. The second half is incorrect. Isolation of letdown has been omitted. Charging pumps will only be secured once PZR is greater than 71%. Also, normal spray flow is not available since PCV-1716 has failed closed isolating instrument air to containment.

Question 79 Tier/Group 1/1 K/A Importance Rating - RO 3.5 SRO 3.9 Ability to determine and interpret the following as they apply to the Loss of DC Power:

DC loads lost; impact on ability to operate and monitor plant systems Reference(s) Sim/Plant design, EPP-417, EPP-27, Foldout H Proposed References to be provided to applicants during examination - None Learning Objective EPP-27-002 Question Source NEW-Question Cognitive Level H -

10 CFR Part 55 Content 43.5 /45.13 Comments -

SRO: Assessing plant conditions and then selecting a pr cedure or section of a 9

procedure to mitigate, recover, or with which to proceedi Candidate must also demonstrate knowledge of the content of the procedure.

Page: 143 of 187 10/13/2011

Rev. 28 EPP-4 REACTOR TRIP RESPONSE Page 4 of 30

__STEP_H ACTION/EXPECTED RESPONSE I RESPONSE NOT OBTAINED I

1. Verify Moisture Seperator IF a loss of power prevents Reheater Steam Valves - CLOSED isolation of the MSRs, THEN close the MSIVs AND MSIV BYPs.

NSR Shutoff Valves

MSR Purge Valves LE ANY Purge Shutoff Valve can NOT be closed from the RTGB AN1 RCS temperature is less than 540°F and lowering, close the MSIVs AND MSIV BYPs.

Locally close Open MSR Steam Valves

2. Determine If Procedure Exit Is Warranted:

a. Check Attack on RNP Site - IN a. Go To Step 3 PROGRESS

b. Check either of the below b. IF a total loss SW OR a loss events - IN PROGRESS of Lake Robinson Dam integrity occurs due to

Total Loss Of SW hostile action, THEN Go To EPP-28, Loss of Ultimate Heat OR Sink.

Loss Of Lake Robinson Dam Go To Step 3.

integrity

c. Go To EPP-28, Loss Of Ultimate Heat Sink

3. Check SI Signal - INITIATED SI initiation occurs during this procedure, THEN Go To Path-i, Entry Point A.

Go To Step 5.

4. Go To Path-i, Entry Point A

5. Perform The Following:

a. Reset SPDS

b. Initiate monitoring of Critical Safety Function Status Trees nFoldoutH

Rev. 28 EPP-4 REACTOR TRIP RESPONSE Page 16 of 30 STEP H ACTION/EXPECTED RESPONSE RESPONSE NOT OBTAINED I

25. Control SIG Levels As Follows:

a. Check S/G levels - ANY a. Perform the following:

GREATER THAN 8%

1) Establish FW Flow using one of the following:

Establish FW bypass flow greater than 6 pph.

0.2x10 OR

Establish AFW flow greater than 300 gpm.

2) WHEN S/G level is greater than 8%, JJIN perform Step 25.b.

3) Go To Step 26.

b. Control feed flow to maintain S/G levels - BETWEEN 39% AND GNERGIZEDEPP

27. Check All The Following EDG Perform the following:

Cooling Annunciators -

EXTINGUISHED a. Locally determine if a high temperature condition exists.

APP-010-E2, EDG A LUBE OIL HI/LO TEMP b. a high temperature condition exists, THEN

APP-0l0-E3, EDG B LUBE OIL shutdown the affected EDG.

HI/LO TEMP

APP-OlO-F2, EDG A COOL WTR HI/LO TEMP

APP-OlO-F3, EDG B COOL WTR HI/LO TEMP

Rev. 33 EPP-Foidouts FOLDOUTS Page 19 of 23 FOLDOUT H (Page 1 of 4)

1. SI ACTUATION CRITERIA IF EITHER condition below occurs, THEN Actuate SI and Go To PATH-i, Entry Point A:

RCS Subcooling - LESS THAN 35°F [55°F]

PZR Level CAN NOT BE MAINTAINED GREATER THAN 10% [32%]

Rev. 33 EPP-Eoldouts FOLDOUTS Page 20 of 23 FOLDOUT H (Page 2 of 4)

2. DC BUS OR INSTRUMENT BUS FAILURE CRITERIA

a. DC Bus failure has occurred. THEN perform the following:

1) DC Bus A fails. THEN perform the following:

a) In the Charging Pump Room, Open CVC-358, RWST TO CHARGING PUMP SUCTION.

b) WHEN CVC-358 is open, close LCV-ll5C, VCT OUTLET from RTGB.

c) In the E-l/E-2 Room, transfer Instrument Bus 2 to MCC-8.

d) In the 4160V Bus Room, trip the Exciter Field Breaker.

e) In EDO A Room perform the following:

Trip EDO A Fuel Racks.

Close DA-21A AND DA-25A, DO A t AIR START OUTLET ISOLATION valves.

2) IF DC Bus B fails, THEN perform the following:

a) In the E-l/E-2 Room, transfer Instrument Bus 3 to MCC-8.

b) In EDO B Room, perform the following:

Trip EDO B Fuel Racks.

Close DA-21B AND DA-25B, DO B AIR START OUTLET ISOLATION valves.

c) Close LCV-460 A & B, LTDN LINE STOPs.

b. j NCC-5 is de-energized, THEN transfer power source to OS Bus using the posted instructions at the Kirk Key Interlocked Breakers.

(CONTINUED NEXT PAGE)

Rev. 33 EPP-Foldouts FOLDOUTS Page 21 of 23 FOLDOUT H (Page 3 of 4)

2. (CONTINUED)

c. IF Instrument Bus failure has occurred. THEN perform the following:

1) IF Instrument Bus 4 fails, ThM maintain Steam Dump in the Tavg Mode of operation.

2) IF a failure of only QIW of the below Instrument Busses occurs, THEN transfer the failed bus to MCC-8.

Instrument Bus 1

Instrument Bus 2

lostrument Bus 3

Instrument Bus 4

3) IF more than ONE Instrument Bus requires transfe r to MCC8 for Nuclear Safety Concerns, THEN strip the affecte d Busses using Attachment 13 of AOP-O24, Loss of Instrument Bus.

prior to transferring the Buss(es) to MCC-8.

3. LOSS OF RCP SEAL COOLING CRITERIA IE both th conditions below are met. THEN perform AOP-Ol8, Reactor Coolant Pump Abnormal Conditions to restore RCP Seal Cooling:

APP-OO1-B2, LABYRINTH SEAL LOW AP - ILLUMINATED AND

APP-OOl-Dl, THERMAL BARRIER LO FLOW - ILLUMINATED

EPP-Foldouts Rev. 33 FOLDOUTS Page 22 of 23 FOLDOUT H (Page 4 of 4)

4. EMERGENCY COOLING WATER SWITCHOVER CRITERIA normal cooling is lost to any of the following components. ThEN estaiDlish emergency cooling water using the referen ced procedure:

Charging Pump Oil Coolers - Use Attachment 1 of AOP-014.

Component Cooling Water System Malfunction.

MDAFW Pumps - Use Attachment 2 of AOP-022, Loss of Service Jater.

5. AFW SUPPLY SWITCHOVER CRITERIA I]? CST level lowers to less than 10%,

ThM switch to backup water supply using OP-402. Auxiliary Feedwater System.

- END -

Rev. 13 EPP-27 LOSS OF DC BUS B Page 4 of 30 STEP H INSTRUCTIONS RESPONSE NOT OBTAINED Check Electrical Status At Time Go To Step 3.

DC Power Was Lost - UNIT SYNCHRONIZED TO THE GRID

2. Inform Load Dispatcher Of The Following:

A loss of DC Control Power has occurred Switchyard DCBs 52/8 AJi 52/9 have failed to trip Backup relaying has caused a North Bus Lock Out which tripped the following Switchyard Circuit Breakers:

52/3, ROCKINGHAM 230KV

52/6. #1 230-115KV BANK 230KV

52/7, DARLINCTON SCPSA 230KV

52/12, DARLINGTON COUNTY PLANT SOUTH 23 0KV

52/14, DARLINGTON COUNTY PLANT NORTH 230KV (3 Request that Load Dispatcher send a Maintenance Crew to locally trip OCBs 52/8 J!

52/9 Check The Cause Of The DC Bus WHEN the cause is determined, Failure KNOWN notify Maintenance to

.-)

correct the problem.

Observe the NO nor to Step 4 and Go To Ste 4.

Rev. 13 EPP-27 LOSS OF DC BUS B Page 5 of 30

STEP H INSTRUCTIONS I I RESPONSE NOT OBTAINED NOTE AFW PUMP B will not be available due to loss of control power to the breaker.

Maintain S/C Levels Becween 8%

And 50% Using Available AFW Pumps:

AFW PUMP A

STEAM DRIVEN AFW PUMP C1ose LCV-460A & B, LTDN LINE 6 Locally Perform Attachment 2 To Restore Power To 4160V AND 480V Busses While Continuing With This Procedure

Rev. 13 EPP-27 I51 LOSS OF DC BUS Page 6 of 30 H STEP H INSTRUCTIONS RESPONSE NOT OBTAINED CAUTION FCV-626 fails closed on a loss of DC Bus B. Seal injection flow is required for RCP Seal Cooling.

- - - ******* ** t t* * * * * * * ** * ** ****** ****** *** **** ** * ****** * ** *** ****** *** * ***

NOTE Instrument Air to the CV is isolated (IA PCV-1716 fails closed) This results in a loss of all PER Spray ANII Letdown. The following steps will control PER level and pressure.

} Lower Charging Flow To Minimum As Follows:

Stop all but one Charging Pump Verify the running Charging Pump Speed Controller in AUTO:

Pump A: SC-l51

Pump B: SC-l52

Pump C: SC-153

Rev. 13 EPP-27 LOSS OF DC BUS B Page 7 of 30 J STEP H INSTRUCTIONS RESPONSE NOT OBTAINED Check RCP Seal Injection Flow - Locally throttle RCP SEAL WATER BETWEEN 8 GPM AND 13 GPM FLOW CONTROL VALVE(s) to obtain flow to each RCP between 8 gpm and 13 gpm.

CVC-297A

CVC-297B

CVC-297C IF required to maintain minimum flow, THEN throttle HIC-121, CHARGING FLOW Valve while maintaining Charging Pump Discharge pressure less than 2500 PSIG.

j the normal Seal Injection Range can NPJ be maintained, an expanded range of between 6 gpin and 20 gpm may be used.

Verify The Following:

a. PCV-456. PZR PORV - IN AUTO

b. RC-535, PORV BLOCK - OPEN

10 Maintain PZR Pressure At Desired Pressure As Follows:

a. Raise pressure as necessary using Control AND Backun Heaters

b. Check PZR Pressure - LESS b. Verify PCV-456, PZR PORV.

THAN 2335 PSIG opens to maintain pressure less than 2335 psig.

WHEN pressure is less than 2335 psig. THEN verify the PORV recloses.

Rev. 13 EPP-27 LOSS OF DC BUS B Page 8 of 30 H STEP H INSTRUCTIONS I RESPONSE NOT OBTAINED CAUTION Starting duty limitations allow only 4 Charging Pump starts per hour and require a minimum of 5 minutes between sLarts.

- - - *** **** t**** t* * * * ** *** * *t**** *** *** * ** ****** * ****** *** *** *** ***

11 Check PER Level - GREATER THAN WHEN PER level Is GreaLer Than 71% 71%, THEN observe the NIJ prior to Step 12 and perform Steps 12 and 13 Go To Step 14.

NOTE FCV-626 will have to be manually opened due to failing closed on a loss of DC Bus B. Seal injection flow is required for RCP Seal Cooling.

12. Check APP-00l-Dl, RCP THERM EAR Perform the following:

COOL WTR LO FLOW - EXTINGUISHED

a. Verify at least one CCW Pump RUNNING.

b. Verify the following CCW valves are UPEN:

CC-716A, CCW TO RCP ISO

CC-716B. CCW TO RCP ISO

CC-735, THERM BAR OUT ISO

CC-730, ERG OUTLET ISO

FCV-626, THERM BAR FLOW CONT

Rev. 30 EPP-7 SI TERMINATION Page 5 of 3]

-ii-i INSTRUCTIONS 1 1 RESPONSE NOT OBTAINED

4. Reduce SW Pressure As Follows:

a. Check number of SW Pumps a. personnel are available.

Running - GREATER THAN 2 THEN locally perform Attachment 3, Throttling CCW Heat Exchanger SW Valves while continuing with this procedure.

Go To Step 5.

b. Stop 1 Pump

c. Check SW Header Pressure c. Go To Step 4.e.

GREATER THAN 50 PSIG

d. Go To Step 4.a

e. Check SW Header pressure e. WHEN personnel are available.

GREATER THAN 40 PSIG THEN locally perform Attachment 3, Throttling CCW Heat Exchanger SW Valves while continuing with this procedure

5. Check DC Busses A N] B - Go To the appropriate procedure:

ENERGIZED

DC Bus A - EPP-26. LOSS OF DC BUS A

DC Bus B - EPP-27. LOSS OF DC BUS B

80. W/E 04 EG2.4.3 SRO 001 The Plant has experienced a LOCA Outside of Containment and the crew has implemented PATH-i and transitioned to EPP-20, LOCA Outside Containment.

Which ONE (1) of the following completes the statement below?

From the instruments listed below, (1) are the Reg. Guide 1 .97 (PAM) instruments that will be utilized by EPP-20 to diagnose and mitigate the accident and the conditions of ITS LCO 3.3.3, Post Accident Monitoring (PAM) Instrumentation are (2)

P1-455, PZR Pressure - 1750 psig and lowering P1-456, PZR Pressure - 1725 psig and lowering P1-457, PZR Pressure - Failed LOW P1-51 1AA, RCS Wide Range Pressure - 1750 psig and lowering P1-511 BA, RCS Wide Range Pressure - 1750 psig and lowering P1-402, RCS Wide Range Pressure - 1725 psig and lowering P1-501, RCS Wide Range Pressure - Failed LOW LT-459, PZR Level Transmitter - 5% and lowering LT-460, PZR Level Transmitter - 5% and lowering LT-461, PZR Level Transmitter - 5% and lowering (REFERENCE PROVIDED)

A. (1) P1-455, 456, 457, 402, 501, LT-459, 460, 461 (NOT PI-511AA, 511BA)

(2) NOT met B. (1) P1-455, 456, 457, 402, 501 (NOT LT-459, 460 ,461, PI-511AA, 5I1BA)

(2) NOT met C (1) P1-Si 1AA, 511BA, 402, 501 (NOT LT-459, 460 ,461, P1-455, 456, 457)

(2) met D. (1) PI-51IAA, S11BA, LT-459, 460,461 (NOT P1-455, 456, 457,402, 501)

(2) met Page: 144 of 187 10/13/2011

The correct answer is C.

A. Incorrect. P1-455,456,457 are not Reg. Guide 1.97 instruments. EPP-20 only uses pressure indication only as a means of diagnosis and mitigation for LOCA Outside Containment. As sections of systems are isolated RCS pressure is monitored to see if a rising trend is observed. Plausible if the candidate thinks that P1-402 and P1-501, which are Reg Guide 1.97, are the instruments credited for in ITS 3.3.3. The bases for ITS 3.3.3 states that the RCS Pressure (Wide Range) instruments are the indications from the Inadequate Core Cooling Monitor. P1-402 and P1-501 are not part of the ICCM and are therefore not credited in ITS 3.3.3.

B. Incorrect. See discussion A above.

C. Correct. P1-51 1AA, 511 BA, 402 and 501 are the only Reg. Guide 1.97 instruments listed in the stem of the question. EPP-020 only uses RCS pressure as an indication to determine if actions to isolate the LOCA have been successful. ITS LCD 3.3.3 requires that 2 RCS Wide Range Pressure instruments be operable. The bases for ITS 3.3.3 states that the RCS Pressure (Wide Range) instruments are the indications from the Inadequate Core Cooling Monitor. P1-402 and P1-501 are not part of the ICCM and are therefore not credited in ITS 3.3.3.

D. Incorrect. See distractor A discussion. The second half of the distractor is correct.

, Question 80 Tier/Group 1/1 K/A Importance Rating - RD 3.7 SRO 3.9 LOCA Outside Containment: Ability to identify post-accident instrumentation.

Reference(s) Sim/Plant design, EPP-20, OMM-007, TMM-026, ITS LCD 3.3.3 and bases.

Proposed References to be provided to applicants during examination ITS 3.3.3 Learning Objective -EPP-20-004 Question Source NEW-Question Cognitive Level H -

10 CFR Part 55 Content 41.6 / 45.4 Comments K/A match because candidate must know which instruments listed are utilized in EPP-20 and what the requirements are for PAM instrumentation operability.

SRO: Candidate must demonstrate knowledge of TS bases that is required to analyze TS required actions and terminology. The TS bases is the only document that specifies that the Wide Range Pressure indication on the ICCM are the ITS 3.3.3 credited RCS pressure indications.

Page: 145 of 187 10/13/2011

81. W/EO5EA2.1 SRO 001 Given the following plant conditions:

- Plant is operating at 100% RTP.

- A feedwater break occurs inside containment.

- Containment pressure reached 4.2 psig and is currently 3.5 psig and lowering.

- AFW flow CANNOT be established.

- The crew has transitioned from PATH-i to FRP-H.1, Response to Loss of Secondary Heat Sink.

- S/G conditions: S/G Level (WR)

A 10%

B 19%

C 18%

Which ONE (1) of the following completes the statement below?

Transition to the RCS Bleed and Feed steps of FRP-H.1 (1) required.

The NEXT action required to be performed by the crew will be to (2)

A. (1)is (2) initiate a safety injection signal B (1) is (2) stop all RCPs C. (1) is NOT (2) verify all S/G blowdown and sample isolation valves - CLOSED D. (1) is NOT (2) check that the AFW lines are intact Page: 146 of 187 10/13/2011

The correct answer is B.

A. Incorrect. The first part is correct. The RCPs are to be secured immediately due to a loss of heat sink. Initiation of a safety injection signal is the second action the crew will take when establishing bleed and feed.

B. Correct.

C. Incorrect. Adverse numbers exist. Transition to bleed and feed are any two S/G wide range levels less than 10% [19%]. Two steam generators are less than 19%,

therefore bleed and feed is required. The second half would be correct had bleed and feed not been required.

D. Incorrect. Adverse numbers exist. Transition to bleed and feed are any two SIG wide range levels less than 10% [19%]. Two steam generators are less than 19%,

therefore bleed and feed is required. The second half would have been the second action the crew would have taken had bleed and feed not been required.

Question 81 Tier/Group 1/1 K/A Importance Rating - RO 3.4 SRO 4.4 Ability to determine and interpret the following as they apply to the (Loss of Secondary Heat Sink): Facility conditions and selection of appropriate procedures during abnormal and emergency operations.

Reference(s) Sim/Plant design, FRP-H.1, OMM-022 Proposed References to be provided to applicants during examination - None Learning Objective FRP-H.1-001, -004 Question Source NEW-Question Cognitive Level H -

10 CFR Part 55 Content 43.5 / 45.13 SRO: The candidate must assess the given plant conditions during the emergency given and the determine is a given section is applicable. This is equivalent to the knowledge of diagnostic steps and decision points in the EOP network that involves transitions to event specific sub-procedures or emergency contingency procedures.

Page: 147 of 187 10/13/2011

Rev. 24 FRP-H.1 RESPONSE TO LOSS OF SECONDARY HEAT SINK Page 4 of 45 f__STEP H INSTRUCTIONS I f RESPONSE NOT OBTAINED I

- - - - t***-******** ****************************************

CAUTION Peed flow is not re-established to any faulted S/C if an intact SIG is available.

Total Feed Flow - LESS Go To St

ØCheck THAN 300 GPN DUE TO OPERATOR ACTION

2. Reset SPDS And Return To Procedure And Step In Effect 0 Determine If Secondary Heat Sink Is Required As FDllows:

a. Check RCS pressure - GREATER a. Reset SPDS and Go To PATH-i, THAN ANY NON-FAULTED S/G Entry PoinL C.

PRESSURE

b. Check RCS temperature - b. Perform the following:

GREATER THAN 350°F [310°F]

1) Place RHR System in service using Supplement I.

2) WJ+/-N adequate cooling with RHR is established, THEN reset SPDS and return to procedure and step in effect.

Check Any Two S/G Wide Range any two S/G Wide Range Levels Levels - LESS THAN 10% lower to less than 10% [19%]

IN Go To Step 5.

VI YJ Go To Step 6.

5 Perform The Following:

pallRPs

b. Observe CAUTION prior to Step 31 and Co To SLep 31

H STEP H INSTRUCTIONS I I RESPONSE NOT OBTAINED

29. Determine If Condensate Flow Is Adequate:

a. Check the following: a. Go To Step 30.

Core Exit TIC temperature

- LOWERING OR

SIG Wide Range level -

RISING IN AT LEAST ONE SIC

b. Maintain FW flow to restore S/C level to greater than 8%

[18%]

c. Reset SPDS And Return To Procedure And Step In Effect

30. Any Two SIC Wide Range Levels - TE FW flow is restored during LESS THAN 10% [19%] steps prior to step 31, THEN Go To Step 28.

Go To Step 3.

CAUTION Steps 31 through 35 must be performed quickly in order to establish RCS heat removal by RCS bleed and feed.

8.3.13 Incorrect EOP Transition

1. Should the Operator determine that he is in an incorrect Path or EPP, he has two options:

If the incorrect transition is immediately recognizable AND no alterations of the WOG mitigative strategy have occurred, he may move back to the point in the Network where the incorrect transition has occurred.

If the incorrect transition is not immediately recognizable OR alterations in the mitigative strategy have occurred, the Operator should move to Path-i, Entry Point A, and start over.)

2. During the rediagnosis described above, complete reactuation of the Engineered Safety Features is allowed, but not required.

Reactuation of necessary safety features during rediagnosis is guided by the requirements of the applicable Foldout and Operator judgement based on the symptoms present.

8.3.14 Adverse Containment Conditions Usage

1. When adverse containment conditions develop, the use of adverse containment condition setpoints shall be initiated.

2. The use of adverse containment condition setpoints shall be maintained from that point forward, even when adverse containment conditions no longer exist.

3. An adverse containment condition setpoint may or may not be provided. The operator shall use a setpoint with no brackets if no setpoint within brackets is provided, even if adverse containment conditions exist.

8.3.15 Special EPP Priority

1. Certain contingency EPPs take precedence over FRPs because of their treatment of specific initiating events. In all such cases, this precedence is identified in a CAUTION or NOTE at the beginning of the EPP.

OMM-022 Rev. 35 Page 40 of 56

ATTACHMENT 10.4 Page 1 of 3 GLOSSARY 1.1 Definitions 1.1.1 Adverse Containment Conditions If the CV pressure is greater than or equal to 4 psig, then adverse containment conditions exist. When adverse setpoints are provided, they will be enclosed by brackets: [ j.

1.1.2 Core Cooling Mode When referenced for the current status of the RHR System, the system is aligned to remove decay heat via the normal pathway from RCS loop B hot leg back through RHR to the loop cold legs.

1.1.3 Diverse (In reference to an indication) Having multiple indications of different types for indication of the same parameter. An example of diverse indications for the same parameter would be the use of SIG level increase, as well as AFW Line Flow Indication to verify that AFW Flow exists.

1 .1.4 Go To An action verb requiring the operator to leave the procedure or step currently in effect and implement the referenced procedure or step.

The operator does not return to the EOP or AOP unless explicitly directed to by the procedure transitioned to.

1.1.5 Injection Mode When referenced for the current status of the RHR System, the system is aligned to take a suction on the RWST and discharge to the loops. (Normal at-power RHR line up) 1.1.6 Normal Describes a condition in which the parameter under consideration is within a range that can be expected during routine plant operation or is being controlled in accordance with approved plant procedures. When making this determination previous trends should be used. (RAIL 94R0296) 1.1.7 Nuclear Safety Concern A condition is said to have a Nuclear Safety Concern when that condition has the possibility of jeopardizing the health and/or safety of the public to the extent that the SM determines that action is needed to mitigate the condition.

1.1.8 Perform An action verb directing the operator to accomplish certain actions using the referenced procedure and implicitly requiring the operator to remain in the procedure in effect. This action may be reinforced by the statement, while continuing with this procedure.

OMM-022 Rev. 35 Page 54 of 56

82. W/EOJ5EG2.1.32SR0001 Given the following plant conditions:

- A seismic event has lead to a LOCA and rupture of SW piping in the CV.

- PATH-i completed to the point of transition to another procedure.

- Only one train of CV Spray is operating properly.

- The following conditions exist in Containment:

- Containment Pressure is 24 psig and rising.

- Containment Sump Level is 385 inches and rising.

Which ONE (1) of the following completes the statement below?

Based on the current conditions, containment (1) is the highest priority and the basis for this is (2)

A. (1) pressure (2) one train of CV Spray cannot maintain pressure below the containment design pressure B. (1) pressure (2) one train of CV Spray along with loss of SW in containment cannot maintain pressure below the containment design values C (1) level (2) potential flooding of critical systems and components needed for future plant recovery may occur D. (1) level (2) dilution of sump water with SW may potentially cause a return to criticality The correct answer is C.

A. Incorrect. As long as one train of CV spray is operating containment pressure will not become the top priority until pressure reaches 42 psig. Since above 10 psig, the operator is sent to a section in the CSFSTs that verifies adequate spray flow.

B. Incorrect. As long as one train of CV spray is operating containment pressure will not become the top priority until pressure reaches 42 psig. Since above 10 psig, the operator is sent to a section in the CSFST5 that verifies adequate spray flow.

C. Correct.

D. Incorrect. The first half of distractor is correct. The basis for FRP-J.2, Containment Flooding, does NOT address reactivity as a concern. The rupture of SW will cause a dilution of the CV Sump water.

Page: 148 of 187 10/13/2011

Question 82 Tier/Group 1/1 K/A Importance Rating - RO 3.8 SRO 4.0 Containment Flooding: Ability to explain and apply system limits and precautions.

Reference(s) Sim/Plant design, CSFST, FRP-J.1 / J.2, FRP-J.2BD Proposed References to be provided to applicants during examination - None Learning Objective FRP-J.2-002, --3 Question Source NEW-Question Cognitive Level H -

10CFRPart55Content- 41.10/43.2/45.12 L

7 SRO,)Candidate must know the nerarchy of the Critical Safety Function Status Trees whpecLtocontainment parameters Candidate must also know the bases for this functional restoration procedure.

Page: 149 of 187 10/13/2011

C Progress Energy Continuous Use H. B. ROBINSON STEAM ELECTRIC PLANT, UNIT NO. 2 PLANT OPERATING MANUAL VOLUME 3 PART 4 Emergency Operating Procedure CSFST CRITICAL SAFETY FUNCTION STATUS TREES REVISION 4 CSFST Rev. 4 Page 1 of 9

CSF-5, CONTAINMENT ENTER GO TO FRP-J.1 CSFST Rev. 4 Page 8 of 9

CONTINUOUS USE H. B. ROBINSON STEAM ELECTRIC PLANT, UNIT NO. 2 PLANT OPERATING MANUAL VOLUME 3 PART 4 FUNCTION RESTORATION PROCEDURE FRP-J.1 RESPONSE TO HIGH CONTAINMENT PRESSURE REVISION S Page 1 of 8

Rev. 8 FRP-J.l RESPONSE TO HIGH CONTAINMENT PRESSURE Page 3 of 8 Purpose and Entry Conditions (Page 1 of 1)

1. PURPOSE This procedure provides actions to respond to high containment pressure.

2. ENTRY CONDITIONS CSF-5, Containment Critical Safety Function Status Tree on a RED.

ORANGE or YELLOW condition.

- END -

Rev. 8 FRP-J.1 RESPONSE TO HIGH CONTAINMENT PRESSURE Page 4 of 8

STEP H INSTRUCTIONS RESPONSE NOT OBTAINED

1. Check CONTAINMENT ISOLATION Perform the following:

PHASE A Valves - CLOSED

a. Momentarily depress either of the CONTAINMENT ISOLATION Pushbuttons.

b. i any CONTAINMENT ISOLATION PHASE A Valve fails to close, THEN locally isolate the affected penetration.

2. Check CONTAINMENT VENTILATION Perform the following:

ISOLATION Valves - CLOSED

a. Momentarily depress either of the CONTAINMENT ISOLATION Pushbuttons.

b. j any CONTAINMENT VENTILATION ISOLATION Valve fails to close, THEN locally isolate the affected penetration.

3. Check CV Pressure - HAS RISEN TO Return to procedure and step in GREATER THAN 10 PSIG effect.

4. Determine Availability Of CV Spray As Follows:

a. Check CV Spray - BEING a. Go To Step 5.

CONTROLLED BY EPP-15. LOSS OF EMERGENCY COOLANT RECIRCULATION

b. Go To Step 7

5. Check Spray Additive Tank Level Verify Spray Additive Tank

- GREATER THAN 0% isolated as follows:

. SI-845A, SAT DISCH. CLOSED

SI-8453, SAT DISCH. CLOSED

SI-845C, SAT THROTTLE VALVE.

CLOSED

Rev. 8 FRP-J.1 RESPONSE TO HIGH CONTAINMENT PRESSURE Page 5 of 8

STEP H INSTRUCTIONS RESPONSE NOT OBTAINED

6. Establish CV Spray As Follows:

a. Verify OPEN CV Spray Pump Inlet Valves:

SI-844A

SI-844B

b. Verify both CV Spray Pumps -

RUNNING

c. Verify OPEN the following Containment Spray Valves:

SI-845A, SAT DISCH

SI-845B, SAT DISCH

SI-88OA. PUMP A DISCH

51-8803, PUMP A DISCH

SI-88OC, PUMP B DISCH

SI-880D, PUMP B DISCH

d. Check Spray Additive Tank d. Adjust SI-845C, SAT flow - APPROXIMATELY 12 GPM THROTTLING to obtain approximately 12 gpm Spray Additive Tank flow.

7. Verify CONTAINI1ENT ISOLATION PHASE B Valves - CLOSED

8. Verify All RCPs - STOPPED

9. Verify CV AIR RECIRC COOLERs -

RUNNING HVI-1-l

HVH-2

HVH-3

HVH-4

Rev. 8 FRP-J.1 RESPONSE TO HIGH CONTAINNENT PRESSURE Page 6 of 8

STEP H INSTRUCTIONS RESPONSE NOT OBTAINED

10. Verify The Following:

a. All MSIV AND MSIV BYP Valves

- CLOSED

b. All MSIV Control Switches -

SELECTED TO CLOSE

11. Check S/G SL:acus - AT LEAST ONE Perform Lhe following:

INTACT

a. Maintain feed flow to each S/G between 80 gpm and 90 gpm.

b. Go To Step 13.

CAUTION At least one S/G must be maintained available for RCS coolcio wn.

- - - - t* ******* * * **

12. Determine If Any S/G Is Faulted As Follows:

a. Check pressures in all S/Gs: a. Go To Step 13.

ANY S/G PRESSURE LOWERING IN AN UNCONTROLLED MANNER OR

ANY S/G COMPLETELY DEPRES SURI ZED

b. Isolate affected S/C(s) using EPP-SIIPPLEMENTS. Supplement 0, S/G Isolation

13. Reset SPDS AND Return To Procedure And Step In Effect

- END -

FRP-J.1 Rev. 8 RESPONSE TO HIGH CONTAINMENT PRESSURE Page 7 of 8 1A Continuous Action Steps (Page 1 of 1)

Main Body

5. Check Spray Additive Tank Level - GREATER THAN 0%.

WHEN tank level reaches 0%, THEN isolate tank.

Rev. 8 FRP-J.1 RESPONSE TO HIGH CONTAINMENT PRESSURE Page 8 of 8 lB Continuous Action Steps (Page 1 of 1)

Main Body

5. Check Spray Additive Tank Level - GREATER THAN 0%.

WHEN tank level reaches 0%, THEN isolate Lank.

CONTINUOUS USE CAROLINA POWER AND LIGHT COMPANY H. B. ROBINSON SEG PLANT PLANT OPERATING MANUAL VOLUME 3 PART 4 FUNCTION RESTORATION PROCEDURE FRPJ.2 RESPONSE TO CONTAINMENT FLOODING REVISION 3 RECOMMENDED BY:

Procedure Coordinator

/94 Date APPROVED BY: 474/76 Manager - Operations Date Page 1 of 7

Rev.3 FRP-J.2 RESPONSE TO CONTAINMENT FLOODING Page 3 of 7 1.0 PURPOSE This procedure provides actions to respond to containment flooding.

2.0 ENTRY CONDITIONS CSF-5, Containment Critical Safety Function Status Tree on an ORANGE condition.

Rev. 3 FRP-J.2 RESPONSE TO CONTAINMENT FLOODING Page 4 of 7 H STEP H INSTRUCTIONS I I RESPONSE NOT OBTAINED

1. Check Any S/G - FAULTED QE Go To Step 3.

RUPTURED

2. Verify Any Faulted Q. Ruptured S/G - ISOLATED USING SUPPLEMENT G

3. Determine If A CCW Leak Exists Go To Step 5.

As Follows:

Check CCW Surge Tank level -

DECREASING OR

Check excessive makeup required to maintain CCW Surge Tank Level stable

4. Isolate CCW To Containment As Follows:

a. Verify All RCPs STOPPED

b. Locally close CC-737A, CCW SUPPLY TO EXCESS LETDOWN HEAT EXCHANGER Valve

c. Verify the following CCW Containment Isolation Valves

- CLOSED:

CC-739, CCW FROM EXCESS LTDN HX

CC-7l6A, CCW TO RCP ISO

CC-716B, CCW TO RCP ISO

CC-626, THERMAL BAR FLOW CONT

CC-730, BRG OUTLET ISO

CC-735, THERMAL BAR OUT ISO

Rev. 3 FRP-J.2 RESPONSE TO CONTAINMENT FLOODING Page 5 of 7 STEP H INSTRUCTIONS I I RESPONSE NOT OBTAINED I

5. Determine If A Fire Water Leak Verify The Following Fire Water Exists As Follows: Containment Isolation Valves -

CLOSED:

Check APP-044-C55, E.D. FIRE PUMP RUNNING - CLEAR

FP-256, RCP SPRINKLER ISOLATION VALVE AND

FP-258, RCP SPRINKLER

Check APP-044-C58, M.D. FIRE ISOLATION VALVE PUMP RUNNING CLEAR

FP-248, ELECT PENETRATION CV ISOLATION

FP-249, ELECT PENETRATION CV ISOLATION

6. Verify The Following Primary Water Containment Isolation Valves - CLOSED:

RC-519A, PW TO CV ISO

RCSl9B, PW TO CV ISO

Rev. 3 FRP-J.2 RESPONSE TO CONTAINMENT FLOODING Page 6 of 7 STEP H INSTRUCTIONS RESPONSE NOT OBTAINED

7. Perform The Following To Identify An HVH Cooler Leak:

a. Check APP-002-A8, HVH-l WTR a. Perform the following to OUTLET FLOW LO Alarm -

isolate SW flow to HVH-l:

EXT INGUI SHED

1) Verify HVH-l, CV RECIRC FAN is STOPPED.

2) Verify the following valves are CLOSED:

V6-33A, SW INLET

V6-34A, SW OUTLET

V6-35A, WTR SAMPLING

b. Check APP002-B8, HVH-2 WTR b. Perform the following to OUTLET FLOW LO Alarm -

isolate SW flow to HVH-2:

EXTINGUISHED

1) Verify HVH-2, CV RECIRC FAN is STOPPED.

2) Verify the following valves are CLOSED:

V6-33B, SW INLET

V6-34B, SW OUTLET

V6-35B, WTR SAMPLING

V6-33F, SELECTIVE INLET

c. Check APP-002-C8, HVH-3 WTR c. Perform the following to OUTLET FLOW LO Alarm -

isolate SW flow to HVH-3:

EXTINGUISHED

1) Verify HVH-3, CV RECIRC FAN is STOPPED.

2) Verify the following valves are CLOSED:

V6-33C, SW INLET

V6-34C, SW OUTLET

V6-35C, WTR SAMPLING (CONTINUED NEXT PAGE)

Rev. 3 FRP-J.2 RESPONSE TO CONTAINMENT FLOODING Page 7 of 7 STEP H INSTRUCTIONS I I RESPONSE NOT OBTAINED

7. (CONTINUED)

d. Check APP-002-D8, HVH-4 WTR d. Perform the following to OUTLET FLOW LO Alarm - isolate SW flow to HVH-4:

EXTINGUI SHED

1) Verify HVH-4, CV RECIRC FAN is STOPPED.

2) Verify the following valves are CLOSED:

V6-33D, SW INLET

V6-34D, SW OUTLET

V6-35D, WTR SAMPLING

V6-33E, SELECTIVE INLET

8. Notify Chemistry To Sample The Contact Plant Operations Staff RHR System To Determine CV Sump to determine method for sampling Water Activity CV Sump.

9. Notify Plant Operations Staff Of Containment Water Level AND Activity Level To Obtain Recommended Actions

10. Reset SPDS AND Return To Procedure And Step In Effect

- END -

83. 037 AG2.4.41 SRO 001 Given the following plant conditions:

- The plant is at 100% RTP.

- A tube leak is identified in C SIG.

- Two charging pumps running at maximum speed are able to control and stabilize PZR level with one 45 gpm letdown orifice in service.

- Total RCP Seal Leakoff flow is 7.5 gpm.

Which ONE (1) of the following completes the statement below?

The required action to address this condition is to (1) and EAL Classification for this event is (2)

AOP-035, S/G Tube Leak GP-006-1, Normal Plant Shutdown from Power Operation to Hot Shutdown.

(REFERENCE PROVIDED)

A. (1) Shutdown the plant lAW GP-006-1 while concurrently performing AOP-035 (2) Unusual Event SU6.1, RCS leakage B (1) Shutdown the plant lAW GP-006-1 while concurrently performing AOP-035 (2) Alert FA1 .1, Any loss or any potential loss of either Fuel Clad or RCS C. (1) Isolate C S/G lAW AOP-035 and then commence a plant shutdown lAW GP-006-1 (2) Unusual Event 5U6.1, RCS leakage D. (1) Isolate C S/G lAW AOP-035 and then commence a plant shutdown lAW GP-006-1 (2) Alert FA1 .1, Any loss or any potential loss of either Fuel Clad or RCS Page: 150 of 187 10/13/2011

The correct answer is B.

A. Incorrect. The first half of distractor is correct. The EAL classification is incorrect because the leak rate given is greater than the capacity of one charging pump. A UE would be valid up to primary to secondary leak rate of 77 gpm.

B. Correct.

C. Incorrect. Isolation of the SIC is not a prerequisite to commencing the plant shutdown. However in some cases the crew may progress through AOP-035 SIG isolation prior to actually starting the shutdown. The EAL classification is incorrect because the leak rate given is greater than the capacity of one charging pump. A UE would be valid up to primary to secondary leak rate of 77 gpm.

D. Incorrect. Isolation of the SIG is not a prerequisite to commencing the plant shutdown. However in some cases the crew may progress through AOP-035 SIG isolation prior to actually starting the shutdown. The second half of the distractor is correct.

Question 83 Tier/Group 1/2 K/A Importance Rating - RO 2.9 SRO 4.6 Steam Generator Tube Leak: Knowledge of the emergency action level thresholds and classifications.

Reference(s) Sim/Plant design, Proposed References to be provided to applicants during examination - EAL Matrix Learning Objective AOP-035-004, EAL 004 Question Source NEW -

Question Cognitive Level H -

10CFRPart55Content- 41.10/43.5/45.11 Comments -

SRO: Candidate must know the proper procedure progression for the given condition and requires that an EAL classification be properly determined.

Page: 151 of 187 10/13/2011

Rev. 23 AOP-035 S/G TUBE LEAK Page 5 of 6i j STEP H INSTRUCTIONS I RESPONSE NOT OBTAINED

5. Check RCS Level - LOWERING IN AN Go To Step 12.

UNCONTROLLED MANNER Adjust Charging Flow As Follows:

/ Check Charging Pump Status - a. Start one additional Charging AT LEAST TWO RUNNING Pump.

b Place running Charging Pumps Speed Controllers in MAN AIll2 adjust output to maximum

7. Check RCS Level - LOWERING IN AN Go To UNCONTROLLED MANNER

8. Check Letdown - IN SERVICE Go To Step ii.

9. Verify All Letdown Flowpaths Isolated As Follows:

LCV-460A & B. LTDN LINE STOP Valves - CLOSED

HIC-137, EXCESS LTDN FLOW Controller - ADJUSTED TO 0%

CVC-387, EXCESS LTDN STOP -

CLOSED

10. Check RCS Level - LOWERING IN AN Go To Step 12.

UNCONTROLLED MANNER ii. Trip The Reactor AND Go To Path-i EOP-E-O. Reactor Trip or Safety Injection Control Charging Flow To Maintain Desired RCS Level Check RCS Leakage - GREATER THAN IF leakage exceeds Charging RUNNING CHARGING FLOW flow, THEN Go To Step 6.

Go To Ste 14 Go To Step 6

s. Notify Chemistry Personnel To Periodically Sample All S/Cs For

/

Activity And Boron Concentration

Rev. 23 AOP-035 S/G TUBE LEAK Page 6 of 64 j STEP H INSTRUCTIONS RESPONSE NOT OBTAINED

1. Check Assistance To Open S/C WHEN assistance to open S/C Sample Valves- REQUESTED Sample valves is requested. ThEN observe the NOTE prior to Step 17 and perform Step 17 Observe the NOTE prior to Step 18 and Go To Step 18 NOTE Operation of the S/G Blowdown OVERRIDE OPEN key switches will result in an ITS 3.6.3 entry.

,/7. HEN Requested By Chemistry onnel To Support S/G Samples. THEN Perform The Following:

a. Check R-19 Monitor - IN ALARM a. Observe the NOTE prior to OR EXPECTED TO ALAR1 Step 18 and Go To Step 18

1) Place the S/G Blowdown OVERRIDE OPEN key switch for the affected S/U(s) in the OVERRIDE OPEN position

S/U A BLOWDOWN SGB-1933A & SGB-1933B

S/G B BLOWDOWN SGE-1934A & SGB-1934B

S/G C BLOWDOWN SGB-1935A & SGB-1935B

2) Within ONE Hour restore the S/c Blowdown OVERRIDE OPEN key switch for the affected S/U(s) to the NORMAL position (ITS 3.6.3. Condition B)

Rev. 23 AOP-035 S/G TUBE LEAK Page 7 of 64 STEP INSTRUCTIONS RESPONSE NOT OBTAINED

NOTE Radiation Monitor R-24 does not provide an accurate determination of leakage until S/C samples have been obtained and the monitor has been calibrated for the optimal node for leakage location.

Determine Leak Rate Using At Least One Of The Following Methods:

R-24 Recorder

Perform OST-051, Reactor Coolant System Leakage Evaluation

Perform a Charging versus Letdown balance

Notify Chemistry personne]

to perform isotopic analysis of S/C samples for leak rate determination

Use R-15 to monitor for low level Primary-to-Secondary leakage using the OP-504, Condenser Air Removal section Using R-15 to Monitor for Low Level Primary to Secondary Leakage Use CP-014 Conversion Factors to correlate R-15 to leakage Check Leak Rate Determination - WHEN leak rate determination is COMPLETE complete. THEN observe the JIQTh prior to Step 20 and Go To Step 20.

Rev. 23 AOP-035 S/G TUBE LEAK Page 8 of 64 H STEP H INSTRUCTIONS RESPONSE NOT OBTAINEIJ NOTE

ITS LCO 34.l3 provides a primary to secondary leakage limit of 75 gpd through any one 5/G.

Total leakage is assumed to be coming from a single SIG when unable to determine leakage from the individual S/Cs.

Normally performed steps in GP-006-1 or GP-006-2. such as placing S/C Blowdown to the Flash Tank may require Release Permits.

Check Leak Rate - GREATER THAN IF the leak rate exceeds the OR EQUAL TO 100 GPD FOR A SINGLE limit, THEN Go To Step 21.

S/C Go To Step 22.

Rev. 23 AOP-035 S/G TUBE LEAK Page 9 of 64 INSTRUCTIONS RESPONSE NOT OBTAINED NOTE It is important to perform GP-006-l or GP-006-2 and AOP-035 concurrently to Che exCent possible in order to minimize secondary contamination.

. Perform The Following Power Reduction:

a. Notify Chemistry that a SAL-3 event has occurred Check Reactor Status - MODE 1 h. Ohserve the NOTE prior to R MODE 2 Step 24 and Go To Step 24

c. Initiate Plant Shutdown To

Mode 3 Using GP-006-1, Normal Plant ShutdowEFroin Power Operation To Hot Shutdown, OR GP-006-2., Rapid Plant Shutdown, While Continuing With This Procedure

Adhere to the following time limits:

Be less than 50% power within 1 hour1.157407e-5 days 2.777778e-4 hours 1.653439e-6 weeks 3.805e-7 months of declaring PSAL-3

Be in Mode 3 within 3 hours3.472222e-5 days 8.333333e-4 hours 4.960317e-6 weeks 1.1415e-6 months of declaring PSAL-3 the NOTE prio

22/ Check Leak Rate GREATER THAN IF the leak rate exceeds the OR EQUAL TO 75 GPO FOR A SINGLE limit, THEN Go To Step 23.

SIG Go To Step 105.

H STEP H INSTRUCTIONS I RESPONSE NOT OBTAINED I

NOTE It is important to perform 02-006-1 R GP-006-2 and AOP-035 concurrently to the extent possible in order to minimize secondary contamination.

23. Perform The Following Power Reduction:

a. Notify Chemistry that a PSAL-2 event has occurred

b. Check Reactor Status - MODE 1 b. Observe the NOTE prior to QE MODE 2 Step 24 and Oo To Step 24

c. Initiate Plant Shutdown To Mode 3 Using OP-006-l, Normal Plant Shutdown From Power Operation To Hot Shutdown, OR GP-0062, Rapid Plant Shutdown, While Continuing With This Procedure

d. Be in Mode 3 within 6 hours6.944444e-5 days 0.00167 hours 9.920635e-6 weeks 2.283e-6 months of declaring PSAL-2

e. Observe the NOTE prior to Step 24 and Oo To Step 24

Rev. 23 AOP-035 S/U TUBE LEAK Page 11 of 64 j STEP H INSTRUCTIONS I RESPONSE NOT OBTAINED NOTE Radiation Monitor R-24 does not provide an accurate determination of leakage until S/U samples have been obtained and Lhe monitor has been caliljrated for the optimal node for leakage location.

24. Identify Leaking S/U Using At Least One Of The Following Methods:

Evaluate indications on R-24 Recorder OR

Evaluate indications on RI-19A. RI-19B. and RI-19C, STM GEN BLOW DN Radiation Monitors OR

Evaluate indications on R-31A. R-31E. and R-31C, STEAMLINE RADIATION MONITORs OR

Chemistry analysis of S/U samples for boron and activity Implement The EALs

6. Review Technical Specification LCOs

ITS LCO 3.4.13

ITS LCO 3.7.15

ITS LCO 3.6.3

Rev. 23 AOP-035 S/G TUBE LEAK Page 12 of 6a STEP INSTRUCTIONS I I RESPONSE NOT OBTAINED C, Initiate Monitoring RCS Leak Rate As Follows:

I a. Check Radiation Monitor R-24

- IN SERVICE

a. Go To Step 27.d.

b. Log R-24 readings at 15 minute intervals

c. Go To Step 28 d Check RCS Leak Rate - LESS d. Log RCS leakage estimates at THAN 10 GPM 15 minute intervals.

Go To Step 28.

e. Monitor R-15 Trends Using Attachment 5, R-15 Monitoring Contact An Operator To Bypass The Condensate Polishers As Follows:

a. Place the SECONDARY BYPASS Switch to the OPEN position

b. Depress the OFF pushbutton for each in service demineralizer Perform Attachment 4, Controlling Secondary Contamination, While Continuing With This Procedure

Rev. 23 AOP-035 S/G TUBE LEAK Page 13 of 64 j STEP H INSTRUCTIONS RESPONSE NOT OBTAINED

30. Isolate Nan-essential Flowpaths From The Affected S/C As Follows:

Verify SDAFW Pump STEAM SHUTOFF from affected S/C -

CLOSED:

V1-8A OR

V1-8B nu in g with this proc edur e NOLE At high primary to secondary leak rates the ability to cooldown will be limited by RCS makeup capability. a rapid RCS cooldown is required ANI2 difficulty is experienced maintaining PZR level, THEN consideration should be given to initiation of Safety Injection.

3 . Check Turbine - TRIPPED WI+/-N the Turbine is tripped as directed by GP-006-l or GP-006-2. THEN Go To Step 32.

32. heck The Following Rod Banks - WHEN the rod banks are fully FULLY INSERTED: inserted, THEN perform Step 33.

All Control Banks Go To Step 34.

Shutdown Bank B

Shutdown Bank A

Rev. 23 AOP-035 S/G TUBE LEAK Page 1L 1 of 64 INSTRUCTIONS I I RESPONSE NOT OBTAINED Perform ONE Of The Following:

Verify Reactor Trips Breakers OPEN

// -

OR Withdraw The Following Rod Banks to 5 steps:

Shutdown Bank A

Shutdown Bank B

Control Bank A

Control Bank B

Control Bank C I Control Bank D 3 Control Charging Flow To Maintain PZR Level Between 22%

and 53%

Borate The RCS Using Attachment 3, Establishing Mode 5 Boron Concentration, While Continuing With This Procedure

.Check Tavg - LESS TN 547°F Perform one of the following to reduce Tavg between 543°F and 547° F:

Slowly adjust PC-464B, STEAM HEADER PRESS Controller auto setpoint pot OR

Slowly adjust PC-464B output in MAN WHEN Tavg is between 543°F and 547°F, THEN Go To Step 37.

Attachment 2, S/G Isolation At Hot Shutdown

Rev. 23 AOP-035 S/U TUBE LEAK Page 47 of 64 ENUOUS USE ATTACHMENT 1 LOCAL S/G ISOLATION NOTE MS-20 is located in the pipe jungle approximately one foot above V1-8A.

1. j S/G A is to be isolated. THEN perform the following:

a. Close MS-20, SC A BYPASS DRN & WARN-UP LINE TO AFW PUMP.

b. Verify CLOSED NS-19, SC A STEAM LINE BEFORE SEAT DRAIN ROOT ISOL.

c. Verify CLOSED NS-21, SG A STEAM STOP V1-3A AFTER SEAT DRAIN ROOT ISOL.

d. Close the S/U Blowdown Isolation and Sample Valves by removing power to R-19A (ON-OFF switch located inside the large cabinet, bottom right hand corner) -

e. Go To Step 4.

Rev. 23 AOP-035 S/G TUBE LEAK Page 48 of 64 CONTINUOUS USE ATTACHMENT 1 LOCAL 5/C ISOLATION (Page 2 of 3)

NOTE MS-29 is located in the pipe jungle approximately one foot above V1-8E.

2. IF S/C B is to be isolated. T1II perform the following:

a. Close MS-29, SC B BYPASS DRAIN & WARM-UP LINE TO AFW PUMP.

b. Verify CLOSED MS-28. SC B STEAM LINE BEFORE SEAT DRAIN ROOT ISOL.

c. Verify CLOSED MS-30, SC B STEAM STOP V1-3B AFTER SEAT DRAIN ROOT ISOL.

d. Close the S/C Blowdown Isolation and Sample Valves by removing power to R19B (ON-OFF switch located inside the large cabinet, bottom right hand corner)

e. Go To Step 4.

NOTE MS-38, is located in the pipe jungle approximately one foot above Vi- 8 C.

3. IF S/C C is to be isolated, THEN perform the following:

a. Close MS-38, SC C BYPASS DRAIN & WARM-UP LINE TO AFW PUMP.

b. Verify CLOSED MS-37, SC C STEAM LINE BEFORE SEAT DRAIN ROOT ISOL.

c. Verify CLOSED MS-39, SC C STEAM STOP V13C AFTER SEAT BRAIN ROOT ISOL.

d Close the S/G Blowdown Isolation and Sample Valves by removing power to R-19C (ON-OFF switch located inside the large cabinet, bottom right hand corner)

Rev. 23 AOP-035 S/G TUBE LEAK Page 49 of 64 CONTINUOUS USE ATTACHMENT 1 LOCAL S/C ISOLATION (Page 3 of 3)

4. Notify Control Room personnel that actions of Attachment 1 to isolate the affected S/C are complete.

- END -

Rev. 23 AOP-035 S/G TUBE LEAK Page 50 of 64

/ /_

7 J NTiNUOUS USE ATTACHMENT 2 Ic ISOL TROT SHUTDOWN

/

NOTE Closure of the MSIV in Lhe affected S/G will invalidaLe the readings from Radiation Monitor R-15 for use in determining primary to secondary leak rate.

Opening the breakers for the any V1-8, V2-14. OR V2-16 valve will require entry into Technical Specifications 3.7.4

Based upon leak size and equipment availability, breakers may need to be re-closed to support maintaining level in the isolated S/c per this procedure.

1. IF S/G A is to be isolated, j1 perform the following:

a. Close Vl-3A. MSIV.

b. Verify CLOSED MS-353A, MSIV V1-3A BYP.

c. Place the A FRV controller FCV-478 in MAN AND close FCV-478.

d. Adjust A FRV Bypass Valve controller FCV-479 to close FCV-479.

e. Close V2-6A, EW HDR SECTION.

f. Verify CLOSED V2-16A. AFW HDR DISCH Valve.

g. Verify CLOSED V2-14A, PUMP DISCH Valve.

h. Verify RV1-1. PORV. setpoint at 1035 psig using UNIT 2 STATUS BOARD pot setting.

i. Dispatch Operator To The E-l/E-2 To Perform The Following:

At MCC-9, verify V2-16A closed open breaker V2-16A, MDAFW PUMP HEADER DISCHARGE TO S/G A (CMPT-2ML)

(CONTINUED NEXT PAGE)

Rev. 23 AOP-035 S/G TUBE LEAK Page 51 of 64 CONTINUOUS USE ATTACHMENT 2 S/C ISOLATION AT HOT SHUTDOWN (Page 2 of 3)

1. (CONTINUED)

j. Dispatch Operator To The Aux. Bldg. To Perform The Following:

At MCC-lO. verify V2-14A closed open breaker V2-l4A.

SDAFN PUMP TO S/C A (CMPT- 3C)

At MCC-lO. verify V2-16A closed open breaker V2l6A.

MDAFW PUMP HEADER DISCHARGE TO S/C A (CMPT-4C)

At MCC-5, verify Vl-8A closed D open breaker Vl-8A, SDAFN PUMP STEAM ISOLATION (CMPT-16F)

2. IF S/C B is to be isolated, THEN perform the following:

a. Close Vl-3B, MSIV.

b. Close MS-353B, t1SIV Vl-3B BYP.

c. Place the B FRV controller FCV-488 in MAN AND close FCV-488.

d. Adjust B FRV Bypass Valve controller FCV-489 to close FCV-489.

e. Close V2-6B, FW HDR SECTION.

f. Verify CLOSED V2-16B. AFW HDR DISCH Valve.

g. Verify CLOSED V2-l4B, PUMP DISCH Valve.

h. Verify RV1-2, PORT. setpoint at 1035 psig using UNIT 2 STATUS BOARD pot setting.

i. Dispatch Operator To E-l/E-2 Room To Perform The Following:

At MCC-9. verify V2-l4B closed A. open breaker V2-14B, SDAFW PUMP TO S/C B (CMPT- 1C)

At MCC-6. verify Vl-8B closed ANL open breaker Vl-8B, SDAFW PUMP STEAM ISOLATION (CMPT-16M)

j. Dispatch Operator To The Aux. Bldg. To Perform The Following:

At MCC-lO, verify V216B closed open breaker V2-16B, MDAFW PUMP HEADER DISCHARGE TO S/C B (CMPT-4F)

Rev. 23 AOP-035 S/G TUBE LEAK Page 52 of 64 CONTINUOUS USE ATTACHMENT 2 S/C ISOLATION AT HOT SHUTDOWN (Page 3 of 3)

3. I S/C C is to be isolated, THEN perform the following:

a. Close V1-3C. MSIV.

b. Close MS-353C. MSIV V1-3C BYP.

r. Place the C FRV controller FCV-498 in MAN AND close FCV-498.

d. Adjust C FRV Bypass Valve controller FCV-499 to close FCV-499.

e. Close V2-6C, FW HDR SECTION.

f. Verify CLOSED V2-16C, AFW HDR DISCH Valve.

g. Verify CLOSED V2-14C, PUMP DISCTI Valve.

h. Verify RV1-3. PORV, setpoint at 1035 psig using UNIT 2 STATUS BOARD pot setting.

i. Dispatch Operator To The E-l/E-2 To Perform The Following:

At MCC-9, verify V2-16C closed ANJI open breaker V2-l6C.

MDAFW PUMP HEADER DISCHAROE TO S/C C (CMPT-3J)

At MCC-6, verify V]-8C closed AND open breaker Vi-8C, SDAFW PUMP STEAM ISOLATION (CMPT-18M)

j. Dispatch Operator To The Aux. Bldg. To Perform The Following:

At MCC-1O. verify V2-l4C closed AND open breaker V2-l4C, SDAFW PUMP TO S/C C ( CMPT - 414)

4. Return to Procedure and Step in effect.

- END -

Rev. 23 AOP-035 S/G TUBE LEAK Page 53 of 64 CONTINUOUS USE ATTACHMENT 3 ESTABLISHING RCS COLD SHUTDOWN BORON CONCENTRATION (Page 1 of 3)

1. Record the minimum required Mode 5 Boron concentration.

Ppm

2. Determine RCS boron concentration change required to establish CSD boron concentration.

Required CSD Latest RCS Boron Concentration Boron Sample

3. Determine volume of boric acid to be added using Station Curve Book.

gallons 4 IF the MOV-35O, BA TO CHARGING PMP SUCT Valve flowpath is unavailable, THEN Borate the RCS using OP-301. Chemical and Volume Control System (CVCS) Section RCS Boration Quick Checklist

a. WHEN Boration is complete, ]I1 Go To Step 13.

5. IF the MOV-350, BA TO CHARGING PMP SUCT Valve flowpath will be used, THEN open MOV-350, BA TO CHARGING PMP SUCT Valve.

6. Start Boric Acid Pump aligned for Blended Makeup.

7. Record time boration commenced.

8. Record flowrate indicated on Fl-lb. BORIC ACID BYPASS FLOW.

gpm

9. Determine time required to establish CSD boron concentration.

Boric Acid Volume Required (gal) minutes Fl-hO Flowrate (gpm)

Rev. 23 AOP-035 SIG TUBE LEAK Page 56 of 64 Th-

-Th tCONTINUOUS US ATTACHMENT 4 CONTROLLING SECONDARY CONTAMINATION (P a13L-&

1. Contact Health Physics personnel to perform the following:

a. Walkdown secondary systems to catalog sources of secondary leakage for polenLial wasLe releases.

b. Perform radiation surveys in the secondary with emphasis on the Condensate Polishing Demineralizers, and resin columns in the Secondary Sample Room and Condensate Polisher Sample Room.

c. Establish radiation control boundaries as necessary.

2. Contact Operations Staff to perform the following:

a. NOT already bypassed, THEN determine the level of secondary contamination at which the Condensate Polishing Deniineralizers should be bypassed.

b. Determine the method of removal of contaminated secondary water:

Drain the Condenser to the Waste Disposal System using 0P508, Condenser Drain System section Draining the Condenser to the Waste Disposal System

Release the secondary to the storm drains.

Other alternative means such as vendor processing.

c. any secondary radiation monitors are inoperable, THEN elevate repair priority.

d. IF contaminated, THEN develop a method of removal AND disposal of the resin in the Condensate Polishing Demitieralizers.

e. Evaluate current waste disposal capacity determine the need for additional personnel to process waste after plant shutdown.

Rev. 23 AOP-035 S/G TUBE LEAK Page 57 of 64 CONTINUOUS USE ATTACHMENT 4 CONTROLLING SECONDARY CONTAMINATION (Page 2 of 3)

3. Contact Chemistry Personnel to perform the following:

a. Sample secondary systems for activity.

b. Develop releases, as required, for the secondary systems.

Hotwell

Feedwater and Condensate Piping

Condensate Pump and Condensate Polishing Building Sumps

S/G Elowdown

c. Determine the need to reduce Radiation Monitor Setpoints to provide additional monitoring capability.

d. Develop R-15 Conversion Factors for determining S/G Leak Rate vs RNS readings.

Rev. 23 AOP-035 S/G TUBE LEAK Page 58 of 64 CONTINUOUS USE ATTACHMENT 4 CONTROLLING SECONDARY CONTAMINATION (Page 3 of 3)

NOTE

ES-33, HEATER 5B EXT STEAM TO PRV-1985, is located approximately 15 feet in the overhead above Heater 4A.

A valve wrench AND ladder will be required to close ES-33.

Auxiliary Steam will be lost during the period follow ing isolation of Extraction Steam until the boilers have pressu rized.

4. Contact An Operator To Perform The Following:

a. LE directed by Operations Management. THEN perform the following to bypass the Condensate Polishers:

1) Place the SECONDARY BYPASS Switch to the OPEN position

2) Depress the OFF pushbutton for each in service demineralize r

3) Secure ANY evolution that passes water through the beds.

such as a low volume rinse

b. Stop the Condensate Pit Sump Pump the Condensate Polishing Building Sump Pump.

c. Close ES-33. HEATER 5B EXT STEAM TO PRV-l985. to isola te Main Steam from the Auxiliary Steam System.

d. Startup the Auxiliary Boilers using OP-401, Auxiliary Heating System.

e. Line up the Auxiliary Steam condensate return to the Auxiliary Boilers as follows:

Close AS-327, COND RET TO MISC DRN COLLECTING TK FROM AUX BLDG

Open AS-326, COND RET TO COND TK A & B FROM AUX BLDG

- END -

84. 076 AA2.05 sRO 001 ft-NO IL Nd PL 145 TI- 139 TI - 141 Ti 143 1O Pi - 13

- Plant is stable at 100% RTP.

- R-9, Letdown Line Area, radiation monitor had a valid alarm and a reading of 15,000 mrem/hr prior to R-9 failing.

- RCS samples indicate an RCS Activity of 550 pCi/gm 1-131 Dose Equivalent.

Which ONE(1) of the following completes the statement below?

lAW AOP-005, Radiation Monitoring System, letdown flow (1) and lAW the Emergency Action Level Matrices, an (2) must be declared.

(REFERENCE PROVIDED)

A. (1) may remain as-is (2) Unusual Event B. (1) may remain as-is (2) Alert C. (1) is required to be reduced (2) Unusual Event Dv (1) is required to be reduced (2) Alert Page: 152 of 187 10/13/20 11

The correct answer is D.

A. Incorrect. The given letdown flow reading is indicative of one 60 gpm and one 45 gpm letdown orifices being in service. AOP-005 requires that letdow n be reduced to less than or equal to one letdown orifice valve open. Therefore, letdown flow is required to be reduced. The second part is incorrect. The cand idate may confuse the 550 pCi/gm 1-131 Dose Equivalent reading as being greater than a R-9 reading of 500 mrem/hr on the EAL Matrix for an Unusual Event. The activity reading exceeds the 300 pCi/gm 1-131 Dose Equivalent limit for a loss of the Fuel Claddi ng Barrier which results in meeting the Alert declaration criteria.

B. Incorrect. The given letdown flow reading is indicative of one 60 gpm and one 45 gpm letdown orifices being in service. AOP-005 requires that letdow n be reduced to less than or equal to one letdown orifice valve open. Therefore, letdow n flow is required to be reduced. The second part of distractor is correct.

C. Incorrect The given letdown flow reading is indicative of one 60 gpm and one 45 gpm letdown orifices being in service. AOP-005 requires that letdow n be reduced to less than or equal to one letdown orifice valve open. Therefore, letdown flow is required to be reduced. The candidate may confuse the 550 pCi/gm 1-131 Dose Equivalent reading as being greater than a R-9 reading of 500 mrem/hr on the EAL Matrix for an Unusual Event. The activity reading exceeds the 300 pCi/gm 1-131 Dose Equivalent limit for a loss of the Fuel Cladding Barrier which results in meeting the Alert declaration criteria.

D. Correct Question 84 Tier/Group 1/2 K/A Importance Rating - RO 2.2 SRO 2.5 Ability to determine and interpret the following as they apply to the High Reactor Coolant Activity: CVCS letdown flow rate indication Reference(s) Sim/Plant design, Proposed References to be provided to applicants during examination

- EAL Matrix Learning Objective AOP-005-004, EAL 004 Question Source NEW-Question Cognitive Level H -

10 CFR Part 55 Content 43.5/45.13 Comments -

SRO: Candidate must make an EAL Declaration, which is an SRO functio n.

Page: 153 of 187 10/13/2011

AOP-005 RADIATION MONITORING SYSTEM Rev. 29 Page 24 of 58 j STEP H INSTRUCTIONS I RESPONSE NOT OBTAINED ATTACHMENT 9 AREA MONITOR R-9 - LETDOI,JN LINE AREA (Page 1 of 2)

Place VLC Switch To EMERG Position Place And Hold EVACUATION ALARM Switch To LOCAL Position For 15 SECONDS

3. Announce The Following Ove r

Plant PA System:

ATTENTION ALL PERSONNEL.

A HIGH RADIATION ALARM HAS BEEN RECEIVED ON LETDOWN LINE ARE A

MONITOR R-9. ALL NON-ESSENTIAL PERSONNEL EVACUATE AUXILIA RY BUILDING UNTIL FURTHER NOT ICE Repeat PA Announcement Place VLC Switch To NORM Pos ition I

6. Contact RC Personnel To Per form

- A Survey In The Following Are as To Determine Magnitude Of Radiation Source:

Lower level Aux Building

VCT area

7. Check Letdown Orifice Isolati on Refer to OP-301. CHEMICAL Valve(s) LESS THAN OR EQUAL TO AND VOLUME CONTROL SYSTEM, for ONE of the following OPEN:

direction on removal of an orifice from service.

8. Control Charging Flow To Maintain PZR Level

AOP-005 Rev. 29 RADIATION MONITORING SYSTEM Page 25 of 58 l STEP H INSTRUCTIONS I J RESPONSE NOT OBTAINED I

ATTACHMENT 9 AREA MONITOR R-9 - LETDOWN LINE AREA (Page 2 of 2)

9. Request E&C To Sample The RCS To Determine The Following:

Gross Activity

Iodine

Gaseous Activity

10. Go To The Main Body, Step 1.b, Of This Procedure

- END -

ATTACHMENT 5.2 Page 1 of 24 FISSION PRODUCT BARRIER LOSSIPO TENTIAL LOSS MATRIX AND TECHNICAL BASES Table F-I Fission Product Barrier Matrix Fuel Cladding Barrier Reactor Coolant System Barrier Loss Potential Loss Containment Barrier Loss Potential Loss r CSFST 1. CSFST Core Cooling-RED Loss

1. CSFST Core Cooling- Potential Loss OR 1. CSFST RCS Integrity-RED Q None 1. CSFST Containment- RED CSFST Heal Sink-RED CSFSTIleatSink-PED None aod heat sink required and heat sink required Cnre Exit TICS 2. Core coil T/Cs S I ,200F 2. Core coil TICs 705F

2. Cone exit T/Cs 1 ,200F None I None Core coolirig nesloralioo procedures not elfectioe None within 15 mit.

3. All of the lollowing:

- Core Coil T/Cs 7S0F

- Reactor Vessel water level < Table E-2 thresholds Radiation - Core cooliog restoration procedures

3. Coolainmenl High Range not elf ectrue Radiation Monitor R-32A or 1. Containment High Range vethin 15 minotes R-32B n 105 Rem/hr Radiation Monilor R-32A or

4. Containment High Range Radiat R-32B n5 Rem/hr ion Monilor R-32A or R-32B v 2000 Rem/hr None

4. letdown line area radiation Noon None monitor R-9 n 25,000 mRem/hr Inventory

3. Reactor Vessel waler level 2. RCS leak rule n available Table F-2 thresholds 2. Unisolalole RCS leak exceeding makeop capacity as indicated 1. Rapid sneoptained Containment pressu the capacity of one charging pump re drop 5. Containment pressure 42 psig and by a loss of RCS subcooling (77 gpm) following indial increase increasing toss than 35F (55f9

2. Following LOCA, Containment pressure or sump 6. Containment hydrogen concentralion 54%

None leoni response not consistent with LOCA

3. SGTR that results in an ECCS conditions (SI) actuation 7. Conlainment pressure 10 psig with u one full

3. Ruptured S/G is also fautted outside of train of depreosunzalion equipment Conlainment operating i Note. One Containment Spray system Solo and

4. Containment Cooling System fain mnpris soc north PnimatyIo_seuondary leakage > 10 gpm e one tot train non-/soluble steam release from affecte xl deprnsssrizntiOn equipment d S/G to Other 5. Coolant actisnty the ennironment No0 3oo/gm I-IS 5.

n Containment isolation vatoe(s) not closed after None None Containment isolation ANI2 None Judgment 6. Any condition in the opinion Downstream pathway to the enicrnnmenl edsts

4. Any condilion in the opinion i

of the SEC that indicates 4. Any condition in the opinion 3. Any condition in the opinion of Ihe SEC that indicates nf the SEC that indicates 6. Any condition in the opinion of the SEC loss of the Fuel Clad burner potential loss of the Fuet St the SEC that indicates that 6. Aey condition in the opinion of the SEC loss of the RCS harrier indicalns loss of the Containment barrier that Clad barrier potential loss of the RCS indicates potential Inns of Ihe Cantulomnot barrier burner EPCLA-04 Rev. 2 Page 228 of 251

ATTACHMENT 5.2 Page 4 of 24 FISSION PRODUCT BARRIER LOSS/POTEN TIAL LOSS MATRIX AND TECHNICAL BASES The specified value of 100 Rem/hr is conserva tively at the low end of the calculated range. This value is higher than that specified for RCS barrier Loss #3.

It is important to recognize that the radiation mon itor may be sensitive to shine from the Reactor Vessel or RCS piping.

Monitors used for this Fission Product Barrier Loss threshold are the Containment High Range Radiation Monitors R-32A and R-32 B. These monitors provide indication in the Control Room with a range of 1 E0 to 1 E7 Rem/hr (Ref. 3).

RNP

References:

1. EPTSC-07, Damage Assessment

2. RNP-M/MECH-1744, R-32A and R-32B Calc ulation for Core Damage Assessment

3. UFSAR Section 12.3.3.1.2.2

4. OMM-014, Radiation Monitor Setpoints

4. Letdown line area radiation monitor R-9>

25,000 mRemlhr The normal CVCS charging and letdown flow path allows purification of the reactor coolant and control of the RCS volume. Hot (547°F) reactor coolant from the cold leg of loop 1 passes through the regenerative heat exchanger. The discharge of the regenerative heat exchanger then passes through the non-regenerative heat exchanger. Downstream of the non-regenerative heat exchanger and upstream of the mixed bed demineralizers, the letdown stream passes by area radiation monitor R-9, which is mounted above the letdown line pipe. In order for R-9 readings to represent fission product activity in the reactor coolant and thereby warn of potential fuel element failure, letdown must be in service allowing flow through the letdown line and past the radiation monitor.

Fuel failure in excess of 5% or 300 pCi/gm 1-131 Dose Equivalent will trigger the threshold value of 25,000 mR/hr (Ref.1).

RNP

References:

1. RNP-M-MECH-1745, Calculation of Setpoints for Accident Rad Monitors and EP Declaration Levels

2. OMM-014, Radiation Monitor Setpoints EPCLA-04 Rev. 2 Page 231 of 251

ATTACHMENT 5.2 Page 5 of 24 FISSION PRODUCT BARRIER LOSS/POTENTIAL LOSS MATRIX AND TECHNICAL

5. Coolant activity> 300 pCilgm 1-131 Dose Equivalen t

Elevated reactor coolant activity represents a potential degradation in the level of safety of the plant and a potential precursor of more serio us problems. The threshold Dose Equivalent 1-131 concentration is well above that expected for iodine spikes and corresponds to about 5% fuel clad dam age. When reactor coolant activity reaches this level the Fuel Clad barrier is considered lost.

RNP

References:

1. RNP-M-MECH-1745, Calculation of Setpoints for Acci dent Rad Monitors and EP Declaration Levels

6. Any condition in the opinion of the SEC that indic ates Loss of the Fuel Clad barrier The Site Emergency Coordinator (SEC) judgment thres hold addresses any other factors relevant to determining if the Fuel Clad barrier is lost. Such a determination should include imminent barrier degradation, barrier mon itoring capability and dominant accident sequences.

Imminent barrier degradation exists if the degradation will likely occur within two hours based on a projection of current safety syste m performance. The term imminent refers to recognition of the inability to reach safety acceptance criteria before completion of all checks.

Barrier monitoring capability is decreased if there is a loss or lack of reliable indicators. This assessment should include instrumentati on operability concerns, readings from portable instrumentation and cons ideration of offsite monitoring results.

Dominant accident sequences lead to degradation of all Fission Product Barriers and likely entry to the EOPs. The SEC should be mindful of the Loss of AC power (Station Blackout) and ATWS EALs to assure timely emergency classification declarations.

RNP

References:

None EPCLA-04 Rev. 2 Page 232 of 251

DISCUSSION (From the WOG FR-Z.2 Basis Document)

1. INTRODUCTION Guideline FR-Z.2, RESPONSE TO CONTAINMENT FLOODING, is a Function Restoration Guideline (ERG) provides procedural guidance when the containment that level is greater than flood level.

There is only one explicit transition to guideline FR-Z.2

. It is from the Critical Safety Function Status Tree CONTAINMENT, on an ORANGE priority when contain E-O.5, ment sump level is greater than flood level.

After all the actions in guideline FR-Z.2 are comple ted, the operator is instructed to return to the guideline effect. and step in

2. DESCRIPTION Guideline FR-Z.2, RESPONSE TO CONTAINMENT FLOO DING, provides actions to respond when the contain level is greater than design flood level. This level is ment significant since the critical systems and components, necessary to ensure an orderly safe plant shutdown and which are provide feedback to the operator regarding plant conditi are normally located above the design flood level. Theref ons, ore, the guideline FR-Z.2 is entered from the Contai Status Tree on an ORANGE priority when this design nment flood level is exceeded.

The primary purpose of the containment sump area is to collect the water injected into the containment or the reactor coolant system following an accident. The spilled from water collected in the containment sump is then availab long term core and/or containment cooling via the emerge le for ncy core cooling or containment spray recirculation systems. In addition, the containment sump collects the injected or spilled water into areas such that vital system components will not be flooded and thus rendered inoper s or able.

The maximum level of water in the containment follow ing a major accident generally is based upon the entire contents of the reactor coolant system, refueling water water storage tank, condensate storage tank, and SI accum This water volume approximates the maximum water ulators.

volume introduced into the containment following a LOCA a steamline or feedline break inside containment. plus An indicated water level in the containment greater than the maximum expected volume (design basis flood level) an indication that water volumes other than those represe is nted by the above noted volumes have been introduced the containment. Also, the high water level provides into an indication that potential flooding of critical systems and components needed for plant recovery may occur The actions in this guideline attempt to identify any unexpe cted source of water and isolate it if possible. Beyon the plant engineering staff is consulted to determine if d that transfer of containment sump water to other tanks is appropriate.

3. RECOVERY/RESTORATION TECHNIQUE The objective of the recovery/restoration technique incorp orated into guideline FR-Z.2 is to provide actions to respon to containment flooding. d The following subsections provide a summary of the major action categories of operator actions and the key decision points for guideline FR-Z.2, RESPONSE TO utility CONTAINMENT FLOODING.

3.1 High Level Action Summary A high level summary of the actions performed in FR-Z.2 is given below in the form of major action categories.

are discussed below in more detail. These MAJOR ACTION CATEGORIES IN FR-Z.2 o Try to Identify Unexpected Source of Sump Water and Isolate It if Possible o Notify Plant Engineering Staff of Sump Level and Activi ty Level o Try to Identify Unexpected Source of Sump Water and Isolate It if Possible The first action in this guideline is to try to identify the source of water which is causing containment flooding it. The concern regarding flooding is that critical plant and isolate components needed for plant recovery could be damag rendered inoperable. ed and o Notify Plant Engineering Staff of Sump Level and Activi ty Level By knowing the sump level and activity level, the plant engine ering staff can determine if the excess water can be transferred to storage tanks located outside containment.

FRP-J.2-BD Rev 3 Page 3 of 6

85. W/E 09 EA2.1 SRO 001 Given the following plant conditions:

- A loss of off-site power and reactor trip has occurred.

- The crew performed actions of PATH-i and has transitioned to EPP-4, Reactor Trip Response.

- A rupture in the Instrument Air System at time of trip has resulted in Instrument Air pressure lowering to 20 psig.

- CETC temperature is 555°F and rising 15 minutes after the trip.

- S/G pressure is 1075 psig and rising.

Which ONE (1) of the following completes the statements below?

RCS Natural Circulation (1) exist(s).

In the situation described above, detailed steps regarding the control of RCS temperature will be provided in (2)

A. (1) does (2) AOP-017, Loss of Instrument Air B. (1) does (2) EPP-4, Reactor Trip Response C. (1) does NOT (2) EPP-4, Reactor Trip Response D (1) does NOT (2) AOP-017, Loss of Instrument Air Correct answer is D.

A. Incorrect. NC does not exist with Tave at 555° F and S/G pressures at 1185 psig.

Also, nitrogen must be manually aligned to S/G PORV5 on a loss of air.

B. Incorrect. NC does not exist. AOP-017 provides the procedural direction on how to control S/G pressure and RCS temperature on a loss of instrument air. AOP-017 is a concurrent use procedure.

C. Incorrect. Nitrogen must be manually aligned to S/G PORVs on a loss of Air in accordance with AOP-017.

D. Correct.

Page: 154 of 187 10/13/2011

Question 85 Tier/Group 1/2 K/A Importance Rating - RO 3.1 SRO 3.8 Ability to determine and interpret the following as they apply to the (Natural Circula tion Operations): Facility conditions and selection of appropriate procedures during abnormal and emergency operations.

Reference(s) Sim/Plant design, Supplement E, AOP-017, EPP-4, EPP-5 Proposed References to be provided to applicants during examination None -

Learning Objective EPP-5-004 Question Source BANK (Last used on 2007 NRC Exam. Format of question modifi ed significantly.)

Question Cognitive Level H-10 CFR Part 55 Content- 43.5/45.13 Comments -

SRO: Candidate must have knowledge of when to implement attachments within abnormal I emergency procedures. Candidate must know that the steps to control RCS temperature using nitrogen aligned to the SIG PORVs is contained in AOP-017 and not EPP-4. Procedure selection and knowledge of procedure content versus knowledge of procedure mitigation strategy.

Page: 155 of 187 10/13/2011

Rev. 41 EPP-Supplements SUPPLEMENTS Page 29 of 102

STEP H INSTRUCTIONS CONTINUOUS USE RESPONSE NOT OBTAINED I

Galir:ulati::rificat ion

1. Check Natural Circulation Status Raise the rate of dumping steam.

As Follows:

Steam pressure - STABLE OR DECREAS ING AND

RCS subcooling - GREATER THAN 35°F [55° F]

AND

Core exit TICs - STABLE OR DECREASING AND

RCS hot leg temperatures -

STABLE OR DECREASING AND

RCS cold lag temperatures -

TRENDING TO SATURATION TEMPERATURE FOR STEAM PRESSURE

2. Return To Procedure And Step In Effect

- END -

Rev. 40 AOP-017 LOSS OF INSTRUMENT AIR Page 18 of 68 H STEP H INSTRUCTIONS RESPONSE NOT OBTAINED SECTION B HOT SHUTDOWN (WITHOUT RHR IN SERVICE)

(Page 1 of 10)

1. D termine If IA Capacity Has een Restored As Follows:

a. Check IA Header pressure: a. I. IA capacitzy is restored, THEN Go To Step 1.b.

GREATER THAN 85 PSIG Go To Ste AND

STABLE OR RISING

b. Go To Attachment 4, Restoration From Loss of Instrument Air Control RCS Temperature By Dumping Steam Using One Of The Following Methods Listed In Order Of Preference:

a. Steam Dump to Condenser

b. Steam Line PORVs controlled

c. Stecm Line PORVs controlled by nitrogen using Attachment 2, Nitrogen Alignment to Steam Line PORVo

d. Manually steam each intact S/C using Attachment 3, Manual Steam Dump of S/Gs

3. Check S/C Level Control -

IE any S/C level is affected, ADVERSELY AFFECTED BY LOSS OF IA THEN perform Step 4.

Observe NOTE prior to Step 5 and Go To SLep 5.

4. Establish AFW Flow To Maintain S/C Levels At Desired Level

AOP-017 Rev. 40 LOSS OF INSTRUMENT AIR I

Page 39 of 68 STEP_H NOT OBTAINED I

ATTACHMENT 2 GEN ALIGNMENT TO STEAM LINE PORVs kge 1 of 5)

A Locked Valve Key is required to perform Lhis at:Lachment.

1. Check NSIVs As Follows:

a. Check MSIVs CLOSED

a. IF the MSIVs close. THEN Perform step 1.b.

Go To Step 2.

b. Place the MSIV Control Switches in the CLOSE position

2. Check Steam Line PORVs TO BE Go To Step 9.

CONTROLLED FROM RTCB NOTE

. Steps 3 through 7 align backup nitrogen to control Steam Line PORVs and ensure the MSIVs remain close d.

. IA-297 is located at the Southeast corn er of Pipe Jungle at an elevation between the feed and steam lines.

3. Close IA-297, HDR STOP TO PORV STATION & MSIVS NOTE SDN-13 is located at the Steam Dump Nitrogen Accumulator.

4. Open SDN-l3. NITROGEN BACKUP SUPPLY

AOP-017 Rev. 40 LOSS OF INSTRUMENT AIR Page 40 of 68 H STEP H INSTRUCTIONS I H RESPONSE NOT OBTAINED I

CONTINUOUS USE ATTACHMENT 2 NITROGEN ALIGNMENT TO STEAM LINE PORVs (Page 2 of 5)

NOTE SDN-28 and SDN-29 are located at:

the Southeast: corner of Pipe Jun on the Mezzanine Deck. gle

5. Unlock A Close SDN-29. STEAM LINE PORV NITROGEN B/U TO IA TELL-TALE DRAIN

6. Unlock AND Open SDN-28, NITROGE N

BACKUP TO STEAM LINE PORTS NOTE IA-423 is located at the Southea st corner of Pipe Jungle on the Mezzanine Deck.

7. Unlock AND Open IA-423, NITROGE N

TO STEAM LINE PORVS

8. Go To Section And Step In Effect

AOP0l7 Rev. 40 LOSS OF INSTRUMENT AIR Page 41 of 68 j STEP H INSTRUCTIONS I RESPONSE NOT OBTAINED CONTINUOUS USE -

ATTACHMENT 2 NITROGEN ALIGNMENT TO STEAM LINE PORVs (Page 3 of 5)

9. Transfer Steam Line PORV Con trol To The Local Controllers At The Secondary Control Panel As Follows:

a. Place PIC-477, manual thumbwheel, to the closed position by rotating the white thumbwheel in the up direction

b. Place PORV RV-l Switch in the DEFEAT position

c. Place the transfer switch on PIC-477 to MAN position

d. Place PIC-487, manual thumbwheei, to the closed position by rotating the white thumbwheel in the up direction

e. Place PORV RV-2 Switch in the DEFEAT position

f. Place the transfer swi tch on PIC-487 to MAN o5ition

g. Place PIC-497, manual thumbwheel, to the closed position by rotating the white thumbwheei in the up direction

h. Place PORV RV-3 Switch in the DEFEAT position

i. Place the transfer switch on PIC-497 to MAN position

Rev. 40 AOP-017 LOSS OF INSTRUMENT AIR Page 42 of 68 STEP H INSTRUCTIONS RESPONSE NOT OBTAINED CONTINUOUS USE ATTACHMENT 2 NITROGEN ALIGNMENT TO STEAM LINE PORVs (Page 4 of 5)

NOTE

. Steps 10 through 14 align backup nitrogen Lo control Steam Line PORVs and ensure the MSIVs remain closed.

. IA-297 is located at the Southeast corner of Pipe Jungle at an elevation between the feed and steam lines.

10. Close IA-297. HDR STOP TO PORV STATION & MSIVS NOTE SDN-13 is located at the Steam Dump Nitrogen Accumulator.

11. Open SDN13, NITROGEN BACKUP SUPPLY NOTE SDN-28 and SDN-29 are located at the Southeast corner of Pipe Jungle on the Mezzanine Deck.

12. Unlock AND Close SDN-29, STEAM LINE PORV NITROGEN B/U TO IA TELL-TALE DRAIN

13. Unlock AND Open SDN-28, NITROGEN BACKUP TO STEAM LINE PORVS

AOP-017 Rev. 40 LOSS OF INSTRUMENT AIR Page 43 of 68 STEP H INSTRUCTIONS I RESPONSE NOT OBTAINED I

CONTINUOUS USE ATTACHMENT 2 NITROGEN ALIGNMENT TO STEAM LINE PORVs (Page 5 of 5)

NOTE IA-423 is located at: the Southeast corner of Pipe Jungle on the Mezzanine Deck.

14. Unlock Open IA-423, NITROGEN TO STEAM LINE PORVS

15. Control RCS Temperature From The Secondary Control Panel By Opening And Closing The PORVo As Follows:

To open a PORV, rotate the white manual thumbwheel of the desired pressure indicating controller in the DONN direction

To close a PORV, rotate the white manual thumbwheel of the desired pressure indicating controller in the UP direction

16. Cc To Section And Step In Effect

- END -

Rev. 40 AOP-017 LOSS OF INSTRUMENT AIR Page 44 of 68 CONTINUOUS USE ATTACHMENT 3 MANUAL STEAM DUMP OF S/Gs (Page 1 of 4)

NOTE

OP-923. Containment: Ini:egrit:y, provides the cont:ro ls for opening valves that serve as Containment Integrity.

A Locked Valve Key is required to perform this attachm ent.

1. Align the following drains located at the Pipe Jungle

Unlock and open MS-19, SQ A STEAM LINE BEFORE SEAT DRN ROOT IS OL

Open MS-19A, SC A STEAM LINE BEFORE SEAT URN ISOL

Throttle MS-40, SQ A STEAM LINE BEFORE SEAT DRA{N ISOL

Open MS-21, SQ A STEAM STOP V1-3A AFTER SEAT DRN ROOT ISOL

Throttle MS-43, SQ A STEAM STOP V1-3A AFTER SEAT DRAIN ISOL

Unlock and open MS-28, SG B STM LINE BEFORE SEAT DRAIN ROOT I SOL

Open MS-28A, SQ B STM LINE BEFORE SEAT DRAIN ISOL

Throttle MS-4l, SQ B STEAM LINE BEFORE SEAT DRAIN ISOL

Open MS-3D. SC B STEAM STOP V1-3B AFTER SEAT DRAIN ROOT ISOL

Throttle MS-44, SQ B STEAM STOP V133 AFTER SEAT DRAIN ISOL

Unlock and open MS-37, SQ C STEAM LINE BEFORE SEAT DRAIN ROOT ISOL

Open MS-37A. SC C STEAM LINE BEFORE SEAT DRAIN ISOL

Throttle MS-42. SC C STEAM LINE BEFORE SEAT DRAIN ISOL

Open MS-39, SQ C STEAM STOP V1-3C AFTER SEAT DRAIN ROOT ISOL (CONTINUED NEXT PAGE)

Rev. 40 AOP-017 LOSS OF INSTRUMENT AIR Page 45 of 68 CONTINUOUS USE ATTACHMENT 3 MANUAL STEAM DUMP OF SIGs (Page 2 of 4)

1. (CONTINUED)

. Throttle MS-45, SG C STEAM STOP V1-3C AFTER SEAT DRAIN ISOL

AOP-017 Rev. 40 LOSS OF INSTRUMENT AIR Page 46 of 68 CONTINUOUS USE ATTACHMENT 3 MANUAL STEAM DUMP OF S/Gs (Page 3 of 4)

2. j additional steaming is required, IIIN perform the follo wing, as necessary, to control RCS temperature:

a. Unlock and close the breakers for the MSIV BYP Valves on MCC-8:

MS-353A, MSIV Vl-3A BYP (CMPT ic)

MS-353B, MSIV Vl-3B BYP (CMPT 2C)

MS-353C, MSIV Vl-3C BYP (CMPT 3C)

b. Open the following MSIV BYPs from the RTGB

MS-353A, MSIV Vl-3A BYP

MS-353B. MSIV Vl-3B BYP

MS-3530, MSIV V1-3C BYP

c. Throttle open the Seventy Two Inch Header Vent Valves:

NS-231, 72 HEADER ATMOS VENT

NS-232, 72 HEADER ATMOS VENT

d. Perform the following on the North Header (located on the mezzanine level, above MCC-8) (ladder required)

1) Open the North Header Drain and Vent Valves:

. MS-98, NORTH MAIN STEAM LINE DRAIN ROOT ISOLA TION

MS-99, NORTH MAIN STEAM LINE VENT ISOL

2) Throttle MS-l0O, NORTH MAIN STEAM LINE VENT TO ATMOS, as directed by the RTGB operator.

(CONTINUED NEXT PAGE)

AOP-017 Rev. 40 LOSS OF INSTRUMENT AIR Page 47 of 68 CONTINUOUS USE ATTACHMENT 3 MANUAL STEAM DUMP OF S/Go (Page 4 of 4)

2. (CONTINUED)

e. Perform the following on the South Header (located on the mezzanine level, above and betw een MCC 14 and Lube Oil Vapo Extractor) (ladder required) r

1) Open the South Header Dra in and Vent Valves:

MS94, SOUTH MAIN STEAM LINE ORN ROOT ISOL

MS-95, SOUTH MAIN STEAM LINE VENT ISOL

2) Throttle MS-96, SOUTH MAI N STEAM LINE VENT TO ATMOS ISOLATION, as directed by the RTGB operator.

- END -

86. 003 A2.03 SRO 001 Given the foHowing plant con ditions:

Initial Conditions:

Plant is operating at 100% RT P.

A RCP Motor Upper Thrust Bearing temperature indicates

- C RCP Motor Upper Guide Be 230° F.

aring temperature indicates 205

°F.

Current Conditions:

- RTBs open.

S/G Levels within normal ban d.

- Pressurizer pressure is normal.

Which ONE (1) of the following correctly describes whether RC required to be shutdown and wh Ps A and/or C are ether the conditions of LCO 3.4 3, are met? .5, RCS Loops Mode A. Both A and C RCPs are req uired to be secured.

Conditions of LCO 3.4.5 met.

B. A RCP is required to be sec ured. C RCP is NOT required to be secured.

Conditions of LCO 3.4.5 met.

C Both A and C RCPs are required to be secured.

Conditions of LCO 3.4.5 NOT met.

D. A RCP is required to be sec ured. C RCP is NOT required to be secured.

Conditions of LCO 3.4.5 NOT met.

Page: 156 of 187 10/13/2011

The correct answer is C.

f, A. Incorrect. The first part of dis tractor is correct. Both AOP-018 W that the RCP is to be tripped if any and AOP-014 state RCP motor bearing temperature 200°F. The conditions of LCO is greater than 3.4.5 are NOT met. LCO 3.4.5 loops be operable and one RCS req uir es that two RCS loop shall be in operation as lon open. Candidate may think tha g as the RTBs are t the loop is operable since the 16%. However, LCO 3.4.5 bas SIGs are greater than es states that an Operable RCS Operable RCP and one Operable loop consists of one SIG, which has a minimum water SR 3.4.5.2 (>= 16%). An RCP level specified in is Operable if it is capable of bei to provide forced flow if requir ng powered and is able ed. Since the B and C RCPs had high motor bearing temperatures to be secured due to then they are not available for ope ration.

B. Incorrect. Candidate incorrect ly assumed that operation of C greater than 200°F Motor Beari RCP is allowed at ng Temperature. The plausibility for RCP Pump Bearing temperatu for this is that the limit re is 225°F. See A above for remaining justification.

C. Correct.

D. Incorrect. Candidate incorrect ly assumed that operation of C greater than 200° F Motor Beari RCP is allowed at ng Temperature. The plausibil for RCP Pump Bearing temperatu ity for this is that the limit re is 225°F. It is plausible for the the conditions of LCO 3.4.4, RC candidate to apply S Loops Modes I and 2, to thi s situation and think

, that 3.4.5 are NOT met. LCO 3.4 -

.4 requires that all three loops operation. Also, the candidate be operable and in could have simply assumed tha three loops to be Operable. t LCO 3.4.5 required all Page: 157 of 187 10/13/2011

Question 86 Tier/Group 2/1 K/A Importance Rating - RO 2.7 SRO 3.1 Ability to (a) predict the impacts of the following malfunctions or operations on the RCPS; and (b) based on those predictions, use procedures to correct, control, or mitigate the consequences of those malfunctions or operations: Problems associated with RCP motors, including faulty motors and current, and winding and bearing temperature problems Reference(s) Sim/Plant design, APP-001, AOP-014, AOP-018, ITS 3.4.4, 3.4.5 Proposed References to be provided to applicants during examination None -

Learning Objective AOP-0 14-004 Question Source NEW -

Question Cognitive Level H -

10 CFR Part 55 Content 41.5 /43.5 / 45.3 /45.13 Comments -

SRO: Motor parameter being out of spec (above manual trip setpoint) requires RCPs to be secured, which renders RCS loops inoperable. Procedures, in the form of Tech Specs and AOPs, must be applied to mitigate the conditions. The question would qualify as SRO-only because the applicant must apply basis information to determine whether the loop is operable.

Reviewed and approved by MAB.

Page: 158 of 187 10/13/2011

87. 007 A2.05 SRQ 001 Given the following plant conditions:

- Plant is operating at 90% RTP following a refueling outage.

- PCV-455C, PZR PORV, has developed excessive seat leakage.

- APP-003-B3, PRT HI TEMP AND APP-003-C3, PRT HI PRESS, has alarmed.

- PRT Pressure is 6.1 psig and rising.

- RC-536, PZR PORV BLOCK, has been closed to isolate the leakage.

Which ONE (1) of the following completes the statements below?

lAW ITS LCO 3.4.11 Bases, PCV-455C (1) operable and power (2) required to be removed from RC-536.

A (1) is NOT (2) is NOT B. (1)is (2) is C. (1)is (2) is NOT D. (1)15NOT (2) is Page: 159 of 187 10/13/2011

The correct answer is A.

A. Correct.

B. Incorrect. ITS LCO 3.4.11 bases states that an Operable PORV is required to be capable of manually opening and closing, and not experiencing excessive seat leakage. This is a recent change to the ITS bases. In the past the bases did not address seat leakage. The PORV was only required to be capable of manually opening and closing to be considered operable. Candidate may think that since the PORV is leaking and must be isolated that it would be prudent to remove power to prevent inadvertent reinitiation of the PORV seat leakage.

C. Incorrect. ITS LCO 3.4.11 bases states that an Operable PORV is required to be capable of manually opening and closing, and not experiencing excessive seat leakage. This is a recent change to the ITS bases. In the past the bases did not address seat leakage. The PORV was only required to be capable of manually opening and closing to be considered operable. For this distractor the candidate incorrectly determines that the PORV is Operable. Therefore, it would seem logical that the PORV block valve would not have power removed.

D. Incorrect. The first part of the distractor is correct. The second part of the distractor would be correct if the PORV was inoperable and not capable of being manually cycled. In the situation given, the PORV is inoperable solely on the fact that it has excessive seat leakage.

Question 87 Tier/Group 2/1 K/A Importance Rating - RO 3.2 SRO 3.6 Ability to (a) predict the impacts of the following malfunctions or operations on the PRTS; and (b) based on those predictions, use procedures to correct, control, or mitigate the consequences of those malfunctions or operations: Exceeding PRT high-pressure limits Reference(s) Sim/Plant design, AOP-019, AOP-016 Proposed References to be provided to applicants during examination None -

Learning Objective AOP-016-002, AOP-019-002, PZROO4 Question Source NEW -

Question Cognitive Level H -

10 CFRPart55 Content- 41.5/43.5/45.3/45.13 Comments K/A match because candidate must determine the correct actions to take for a condition given that could lead to exceeding the pressure limits of the PRT.

SRO: The candidate must demonstrate knowledge of TS bases to determine the operability of a plant component.

Reviewed and approved by MAB.

Page: 160 of 187 10/13/2011

88. 022 G2.4.50 SRO O01 Given the following plant conditions:

- The plant is operating at 100% RTP.

- HVH-1 is OOS due to bearing damage.

- B CV Spray Pump is OOS due to a motor calcu lation error.

APP-002-A7, HVH-1/2/3/4 HI VIB, is received and the HIGH VIBRATION white light is illuminated for HVH-3.

Which ONE (1) of the following completes the statements below?

To verify the alarm the operator should (1)

If the alarm is valid, the most limiting ITS LCO condition(s) met requires that (2)

(REFERENCE PROVIDED)

A. (1) stop HVH-3, depress the vibration switch reset pushbutton, and then restart cn HVH-3 -

(2) the containment spray train AND one containm ent cooling train be restored to OPERABLE status in 72 hours8.333333e-4 days 0.02 hours 1.190476e-4 weeks 2.7396e-5 months B (1) depress the vibration switch reset pushbutto n

(2) entry into LCO 3.0.3 be performed immediately C. (1) stop HVH-3, depress the vibration switch reset pushbutton, and then restart HVH-3 (2) entry into LCO 3.0.3 be performed immediat ely D. (1) depress the vibration switch reset pushbutto n

(2) the containment spray train AND one containm ent cooling train be restored to OPERABLE statu s in 72 hours8.333333e-4 days 0.02 hours 1.190476e-4 weeks 2.7396e-5 months Page: 161 of 187 10/13/2011

The correct answer is B.

A. Incorrect. The fan does not need to be stopped to reset the vibration alarm.

Plausible since some components are requ ired to be stopped to reset various functions. The second half of the distractor is correct.

B. Correct.

C. Incorrect. The fan does not need to be stop ped to reset the vibration alarm.

Plausible since some components are required to be stopped to reset various functions. The second half of the distractor is also incorrect because HVH-1 and HVH-2 makeup one train of containment cool ing. Candidate may think that two HVH units being OOS equates to two containment trains being OOS.

D. Incorrect. The first half of the distractor is correct. The second half of the distractor is incorrect because HVH-1 and HVH-2 makeup one train of containment cooling.

Candidate may think that two HVH units bein g OOS equates to two containment trains being OOS.

Question 88 Tier/Group 2/1 K/A Importance Rating - RO 4.2 SRO 4.0 Containment Cooling System (CCS): Ability to verify system alarm setpoints and operate controls identified in the alarm resp onse manual.

Reference(s) Sim/Plant design, APP-002-A7, ITS 3.6.6 Proposed References to be provided to appl icants during examination ITS 3.6.6 Learning Objective CVHVAC 008 Question Source NEW-Question Cognitive Level H -

10 CFR Part 55 Content 41.10/43.5/45.3 Comments -

SRO: Application of Required Actions of Tech Specs.

Page: 162 of 187 10/13/2011

ALARM APP-002-A7 HVH-1/2/3/4 HI VIB AUTOMATIC ACTIONS

1. None Applicable CAUSE

1. Fan Starting

2. Fan out of balance

3. Fan loose at pedestal

4. Vibration Switch failure OBSERVATIONS

1. High Vibration alarm lights on RTGB.

2. HVH1, 2, 3, & 4 AIR FLOW LOST Annunci ators (APPOO2-A5, B5, C5, & D5)

ACTIONS CK (1

1. IF the AIR FLOW LOST annunciator is also illuminated, THEN STOP the affected fan.

2. ATTEMPT to Reset High Vibration alarm.

a) IF the alarm will NOT reset AND the fan is requ ired for plant operation, THEN DISPATCH personnel to check the affected fan vibration.

b) IF the fan is NOT required for plant operation

, THEN STOP the affected fan.

4. IF available, THEN START a standby Con tainment Recirc Cooler Fan.

5. IF local checks confirm high vibration, THE N CONTACT Engineering for investigation.

DEVICE/SETPOINTS

1. Vibration Switch /

POSSIBLE PLANT EFFECTS

1. Loss of HVH Fan

2. Possible entry into TECH SPEC LCO

3. CV elevated temperature.

REFERENCES

1. ITS LCD 3.6.6

2. CWD B-190628, Sh 511R APP-002 Rev. 62 Page 1 1 of 65

Containment Spray and Cooling Sys tems 3.6.6 3.6 CONTAINMENT SYSTEMS 3.6.6 Containment Spray and Cooling Sys tems LCO 3.6.6 Two containment spray trains and trains shall be OPERABLE. two containment cooling APPLICABILITY; MODES 1, 2, 3, and 4.

ACTI ONS CONDITION REQUIRED ACTION COMPLETION TIME

-=---

A. One containment spray A.1 train inoperable. Restore containment spray train to OPERABLE status.

10 days from discovery of failure to meet the LCO B. Required Action and B.1 associated Completion Be in MODE 3. 6 hours6.944444e-5 days 0.00167 hours 9.920635e-6 weeks 2.283e-6 months Time of Condition A AND not met.

B.2 Be in MODE 5. 84 hours9.722222e-4 days 0.0233 hours 1.388889e-4 weeks 3.1962e-5 months C. One containment C.1 cooling train Restore containment 7 days inoperable. cooling train to OPERABLE status.

10 days from discovery of failure to meet the LCO (continued)

HBRSEP Unit No. 2 3.6-15 Amendment No. 176

Containment Spray and Cooling Sys tems 3.6.6 ACTIONS (continued)

CONDITION REQUIRED ACTION COMPLETION TIME r

D. Two containment D.1 cooling trains Restore one ur) inoperable. containment cooling train to OPERABLE status.

r E. Required Action and E.1 associated Completion Be in MODE 3. 6 hours6.944444e-5 days 0.00167 hours 9.920635e-6 weeks 2.283e-6 months Time of Condition C or D not met.

E.2 Be in MODE 5. 36 hours4.166667e-4 days 0.01 hours 5.952381e-5 weeks 1.3698e-5 months F. Two containment spray F 1 trains inoperable.

Any combination of three or more trains inoperable.

SURVE I LLANCE_REQU I REMENTS SURVEI LLANCE FREQUENCY SR 3.6.6.1 Verify each containment spray man operated, and automatic valve in ual, power 31 days path that is not locked, sealed, or the flow otherwise secured in position is in correct position. the (continued)

HBRSEP Unit No. 2 3.6-16 Amendment No. 176

Containment Spray and Cooling Sys tems 3.6.6 SURVEILLANCE REQUIREMENTS (continued)

SURVEILLANCE FREQUENCY SR 3.6.6.2 Operate each containment cooling unit for train fan 31 days 15 minutes.

SR 3.6.6.3 Verify cooling water flow rate to cooling unit is each 31 days 750 gprn.

SR 3.6.6.4 Verify each containment spray developed head at the flow testpumps In accordance greater than or equal to the requirepoint is with the developed head. d Inservice Testing Program SR 3.6.6.5 Verify each automatic containment valve in the flow path that is not spray 18 months sealed, or otherwise secured in poslocked, actuates to the correct position on ition, actual or simulated actuation sign an al.

SR 3.6.6.6 Verify each containment spray pum automatically on an actual or simpulat starts 18 months actuation signal. ed SR 3.6.6.7 Verify each containment cooling tra starts automatically on an actual in 18 months simulated actuation signal. or SR 3.6.6.8 Verify each spray nozzle is unobstr ucted. Following activities which could result in nozzle blockage HBRSEP Unit No. 2 3.6-17 Amendment No. 4-36 194

89. 059 A2.03 SRO 001 Given the following plant conditions:

- The plant has experienced a Small Break LOCA inside Containment.

- PATH-i is currently being implemented.

- The BOP became distracted and allowed AFW to feed the S/Gs to the following Narrow Range levels.

-ASIG 2%

-BS/G 10%

- C S/G: 86%

Which ONE (1) of the following completes the statement below?

The major concern with C S/G is the (i) and isolation of feedwater to C S/G is required to be performed lAW (2)

A (1) increased dead weight and water hammer effects on main steamlines (2) FRP-H.3, Response to Steam Generator High Level B. (1) increased dead weight and water hammer effects on main steamlines (2) Supplement G, Steam Generator Isolation C. (1) increased dead weight on the S/G vessel external supports in the CV (2) FRP-H.3, Response to Steam Generator High Level D. (1) increased dead weight on the S/G vessel external supports in the CV (2) Supplement G, Steam Generator Isolation Page: 163 of 187 10/13/2011

The correct answer is A.

A. Correct.

B. Incorrect. The first part of the distractor is correct. The second half of the distractor would reduce S/C level, however, FRP-H.3 has the operator isolate steam prior to draining the SIG.

C. Incorrect. The SIC supports would experience a higher load, however, the S/C supports are designed to handle full S/Cs as experienced during cold shutdown conditions when SIGs are placed in wet layup. The steam line supports may be challenged and the need for additional bracing is addressed in FRP-H.3. The second half of the distractor is correct.

D. Incorrect. The SIG supports would experience a higher load, however, the S/C supports are designed to handle full S/Gs as experienced during cold shutdown conditions when S/Cs are placed in wet layup. The steam line supports may be challenged and the need for additional bracing is addressed in FRP-H.3. The second half of the distractor would reduce S/G level, however, FRP-H.3 has the operator isolate steam prior to draining the SIG.

The S/C supports would experience a higher load, however, the SIG supports are designed to handle full S/Cs as experienced during cold shutdown conditions when S/Cs are placed in wet layup. The steam line supports may be challenged and the need for additional bracing is addressed in FRP-H.3.

Question 89 Tier/Group 1/1 K/A Importance Rating - RO 3.7 SRO 3.9 Ability to (a) predict the impacts of the following malfunctions or operations on the MEW; and (b) based on those predictions, use procedures to correct, control, or mitigate the consequences of those malfunctions or operations: Overfeeding event Reference(s) Sim/Plant design, APP-006-F2, FRP-H.3, FRP-H.3BD, Supplement G.

Proposed References to be provided to applicants during examination None -

Learning Objective FRP-H.3-003 Question Source NEW -

Question Cognitive Level H -

10 CFR Part 55 Content- 41.5 /43.5 /45.3 /45.13 Comments Originally had increased dead weight on the steam generator vessel supports. However, every validator chose this distractor due to it being so similar to the concern with the structural concerns associated with the steam lines.

SRO: Assessing plant conditions and then selecting a procedure to mitigate, recover, or

, with which to proceed. Procedure selection that is not a major EOP or Red/Orange FRP. The procedure required to be selected is a Yellow priority FRP. Also, testing the knowledge of the basis for the FRP.

Page: 164 of 187 10/13/2011

APP-006-F2 ALARM SIG C NAR RANGE HI LEVEL ***

WILL REFLASH AUTOMATIC ACTIONS

1. None Applicable CAUSE

1. Instrument Channel Failure:

1) Steam Flow

2) Feedwater Flow

3) Steam Generator Level

2. Level Control System Failure

3. Increase in Steam Flow

4. Excessive Auxiliary Feedwater Flow OBSERVATIONS

1. Steam Generator Level

2. Feedwater Flow

3. Steam Flow

4. Turbine First Stage Pressure

5. AFW Pump Discharge Flows ACTIONS CK (/)

1. IF an Instrument Channel supplying SGLC has failed, THEN refer to AOP-025.

2. IF Feedwater Control failure, THEN refer to AOP-01 0.

3. IF an Instrument Channel NOT supplying SGLC has failed, THEN removed from service using OWP-027.

DEVICE/SETPOINTS

1. LC-494, LC-495, LC-496 I 60% of span LC-494-1(X-1), LC-494-1(X-2), LC-495-1(X-1), LC-495-1(X-2), LC-496-1(X-1), LC-496-1(X-2) I 75% of span (reflash)

POSSIBLE PLANT EFFECTS

1. FW Isolation signal occurs at 75% causing a Turbine Trip.

REFERENCES

1. ITS Table 3.3.1-1 Item 13, Table 3.3.3-1 Item 13

2. AOP-010, Main Feedwater/Condensate Malfunction

3. AOP-025, RTGB Instrument Failure

4. OWP-027, Steam Generator Level

5. CWD B-190628: Sheet 399, Cable L; Sheet 417, Cable M; Sheet 420, Cables K, Q APP-006 Rev. 30 Page 30 of 34

CONTINUOUS USE H. B. ROBINSON STEAM ELECTRIC PLANT, UNIT NO. 2 PLANT OPERATING MANUAL VOLUME 3 PART 4 FUNCTION RESTORATION PROCEDURE FRP-H.3 RESPONSE TO STEAM GENERATOR HIGH LEVEL REVISION 10 Page 1 of 7

Rev. 10 FRP-H.3 RESPONSE TO STEAM GENERATOR HIGH LEVEL Page 3 of 7 Purpose and Entry Conditions (Page .1 of 1)

1. PURPOSE This procedure provides actions to respond to a steam genera tor high level condition and to address the steam generator overfil l

concern.

2. ENTRY CONDITIONS

a. CSF-3, Heat Sink Critical Safety Function Status Tree on a

YELLOW condition.

b. FRP-H.2, Response To Steam Generator Overpressure. if the affected S/G level is high.

c. FRP-H.4, Response To Loss Of Normal Steam Release Capability, if the affected S/C level is high.

- END -

Rev. 10 FRP-H.3 RESPONSE TO STEAM GENERATOR HIGH LEVEL Page 4 of 7 f__STEP INSTRUCTIONS I I RESPONSE NOT OBTAINED CAUTION Steam release from any S/C with level greater than 84% [82%] could result in damage to the Steamlines.

NOTE Throughout this procedure. affected refers to any S/G in which level is greater than 75%. Overfilled refers to any S/G in which level is greater than 84% [82%]

1. Check Any S/G level - GREATER Reset SPDS return to THAN 75% procedure and step in effect.

2. Determine If A S/C Evaluation Is Needed:

a. Check Any S/G - GREATER THAN a. I level increases above 84%

84% [82%] [82%]. IIIN perform Step 2.b.

Go To Step 3.

b. Contact Operations Staff to have an evaluation performed on the S/G for overfilled con iderations tab1ishFWIsolationAs

a. Verify FW PUMPS A AND B -

S TOPPED

b. Verify affected S/C(s) FW REG Valves - CLOSED

c. Verify affected S/G(s) FW REG BYP Valves - CLOSED

d. Verify affected S/C(s) FW HOR SECTION Valves- CLOSED

Rev. 10 FRP-H.3 RESPONSE TO STEAM GENERATOR HIGH LEVEL Page 5 of 7 H__STEP_H INSTRUCTIONS I RESPONSE NOT OBTAINED

4. Isolate AFW Flow To Affected S/C(s)

5. Check Affected S/G(s) Level:

a. S/C level - LESS THAN 84% a. Go To Step 6.

[8 2%]

b. S/C level - DECREASING b. Go To Step 6.

c. Control AFW flow to maintain level between 8% [18%] and 50%

d. Reset SPDS AND return to procedure and step in effect

6. Isolate Overfilled S/C(s) As Follows:

a. Verify affected S/C(s) PORV controller setpoint to 1035 psig

b. Verify the affected S/C(s)

MSIV AND MSIV BYP - CLOSED

c. Maintain steam supply to the SDAFW Pump from at least one S/G

d. Verify the affected S/C(s)

STEAM SHUTOFF to SDAFW Pump -

CLO S ED

e. Locally verify the affected S/C(s) Warmup Steam Supply Valve to SDAFW Pump - CLOSED

f. Locally verify the affected S/C(s) MSIV Above and Below Seat Drains - CLOSED

7. Contact Operations Support Staff To Evaluate Need To Brace Steam Lines Due To Dead Weight Loads Caused By Water In The Lines, While Continuing With This Procedure

Rev. 10 FRP-H.3 RESPONSE TO STEAM GENERATOR HIGH LEVEL Page 6 of 7 H__STEP H INSTRUCTIONS I I RESPONSE NOT OBTAINED I

NOTE The POST ACCIDENT SAMPLING PHASE A CV ISOLATION OVERRIDE Key Switches may be used to monitor affected S/G(s) blowdown for radiation.

8. Check The Following Radiation Go To Step 11.

Monitors For The Affected S/G(s) -INCREASING OR IN ALARM

R-19(s), S/G Blowdown Radiation Monitor OR

R-31(s). S/G Steamline Radiation Monitor

9. Check Any Of The Following SGTR Reset SPDS A Go To PATH-2.

EPPs - IN EFFECT: Entry Point J.

EPP-12, Post-SGTR Cooldown Using Backfill

EPP-13, Post-SGTR Cooldown Using Blowdown EPP-14, Post-SGTR Cooldown Using Steam Dump

EPP-17. SGTR With Loss Of Reactor Coolant: Subcooled Recovery

EPP-18, SGTR With Loss Of Reactor Coolant: Saturated Recovery

EPP-19, SGTR Without Pressurizer Pressure Control

10. Reset SPDS AND Return To Procedure And Step In Effect

Rev. 10 FRP-H.3 RESPONSE TO STEAM GENERATOR HIGH LEVEL Page 7 of 7

__STEP H INSTRUCTIONS I I RESPONSE NOT OBTAINED I

CAUTION During performance of subsequent steps to drain the affected S/C(s).

unisolation of the steam release paths from overfilled S/C(s) before the overfill evaluation has been completed could result in damage.

11. Initiate Draindown Of Affected S/G(s):

Establish normal S/C blowdown OR

Use the S/G blowdown/wet layup system OR

Use other appropriate drain paths

12. Reset SPDS AND Return To Procedure And Step In Effect

- END -

NON Progress Energy POM H. B. ROBINSON STEAM ELECTRIC PLANT, UNIT NO. 2 FRP-H. 3-BD FRP-H3 BASIS DOCUMENT REVISION 10 FRP-H.3-BD Rev 10 Page 1 of 10

DISCUSSION (From the WOG FR-H.3 Basis Document)

1. INTRODUCTION Guideline FR-H.3, RESPONSE TO STEAM GENERATOR HIGH LEVEL, provides guidance to address a not satisfied condition (i.e., YELLOW priority) for secondary system inventory that results from a high level condition in any SG.

Since the Optimal Recovery Guidelines (ORG5) address the restoration and maintenance of SG narrow range levels following a reactor trip condition, guideline FR-H.3 is considered a YELLOW priority.

Guideline FR-H.3 has been developed and structured to maintain secondary heat sink control, and to provide the utility with an appropriate criterion at which to address the steam generator overfill concern and its implications. The actual evaluation of steam generator overfill status and all of the actions necessary to restore an overfilled SG to service are not addressed in guideline FR-H.3. Steam generator overfill and its potential consequences are the subject of Nuclear Regulatory Commission (NRC) Generic Letter 81-28, dated July 31, 1981 (Reference 1). This letter requested utilities to evaluate credible plant-specific scenarios and include appropriate information in plant-specific training programs stressing the possible consequences of steam generator overfill.

The objective of guideline FR-H.3 is to prevent the levels in the SGs from increasing above the narrow range span so that each SG remains effective for secondary heat removal. In addition, this guideline utilizes the margin between the SG high-high level signal and the top of the narrow range span to prevent an overfill condition. Effectiveness of all steam generators is necessary to permit the operator to optimally control secondary heat sink in responding to a plant emergency.

There are two entries into guideline FR-H.3. One is from a YELLOW priority on the Heat Sink Critical Safety Function Status Tree, F-O.3, based on operator judgement. The other entry is from FR-H.2, RESPONSE TO STEAM GENERATOR OVERPRESSURE, Step 3, if the affected SG narrow range level is high.

Guideline FR-H.3 may be exited at several locations. When all actions of this guideline have been completed, or after it has been determined that SG narrow range levels are below the upper tap and decreasing, the operator is instructed to return to the guideline and step that was in effect when FR-H.3 was entered. In addition, if the affected SG(s) has abnormal radiation indications, the operator is directed to E-3, STEAM GENERATOR TUBE RUPTURE, unless an E-3 or ECA-3 series guideline is in effect, in which case the operator returns to that guideline.

2. DESCRIPTION SG high level can constitute an initiating event that results in a reactor trip or can occur in combination with other plant conditions following a reactor trip.

Following a reactor trip, either the reactor trip (P-4) signal in combination with a low Tavg signal or an SI signal will isolate main FW flow to the SGs. Depending on the plant condition, the auxiliary feedwater (AFW) system is manually or automatically actuated to establish AFW flow to the steam generators consistent with core decay heat removal requirements.

Following actuation of FW isolation, the operator verifies in E-O, REACTOR TRIP OR SAFETY INJECTION, that appropriate FW control and isolation valves are closed. This ensures that the SGs will not overfill due to excessive main FW addition. The operator then controls AFW flow to restore and maintain the required SG narrow range level.

Through verification of FW isolation and control of AFW flow, guideline FR-H.3 is compatible with the Optimal Recovery Guidelines in the restoration and maintenance of SG narrow range level.

A steam generator high level condition may also occur due to a steam generator tube rupture. The recovery technique utilized in guideline FR-H.3 determines if a SGTR exists and then transfers the operator to the E-3 or ECA-3 series guideline as appropriate.

3. RECOVERY/RESTORATION TECHNIQUE The objective of the recovery/restoration technique incorporated into guideline FR-H.3 is to respond to a SG high level condition and to address the SG overfill concern.

The following subsections provide a summary of the major categories of operator actions and the key utility decision points for guideline FR-H.3, RESPONSE TO STEAM GENERATOR HIGH LEVEL.

FRP-H.3-BD Rev 10 Page 3 of 10

3.1 High Level Action Summary A high level summary of the actions performed in FR-H.3 is given in the form of major action categories. These are described below in more detail.

MAJOR ACTION CATEGORIES IN FR-H.3 o Isolate Affected SG o Check Affected SG Radiation o Establish Blowdown from the ffected SG o Isolate Affected SG After identifying the affected SG, the operator should verify that the main FW pumps are stopped and main FW to the affected SG is isolated. This ensures that no main FW addition will cause the SG level to increase further.

The operator isolates AFW flow to the affected SG to minimize the level increase in the affected SG. With main FW and AFW isolated, no other normal source of water addition is available. The operator should then check the affected SG level to determine if level is still in the narrow range. If level is still in the narrow range, the operator should control AFW flow to decrease the affected SG level. If the operator is successful in reducing level by throttling AFW flow, the operator is transferred to the guideline and step in effect.

If the affected SG level either fails to decrease after AFW isolation or increases above the narrow range, the operator should proceed to isolate the affected SG steam release paths. If level increases above the narrow range, the operator cannot monitor level and cannot ensure that the SG does not overfill. If level fails to decrease, this may be an indication of either isolation valve leakage or steam generator tube rupture.

o Check Affected SG Radiation Having isolated the affected SG, the operator should evaluate if the affected SG is ruptured by checking its radiation level. If the affected SG is ruptured, the operator is transferred to an E-3 or ECA-3 series guideline, as appropriate.

o Establish Blowdown from the Affected SG If the affected SG radiation levels are normal, blowdown is established to reduce the level in the affected SG into the normal operating band.

3.2 Key Utility Decision Points There is one key utility decision point in this guideline when the utility must determine an appropriate course of action.

After it has been determined that SG narrow range level has increased to greater than a value corresponding to SG level at the upper tap, an evaluation should be made for SG overfill considerations. The utility must address the methods to be used for the SG overfill evaluation and the actions necessary to return an overfilled SG to service.

Guideline FR-H.3 alerts the operator of the need for an evaluation and steam release restrictions, but does not provide the specifics for the evaluation or subsequent actions to address an overfilled SG. The NRC Generic Letter 81-28 (Reference 1) provides information and requirements for utilities to develop the necessary actions to respond to an overfilled SG.

FRP-H.3-BD Rev 10 Page 4 of 10

STEP SPECIFIC DESCRIPTION AND RNP DIFFERENCES The following pages will provide the RNP step number, the ERG step number, the WOG basis for each step where applicable, the differences between the ERG and RNP step, and the Category of deviation (SSD).

RNP WOG BASIS/DIFFERENCES STEP STEP PEC PEC WOG BASIS N/A, there is no WOG basis description for the PEC, other than the general description.

RNP DIFFERENCES/REASONS The RNP entry conditions include entry from FRP-H.i. WOG FR-H.4 contains a caution pertaining to steam release from a S/G with high level. This caution has been incorporated in FRP-H.4 as a step in order to eliminate action steps in cautions and notes. As part of the step, a transition to FRP-H.3, was added since the caution dealt with high level and FRP-H.3 is the procedure for high level.

SSD DETERMINATION This is an SSD per criterion 10 and ii.

Ci Ci WOG BASIS PURPOSE: To alert the operator to the potential of overfilling the steam generator to the point where water may have entered the steam lines BASIS:

If the affected SG level has increased above the narrow range, the operator cannot be sure if the SG is filled to the steamline. The objective of the status evaluation is to determine if water is in the steamline. Just decreasing affected SG level into the narrow range does not ensure that water does not remain in the affected SG steamline. An evaluation of the steamline conditions should occur prior to releasing steam from any SG with level above (M.08)% [(M.09)% for adverse containment] to prevent potential damage to piping, valves, or turbines.

KNOWLEDGE:

Understanding of potential effects of SG overfill, including:

Valve inoperability due to effects of water or two-phase flow

Water hammer effects on main steam lines

Increased dead weight placed on the mn steamline and its supports RNP DIFFERENCES/REASONS The RNP caution has been reworded and part of the caution moved to step 2 in order to eliminate action steps within the cautions and notes.

SSD DETERMINATION This is an SSD per criterion ii.

Ni Ni WOG BASIS PURPOSE: To define the terminology used in the guideline BASIS:

The definition of the word affected SG reduces descriptive requirements throughout the remainder of the guideline.

RNP DIFFERENCES/REASONS There are essentially no differences.

FRP-H.3-BD Rev 10 Page 5 of 10

RNP WOG BASIS/DIFFERENCES STEP STEP SSD DETERMINATION There are essentially no differences.

WOG BASIS PURPOSE: To identify the specific SG that is affected BASIS:

If the operator confirms that any steam generator narrow range level is above the high-high level feedwater isolation setpoint, he has identified the affected SG and continues in guideline FR-H.3. If all steam generator levels are less than this value, there is no affected SG and the operator is transferred to the guideline in effect. The steam generator high-high level feedwater isolation setpoint is selected for entry into guideline FR-H.3 since steam generator level should always be controlled below this value.

RNP DIFFERENCES/REASONS There are essentially no differences.

SSD DETERMINATION This is not an SSD.

2 Cl WOG BASIS See above.

RNP DIFFERENCES/REASONS The RNP step has included an action step to check S/G level for an overfilled condition.

This was removed from the ERG caution. The RNP procedure places the caution or note in an action step to prevent actions within cautions and noted as required by the writers guide.

SSD DETERMINATION This is an SSD per criterion 11.

3 2 WOG BASIS PURPOSE: To verify the automatic FW protective actions of the SG high-high level signal BASIS:

The operator should immediately verify FW pump trip and FW isolation. If the FW pumps have not tripped, the operator should manually trip them to remove the high pressure source of water to the affected SG. The main feedwater control, bypass and isolation valves should be verified as closed or should be manually closed. This step addresses the possibility that a valve may have failed to automatically close for the automatic feedwater isolation that accompanied the SG high-high level signal.

RNP DIFFERENCES/REASONS There are essentially no differences.

SSD DETERMINATION This is not an SSD.

FRP-H.3-BD Rev 10 Page 6 of 10

RNP WOG BASIS/DIFFERENCES STEP STEP 4 3 WOG BASIS PURPOSE: To isolate AFW flow as a potential source of water overfilling the affected SG(s)

BASIS:

AFW flow isolation to the affected SG(s) allows the operator to minimize further level increases. AFW flow can still be maintained to the unaffected SG(s) to control plant conditions.

RNP DIFFERENCES/REASONS There are essentially no differences.

SSD DETERMINATION This is not an SSD.

5 4 WOG BASIS PURPOSE: To evaluate the effects of main FW and AFW isolation actions BASIS:

The operator should continue to monitor affected steam generator narrow range level to determine if level is decreasing. If level is less than the value corresponding to SG level at the upper tap and decreasing, operator actions have been successful. The operator then controls AFW flow to maintain narrow range level in the normal operating band and transfers back to the guideline in effect to continue plant recovery. If level is still above the upper tap value or level is not decreasing, the operator is directed to Steps 5 through 8 where the affected SG(s) is isolated and evaluated for a possible tube failure.

RNP DIFFERENCES/REASONS There are essentially no differences.

SSD DETERMINATION This is not an SSD.

FRP-H.3-BD Rev 10 Page 7 of 10

RNP WOG BASIS/DIFFERENCES STEP STEP 6 5, C6, WOG BASIS 6, & 7 ERG Step 5 (step 6.a)

PURPOSE: To prevent steam release through the SG PORVs when the affected SG level(s) is above the upper tap BASIS:

The setpoint should be greater than no-load pressure in order to minimize the steam releases from the affected SG and less than the minimum safety valve setpoint to prevent lifting of the code safety valves. The 25 psi margin is a typical value to allow for opening of the PORV prior to lifting of the safety valve.

KNOWLEDGE:

N/A ERG C6 (step 6.c)

PURPOSE: To warn the operator that the steamline to the turbine-driven AFW pump must not be isolated if it is the only source of feed flow to the steam generators BASIS:

If the turbine-driven AFW pump is the only operable source of feed flow to the steam generators (i.e.,no other MD AFW pumps or other operable pumps are capable of providing feed flow to the SGs), then isolation of its steam supply line may degrade system conditions and result in a transition to FR-H.1. Therefore, this isolation must not be performed.

ERG Step 6 (step 6.d & 6.e)

PURPOSE: To isolate the affected SG in order to minimize the potential for radioactive steam releases from the affected SG and to minimize the potential release of two-phase flow in the steamlines which could result in damage to piping, valves and turbines.

BASIS:

The operator arrives at this step after main FW and AFW isolation is completed because level is either above the upper tap or is not decreasing. This indicates a possible SG overfill condition and/or tube rupture. Therefore, the SG steam paths are isolated to prevent potential damage to piping, valves and turbines from two-phase flow and to minimize radioactive steam releases if a SGTR exists.

ERG Step 7 (step 6.a)

PURPOSE: To isolate the affected SG in order to minimize the potential for radioactive steam releases from the affected SG and to minimize the potential release of two-phase flow in the steamlines which could result in damage to piping, valves and turbines.

BASIS:

The operator arrives at this step after main FW and AFW isolation is completed because level is either above the upper tap or is not decreasing. This indicates a possible SG overfill condition and/or tube rupture. Therefore, the SG steam paths are isolated to prevent potential damage to piping, valves and turbines from two-phase flow and to minimize radioactive steam releases if a SGTR exists.

RNP DIFFERENCES/REASONS The RNP step has combined the ERG steps since they all involve S/G isolation. The RNP step includes the caution from ERG C6 to prevent actions within cautions and notes as required by the writers guide. The RNP step has also included a step for the steam line drains as these are also common valves closed for S/G isolation. The intent of the ERG has not been changed.

FRP-H.3-BD Rev 10 Page 8 of 10

RNP WOG BASIS/DIFFERENCES STEP STEP SSD DETERMINATION This is an SSD per criterion 10 and 11.

7 N/A WOG BASIS N/A, this step is not in the WOG ERG.

RNP DIFFERENCES/REASONS This step was added to support the response to Generic Letter 81-28. Analysis of the steam lines may require structural bracing to prevent failure. This will be evaluated by staff personnel.

SSD DETERMINATION This is an SSD per criterion 10.

N8 8 WOG BASIS See below.

RNP DIFFERENCES/REASONS This note has been added as an additional resource for monitoring S/G radiation as noted in the ERG step 8 for plant specific means. The Phase A Override Key Switches may be used for drawing S/G samples for the presence of activity.

SSD DETERMINATION This is an SSD per criterion 4.

8-10 8 WOG BASIS PURPOSE: To check the affected SG for a SG tube rupture BASIS:

Steam generator level increasing or above the narrow range with main FW and AFW flow isolated is one symptom of a steam generator tube rupture. In this step another symptom of a steam generator tube rupture is checked, i.e., abnormal radiation level in the SG. If radiation levels are normal, the operator proceeds in guideline FR-H-3. If radiation levels are abnormal, the affected steam generator is determined to be ruptured and a transition to the appropriate Optimal Recovery Guideline (ORG) is made. If the guideline in effect is an E-3 or ECA-3 series guideline, the operator is addressing steam generator tube rupture recovery in the optimal manner and should return to that guideline. If the guideline in effect is not an E-3 or ECA-3 series guideline, the operator should go to guideline E-3, STEAM GENERATOR TUBE RUPTURE, to address a steam generator tube rupture.

KNOWLEDGE:

How to obtain secondary radiation level readings including signals that may need to be reset

Normal means the value of a process parameter experienced during routine plant operations.

FRP-H.3-BD Rev 10 Page 9 of 10

RNP WOG BASIS/DIFFERENCES STEP STEP RNP DIFFERENCES/REASONS Plant specific means have been included as directed by the ERG. Radiation Monitor R-15 has not been included in the secondary monitors listed since it is expected at this time for the Turbine to be tripped. In addition, the MSIVs and Bypasses for the affected S/G have been closed by previous steps, thus removing a pathway to monitor R-15.

The ERG RNO step has been placed as a separate step in order to provide a listing of all the E-3 & ECA-3 series procedures. The RNP procedure will return the operator to the ECA-3 series steps directly if these procedure were in effect at the time of entry to this procedure.

SSD DETERMINATION This is an SSD per criterion 4.

Cli N/A WOG BASIS N/A, this step is not in the WOG ERG.

RNP DIFFERENCES/REASONS S/Gs have been previously isolated to prevent damage due to the overfill condition. A step to direct evaluation of the overfilled condition prior to commencing steam release is in effect. This caution serves as a reminder that the evaluation must be completed prior to blowdown.

SSD DETERMINATION This is an SSD per criterion 10.

ii 9 WOG BASIS PURPOSE: To reduce affected SG level into the normal operating range through blowdown BASIS:

Level must be decreased into the normal operating range prior to restoring the SG to service. SG blowdown can be used to decrease the affected SG(s) level since Step 8 verified a normal radiation level is present.

RNP DIFFERENCES/REASONS Plant specific means are listed as directed by the ERG.

12 10 SSD DETERMINATION PURPOSE: To direct the operator to the proper guideline following successful completion of the steps in this guideline BASIS:

The operator has done everything possible to mitigate the SG high level condition.

Therefore, the operator should continue plant recovery operations by returning to the guideline and step that was in effect at the time FR-H.3 was entered.

WOG BASIS There are essentially no differences.

RNP DIFFERENCES/REASONS This is not an SSD.

FRP-H.3-BD Rev 10 Page 10 of 10

90. 064 G2.4.46 SRO 001 Given the following plant conditions.

- The plant was at 100% power and experienced reactor trip coincident with a loss of the SUT.

- A and B EDG are supplying power to 480V buses E-1 and E-2.

- APP-010-E5, EDG RM A COOL FAN HI TEMP/OVLD, alarm is received.

- Readings from a calibrated temperature instrument indicate that EDG A room is at 128°F.

Which ONE (1) of the following completes the statements below?

A EDG (I) required to be declared inoperable. The actions required due to the alarm and temperature reading is to (2)

A (1) is NOT (2) notify the System Engineer to investigate the cause and initiate corrective action lAW APP-010-E5 B. (1) is NOT (2) shutdown lAW OP-604, Diesel Generators A and B C. (1)is (2) notify the System Engineer to investigate the cause and initiate corrective action lAW APP-010-E5 D. (1)is (2) shutdown lAW OP-604, Diesel Generators A and B Page: 165 of 187 10/13/2011

The correct answer is A.

A. Correct- Per APP-010-E5, the EDG A must not be declared inoperable unless the room exceeds 130°F. With the high temperature the system engineer must be notified and the cause of the alarm must be investigated and corrective actions initiated.

B. Incorrect. The first part of the distractor is correct. If the EDG was running for testing and the high temperature / alarm was due to a fan breaker tripping then the EDG would be shutdown lAW OP-604. Fan operation is not discussed in the stem of the question.

This makes this distractor plausible.

C. Incorrect. The EDG room temperature must exceed 130°F prior to requiring that the EDG be declared OOS. The second part of the distractor is correct.

D. Incorrect The EDG room temperature must exceed 130°F prior to requiring that the EDG be declared OOS. If the EDG was running for testing and the high temperature I alarm was due to a fan breaker tripping then the EDG would be shutdown lAW OP-604. Fan operation is not discussed in the stem of the question.

This makes this distractor plausible.

Question 90 Tier/Group 2/1 K/A Importance Rating - RO 4.2 SRO 4.2 Emergency Diesel Generator: Ability to verify that the alarms are consistent with the plant conditions.

Reference(s) Sim/Plant design, APP-010, OST-401-2, OP-604 Proposed References to be provided to applicants during examination None -

Learning Objective EDGO6 Question Source NEW Question Cognitive Level H -

10 CFR Part 55 Content 41.5 /43.5 /45.3 / 45.13 Comments K/A match because candidate know the high temperature limit for EDG operability.

SRO: Candidate must assess plant conditions and then select a procedure to mitigate the conditions given. In this situation the SRO must know the content of APP-01 0-E5.

10/13/2011 Page: 166 of 187

91. 011 G2.2.38 SRO 001 Given the foflowing plant conditions:

- Plant is in Mode 3.

- PZR level transmitter LT-459 fails LOW.

- No operator actions are taken.

- At 1700 PZR level is 85.1% and rising at a rate of 0.5%/mm.

- PZR pressure is being maintained constant.

Which ONE(1) of the following completes the statements below?

At the current rate of level rise (1) is the EARLIEST time at which the ITS 3.4.9, Pressurizer, will NOT be met.

The bases for the limit in this Mode is to ensure that the (2)

A. (1) 1712 (2) RCS does NOT go solid when criticality is achieved and preserves a steam space for pressure control B (1) 1714 (2) RCS does NOT go solid when criticality is achieved and preserves a steam space for pressure control C. (1) 1712 (2) PZR level remains within the calibrated level range and provide protection against water relief through the PZR PORVs D. (1) 1714 (2) PZR level remains within the calibrated level range and provide protection against water relief through the PZR PORVs Page: 167 of 187 10/13/2011

The correct answer is B.

A. Incorrect. The time given is based on the Pressurizer Water Level - High reactor trip setpoint of 91%. The second half of the answer is correct.

B. Correct.

C. Incorrect. The time given is based on the Pressurizer Water Level High reactor trip setpoint of 91 %. The last half of the second distractor is from the basis for the Pressurizer Water Level-High reactor trip with the exception that it is to provide protection against water relief through the pressurizer safety valves. The PZR level indication is calibrated throughout the full range of indication.

D. Incorrect. The first half of the distractor is correct. The last half of the second distractor is from the basis for the Pressurizer Water Level-High reactor trip with the exception that it is to provide protection against water relief through the pressurizer safety valves. The PZR level indication is calibrated throughout the full range of indication.

Question 91 Tier/Group 2/2 K/A Importance Rating - RO 3.6 SRO 4.5 Pressurizer Level Control System (PZR LCS): Knowledge of conditions and limitations in the facility license.

Reference(s) - Sim/Plant design, System Description, ITS 3.4.9, ITS 3.4.9 Bases Proposed References to be provided to applicants during examination None -

Learning Objective PZR 010, 012 Question Source - NEW Question Cognitive Level H -

10 CFR Part 55 Content 41.6 / 45.4 Comments -

SRO: Knowledge of TS bases.

Page: 168 of 187 10/13/2011

SD-059 PRESSURIZER SYSTEM the CV.

The PRT is normally filled to 70% with primary water. A 3 psig nitrogen atmosphere is maintained in the PRT to blanket the water. Primary water may be added to the tank by use of the primary water pumps and valves operated from the RTGB. Water may also be drained from the tank by utilizing either of the RCDT pumps and valves operated from the WDBRS panel.

Steam discharged to the PRT from the PZR PORVs and Safeties is directed to the sparger, a pipe containing spray nozzles, near the bottom of the PRT. This allows the high energy steam to be quenched in the water of the PRT. This will allow limited discharge of steam to the PRT before the pressure in PRT raises sufficiently to rupture the rupture discs.

4.0 INSTRUMENTATION 4.1 PZR Instrumentation

4. 1. 1 Temperature Instrumentation The following temperature elements provide indication and alarm on the RTGB:

1. PZR Liquid Space (TE-453)

2. PZR Steam Space (TE-454)

3. PZR Spray Line (TE-451 and 452)

4. PZR Surge Line (TE-450)

5. Discharge of PORVs (TE-463) and each Safety Valve (TE-465, 467, and 469) 4.1.2 Level Three PZR level transmitters, calibrated at normal operating temperatures, are used to provide signals for reactor protection (High Level Trip).

1. LT-459

2. LT-460

3. LT-461 One PZR level signal, LT-462, is provided for indication when the system is in cold condition and therefore is calibrated at cold conditions.

Channels 459, 460, and 461 are used in protection and are available for control functions by a switch on the RTGB. Normally, Channels 459 and 460 are used for control, and PZR Page 13 of 27 Revision 9 INFORMA TION USE ONL Y

SD-059 PRESSURIZER SYSTEM either can be replaced by Channel 461. Channel 459 normally provides signal for charging pump speed control, set point deviation alarm, and will turn on backup heaters (if they are in automatic) on a high level error signal to heat incoming water. Either control channel can provide a letdown isolation signal (shut 460A and B in the CVCS system) and turn off all PZR heaters.

There is an additional PZR level signal LT-607D used for indication on the Dedicated Shutdown panel.

4.1.3 Pressure There are eight pressure transmitters on the PZR.

1. PT-445

provides a signal for operating power operated relief valve PCV-456.

provides a high and low pressure alarm.

provides pressure indication on the RTGB.

2. PT-444

provides pressure indication on the RTGB and at the motor driven auxiliary feedwater pump station.

provides signal to a proportional plus reset controller (PC-444J) on the RTGB.

provides signal to PC-444J for operating power operated relief valve PCV 455C.

provides signal to PC-444J for spray valves PCV-455A and B.

provides signal to PC-444J for heater control and high controller output alarm.

3. PT-455, 456, and 457 Are the three PZR pressure protection channels that supply the following to reactor protection and safeguards:

High PZR Pressure Trip. (2376 psig)

Low PZR Pressure Trip. (1844 psig) rate sensitive

Low Pressure Signal for Safety Injection. (1715 psig)

Block permissive/auto unblock of low pressure and steam line DP safeguards and block power operated relief valve (PORV) opening.

Input to over temperature Delta-T Reactor Trip and Turbine Runback.

PZR Page 14 of 27 Revision 9 INFORMA TION USE ONL V

SD-059 PRESSURIZER SYSTEM in Automatic. This permissive is supplied by the protection channels meeting a 2/3 logic.

As stated before PCV-456 receives its signal from PT-445 set at 2335 psig and PCV-455C receives its signal from PC-444A at +/- 100 psi which is nominally 2335 psig also. When the key switch for OVERPRESSURE PROTECTION on the RTGB is place in the LOW PRESSURE position (one switch for each PORV) the input to each PORV is shifted to the LTOPP controller.

5.1.4 Low Temperature Overpressure Protection Control (LTOPP) (PZR-Figure 11)

LTOPP control is required to be activated when the RCS is cooled down below 360 F to minimize Pressurized Thermal Shock (PTS) concerns. The LTOPP controller uses the lowest of TE-410, TE-420 and TE-430 to determine RCS temperature and pressure as sensed by PT-500 and PT-501. The lift setpoint is variable based upon auctioneered low RCS temperature. At an RCS temperature of 360°F, the pressure setpoint is 400 psig.

The setpoint of the Comparators PC502 and PC503 are increased as RCS temperature is increased. The setpoint will not decrease below 400 psig.

There is one alarm associated with each channel of LTOPP. It actuates for 3 reasons: (1)

RCS temperature is <360°F and LTOPP is not selected on the key switch for OVERPRESSURE PROTECTION, (2) The PORV has received an actuation signal based upon current pressure and temperature or (3) the associated Block valve is shut.

5.1.5 PZR Level Control (PZR-Figure 10)

PZR level is controlled by controlling charging pump speed. The level is programmed to ramp up as Tavg increases by LC-459G. This maintains approximately constant mass in the RCS as Tavg is increased and the coolant in the RCS expands. Level program is 22.2% at Tavg of 547°F and 53.3% at Tavg of 575.9°F.

There are 3 PZR level channels LT-459, LT-460 and LT-461. LC-459G the PZR level controller is normally fed by level channel LT-459 but can be replaced by LT-461 with a selector switch on the RTGB. The output of LC-459G is then fed to the charging pump speed controllers to control speed of the charging pump if their controllers are selected to Auto.

If PZR level increases 5% above program LC-459D will turn on the backup heaters and sound an annunciator for High Level Heaters on.

On PZR low level of 14.4%, proportional and backup heaters are deenergized and letdown is isolated by shutting LCV-460A & B if respective control switches are in auto. LC-459 and the LC-460, the low level bistables, are normally supplied by LT-459 and LT-460 respectively but either can be replaced by LT-461 with a selector switch on the RTGB.

PZR Page 19 of 27 Revision 9 INFORMATION USE ONLY

SD-059 PRESSURIZER SYSTEM LC-459 will only turn off the backup heaters that are selected to Automatic where LC-460 will turn off the backup heaters in Automatic or Manual. The only time this would have any bearing would be in the event of an instrument failure. If the channel feeding LC-459, usually LT-459, were to fail low the proportional heaters and any backup heaters in Automatic would de-energize and any backup heater in manual would remain energized.

5.1.6 PZR Level Control Setpoints (PZR Figure 9)

1. Level program as function of Median Select Tavg (TM-459) for Tavg 547°F 22.2% of level span for Tavg 575.9°F 53.3% of level span (Program is linear from 547°F to 575.9°F)

Low limit 22.2% of level span High limit 53.3% of level span

2. Low-Low Level Heater Cutout (LC-459C, LC-460C) 14.4% of level span

3. Level Controller (LC-459F) 10% charging pump Proportional gain speed/% level deviation Reset time constant 430 seconds

4. Letdown Valve Isolation 14.4% of level span

5. Back-up Heaters on + 5% of programmed level 6.0 SYSTEM OPERATION 6.1 Normal Operation Insurge of RCS Coolant produced by increase in Tavg. An insurge of coolant will reduce volume of the steam bubble causing an increase in the temperature and pressure of the steam. The steam space or bubble becomes superheated and some minor condensation occurs at surface and on walls.

The increased pressure causes the spray valve to open which cools and condenses a part of the steam bubble, thereby reducing pressure.

The increase in level will energize backup heaters if the level increases to 5% above PZR Page 20 of 27 Revision 9 INFORMA TION USE ONL Y

PROGRAM LEVEL LEVEL SETPOINTS PZR-FIGURE-9

1. Control Level High Low

2. Low Level, Htrs off, Ltdn Secured

3. Protection Low Level Alarm

4. High Level Alarm and Trip 53.3%

B/U Htrs On 22.2%

14.4%

6.0%

547 575.9 Median Tavg (°F) pzrfll INFORMA TION USE ONL Y

LEVEL CONTROLLER PZR-FIGURE- 10 MEDIAN LT-461 LT-460 Tavg I + - ADJUSTABLE NO LOAD Tavg SETPOINT I I CONTROLLER I I L

I I I I LEVEL PROGRAM :-r-t:

CONTROLLER II, ,iI.

I I _I I I I I I I I I L I I

I I

1 LO LVL ALARM LETDOWN ISOLATION VALVE CONTROL SELECTOR SWITCH (CONTROL BOARD)

HI LVL ALARM HEATERS OFF BEATERS ON (5/. HIGH) pzrfl2 INFORMA TION USE ONL V

Pressurizer 3.4.9 3.4 REACTOR COOLANT SYSTEM (RCS) 3.4.9 Pressurizer LCO 3.4.9 The pressurizer shall be OPERABLE with:

a. Pressurizer water level 63.3% in MODE 1;

b. Pressurizer water level 92% in MODES 2 and 3; and

c. Pressurizer heaters 0 ERABLE with a capacity of 125 kW and capable of being powered from an emergency power supply.

APPLICABILITY: MODES 1, 2, and 3.

ACTIONS CONDITION REQUIRED ACTION COMPLETION TIME A. Pressurizer water A.1 Be in MODE 3 with 6 hours6.944444e-5 days 0.00167 hours 9.920635e-6 weeks 2.283e-6 months level not within reactor trip breakers limit. open.

AND A.2 Be in MODE 4. 12 hours1.388889e-4 days 0.00333 hours 1.984127e-5 weeks 4.566e-6 months B. Capacity of required B.1 Restore required 72 hours8.333333e-4 days 0.02 hours 1.190476e-4 weeks 2.7396e-5 months pressurizer heaters pressurizer heaters

< 125 kW. to OPERABLE status.

C. Required pressurizer C.1 Restore capability to 72 hours8.333333e-4 days 0.02 hours 1.190476e-4 weeks 2.7396e-5 months .

heaters not capable of power the required being powered from an pressurizer heaters emergency power from an emergency supply. power supply.

(continued)

HBRSEP Unit No. 2 3.4-21 Amendment No. 218

Pressuri zer B 3.4.9 B 3.4 REACTOR COOLANT SYSTEM (RCS)

B 3.4.9 Pressurizer BACKGROUND The pressurizer provides a point in the RCS where liquid and vapor are maintained in equilibrium under saturated conditions for pressure control purposes to prevent bulk boiling in the remainder of the RCS. Key functions include maintaining required primary system pressure during steady state operation, and limiting the pressure changes caused by reactor coolant thermal expansion and contraction during normal load transients.

The pressure control components addressed by this LCO include the pressurizer water level, the required heaters, and their controls and emergency power supplies.

Pressurizer safety valves and pressurizer power operated relief valves are addressed by LCO 3.4.10, Pressurizer Safety Valves, and LCO 3.4.11. Pressurizer Power Operated Relief Valves (PORVs), respectively.

The intent of the LCO is to ensure that a steam bubble exists in the pressurizer prior to power operation to minimize the consequences of potential overpressure transients. The presence of a steam bubble is consistent with analytical assumptions. Relatively small amounts of noncondensible gases can inhibit the condensation heat transfer between the pressurizer spray arid the steam, and diminish the spray effectiveness for pressure control.

Electrical immersion heaters, located in the lower section of the pressurizer vessel, keep the water in the pressurizer at saturation temperature and maintain a constant operating pressure. A minimum required available capacity of pressurizer heaters ensures that the RCS pressure can be maintained. The capability to maintain and control system pressure is important for maintaining subcooled conditions in the RCS and ensuring the capability to remove core decay heat by either forced or natural circulation of reactor coolant. Unless adequate heater capacity is available, the hot, high pressure condition cannot be maintained indefinitely and still provide the required subcooling margin in the primary system. Inability to control the system pressure and maintain subcooling under conditions of natural circulation flow in the primary system could lead to (continued)

HBRSEP Unit No. 2 B 3.4-44 Revision No. 0

Pressurizer B 3.4.9 BASES BACKGROUND a loss of single phase natural circulation and decreased (continued) capability to remove core decay heat.

APPLICABLE In MODES 1, 2, and 3. the LCO requirement for a steam bubble SAFETY ANALYSES is reflected implicitly in the accident analyses. Safety analyses performed for lower MODES are not limiting. All analyses performed from a critical reactor condition assume the existence of a steam bubble and saturated conditions in the pressurizer. In making this assumption, the analyses neglect the small fraction of noncondensible gases normally present.

Safety analyses presented in the UFSAR (Ref. 1) do not take credit for pressurizer heater operation: however, an implicit initial condition assumption of the safety analyses is that the RCS is operating at normal pressure.

The maximum pressurizer water level limit satisfies Criterion 2 of the NRC Policy Statement. Although the heaters are not specifically used in accident analysis, the need to maintain subcooling in the long term during loss of offsite power, as indicated in NUREG-0737 (Ref. 2), is the reason for providing an LCO.

LCO The LCO requirement for the pressurizer to be OPERABLE with a water level of 63.3% in MODE 1, and 92% in MODE 2 and MODE 3, ensure s that a steam bubble exists. The pressurizer water level of 63.3% in MODE 1 is the normal programmed level plus 10%, which is consistent with the assumptions used in the accident analyses. The water level of 92%

MODE 2 and MODE 3 is protect ed by the pressu rizer high level trip setpoint at 91%, and is adequa te protect ion for the pressurizer when load rejection is not a concern. A higher water level is necessary in the ppssirizer during roq]pwn to maintain pressurizer coldon li,rnjjs. This level requirement a]c assures theRCS does not ao solid when Lticality is acThieved. Umiting the LCO maximum operating water level preservesifie steam space for pressure control.

The LCO has been established to ensure the capability to establish and maintain pressure control for steady state operation and to minimize the consequences of potential (continued)

HBRSEP Unit No. 2 B 3.4-45 Revision No. 0

92. 045 A2.11 SRO 001 Given the following plant conditions:

- The plant was at 100% RTP.

- Power Distribution Control target values (100%).

N-41: -2.0% N-43: -2.0%

N-42: -2.0% N-44: -2.0%

- Target Band +1- 5%

- APL = 102%

runbacks.

- At 1600 the plant has just experienced two spurious OT Delta T turbine

- At 1602 the plant stabilized at 88% RTP.

Time N-41AFD N-42 AFD N-43 AFD N-44 AFD 1603 -10.1 -10.2 -10.1 -10.3 1617 - 8.9 -9.0 -8.9 -9.1 1642 -7.1 -7.2 -7.1 -7.3 1705 - 6.9 -7.0 -6.9 -7.1 1710 -6.5 -6.6 -6.5 -6.6 Which ONE (1) of the following completes the statement below?

lAW ITS 3.2.3, Axial Flux Difference, reactor thermal power (1) and the basis for this action is (2)

(REFERENCE PROVIDED)

A. (1) is limited to a maximum of 90% RTP cant accident (2) the xenon axial distribution at this power level is not a signifi analysis parameter B. (1) is limited to a maximum of 90% RTP is cannot be (2) the radial xenon peaking factors assumed in the accident analys exceeded at this power level C (1) must be reduced to below 50% RTP cant accident (2) the xenon axial distribution at this power level is not a signifi analysis parameter D. (1) must be reduced to below 50% RTP is cannot be (2) the radial xenon peaking factors assumed in the accident analys exceeded at this power level 10/13/2011 Page: 169 of 187

The correct answer is C.

A. Incorrect. The penalty points have exceeded 1 hour1.157407e-5 days 2.777778e-4 hours 1.653439e-6 weeks 3.805e-7 months . Per ITS 3.2.3 power must be reduced to below 50%. Power could have stayed between 50% and 90% had less than 1 hour1.157407e-5 days 2.777778e-4 hours 1.653439e-6 weeks 3.805e-7 months of penalty points been accumulated. The second half of the answer is correct.

B. Incorrect. The penalty points have exceeded 1 hour1.157407e-5 days 2.777778e-4 hours 1.653439e-6 weeks 3.805e-7 months . Per ITS 3.2.3 power must be reduced to below 50%. Power could have stayed between 50% and 90% had less than 1 hour1.157407e-5 days 2.777778e-4 hours 1.653439e-6 weeks 3.805e-7 months of penalty points been accumulated. The second half of the distractor is similar to the basis for being outside the acceptable operation limits. Distractor also refers to radial xenon peaking factor vice axial peaking factors.

C. Correct.

D. Incorrect. The first half of the distractor is correct. The second half of the distractor is similar to the basis for being outside the acceptable operation limits. Distractor also refers to radial xenon peaking factor vice axial peaking factors.

Question 92 Tier/Group 2/2 K/A Importance Rating - RO 2.4 SRO 2.9 Ability to (a) predict the impacts of the following malfunctions or operation on the MT/G system; and (b) based on those predictions, use procedures to correct, control, or mitigate the consequences of those malfunctions or operations: Control problems in primary, e.g., axial flux imbalance; need to reduce load on secondary Reference(s) Sim/Plant design, ITS 3.2.3, FMP-009, ITS 3.2.3 Bases Proposed References to be provided to applicants during examination - FMP-009 Target and Operating Band Diagram Learning Objective AOP-15-004, FMP-009-007 Question Source NEW-Question Cognitive Level H -

10 CFR Part 55 Content 41.5 / 43.5 /45.3 I 45.5 Comments -

SRO: Application of required actions in accordance with Tech. Specs. and bases of Tech. Specs.

10/13/2011 Page: 170 of 187

0 ATTACHMENT 10.2 Page 3of5 TARGET AND OPERATING BAND EXAMPLES FIGURE 3 100 -

(-QQOi Li 11 + .29 UNA :CEPTABI E NACC [P *AB LE OP RATION / OPERATI 80-

/1

/1 7,

/

60-AC( [P AL O [RAT ON o) (+21.50) 40-1z -A-20-

+ I TARGET E NOS

+ I TARGET NOS

-w Et-UE-API x 0.9

-r T I I 0- ., r 20 0 LI 40 40 AXLAL FLUX DiFFERENCE ()

¶!E F 6ACJ Rev. 17 Page 28 of 34 FMP-009

AFD 3.2.3 3.2 POWER DISTRIBUTION LIMITS 3.2.3 AXIAL FLUX DIFFERENCE (AFD) (PDC-3 Axial Offset Control Methodology)

LCO 3.2.3 The AFD:

a. Shall be maintained within the target band about the target flux difference. The allowable values of the target band are specified in the COLR.

NOTE The AFD shall be considered outside the target band when two or more OPERABLE excore channels indicate AFD to be outside the target band.

b. May deviate outside the target band with THERMAL POWER

< 90 RTP or 0.9 APL, whichever is less, but 50 RTP, provided AFD is within the acceptable operation limits and cumulative penalty deviation time is 1 hour1.157407e-5 days 2.777778e-4 hours 1.653439e-6 weeks 3.805e-7 months during the previous 24 hours2.777778e-4 days 0.00667 hours 3.968254e-5 weeks 9.132e-6 months . The acceptable operation limits are specified in the COLR.

NOTES

1. Penalty deviation time shall be accumulated on the basis of a 1 minute penalty deviation for each 1 minute of power operation with AFD outside the target band.

2. The Allowable Power Level (APL) is the limitation placed on THERMAL POWER for the purposes of applying the AFD target flux and operational limit curves. The APL is as follows:

APL = minimum over Z of (1O0)(F(Z))(K(Z))/F(Z)

c. May deviate outside the target band with THERMAL POWER

< 50% RTP.

NOTE Penalty deviation time shall be accumulated on the basis of a 0.5 minute penalty deviation for each 1 minute of power operation with AFD outside the target band.

HBRSEP Unit No. 2 3.2-7 Amendment No. 176

AFD

3.2.3 APPLICABILITY

MODE 1. with THERMAL POWER > 15% RTP.

NOTE A total of 16 hours1.851852e-4 days 0.00444 hours 2.645503e-5 weeks 6.088e-6 months of operation may be accumulated with AFD outside the target band without penalty deviation time during surveillance of power range channels in accordance with SR 3.3.1.6, provided AFD is maintained within acceptable operation limits.

ACTI ONS CONDITION REQUIRED ACTION COMPLETION TIME A. THERMAL POWER A.1 Restore AFD to within 15 minutes 90% RTP or 0.9 APL, target band.

whichever is less.

AND AFD not within the target band.

B. Required Action and 8.1/Reduce THERMAL POWER 15 minutes associated Completion to < 90% RTP or 0.9 Time of Condition A APL, whichever is not met. less.

(continued) r HBRSEP Unit No. 2 3.2-8 Amendment No. 176

AFD 3.2.3 ACTIONS (continued)

CONDITION REQUIRED ACTION COMPLETION TIME C. NOTE C.1 Reduce THERMAL POWER 30 minutes Required Action C.1 to < 50% RTP.

and C.2 must be completed whenever AND Condition C is entered. C.2 Restore cumulative Prior to penalty deviation increasing time to less than 1 THERMAL POWER

- hour. to 50% RTP RTP or 0.9 APL, whichever is less, and 50% RTP with cumulative penalty deviation time > 1.

hour during the previous 24 hours2.777778e-4 days 0.00667 hours 3.968254e-5 weeks 9.132e-6 months .

)

THERMAL POWER < 90%

RTP or 0.9 APL.

whichever is less, and 50% RTP with AFD not within the acceptable operation limits.

D. NOTE D.1 Reduce THERMAL POWER 9 hours1.041667e-4 days 0.0025 hours 1.488095e-5 weeks 3.4245e-6 months Required Action D.1 to < 15% RTP.

must be completed whenever Condition D is entered.

Required Action and associated Completion Time for Condition C not met.

HBRSEP Unit No. 2 3.2-9 Amendment No. 176

R 4 Reference Progress Energy Use H. B. ROBINSON STEAM ELECTRIC PLANT, UNIT NO. 2 PLANT OPERATING MANUAL VOLUME 6 PART 5 FMP-009 POWER DISTRIBUTION CONTROL REVISION 17 FMP-009 Rev. 17 Page 1 of 34

TABLE OF CONTENTS SECTION PAGE 1.0 PURPOSE 4

2.0 REFERENCES

4 3.0 RESPONSIBILITIES 5

4.0 PREREQUISITES 5

5.0 PRECAUTIONS AND LIMITATIONS 5

6.0 SPECIAL TOOLS AND EQUIPMENT 5

7.0 ACCEPTANCE CRITERIA 5

8.0 PROCEDURE 8.1 Definitions 6 8.2 Power Distribution Control Methodology 6 8.3 ERRS Monitoring of AFD 9 8.4 Manual Monitoring of AFD 11 8.5 Divergent Axial Oscillation Control 18 19 9.0 RECORDS 21 10.0 ATTACHMENTS 10.1 ERFIS CAOC SOFTWARE AND AFD RELATED 21 PARAMETERS 22 10.2 TARGET AND OPERATING BAND EXAMPLES 10.3 ERFIS CAOC WARNING/STATUS/ALARM MES 26 SAGES 31 10.4 DIVERGENT AXIAL OSCILLATION 10.5 MANUAL AFD MONITORING LOG 32 34 FMP-009 Rev. 17 Page 3 of 34

1.0 PURPOSE 1.1 To provide instructions and guidance to ensure that the core axial power distribution is maintained within the limits established in Technical Specifications (ITS) LCO 3.2.3, SR 3.2.3.1 and SR 3.2.3.2 1.2 To provide instructions for identifying, monitoring and controlling divergent axial oscillations.

1.3 To satisfy Technical Specification (ITS) SR 3.2.3.2

2.0 REFERENCES

2.1 Technical Specifications (ITS) 1.1, LCO 3.2.3, SR 3.2.3.1, SR 3.2.3.2, SR 3.2.3.3 2.2 FMP-001, Core Operating Limits Report (COLR) 2.3 XN-76-40(A), Exxon Nuclear Power Distribution Control For Pressurized Water Reactors, September 1976 2.4 XN-NF-77-57 and XN-NF-77-57 Supplement 1 (A), Exxon Nuclear Power Distribution Control for Pressurized Water Reactors Phase II, May 1981 2.5 XN-NF-77-57 Supplement 2(A) and XN-NF-77-57 Supplement 2 Addendum 1 (A), Exxon Nuclear Power Distribution Control for Pressurized Water Reactors Phase II, October 1982 2.6 ANF-88-054(P), PDC-3: Advanced Nuclear Fuels Corporation Power Distribution Control for Pressurized Water Reactors and Application of PDC-3 to H.B. Robinson Unit 2, July 1988 2.7 EST-003, I ncore/Excore Detector Calibration 2.8 SCM-003, Plant Computer Systems Database Control Procedure 2.9 UFSAR 1.5.3, 3.1.1.2.2, 3.1.2.7, 4.3.1.6, 4.3.2.2, 4.3.2.6, 4.3.3.3, 4.4.3.1, 7.2.1.1.2, 7.2.1.1.7, 7.7.1.5, 7.7.1.6 2.10 EC 47211 ERFIS Data Concentrator replacement.

2.11 EC 47160 NSS and BOP Analysis to Support Appendix K Uprate FMP-009 Rev. 17 Page 4 of 34

3.0 RESPONSIBILITIES 3.1 Reactor Engineering is responsible for performing flux maps every 31 Effective Full Power Days (EFPDs) to determine the Target Axial Flux Difference (AFD) values, the Target Band values and the Allowable Power Level (APL) value in accordance with Technical Specifications (ITS) SR 3.2.3.3 and LCO 3.2.3.

Reactor Engineering is also responsible for ensuring that the Control Room Status Board and the ERFIS CAOC software is updated to reflect the correct Target AFD values, Target Band values and APL value. Reactor Engineering is also responsible for ensuring the ERFIS CAOC software is updated to reflect the correct lncore/Excore calibration constants.

3.2 The Control Operator is responsible for maintaining the AFD within the limits specified in Technical Specifications (ITS) LCO 3.2.3 and SR 3.2.3.1 and the COLR. The Control Operator is also responsible for logging the AFD in accordance with Technical Specification (ITS) SR 3.2.3.2 when the AFD Alarms are inoperable.

3.3 The Superintendent Shift Operations is responsible for reviewing the Manual AFD Monitoring Log.

4.0 PREREQUISITES N/A 5.0 PRECAUTIONS AND LIMITATIONS 5.1 Any Technical Specification Required Action regarding reactor power limitations, including the setting of trip setpoints, should be based on a Rated Thermal Power (RTP) of 2339 MWth. A trip setpoint based on a 2300 MWth would satisfy Technical Specification requirements: however, if a trip setpoint is based on an RTP of 2300 MWth, then the actual trip would occurr at a lower indicated power when operating based on a 2339 MWth RTP.

6.0 SPECIAL TOOLS AND EQUIPMENT N/A 7.0 ACCEPTANCE CRITERIA N/A FMP-009 Rev. 17 Page 5 of 34

8.0 PROCEDURE 8.1 Definitions 8.1.1 Axial Flux Difference (AFD)

The Axial Flux Difference (AFD) is defined as the difference in normalized flux signals between the top and bottom halves of a two section excore neutron detector (ITS 1.1). This parameter is synonymous with Delta Flux, Indicated Flux Difference, Al, %Al, %A Flux and Aq. AFD can also be related to core Axial Offset (AC) using the following equation:

AFD = AC

Power Level/Rated Thermal Power.

AFD relates the power in the top of the core to the power in the bottom of the core as seen by the excore NIS Power Range detectors. A separate AFD value is calculated for each NIS Power Range channel. The equations and ERFIS Point IDs used in calculating AFD for each of the four Power Range channels are shown in ATTACHMENT 10.1. It should be noted that the ERFIS AFD is calculated once per minute and is based on 1 minute average values for V(top), V(bottom) and P.

8.1.2 Target Value (TV)

The Target Value, also known as the Target Flux Difference, is the value of AFD determined in conjunction with the measurement of FQ(Z) under equilibrium conditions within 31 EFPD after each refueling and every 31 EFPD thereafter (ITS SR 3.2.3.3). During startup and power ascension following each refueling, the Target Value may be based on design predictions until equilibrium conditions for long term operation are reached. Like AFD, the Target Value is power dependent (examples of the variation of Target Value with power are provided in ATTACHMENT 10.2). A separate Target Value is calculated for each NIS Power Range channel. The Target Value for a Power Range channel is generally the average ERFIS AFD value recorded for that channel during the course of the flux map. The equations and ERFIS Point IDs used in calculating the power dependent Target Value for each of the four Power Range channels are shown in ATTACHMENT 10.1.

FMP-009 Rev. 17 Page 6 of 34

8.1.3 Allowable Power Level (APL)

The Allowable Power Level is the limit placed on reactor power due to the FQV(Z) peaking factor. The APL is used in applying the AFD target flux and operational limit curves (ITS LCD 3.2.3). The equation for determining the APL is provided in Technical Specification (ITS) LCD 3.2.3. The effect of APL on the Target Bands and Operating Bands can be seen in ATTACHMENT 10.2 8.1.4 Target Bands (TB)

The Target Bands establish a region of operation around the Target Value in which the AFD may vary without adversely affecting the axial power distribution or the axial xenon distribution. The allowable values of the Target Band are provided in the COLR for each cycle. The allowable Target Band values are currently +/-3% and +/-5%. If the APL is less than 90% RTP, then the values of the Target Bands are reduced to account for the effects of the reduced APL; however, they are still referred to as the +/-3% and +/-5% Target Bands in order to maintain a consistent nomenclature under all operating conditions. Since the Target Band moves with the Target Value, separate Upper and Lower Target Bands are calculated for each NIS Power Range channel (examples of the variation of the Target Bands with power and with APL are provided in ATTACHMENT 10.2). The equations and ERFIS Point IDs used in calculating the Target Bands for each of the four Power Range channels are shown in ATTACHMENT 10.1.

FMP-009 Rev. 17 Page 7 of 34

8.1.5 Operating Bands (OB)

The Operating Bands establish a region of acceptable operation outside of the Target Bands in which the AFD may vary for a short time period without adversely affecting the axial power distribution or the axial xenon distribution. The Operating Bands are only applicable to operation at power levels between 50% RTP and 90% RTP (or 90% APL if the APL is less than 100% RTP). The allowable values of the Operating Bands are provided in the COLR for each cycle. The Operating Bands use the same nomenclature as the Target Bands (i.e.

+/-3% and +/-5% Operating Bands). The +/-% Operating Bands are used with the

+/-3% Target Bands and the +/-5% Operating Bands are used with the Target Bands. If

+/-5%

the APL is less than 90% RTP, then the values of the Operating Bands are reduced to account for the effects of the reduced APL; however, they are still referred to as the +/-3% and +/-5% Operating Bands in order to maintain a consistent nomenclature under all operating conditions. If 0.9*APL is less than 90% RTP, then the top of the Operating Bands is limited to 0.9*APL. The Operating Bands, like Target Bands, move with the Target Value (examples of the variation of the Operating Bands with power and APL are provided in ATTACHMENT 10.2). Separate Upper and Lower Operating Bands are calculated for each NIS Power Range channel. The equations and ERFIS Point IDs used in calculating the Operating Bands for each of the four Power Range channels are shown in ATTACHMENT 10.1.

8.1.6 Penalty Points Penalty Points are used to track the amount of time that operation outside of the Target Bands has occurred. Penalty point accumulation only occurs when two or more operable Power Range channels indicate that AFD is outside of the Target Bands. Penalty points are related to time of operation outside of the Target Bands through the following relations:

50% RTP: 1 Penalty Point= 1 minute outside the Target Bands

<50% RTP: 1 Penalty Point= 2 minutes outside the Target Bands Penalty points are eliminated by operation within the Target Bands at the same rates at which they were accumulated. The ERFIS Point ID used to track penalty point accumulation is shown in ATTACHMENT 10.1.

FMP-009 Rev. 17 Page 8 of 34

8.1.7 Target Warning Bands (TWB)

The Target Warning Bands are provided to alert the Operator that the AFD for one or more NIS Power Range channels is approaching the Target Bands (examples of the Target Warning Bands are provid ed in ATTACHMENT 10.2). Separate upper and lower Target Warning Bands are calculated for each NIS Power Range channel. The equatio ns and ERFIS Point IDs used in calculating the Target Warning Bands for each of the four Power Range channels are shown in ATTACHMENT 10.1.

8.1.8 Operating Warning Band (OWB)

The Operating Warning Bands are provided to alert the Operat or that the AFD for one or more NIS Power Range channels is approaching the Operating Bands (examples of the Operating Warning Bands are provided in ATTACHMENT 10.2). Separate upper and lower Operating Warning Bands are calculated for each NIS Power Range channe

l. The equations and ERFIS Point Ds used in calculating the Operat ing Warning Bands for each of the four Power Range channels are shown in ATTACHMENT 10.1.

8.2 Power Distribution Control Methodology 8.2.1 The Power Distribution Control (PDC) methodology for contro lling the core axial power distribution tries to avoid the building-in of advers e

axial power distributions during plant operations by maintaining a

relatively constant power shape based on the equilibrium conditions encountered throughout a given core cycle. Maintaining a relatively constant axial power shape ensures that the FQ(Z) peaking factor limit will not be exceeded. Since the building-in of adverse power shapes is a function of power level, the restrictions on deviation from the Target Value also vary with power level.

8.2.2 The Operator can use the RTGB AFD meters or the ERFIS AFD point lDs to monitor the status of AFD. Spurious alarms and any other applicable comments relating to AFD monitoring should be entered in the Control Operators narrative log, when necessary.

FMP-009 Rev. 17 Page 9 of 34

8.2.3 The AFD is considered to be outside of the Target Band s or Operating Bands when the AFD for two operable Power Range channels exceed their Target Bands or Operating Bands.

8.2.4 At power levels >90% RTP (or 0.9*APL, whichever is less)

, the AFD must be maintained within the Target Bands. If the AFD is outside of the Target Bands then the AFD must be returned to within the Target Bands within 15 minutes or power must be reduced below 90%

0.9*APL, whichever is less) within RTP (or 30 minutes (Technical Specification (ITS) LCD 3.2.3 Conditions A and B). Penalty Points are accumulated while the AFD is outside the Target Bands.

8.2.5 At power levels <90% RTP (or 0.9*APL, whichever is less) but >50%

RTP, the AFD may deviate from the Target Bands as long as the total number of Penalty Points incurred over the previous 24 hours2.777778e-4 days 0.00667 hours 3.968254e-5 weeks 9.132e-6 months does not exceed 60 Penalty Points. The AFD must be maintaine d within the Operating Bands. If the number of accumulated Penalty Points exceeds 60 or if the AFD is outside of the Operating Bands then power must be reduced below 50% RTP within 30 minutes (Technical Specification (ITS)

LCD 3.2.3 Condition C). If power is not reduced below 50% RTP within 30 minutes then power must be reduced below 15% RTP within 9 hours1.041667e-4 days 0.0025 hours 1.488095e-5 weeks 3.4245e-6 months (ITS LCO 3.2.3 Condition D) 8.2.6 At power levels <50% RTP, the AFD may deviate from the Target Bands since adverse power shapes at lower power levels are suffici ently accounted for by the F(zI) input to the Overtemperature T (OTzT) and Overpower T (OPzT) Reactor Protection setpoints. A power increase to >50% RTP is permitted only if the accumulation of Pena lty Points within the previous 24 hour2.777778e-4 days 0.00667 hours 3.968254e-5 weeks 9.132e-6 months period does not exceed 60 points.

8.2.7 At power levels <15% RTP, AFD monitoring is not required by the Technical Specifications (ITS LCO 3.2.3). The ERFIS CAOC program does not perform any AFD calculations below 15% power in order to prevent extraneous alarms during periods when the instr umentation noise levels are significant and power operations is minimal.

FMP-009 Rev. 17 Page 10 of 34

8.2.8 Certain evolutions such as Incore/Excore calibrations require the AFD to be outside of the Target Bands. Deviation from the Target Bands for a limited amount of time is permitted by the Technical Specifications provided the AFD is maintained within the Operating Bands (Technical Specifications (ITS) LCO 3.2.3).

8.3 ERFIS Monitoring of AFD 8.3.1 Normal Operation During normal operation above 15% power, the ERFIS CAOC software program calculates the following values for each of the four NIS Power Range channels once per minute:

1. AFD;

2. Target Value for the current power level;

3. Upper and Lower Target Bands for the current power level;

4. Upper and Lower Operating Bands for the current power level;

5. Upper and Lower Target Warning Bands for the current power level; and,

6. Upper and Lower Operating Warning Bands for the current power level.

The CAOC software program compares the calculated AFD for each Power Range channel to that channels Target Warning Bands, Target Bands, Operating Warning Bands and Operating Bands. If a Power Range channel crosses one or more of the bands, the ERFIS CAOC program V

informs the Operator of the condition by providing a message on the ERFIS alarm screen and a report on the Control Room printer and if necessary by actuating the appropriate annunciators on the RTGB (APP 005-D6, z FLUX WARNING/STATUS and APP-005-E4, z FLUX ALARM). The ERFIS CAOC reports that are printed on the Control Room printer are retained as part of the operating logs.

FMP-009 Rev. 17 Page 11 of 34

8.3.1 (Continued)

The ERFIS CAOC software program automatically accumulates Penalty Points at the appropriate rate based on power level if two or more operable Power Range channels are outside of their Target Bands. The program also automatically subtracts penalty points at the appropriate rate if the AFD is within the Target Band and the required time since the points were accumulated (24 hours2.777778e-4 days 0.00667 hours 3.968254e-5 weeks 9.132e-6 months ) has elapsed.

8.3.2 ERFIS CAOC Alarms If the calculated AFD for any channel is outside of any of the bands for that channel then an alarm is generated via annunciators APP-005-D6 and/or APP-005-E4. The specific cause of the alarm (i.e. the identification of the channel and the band that has been exceeded) is displayed on the ERFIS alarm screen and a report is printed on the Control Room printer. Examples of the types of warning/status/alarms messages are shown in ATTACHMENT 10.3.

8.3.3 ERFIS CAOC Shift Summary Report A Shift Summary Report is printed on the Control Room printer at 0730, 1530, and 2330 hours0.027 days 0.647 hours 0.00385 weeks 8.86565e-4 months . The Shift Summary Report is intended to provide information on the change in AFD with time to allow the Operator or Reactor Engineer to easily detect axial oscillations or instrument calibration problems.

The Shift Summary Report lists the AFD for each of the four channels at the time of the report as well as the Minimum AFD and Maximum AFD each of the channels reached during the eight hour period preceding the report.

The report also lists the values for the Target Bands, Target Warning Bands, Operating Bands and Operating Warning Bands for each channel at the time of the report. The report has blanks for the Operator to record the AFD indication from the RTGB meters in order to verify that the RTGB indicated AFD is within 2% of the ERFIS calculated AFD. A deviation between the RTGB indicated AFD and the ERFIS calculated AFD of greater that 2% is not expected and would warrant further investigation to determine if an ERFIS or NIS problem exists. The Shift Summary Report is retained as part of the normal operating logs.

FMP-009 Rev. 17 Page 12 of 34

8.3.4 Removing a Channel From Service in CAOC A NIS Power Range channel may be removed from service in the ERFIS CAOC program by removing that channels instantaneous % power point from scan. This will generate an APP-005-D6, FLUX WARNING, alarm with the following description displayed on the CAOC alarm report:

CHANNEL #_ NOW OUT OF SERVICE.

A Power Range channel may be returned to service in the ERFIS CAOC program by restoring that channels instantaneous % power point to scan. This will generate an APP-005-D6, FLUX STATUS, alarm with the following description displayed on the CAOC alarm report:

CHANNEL #_ JUST RETURNED TO SERVICE.

The ERFIS point IDs used in removing channels from service and restoring channels to service are as follows:

NIS CAOC ERFIS CHANNEL CHANNEL POINT ID N41 #1 NINOO41A N42 #2 NINOO42A N43 #3 NINOO43A N44 #4 NINOO44A FMP-009 Rev. 17 Page 13 of 34

8.3.5 Demand AFD Report Disabling Alarms and Penalty Logging During certain activities such as Incore/Excore calibrations or other maintenance or calibration activities involving the Power Range channels, it may be necessary to demand an AFD printout, disable the alarm function and/or Penalty Point logging function of the ERFIS CAOC computer program to provide immediate information or to prevent extraneous alarms and/or inadvertent accumulation of Penalty Points.

To initiate any of these ERFIS functions select TOC AFD4. The current state of these functions is reflected in the Current State column in the lower part of the display. Select the button appropriate for the desired function to toggle the desired state in the New State column. The New State indication will update in the lower part of the screen to reflect the selected condition. Toggle the buttons as appropriate to enable or disable logging and alarming or to demand an AFD printout. Once the desired states have been input, select the Update. Button to execute the new states. The AFD demand print will only print once and the CAOC program will set the Current State to Off automatically. The Alarm and logging states will remain until new states are input and Update Button is selected. Disabling of the Alarm or Penalty Point Logging functions is treated as removing the AFD monitoring program from service and manual monitoring of AFD is required in accordance with Technical Specification (ITS) SR 3.2.3.2. An alternative to disabling the Alarm and Penalty Point Logging functions during Incore/Excore calibrations and other maintenance activities is to allow the Penalty Points to be accumulated and remove any invalid points after completion of the calibration as described in 8.3.7.

8.3.6 ERFIS Out Of Service If the ERFIS computer, the CAOC software program or the RTGB annunciators which provide AFD monitoring (APP-005-D6 or APP-005-E4) are inoperable then manual monitoring of AFD is required in accordance with Technical Specification (ITS) SR 3.2.3.2. Manual monitoring is described in Section 8.4.

FMP-009 Rev. 17 Page 14 of 34

8.3.7 ERFIS Computer Restart Whenever the ERFIS computer is restarted, the Operator should verify that the Penalty Point file is accurate and should manually update the file if necessary. Several options are available to perform this verification/updating.

1. If no Penalty Points had been accumulated prior to ERFIS being out of service and no Penalty Points were accumulated while ERFIS was out of service, then check that ERFIS Point ID NPUO941 reflects 0 Penalty Points or, if desired, perform the following to view the contents of the Penalty Time Buffer:

a. Type in the turn on code CAOCEDIT or select the TOC from the ERFIS NSSS menu.

b. Enter the desired beginning time to start browsing at the selected time in the Penalty Point Buffer.;

c. Use the -Time, +Time, -1 hour, +1 hour buttons to sequence forward and backward through the Penalty Point Buffer;

d. Select Exit when finished.

2. If invalid Penalty Point data is present in the Penalty Point buffer and no valid Penalty Points have been accumulated in the previous 24 hours2.777778e-4 days 0.00667 hours 3.968254e-5 weeks 9.132e-6 months then the entire 24 hour2.777778e-4 days 0.00667 hours 3.968254e-5 weeks 9.132e-6 months Penalty Point buffer may be initialized to No Penalty by performing the following:

a. Type in the turn on code AFDl;or select the TOC from the ERFIS NSSS menu.

b. Click on the initialization box and then select the initialize button to begin clearing the penalty point buffer.

c. When the confirmation message is displayed select yes to continue or no. If yes is selected, a confirmation message that the penalty point buffer has been cleared will be displayed and the program will automatically exit. If no then select Exit to close the window.

FMP-009 Rev. 17 Page 15 of 34

8.3.7 (Continued)

3. If valid Penalty Points had been accumulated prior to ERFIS being out of service but no Penalty Points were accumulated while ERFIS was out of service and ERFIS was out of service for less than 24 hours2.777778e-4 days 0.00667 hours 3.968254e-5 weeks 9.132e-6 months then perform the following to retain the earlier valid Penalty Point data and insert No Penalty into the buffer for the period of time that ERFIS was out of service:

a. Type in the turn on code AFD2;or select the TOC from the ERFIS NSSS menu

b. Enter the time that ERFIS went out of service as the Restart Begin Time

c. Enter 0 in the Restart penalty rate and then select the Restart button.

d. When the confirmation message is displayed select yes to continue or no. If yes is selected, a confirmation message that the Penalty point Buffer has been restarted will be displayed and the program will automatically exit. If no then select Exit to close the window.

4. If valid Penalty Points were accumulated while ERFIS was out of service then perform the following to manually update any or all of the 24 hour2.777778e-4 days 0.00667 hours 3.968254e-5 weeks 9.132e-6 months Penalty Time buffer:

a. Type in the turn on code CAOCEDIT;or select the TOC from the ERFIS NSSS menu.

b. Using data from ATTACHMENT 10.5, enter the time at which the penalty update block is to begin;

c. Using data from ATTACHMENT 10.5, enter the time the penalty update block is to end; FMP-009 Rev. 17 Page 16 of 34

8.3.7.4 (Continued)

d. Using data from ATTACHMENT 10.5, enter the appropriate penalty rate for the update block from the following choices:

PENALTY VALUE PENALTY RATE POWER 0 No Penalty Any 1 % Penalty Point per minute <50%

2 1 Penalty Point per minute >50%

e. If desired, the penalty buffer can be updated on a minute by minute basis with the CAOCEDIT TOC, ELSE go to step f.

1) Type in the turn on code CAOCEDIT or select the TOC from the ERFIS NSSS menu.

2) Enter the desired beginning time to start browsing at the selected time in the penalty point buffer;

3) Use the -Time, --Time, hour + hour buttons to sequence forward and backward through the penalty point buffer.

4) Enter the desired penalty rate for the desired hour/minute as needed using data from Attachment 10.5 and the above penalty point value table used in step d.

f. When finished with a block or individual hour/minute update, validate the updated penalty time entries by browsing through the buffer as describded in step g above.

If the penalty point data is correct, then select the Update Buffer button to incorporate the update.

g. Select the Exit button to close the window 8.3.8 ERFIS CAOC Program Constants Except for the ERFIS Point IDs described above which are provid ed for the Operators use, all changes to CAOC program constants should be performed in accordance with SCM-003.

FMP-009 Rev. 17 Page17of34

8.4 Manual Monitoring of AFD 8.4.1 If the ERFIS computer, the CAOC software program or the RTGB annunciators which provide AFD monitoring (APP-005-D6 or APP-005-E4) are inoperable then manual monitoring of AFD is required in accordance with Technical Specification (ITS) SR 3.2.3.2.

8.4.2 If the Thermal Power is >90% RTP or 0.9*APL, whichever is less, then the AFD indicated on the RTGB meters must be verified to be within limits and must be logged on ATTACHMENT 10.5 within 15 minutes of the alarms becoming inoperable and every 15 minutes thereafter.

8.4.3 If the Thermal Power is <90% RTP or 0.9*APL, whichever is less, then the AFD indicated on the RTGB meters must be verified to be within limits and must be logged on ATTACHMENT 10.5 within 1 hour1.157407e-5 days 2.777778e-4 hours 1.653439e-6 weeks 3.805e-7 months of the alarms becoming inoperable and every 1 hour1.157407e-5 days 2.777778e-4 hours 1.653439e-6 weeks 3.805e-7 months thereafter.

8.4.4 If two or more operable excore channels indicate that AFD is outside of the Target Band then the applicable Actions of Technical Specifications (ITS) LCO 3.2.3 must be completed and the resultant Penalty Points must be logged on ATTACHMENT 10.5 in accordance with the following rates:

POWER PENALTY LEVEL POINT RATE 50% 1 Poinl/minute RTP

<50% RTP 1/2 PointImnute 8.4.5 If the total number of Penalty Points exceeds 60 in a 24 hour2.777778e-4 days 0.00667 hours 3.968254e-5 weeks 9.132e-6 months period, then the applicable Actions of Technical Specifications (ITS) LCO 3.2.3 must be completed.

FMP-009 Rev. 17 Page 18 of 34

8.4.6 Penalty point are eliminated 24 hours2.777778e-4 days 0.00667 hours 3.968254e-5 weeks 9.132e-6 months after accumulation by operation within the Target Bands at the same rate at which they were accumulated. Elimination of penalty points is denoted by a negative

(-)

value on ATTACHMENT 10.5.

8.5 Divergent Axial Oscillation Control NOTE: UFSAR Sections 1.5.3, 3.1.2.7 and 7.7.1.6 state that procedures are available for the Operator to control axial oscillations. This section provides those procedures.

8.5.1 Axial oscillations can be induced by changes in power level, control rod movement, or a combination of both. A sudden change in either will cause some change in flux shape with a resulting redistribution of xenon concentrations in the core. This will invariably start a xenon oscillation in the axial direction.

8.5.2 Axial oscillations are easily started by control rod motion. The flux shape is very dependent on control rod position due to the high neutron absorption of the control rods. Improper use of the control rods at any time can create very serious oscillations. On the other hand, control rods are the best method for manually controlling a xenon oscillation; therefore, use extreme care when making extensive control rod movement. The control bank should be moved slowly and action taken prior to reaching any limit. Attempt to maintain the control rods retracted as far as is practical during steady-state and power ramp conditions to minimize the pinching effect of the control bank.

8.5.3 Depending on the core conditions and Operator actions, an axial oscillation can be dampened out or amplified until it becomes divergent.

The most serious axial oscillation is the divergent oscillation. Its amplitude increases with each cycle if left to oscillate naturally and can be increased in size by control rod motion if not carefully applied.

FMP-009 Rev. 17 Page 19 of 34

8.5.4 The most important factor in control of a divergent oscillation is the timing of the oscillation. The core oscillates axially with a period of 26 hours3.009259e-4 days 0.00722 hours 4.298942e-5 weeks 9.893e-6 months ; that is, it takes 26 hours3.009259e-4 days 0.00722 hours 4.298942e-5 weeks 9.893e-6 months for the same point on the sinusoidal wave to reoccur (see ATTACHMENT 10.4). The wave may be halved and quartered down to 6.5 hour5.787037e-5 days 0.00139 hours 8.267196e-6 weeks 1.9025e-6 months intervals where the oscillation goes from maximum AFD to Target Value, Target Value to minimum AFD, etc.

Once the timing of the oscillation has been determined, the following control procedure may be used to stop or reduce the oscillation to a minimum:

NOTE: ATTACHMENT 10.4 provides an illustration of the control procedure.

If the oscillation has just begun, an accurate timing determination may be difficult. If the Target Value is known accurately, the control rods should be inserted 5 hours5.787037e-5 days 0.00139 hours 8.267196e-6 weeks 1.9025e-6 months after crossing the Target Value in the positive direction since the equilibrium AFD to peak AFD time is 6.5 hours5.787037e-5 days 0.00139 hours 8.267196e-6 weeks 1.9025e-6 months .

If sufficient rod worth is present, the procedure may be performed in reverse by withdrawing control rods 1.5 hours5.787037e-5 days 0.00139 hours 8.267196e-6 weeks 1.9025e-6 months before the minimum AFD.

The control rod insertion is best done slightly early rather than late since if the insertion is done late an amplification might result which is undesirable.

If after returning the control rods to the initial position the oscillation continues upward, then the control rods were returned to normal too soon. If a downward swing starts, then the control rods were left in too long.

A way of approximating the proper insertion time is to consider it 11.5 hours5.787037e-5 days 0.00139 hours 8.267196e-6 weeks 1.9025e-6 months after the last minimum AFD.

Do not allow the power level to change during the control rod maneuvers since this may induce additional unwanted oscillations which will eventually have to be dampened.

If the core is divergent, the least disturbance may become significant after 1 or 2 periods of oscillation. Therefore, if the control procedure does not work effectively, additional control measures should be taken as soon as practical.

The procedure for control of divergent oscillations can also be effectively applied to very large convergent oscillations where there is a possibility of exceeding control rod insertion limits if normal methods were used.

FMP-009 Rev. 17 Page 20 of 34

8.5.4 (Continued)

1. At 1.5 hours5.787037e-5 days 0.00139 hours 8.267196e-6 weeks 1.9025e-6 months before the most positive peak, determine the AFD from ERFIS or the AFD meters and insert the control rods using dilution until the AFD reaches the Target Value;

2. Determine the change in AFD caused by the control rod insertion (AFD before insertion Target Value);

3. Maintain a constant control rod position and allow AFD to decrease;

4. When AFD is lower than the Target Value by the amount determined in Step 8.5.4.2, withdraw control rods to their original position using boration.

9.0 RECORDS ATTACHMENT 10.5 must be sent to the vault as a QA record 10.0 ATTACHMENTS 10.1 ERFIS CAOC Software And AFD Related Parameters 10.2 Target and Operating Band Examples 10.3 ERFIS CAOC Warning/Status/Alarm Messages 10.4 Divergent Axial Oscillation 10.5 Manual AFD Monitoring Log FMP-009 Rev. 17 Page 21 of 34

ATTACHMENT 10.1 Page 1 of 4 ERFIS CAOC SOFTWARE AND AFD RELATED PARAMETERS EQUATIONS AND ERFIS POINTS USED TO CALCULATE AXIAL FLUX DIFFERENCE (AFD)

AFD = V(top) V(bottom)

K V(top)+ V(bottom) where: V(top) = Voltage representing the core power as seen by a NIS Power Range channel top detector; V(bottom)= Voltage representing the core power as seen by a NIS Power Range channel bottom detector; Incore/Excore calibration constant determined in accordance with EST-003.

P= Power Level (%) at the time of the calculation.

Parameter N41 N42 N43 N44 AFD NPUO900 NPUO9O1 NPUO9O2 NPUO9O3 V(top) NINOO51M NINOO53M NINOO55M NINOO57M V(bottom) NINOO52M NINOO54M NINOO56M NINOO58M K NPKI6I2 NPKI613 NPKI614 NPK1615 P NINOO41M NINOO42M NINOO43M NINOO44M EQUATIONS AND ERFIS POINTS USED TO CALCULATE TARGET VALUES Target Value (P) = Target Valueref PIPref where: Target Value (P) = Target Value at power P; Target Valueref = Target Value during flux map; P = Current power level; and, Pref = Power level during flux map.

Parameter N41 N42 N43 N44 Target Value (P) N/A N/A N/A N/A Target Valueref NPK1 603 NPK1 604 NPK1 605 NPK1 606 P N1N0041M NINOO42M NINOO43M N1N0044M Pref NPK16O8 NPK16O9 NPKI61O NPKI611 FMP-009 Rev. 17 Page 22 of 34

ATTACHMENT 10.1 Page 2 of 4 ERFIS CAOC SOFTWARE AND AFD RELATED PARAMETERS EQUATIONS AND ERFIS POINTS USED TO CALCULATE TARGET BAND VALUES APL> 90% RTP TB Low Limit = TV TB Value TB High Limit = TV + TB Value APL < 90% RTP TB Low Limit = TV [TB Value * (APLI100)]

TB High Limit TV + [TB Value * (APL/100)]

where: TV(P) =Target Value TB Value = Selected Target Band value (+/-3% or+/-5%)

APL Allowable Power Level Parameter N41 N42 N43 N44 Target Band Low Limit NPUO9O5 NPUO9O6 NPUO9O7 NPUO9O8 Target Band High Limit NPUO9O9 NPUO91O NPUO911 NPUO912 Target Band Value NPK162O NPK162O NPKI62O NPK162O APL NPKO32O NPKO32O NPKO32O NPKO32O EQUATIONS AND ERFIS POINTS USED TO CALCULATE TARGET WARNING BAND VALUES TWB Low Limit = TB Low Limit + TWB Value TWB High Limit = TB High Limit TWB Value where: TWB = Target Warning Band; and, TB = Target Band.

Parameter N41 N42 N43 N44 TWB Low Limit NPUO9I3 NPUO914 NPUO915 NPUO916 TWB High Limit NPUO917 NPUO9I8 NPUO919 NPUO92O TB Low Limit NPUO9O5 NPUO9O6 NPUO9O7 NPUO9O8 TB High Limit NPUO9O9 NPUO91O NPUO911 NPUO912 TWB Value NPK1622 NPK1622 NPK1622 NPK1622 FMP-009 Rev. 17 Page 23 of 34

ATTACHMENT 10.1 Page 3 of 4 ERFIS CAOC SOFTWARE AND AFD RELATED PARAMETERS EQUATIONS AND ERFIS POINTS USED TO CALCULATE OPERATING BAND VALUES 5% OB, APL>90% RTP: Upper OB = TV + 0.5 [110 (P/PL 100)]

Lower OB = TV 0.4 [110 (P/PL *100)]

5% OB, APL<90% RTP: Upper OB=TV+ {0.5 [110 (P/PL*1 00)]*(APL/1 00)}

Lower OB= TV {0.4 [110 (P/PL*1 00)]*(APL/1 00)}

3% OB, APL>90% RTP: Upper OB = TV + 0.5 *[106 (P/PL 100)]

Lower OB = TV 0.4 [105- (PIPL *100)]

3% OB, APL<90% RTP: Upper OB=TV + {0 5*[1 06(P/PL*1 00)]*(APL/1 00)}

Lower OB TV {0.4 [105 (P/PL*1 00)]*(APL/1 00)}

where: OB = Operating Band; TV =Target Value; P = Average NIS Power Range power expressed as % RTP; PL = The lesser of 100% RTP or APL; and, APL = Allowable Power Level Parameter N41 N42 N43 N44 Operating Band Low Limit NPUO921 NPU0922 NPU0923 NPU0924 Operating Band High Limit NPU0925 NPU0926 NPU0927 NPU0928 P NINOO41M NINOO42M NINOO43M NINOO44M APL NPKO32O NPKO32O NPKO32O NPKO32O EQUATIONS AND ERFIS POINTS USED TO CALCULATE OPERATING WARNING BAND VALUES OWB Low Limit = OB Low Limit + OW Envelope Value OWB High Limit = OB High Limit OW Envelope Value where: OWB = Operating Warning Band; and, OB = Operating Band.

Parameter N41 N42 N43 N44 OWB Low Limit NPU0929 NPUO93Q NPUO931 NPU0932 OWB High Limit NPU0933 NPU0934 NPU0935 NPU0936 OB Low Limit NPUO921 NPU0922 NPU0923 NPU0924 OB High Limit NPU0925 NPU0926 NPU0927 NPU0928 OWEnvelope Value NPK1616 NPK1616 NPK1616 NPK1616 FMP-009 Rev. 17 Page 24 of 34

ATTACHMENT 10.1 Page 4 of 4 ERRS CAOC SOFTWARE AND AFD RELATED PARAMETERS N41 N42 N43 N44 Minimum AFD over Previous NPUO95O NPUO951 NPU0952 NPU0953 8 hours9.259259e-5 days 0.00222 hours 1.322751e-5 weeks 3.044e-6 months Maximum AFD over Previous NPU0954 NPU0955 NPU0956 NPU0957 8 hours9.259259e-5 days 0.00222 hours 1.322751e-5 weeks 3.044e-6 months Accumlated 24 Hour Penalty Points NPUO9O4 Penalty Points at Last Execution of Program NPUO94I Power Level at Last Execution of Program NPU0939 FMP-009 Rev. 17 Page 25 of 34

Q 0 ATTACHMENT 10.2 Page 1 of 5 TARGET AND OPERATING BAND EXAMPLES E1URE 1 100 AXLAL FLUX DIFFERENCE (%)

FMP-009 Rev. 17 Page 26 of 34

o ATTACHMENT 10.2 Page 2 of 5 TARGET AND OPERATING BAND EXAMPLES LIPJJRE 2 100 80 60 40 20 AXIAL FLUX DIFFFPFNCF (al FMP-009 Rev. 17 Page 27 of 34

ATTACHMENT 10.2 Page 4 of 5 TARGET AND OPERATING BAND EXAMPLES 100-UNA CEPTAB E I f NACCE A

4 BLE Op RATIO N t_,n l *fl OPERAfl )N 80-F

/7 S I, 5-I, 5-60- 5 ACC PERAT ON \

..-S S. tk21a.5

( I9..3.5O) (.li. )

40 I I I I

-I- BANDS

.44 TARGE

+ .b TARGE BANDS i.t Cr sal ,ar

20 - APtzO.9 I

N TE: TARGET VALUE

- i fFR 1fl II 0-I LL 40 20 0 20 40 AXLAL F1.UX DIFFERENCE ()

FMP-009 Rev. 17 Page 29 of 34

U e ATTACHMENT 10.2 Page 5 of 5 TARGET AND OPERATING BAND EXAMPLES FIGURE 5 AXL*J.. FLUX D!FFERENCE (u)

FMP-009 Rev. 17 Page 30 of 34

V ATTACHMENT 10.3 Page 1 of 1 ERFIS CAOC WARNINGI STATUS!ALARM MESSAGES STATUS Messages Denote a condition or message regarding a condition of interest to the Operator.

These may include:

- POWER LEVEL CROSSED 15% INCREASING PENALTY ENABLED

- POWER LEVEL CROSSED 15% DECREASING PENALTY DISABLED

- POWER LEVEL CROSSED 50% INCREASING PENALTY RATE IS FULL

- POWER LEVEL CROSSED 50% DECREASING PENALTY RATE IS HALF -OPER BANDS DISABLED

- POWER LEVEL CROSSED 90%APL INCREASING OPER BANDS EQUAL TARGET BANDS

- POWER LEVEL CROSSED 90%APL DECREASING OPER BANDS RESTORED TO NORMAL

- CHANNEL #_ NOW OUT OF SERVICE CHANNEL # JUST RETURNED TO SERVICE

- CHANNEL # JUST CROSSED THE TARGET WARNING BAND. (decreasing)

- CHANNEL # JUST CROSSED THE OPER WARNING BAND. (decreasing)

- PENALTY POINT ACCUMULATION HAS BEGUN.

- PENALTY POINT ACCUMULATION HAS ENDED.

WARNING Messages Denote a condition or message regarding a condition of impending Technical Specification violation. These may include:

- CHANNEL # JUST CROSSED THE TARGET WARNING BAND. (increasing)

- CHANNEL # JUST CROSSED THE TARGET BAND. (increasing)

- CHANNEL #_ JUST CROSSED THE OPER WARNING BAND. (increasing)

- CHANNEL #_ JUST CROSSED THE OPERATING BAND. (increasing)

- ALARM WHEN PENALTY LEVEL CROSSES 15 GOING UP.

- ALARM WHEN PENALTY LEVEL CROSSES 30 GOING UP.

- ALARM WHEN PENALTY LEVEL CROSSES 45 GOING UP.

- ALARM WHEN PENALTY LEVEL CROSSES 50 GOING UP.

- ALARM WHEN PENALTY LEVEL CROSSES 55 GOING UP.

- ALARM WHEN PENALTY LEVEL CROSSES 60 EITHER DIRECTION.

ALARM Messages Denote a condition which violates PDC limits as set forth in plant Technical Specifications, namely:

- ALARM DUE TO 2 OR MORE CHANNELS OUTSIDE OF THE TARGET BAND WITH POWER ABOVE 90%FP OR 90%APL.

- ALARM DUE TO 2 OR MORE CHANNELS OUTSIDE OF THE OPERATING BAND WITH CORE POWER BETWEEN 50%FP AND 90%FP.

- ALARM DUE TO GREATER THAN 60 PENALTY POINTS AND CORE POWER ABOVE 50%FP.

The following special symbols are printed immediately after the AFD value for a channel, if applicable:

The AFD value for the channel has just crossed a band.

The AFD value for the channel has not crossed a band, but is still outside of at least one.

?? The channel is inoperable.

FMP-009 Rev. 17 Page 31 of 34

ATTACHMENT 10.4 Page 1 of 2 DIVERGENT AXIAL OSCILLATION a

I.

0 a 26 hr. 52 hr.

Div.rg.rit Xenm Oct11acior FMP-009 Rev. 17 Page 32 of 34

ATTACHMENT 10.4 Page 2 of 2 DIVERGENT AXIAL OSCILLATION 1.5 hr.

)

1 x2 S 10

-F

1) xl x2 t i.e NOTE: To apply numbers to the above control maneuver, assume that the Target Value is -5%, the reactor power is 75% RTP and the APL is >100% RTP. The first peak is at +5 (the dotted line representing a natural divergent oscillation). At the point the control rods are inserted, the AFD is +4%, therefore, X1=9% [+4% -

(-5%)]. Stop inserting control rods at -5% and allow the AFD to go to -14% [-5% -

(-9%)] with no control rod motion. When the AFD reaches -14%, pull the control rods back to their original position.

FMP-009 Rev. 17 Page 33 of 34

U C ATTACHMENT 10.5 Page 1 of 1 MANUAL AFD MONITORING LOG This revision is the latest revision available and has been verified against the Document Management System.

(Print)

Name Signature Date Penalty Initials Date/Time Power N41 N42 N43 N44 Points Total Comments

%RTP AFD AFD AFD AFD This Penalty Interval Points SSO Review Date:

FMP-009 Rev. 17 Page 34 of 34

AFD B 3.2.3 B 3.2 POWER DISTRIBUTION LIMITS B 3.2.3 AXIAL FLUX DIFFERENCE (AFD) (PDC3 Axial Offset Control Methodology)

BASES BACKGROUND The purpose of this LCO is to establish limits on the values of the AFD in order to limit the axial power distribution skewing to either the top or bottom of the core. By limiting the amount of power distribution skewing, core peaking factors are consistent with the assumptions used in the safety analyses. Limiting power distribution skewing over time also minimizes the xenon distribution skewing.

which is a significant factor in axial power distribution control.

The operating scheme used to control the axial power distribution, PDC-3, involves maintaining the AFD within a tolerance band around a burnup dependent target, known as the target flux difference, to minimize the variation of the axial peaking factor and axial xenon distribution during unit maneuvers.

The target flux difference is determined at equilibrium xenon conditions. The control banks must be positioned within the core in accordance with their insertion limits and Control Bank D should be inserted near its normal position (i.e., 210 steps withdrawn) for steady state operation at high power levels. The power level should be as near RTP as practical. The value of the target flux difference obtained under these conditions divided by the Fraction of RTP is the target flux difference at RTP for the associated core burriup conditions. Target flux differences for other THERMAL POWER levels are obtained by multiplying the RTP value by the appropriate fractional THERMAL POWER level.

Periodic updating of the target flux difference value is necessary to follow the change of the flux difference at steady state conditions with burnup.

The Nuclear Enthalpy Rise Hot Channel Factor (H) and QPTR LCOs limit the radial component of the peaking factors.

(continued)

HBRSEP Unit No. 2 B 3.2-17 Revision No. 0

AFD B 3.2.3 BASES (continued)

APPLICABLE The AFD is a measure of axial power distribution skewing to SAFETY ANALYSES the top or bottom half of the core. The AFD is sensitive to many core related parameters such as control bank positions, core power level, axial burnup, axial xenon distribution and, to a lesser extent, reactor coolant temperature and boron concentrations. The allowed range of the AFD is used in the nuclear design process to confirm that operation within these limits produces core peaking factors and axial power distributions that meet safety analysis requirements.

The PDC-3 axial offset control methodology (Ref. 1) entails:

a. Establishing an envelope of allowed power shapes and power densities:

b. Devising an operating strategy for the cycle that maximizes unit flexibility (maneuvering) and minimizes axial power shape changes:

c. Demonstrating that this strategy does not result in core conditions that violate the envelope of permissible core power characteristics; and

d. Demonstrating that this power distribution control scheme can be effectively supervised with excore detectors.

The limits on the AFD ensure that the Heat Flux Hot Channel Factor (F (Z)) is not exceeded during either normal 0

operation or in the event of xenon redistribution following power changes. The limits on the AFD also limit the range of power distributions that are assumed as initial conditions in analyzing Condition 2, 3, and 4 events. This ensures that fuel cladding integrity is maintained for the postulated accidents in Chapter 15 of the UFSAR.

The limits on the AFD satisfy Criterion 2 of the NRC Policy Statement.

LCO The shape of the power profile in the axial (i.e., the vertical) direction is largely under the control of the operator, through either the manual operation of the control banks, or automatic motion of control banks responding to (continued)

HBRSEP Unit No. 2 B 3.2-18 Revision No. 0

AFD B 3.2.3 BASES LCO temperature deviations resulting from either manual (continued) operation of the Chemical and Volume Control System to change boron concentration, or from power level changes.

Signals are available to the operator from the Nuclear Instrumentation System (NIS) excore neutron detectors (Ref. 2). Separate signals are taken from the top and bottom detectors. The AFD is defined as the difference in normalized flux signals between the top and bottom excore detector in each detector well. For convenience, this flux difference is converted to provide flux difference units expressed as a percentage and labeled as %A flux or %AI.

Part A of this LCO is modified by a Note that states the conditions necessary for declaring the AFD outside of the target band. The target bands are defined in the COLR.

With THERMAL POWER 90% RTP or 0.9 APL, whichever is less.

the AFD must be kept within the target band. With the AFD outside the target band with THERMAL POWER 90% RTP or 0.9 APL, whichever is less, the assumptions of the accident analyses may be violated.

Parts B and C of this LCO are modified by Notes that describe how the cumulative penalty deviation time is calculated. It is intended that the unit is operated with the AFD within the target band about the target flux difference. However, during rapid THERMAL POWER reductions.

control bank motion may cause the AFD to deviate outside of the target band at reduced THERMAL POWER levels. This deviation does not affect the xenon distribution sufficiently to change the envelope of peaking factors that may be reached on a subsequent return to RTP with the AFD within the target band, provided the time duration of the deviation is limited. Accordingly, while THERMAL POWER is 50% RTP and < 90% RTP or 0.9 APL, whichever is less (i.e.,

Part B of this LCO),. a 1 hour1.157407e-5 days 2.777778e-4 hours 1.653439e-6 weeks 3.805e-7 months cumulative penalty deviation time limit, cumulative during the preceding 24 hours2.777778e-4 days 0.00667 hours 3.968254e-5 weeks 9.132e-6 months , is allowed during which the unit may be operated outside of the target band but within the acceptable operation limits provided in the COLR. This penalty time is accumulated at the rate of 1 minute for each 1 minute of operating time within the power range of Part B of this LCO (i.e., THERMAL POWER > 50% RTP but < 90% RTP or 0.9 APL, whichever is less). The cumulative penalty time is the sum of penalty times from Parts B and C of this LCO.

(continued)

HBRSEP Unit No. 2 B 3.2-19 Revision No. 0

AFD B 3.2.3 BASES

[CO Part B of the LCO is modified by a Note (Note 2) that (continued) describes the relationship of Allowable Power Level (APL) to RTP as a function of the heat flux hot channel factor at RTP, FRTP(Z). The reactor core AFD is analyzed to 100% RTP or ioo9 APL, whichever is less. When F(Z) is less than its limits, 100% RTP is more limiting than .00% APL. When Fv(Z) is greater thai, its limits, 100% APL is more limiting t?ian 100% RTP. Hence the APL results in a more restrictive operating envelope for AFD when F(Z) is greater than its limits. The K(Z) function is specified in the COLR. F(Z) is defined in the Bases of [CO 3.2.1, Heat Flux Hot Channel Factor (F(Z)).

For THERMAL POWER levels > 15% RTP and < 50% RTP (i.e.,

Part C of this LCO), deviations of the AFD outside nf th target band are less significant. The ccumuIation of 1/2 miiiute penalty deviation time per 1 minute of actual time outside the target band reflects this duçi canc. With THERMAL POWER < 15% RTP, AFis not a 1

sianij significant parameter in the assumptions used in the safety analysis and, therefore, requires no limits. Because the xenon distribution produced at THERMAL POWER levels less than 50% RTP does affect the power distribution as power is increased, unanalyzed xenon and power distribution is prevented by limiting the accumulated penalty deviation time.

The frequency of monitoring the AFD by the unit computer is once per minute providing an essentially continuous accumulation of penalty deviation time that allows the operator to accurately assess the status of the penalty deviation time.

Violating the [CO on the AFD could produce unacceptable consequences if a Condition 2, 3, or 4 event occurs while the AFO is outside its limits.

Figure B 3.2.3-1 shows a typical target band and typical AFD acceptable operation limits.

APPLICABILITY AFD requirements are applicable in MODE 1 above 15% RTP.

Above 50% RTP, the combination of THERMAL POWER and core incFfartnrc th core paramefEot primary importance in safety analyses (Ret. J).

(conti nued)

HBRSEP Unit No. 2 B 3.2-20 Revision No. 0

AFD B 3.2.3 BASES APPLICABILITY Between 15% RTP and 1JL1% RTP, this LCO is applicable to (continued) ensure tWat the distributions of xenon are consistent with safety analysis assumptions.

At or below 15% RTP and for lower operating MODES, the stored energy in the fuel and the energy being transferred to the reactor coolant are low. The value of the AFD in these conditions does not affect the consequences of the design basis events.

For surveillance of the power range channels performed according to SR 3.3.1.6, deviation outside the target band is permitted for 16 hours1.851852e-4 days 0.00444 hours 2.645503e-5 weeks 6.088e-6 months and no penalty deviation time is accumulated. Some deviation in the AFD is required for doing the NIS calibration with the incore detector system.

This calibration is performed every 92 days.

Low signal levels in the excore channels may preclude obtaining valid AFD signals below 15% RTP.

ACTIONS With the AFD outside the target band and THERMAL POWER 90% RTP or 0.9 APL, whichever is less, the assumptions used in the accident analyses may be violated with respect to the maximum heat generation. Therefore, a Completion Time of 15 minutes is allowed to restore the AFD to within the target band because xenon distributions change little in this relatively short time.

B.1 If the AFD cannot be restored within the target band, then reducing THERMAL POWER to < 90% RTP or 0.9 APL, whichever is less places the core in a condition that has been analyzed and found to be acceptable, provided that the AFD is within the acceptable operation limits provided in the COLR.

The allowed Completion Time of 15 minutes provides an acceptable time to reduce power to < 90% RTP or 0.9 APL whichever is less without allowing the plant to remain in an unanalyzed condition for an extended period of time.

(continued)

HBRSEP Unit No. 2 B :3.2-21 Revision No. 0

AFD B 3.2.3 BASES ACTIONS C.1 and C.2 (continued)

With THERMAL POWER <: 90% RTP or 0.9 APL, whichever is less but 50% RTP, operation with the AFD outside the target band is allowed for up to 1 hour1.157407e-5 days 2.777778e-4 hours 1.653439e-6 weeks 3.805e-7 months if the AFD is within the acceptable operation limits provided in the COLR. With the AFD within these limits, the resulting axial power distribution is acceptable as an initial condition for accident analyses assuming the then existing xenon distributions. The 1 hour1.157407e-5 days 2.777778e-4 hours 1.653439e-6 weeks 3.805e-7 months cumulative penalty deviation time restricts the extent of xenon redistribution. Without this limitation, unanalyzed xenon axial distributions may result from a different pattern of on buildup and decay. The reduction to a power level < 50% RTP puts the reactor at a THERMAL POWER level at which the AFD is not a significant accident analysis parameter. Restoration of cumulative penalty time to less than one (1) hour prior to increasing THERMAL POWER to above 50% RTP in accordance with Required Action C.2 ensures that the AFD will be within the core analysis.

If the indicated AF[) is outside the target band and outside the acceptable operation limits provided in the COLR, the peaking factors assumed in accident analysis may be exceeded with the existing xenon condition. (Any AFD within the target band is acceptable regardless of its relationship to the acceptable operation limits.) The Completion Time of 30 minutes allows for a prompt, yet orderly, reduction in power.

Condition C is modified by a Note that requires that Required Actions C.1 and C.2 must be completed whenever this Condition is entered.

D.1 If Required Action C.1 is not completed within its required Completion Time of 30 minutes, the xi xenon distribution starts to become significantly skewed with the THERMAL POWER 50% RTP. In this situation, the assumption that a cumulative penalty deviation time of 1 hour1.157407e-5 days 2.777778e-4 hours 1.653439e-6 weeks 3.805e-7 months or less during the previous 24 hours2.777778e-4 days 0.00667 hours 3.968254e-5 weeks 9.132e-6 months while the AFD is outside its target band is acceptable at < 50% RTP, is no longer valid.

(continued)

HBRSEP Unit No. 2 B 3.2-22 Revision No. 0

AFD B 3.2.3 BASES ACTIONS DJ (continued)

Reducing the power level to < 15% RTP within the Conipletion Time of 9 hours1.041667e-4 days 0.0025 hours 1.488095e-5 weeks 3.4245e-6 months and complying with LCO penalty deviation time requirements for subsequent increases in THERMAL POWER ensure that acceptable xenon conditions are restored.

This Required Action must also be implemented either if the cumulative penalty deviation time is > 1 hour1.157407e-5 days 2.777778e-4 hours 1.653439e-6 weeks 3.805e-7 months during the previous 24 hours2.777778e-4 days 0.00667 hours 3.968254e-5 weeks 9.132e-6 months , or the AFD is not within the target band and not within the acceptable operation limits.

Condition D is modified by a Note that requires Action D.1 be completed whenever this Condition is entered.

SURVEILLANCE SR 3.2.3.1 REQUIREMENTS The AFD is monitored on an automatic basis using the unit process computer that has an AFD monitor alarm. The computer determines the 1 minute average of each of the OPERABLE excore detector outputs and provides an alarm message immediately if the AFDs for two or more OPERABLE excore channels are outside the target band and the THERMAL POWER is > 90% RTP or o.g APL. whichever is less. During operation at THERMAL POWER levels < 90% RTP or 0.9 APL, whichever is less but > 15% RTP. the computer sends an alarm message when the cumulative penalty deviation time is

> 1 hour1.157407e-5 days 2.777778e-4 hours 1.653439e-6 weeks 3.805e-7 months in the previous 24 hours2.777778e-4 days 0.00667 hours 3.968254e-5 weeks 9.132e-6 months .

This Surveillance verifies that the AFD as indicated by the NIS excore channels is within the target band and consistent with the status of the AFD monitor alarm. The Surveillance Frequency of 7 days is adequate because the AFD is controlled by the operator and monitored by the process computer. Furthermore, any deviations of the AFD from the target band that is not alarmed should be readily noticed.

SR 3.2.3.2 With the AFD monitor alarm inoperable, the AFD is monitored to detect operation outside of the target band and to compute the penalty deviation time. During operation at 90% RTP or 0.9 APL, whichever is less, the AFD is (continued)

HBRSEP Unit No. 2 B 3.2-23 Revision No. 0

AFD B 3.2.3 BASES SURVEILLANCE SR 3.2.3.2 (continued)

REQU I REMENTS monitored at a Surveillance Frequency of 15 minutes to ensure that the AFD is within its limits at high THERMAL POWER levels. At power levels < 90% RTP or 0.9 APL.

whichever is less, but > 15% RTP, the Surveillance Freque is reduced to 1 hour1.157407e-5 days 2.777778e-4 hours 1.653439e-6 weeks 3.805e-7 months because the AFD may deviate from ncy target band for up to 1 hour1.157407e-5 days 2.777778e-4 hours 1.653439e-6 weeks 3.805e-7 months using the methodology of the Parts B and C of this LCO to calculate the cumulative penalty deviation time before corrective action is require d.

SR 3.2.3.2 is modified by a Note that states that monito and logged values of the AFD are assumed to exist for thered preceding 24 hour2.777778e-4 days 0.00667 hours 3.968254e-5 weeks 9.132e-6 months interval in order for the operator to compute the cumulative penalty deviation time. The AFD should be monitored and logged more frequently in operation for which the power level or control bankperiods of positions are changing to allow corrective measures AFD is more likely to move outside the target band. when the SR 3.2.3.3 Measurement of the target flux difference is accomplished taking a flux map when the core is at equilibrium xenon by conditions, preferably at high power levels with the banks nearly withdrawn. This flux map provides the control equilibrium xenon axial power distribution from which the target value can be determined. The target flux differenc varies slowly with core burnup. e A Frequency of 31 EFPD after each refueling and 31 EFPD thereafter for remeasuring the target flux differences adjusts the target flux difference for each excore to the value measured at steady state conditions. channel A Note modifies this SR to allow the predicted beginning cycle AFD from the cycle nuclear design to be used to of determine the initial target flux difference after each refueling.

A second Note modifies this SR to require that the target flux difference be determined in conjunction with the measurement of the heat flux hot channel factor, FQ(Z). in accordance with SR :3.2.1.1. This is a requirement of the PDC-3 Axial Offset Control Methodology.

(continued)

HBRSEP Unit No. 2 B :3.2-24 Revision No. 6

AFD B 3.2.3 BASES (continued)

REFERENCES 1. ANF-88-054 (Proprietary). PDC-3: Advanced Nuclear Fuels Corporation Power Distribution Control for Pressurized Water Reactors and Application of PDC-3 to H. B. Robinson Unit 2, Advanced Nuclear Fuels Corporation, Richiand, WA 99352, July 1988 (Submitted to NRC by CP&L letter dated August 24. 1989).

2. UFSAR Section 7.2.1.1

3. XN-NF7757(P)(A) (Proprietary). Exxon Nuclear Power Distribution Control for Pressurized Water Reactors, Phase II, Supplement 2 and Supplement 2, Addendum 1,,

Exxon Nuclear Company, Richiand WA 99352, October 1982, page 34.

HBRSEP Unit No. 2 B :3.225 Revision No. 0

AFD B 3.2.3 100 90 80 70 w

0 60 a-

-J 50 LU I

0 u-I 40 I

30 20 10 0

25 -15 -5 15 25 35 AXIAL FLUX DIFFERENCE (%)

Figure B 3.2.3A-1 (Page 1 of 1)

AXIAL FLUX DIFFERENCE Acceptable Operation Limits and Target Band Limits as a Function of RATED THERMAL POWER HBRSEP Unit No. 2 B :3.2-26 Revision No. 0

93. 029 A2.01 SRO 001 Given the following plant conditions:

- The plant is at 100% RTP.

- Maintenance is preparing to enter the CV to repair a leak on a sensing line.

- CV Pressure Relief is in progress with CV pressure currently at 0.05 psig.

- CV Purge Gaseous Waste Release Permit has been issued to allow the CV Purge to commence.

- Both R-ll AND R-12 are in service.

Which ONE (1) of the following completes the statements below?

The CV Purge and CV Pressure Relief (1) be performed concurrently.

R-14C, Auxiliary Building Vent Stack Noble Gas Monitor, (2) required to be operable during the CV Purge.

A. (1)may (2) is NOT B. (1)may (2) is C (1) may NOT (2) is NOT D. (1) may NOT (2) is The correct answer is C.

A. Incorrect. A CV Purge and CV Pressure Relief may not be performed concurrently.

This is 3.6.3 prohibits opening the 42 inch purge and 6 inch pressure relief valves simultaneously. R-14C is normally in service during a pressure relief and purge, but is not required as long as R-1 I AND R-12 are both operable. This requirement is specified in the ODCM and EMP-022, Gaseous Waste Release Permits.

B. Incorrect. See discussion in A above.

C. Correct.

D. Incorrect. The first part of the distractor is correct. See discussion in A above.

Page: 171 of 187 10/13/2011

Question 93 Tier/Group 2 / 2 K/A Importance Rating - RO 2.6 SRO 2.8 Ability to (a) predict the impacts of the following malfunctions or operations on the Containment Purge System; and (b) based on those predictions, use procedures to correct, control, or mitigate the consequences of those malfun ctions or operations:

Maintenance or other activity taking place inside containment Reference(s) Sim/Plant design, EMP-022, ODCM, OP-921 Proposed References to be provided to applicants during examin ation - None Learning Objective CVHVAC 007 Question Source NEW-Question Cognitive Level H -

10 CFR Part 55 Content 41.5 /43.5 /45.3 /45.13 Comments -

SRO: Knowledge Tech Spec requirements that are below the double line and greater than 1 hour1.157407e-5 days 2.777778e-4 hours 1.653439e-6 weeks 3.805e-7 months . Application of Offsite Dose Calculation Manual (ODCM

) requirements.

Knowledge of requirements for gaseous release approvals, i.e.,

release permits.

Page: 172 of 187 10/13/2011

Containment Isolation Valves 3.6.3 ACTIONS (continued)

CONDITION REQUIRED ACTION COMPLETION TIME

0. Required Action and D.1 Be in MODE 3. 6 hours6.944444e-5 days 0.00167 hours 9.920635e-6 weeks 2.283e-6 months associated Completion Time not met. AND OR D.2 Be in MODE 5. 36 hours4.166667e-4 days 0.01 hours 5.952381e-5 weeks 1.3698e-5 months inch penetration (Supply or Exhaust) purge valves open and 6 inch penetration (pressure or vacuum relief) valves open

%taneousi7

)

SURVEI LLANCE REQUIREMENTS SURVEILLANCE FREQUENCY SR 3.6.3.1 -----NOTE----

valves may not be Verify each 42 inch purge supply and 31 days exhaust valve and each 6 inch pressure and vacuum relief valve is closed, except when the valves are open for safety related reasons, or for tests or Surveillances that require the valves to be open.

(conti nued)

HBRSEP Unit No. 2 3.6-10 Amendment No. 176

ATTACHMENT 10.2 Page 1 of 2 GASEOUS WASTE RELEASE PERMIT BATCH CONTAINMENT RELEASE NUMBER: SSN: DATE:

This revision is the latest revision available as verified by:

Name (Print) Initial Signature Date PART I: PRE-RELEASE INFORMATION (E&C)

Pressure Relief Batch Purge Estimated Release Start CV PR Via Vacuum Relief Date Time Other Estimated Release Stop Date Time (check one)

R-11/12 Sample Point during release: CV. or PV (Circle One)

Monitor Setpoint Basis (Circle One)

R-11 CPM EC Activity R-12 CPM EC Activity R-14C (3) CPM EC Activity NA This release can be made within the limits of IOCFR2O and IOCFR5O using the setpoints and restrictions stated herein.

Prepared By: Peer Review:

E&C Supervisor:

PART II: RADIATION MONITOR INFORMATION (OPS and E&C) (CR 98-00002)

_READING R-11 R-12 R-14C(3)

PRIOR (4) CPM CPM CPM SOURCECHECK(5) OPSINI OPSINI SETPOINT VERF. AT (6) CPM CPM CPM UPDATE STATUS BOARD (7) OPS INI DURING RELEASE CPM CPM CPM AFTER RELEASE CPM CPM CPM SETPOINT RETURNED TO (8) CPM CPM CPM STATUS BOARD UPDATED (7) OPS NI Approved for Release: (CR 97-00059)

Shift Manager EMP-022 Rev. 52 Page 50 of 60

ATTACHMENT 10.2 Page 2 of 2 GASEOUS WASTE RELEASE PERMIT - BATCH CONTAINMENT Release #

PART Ill: RELEASE INFORMAT 1 ION (OPS)

Ensure at least one Aux. Building fan running. (OPS)

Ensure no WGDT release in progress. (OPS RELEASE DATE TIME PSIG START PRESSURE RELIEF OR PURGE FAN STOP (2)

P Notes:

1. N/A all blanks not applicable.

2. For a Batch C.V. Purge becoming a Continuous C.V. Purge, the stop time is the start time of the Continuous C.V. Purge.

3. E&C Technician will perform setpoint changes for R-14C as per EMP-013. R-14C setpoint is not required for a CV PR via containment vacuum relief, NA these blanks.

4. If Rad Monitor is out-of-service, refer to Section 7.3.3 OR 7.3.4 of EMP-022. (ITS LCO 3.3.6)

5. Source check for R-12 required prior to each C.V. Release (ODCM Table 3.11-1, item 2.b). If R-12 fails source check, refer to Section 7.3.3 OR 7.3.4. (ITS LCO 3.3.6)

6. If current R-1 1/R-12 or R-14C setpoints are more conservative than those in PART I, the setpoint need not be changed. Log cpm that monitor setpoint was verified at.

7. Verify status board in control room has correct setpoint.

8. Upon completion of C.V. Batch Releases, notify E&C to return R-14C setpoint to listed value on current weekly Continuous Plant Vent release permit (not required for CV PR via Containment Vacuum Relief) and reset R-1 1 and R-12; if changed, as per OMM-014.

Completed by:

(E&C Technician)

Completed by:

(Control Operator)

Reviewed by:

(Shift Manager)

POST RELEASE REVIEW Release Posted By: Date:

Reviewed By Date EMP-022 Rev. 52 Page 51 of 60

7.3.3 Minimum Instrumentation Requirements for Containment Vessel Releases Via Plant Vent Modes 1, 2, 3, 4 AND movement of recently irradiated fuel.

N 1

ES KNoperae>>° No EMP-022 Rev. 52 Page 17 of 60

. 0 TABLE 3.10-1 (Continued)

RADIOACTIVE GASEOUS EFFLUENT MONITORING INSTRUMENTATION Release Pathway/Instrumentation MCD Compensatory Measures

1. Plant Vent (Continued)

c. Radioiodine Sampler 1 With the number of channels operable less than the MCD requirements:

a. Exert best efforts to return the instruments to operable status within 30 days and, if unsuccessful, explain in the next Annual Radioactive Effluent Release Report why the inoperability was not corrected in a timely manner in accordance with Technical Specification 5.6.3 and,

b. Effluent releases via this pathway may continue provided that a continuous sample is collected utilizing auxiliary sampling equipment as required by Table 3.12-1. (note 1)

d. Particulate Sampler 1 With the number of channels operable less than the MCD requirement:

a. Exert best efforts to return the instruments to operable status within 30 days and, if unsuccessful, explain in the next Annual Radioactive Effluent Release Report why the inoperability was not corrected in a timely manner in accordance with Technical Specification 5.6.3 and,

b. Effluent releases via this pathway may be continued, provided that a continuous sample is collected utilizing auxiliary sampling equipment as required by Table 3.12-1. (note 1)

e. Sampler flow rate monitor 1 With the number of channels operable less than the MCD requirement:

a. Exert best efforts to return the instruments to operable status within 30 days and, if unsuccessful, explain in the next Annual Radioactive Effluent Release 12/06 Report why the inoperability was not corrected in a timely manner in accordance with Technical Specification 5.6.3 and,

b. Effluent releases via this pathway may continue provided the flow rate is estimated once per 4 hours4.62963e-5 days 0.00111 hours 6.613757e-6 weeks 1.522e-6 months .

MCO Minimum Channels Operable HBRODCM 3-83 Rev. 28

S TABLE 3.10-1 (Continued)

RADIOACTIVE GASEOUS EFFLUENT MONITORING INSTRUMENTATION Release Pathway/Instrumentation MCO Compensatory Measures Plant Vent (Continued)

f. Plant Vent flow rate 1 With the number of channels operable less than the MCO requirement:

a. Exert best efforts to return the instruments to operable status within 30 days and, if unsuccessful, explain in the next Annual Radioactive Effluent Release Report why the inoperability was not corrected in a timely manner in accordance with Technical Specification 5.6.3 and,

b. Effluent releases via this pathway may continue provided that flow rate is estimated once per 4 hours4.62963e-5 days 0.00111 hours 6.613757e-6 weeks 1.522e-6 months .

2. Containment Vessel via Plant Vent

a. Radionoble gas monitor 1 With the number of channels operable less than the MCO requirement:

(R-12) provides automatic a. Exert best efforts to return the instruments to operable status within 30 days and, termination of Containment if unsuccessful, explain in the next Annual Radioactive Effluent Release Report Vessel releases upon why the inoperability was not corrected in a timely manner in accordance with exceeding alarm/trip Technical Specification 5.6.3 and, Setpoint. b. Effluent releases via this pathway may continue provided that the Plant Vent Radionoble Gas Monitor (RI4C) is operable; otherwise, suspend all releases via this pathway. (note 2)

b. Radioparticulate Monitor i With the number of channels operable less than the MCO requirement:

(R-11) provides automatic a. Exert best efforts to return the instruments to operable status within 30 days and, termination of containment if unsuccessful, explain in the next Annual Radioactive Effluent Release Report vessel releases exceeding why the inoperability was not corrected in a timely manner in accordance with alarm/trip setpoints. Technical Specification 5.6.3 and,

b. Effluent releases via this pathway may continue provided that the Plant Vent Radionoble Gas Monitor (R14C) is operable; otherwise, suspend all releases via this pathway. (note 2)

MCO Minimum Channels Operable HBRODCM 3-84 Rev. 28

C n TABLE 3.10-1 (Continued)

RADIOACTIVE GASEOUS EFFLUENT MONITORING INSTRUMENTATION Release Pathway/Instrumentation MCO Compensatory Measures

2. Containment Vessel via Plant Vent (Continued)

c. Sampler flow rate monitor 1 With the number of channels operable less than the MCO requirement:

(R-1 1) a. Exert best efforts to return the instruments to operable status within 30 days and, if unsuccessful, explain in the next Annual Radioactive Effluent Release Report why the inoperability was not corrected in a timely manner in accordance with Technical Specification 5.6.3 and,

b. Effluent releases via this pathway may continue provided that either the Plant Vent Radionoble Gas Monitor (R-14C) is operable or the flow rate is estimated once per 4 hours4.62963e-5 days 0.00111 hours 6.613757e-6 weeks 1.522e-6 months . (note 2)

3. Fuel Handling Building Lower Level 05/10 Exhaust Vent

a. Radionoble gas monitor 1 With the number of channels operable less than the MCO requirement:

(R-20) a. Exert best efforts to return the instruments to operable status within 30 days and, if unsuccessful, explain in the next Annual Radioactive Effluent Release Report why the inoperability was not corrected in a timely manner in accordance with Technical Specification 5.6.3 and,

b. Effluent releases via this pathway may continue provided that grab samples are taken once per 12 hours1.388889e-4 days 0.00333 hours 1.984127e-5 weeks 4.566e-6 months and analyzed for radionoble gases within 24 hours2.777778e-4 days 0.00667 hours 3.968254e-5 weeks 9.132e-6 months .

b. Sampler flow rate monitor 1 With the number of channels operable less than the MCO requirement:

(R-20) a. Exert best efforts to return the instruments to operable status within 30 days and, if unsuccessful, explain in the next Annual Radioactive Effluent Release Report why the inoperability was not corrected in a timely manner in accordance with Technical Specification 5.6.3 and,

b. Effluent releases via this pathway may continue provided the flow rate is estimated once per 4 hours4.62963e-5 days 0.00111 hours 6.613757e-6 weeks 1.522e-6 months .

MCO Minimum Channels Operable HBRODCM 3-85 Rev. 31

0 TABLE 3.10-1 (Continued)

RADIOACTIVE GASEOUS EFFLUENT MONITORING INSTRUMENTATION Release Pathway/Instrumentation MCO* Compensatory Measures

6. Radwaste Building Exhaust (Continued)

c. Sampler flow rate gauge I With the number of channels operable less than the MCO requirement:

a. Exert best efforts to return the instruments to operable status within 30 days and, if unsuccessful, explain in the next Annual Radioactive Effluent Release Report why the inoperability was not corrected in a timely manner in accordance with Technical Specification 5.6.3 and,

b. Effluent releases via this pathway may continue provided the flow rate is estimated once per 4 hours4.62963e-5 days 0.00111 hours 6.613757e-6 weeks 1.522e-6 months .

7. Deleted.

NA NA MCO - Minimum Channels Operable 12/06 NOTES TO TABLE 3.10-1 Note 1 - No auxiliary sampling is required for periods when normal sampling is off 45 minutes.

Note 2 This MCO is required during Modes 1, 2, 3, 4, and during the movement of recently irradiated fuel assemblies within the containment.

HBRODCM 3-90 Rev. 28

Section 8.4.1 Page 2 of 9 8.4.1.1 (Continued)

!NiI NOTE: In MODES 1, 2, 3, 4, AND when moving recently irradiated fuel in the Containment, the Containment Ventilation Isolation signal from R-l 1 AND R-12 is required to be OPERABLE. (ITS 3.3.6)

In accordance with ODCM requirements, one of the following is required for monitorin during Containment Purging (ODCM Table 3.10-1):

R-11 AND R-12

e. IF R-1 1 is in service, THEN PERFORM the following:

1) IF the current R-1 1 setpoint is higher than the setpoint on the release permit OR it is desired to adjust the RMS setpoint, THEN ADJUST RMS setpoint lAW the new value on the release permit.

2) PERFORM a CHANNEL CHECK on R-1 1.

(ITS SR 3.3.6.1 TBL 3.3.6-1 Item 3)

f. IF R-12 is in service, THEN PERFORM the following:

1) IF the current R-12 setpoint is higher than the setpoint on the release permit OR it is desired to adjust the RMS setpoint, THEN ADJUST RMS setpoint lAW the new value on the release permit.

2) PERFORM a CHANNEL CHECK on R-12.

(ITS SR 3.3.6.1 TBL 3.3.6-1 Item 3)

[ OP-921 Rev. 51 Page 35 of 58

94. G2.1.31 SRO 001 Given the following plant conditions:

- The Motor Driven Fire Pump (MDFP) was started remotely per OST-603, MDFP and EDFP Test (Weekly).

- The MDFP supply breaker tripped open during OST-603.

Which ONE(1) of the following completes the statement below?

MDFP indication (1) available on the Containment Fire Protection Panel.

The Fire Suppression Water Supply System is considered (2) lAW FP-012, Fire Protection Systems Minimum Equipment and Compensatory Actions.

A. (1) is NOT (2) Operable B (1) is (2) Operable C. (1)isNOT (2) Inoperable D. (1)is (2) Inoperable The correct answer is B.

A. Incorrect. The pump status lights on the CFPP in the control room will show dual indication. Second half of the distractor correct.

B. Correct.

C. Incorrect. The pump status lights on the CFPP in the control room will show dual indication. Per FP-012, only ONE fire pump is required for the Fire Suppression Water Supply System to be considered OPERABLE. This requirement is met by the Engine Driven Fire Pump being operable. An EIR will be filled out on the MDFP with a seven day return to service time or initiate an NCR.

D. Incorrect. First part of the distractor is correct. Per FP-012, only ONE fire pump is required for the Fire Suppression Water Supply System to be considered OPERABLE.

This requirement is met by the Engine Driven Fire Pump being operable. An EIR will be filled out on the MDFP with a seven day return to service time or initiate an NCR.

Page: 173 of 187 10/13/2011

Exert from FP-012.

8.2 Fire Suppression Water Supply System NOTE: Each fire pump provides 100% of the required flow. Therefore, the loss of one (1) fire pump does not cause the Fire Suppression Water Supply System to be inoperable as described in 8.2.3.

8.2.1 The Fire Suppression Water Supply System shall be operable with:

1. Two (2) fire pumps, each with a capacity of 2,500 gpm, with their discharge aligned to the yard loop, AND

2. An operable flow path capable of taking suction from the Unit 2 intake structure AND transferring the water through distribution piping with operable sectionalizing OR isolation valves to the systems identified in Sections 8.3 and 8.4.

8.2.2 With less than the above required equipment operable, restore the inoperable equipment to operable status within seven (7) days.

Question 94 Tier 3 K/A Importance Rating - RO 4.2 SRO 4.2 Ability to locate control room switches, controls, and indications, and to determine that they correctly reflect the desired plant lineup.

Reference(s) Sim/Plant design, FP-012, System Description Proposed References to be provided to applicants during examination None -

Learning Objective FPWOO7 -

Question Source NEW -

Question Cognitive Level H -

10 CFR Part 55 Content 41.10, 45.12 Comments K/A match because candidate must know where the status of the MDFP can be obtained in the control room.

SRO: This question is SRO level because it is administration of fire protection program requirements for determining operability of the Fire Suppression Water Supply System.

Reviewed and approved by MAB.

Page: 174 of 187 10/13/2011

95. G2.1.41 SRO 001 Given the following conditions:

- The plant is in MODE 6 for Refueling.

- Core offload is in progress with a Fuel Assembly on the Manipulator.

- Refueling Cavity level is lowering.

Which ONE (1) of the following completes the statements below?

The Fuel Assembly from the Manipulator is required to be placed in the core, in (1) as required by (2)

A. (1) in its original location (2)AOP-013, Fuel Handling Accident B. (1) any location that is bordered by 2 other assemblies (2) AOP-013, Fuel Handling Accident Cs (1) in its original location (2) AOP-020, Loss of Residual Heat Removal (Shutdown Cooling)

D. (1) in any location that is bordered by 2 other assemblies (2) AOP-020, Loss of Residual Heat Removal (Shutdown Cooling)

REVISE The correct answer is C.

A: Incorrect - Place the fuel assembly back in a location where subcritical configuration was known. The transfer cart must be on the CV side to be able to shut the Gate Valve.

B: Incorrect Placing a fuel assembly in an unanalyzed core position could result in a loss or reduction of the required shutdown margin. The transfer cart must be on the CV side to be able to shut the Gate Valve.

C: Correct - Place the fuel assembly back in a location where subcritical configuration was known. The transfer cart must be on the CV side to be able to shut the Gate Valve.

D: Incorrect - Placing a fuel assembly in an unanalyzed core position could result in a loss or reduction of the required shutdown margin. The transfer cart must be on the CV side to be able to shut the Gate Valve.

Page: 175 of 187 10/13/2011

Question 95 Tier 3 K/A Importance Rating - RO 4.6 SRO 4.3 Knowledge of the refueling processes.

Reference(s) AOP-020, Section B., AOP-013 Proposed References to be provided to applicants during examination - None Learning Objective AOP-020-04 Question Source NEW Question Cognitive Level F -

10 CFR Part 55 Content- 41.2 /41.1 /43.6/45.13 Comments -

SRO: Question involves assessing plant facility conditions and having knowledge of the content of the mitigating procedure. Fuel handling in the CV is an SRO only function.

Refuel floor SRO responsibilities.

10/13/2011 Page: 176 of 187

Rev. 32 AOP-020 LOSS OF RESIDUAL HEAT REMOVAL (SHUTDOWN COOLING)

Page 31 of 130

STEP H INSTRUCTIONS I I RESPONSE NOT OBTAINED Section B Loss Of RHR Inventory - Vessel Head Off (Page 2 of 10)

3. Notify Refueling Personnel To Perform The Following:

a. Pla e any fuel assembly in transit in one of the following locations:

Original Core location

Upender

Storage location approved by FMP-019, Fuel and Insert Shuffle

b. Place any Reactor Vessel Upper or Lower Internals in transit in one of the following locations:

Reactor Vessel (preferred location)

Designated storage location in transfer canal

4. Notify Refueling Personnel to Perform the Following:

a. Verify Fuel Transfer Conveyer Car Location - IN CONTAINMENT

b. Verify CV Upender Position -

HORI ZONTAL

c. Verify CLOSED The SFP GATE VALVE

5. Check APP-036-36. Spent Fuel Pit Refer to AOP-O36. SFP Events.

Lo Level - EXTINGUISHED

6. Check Cavity Seal Q Sand Plug Observe the NOTE prior to Failure - IN PROGRESS Step 15 and Go To Step 15.

CONTINUOUS USE H. B. ROBINSON STEAM ELECTRIC PLANT, UNIT NO. 2 PLANT OPERATING MANUAL VOLUME 3 PART 5 ABNORMAL OPERATING PROCEDURE AOP- 013 FUEL HANDLING ACCIDENT REVISION 13 Page 1 of 15

AOP-013 I Rev. 13 FUEL HANDLING ACCIDENT Page 4 Df 15 Purpose and Entry Conditions (Page 1 of 1)

1. PURPOSE This procedure provides the instructions for actions to be taken for a fuel handling accident in Containment, the Spent Fuel Pit Area or the New Fuel Storage Area.

NOTE procedure Other event ha the p0t tit to the assembi Minor bumps 0-f assemblies being moved leaning assemblies are IQI considered accidents for this procedure entry.

2. ENTRY CONDITIONS Upon receiving a report that a fuel handling accident, as described above, has occurred.

- END -

96. G2.2.35 SRO 001 Given the following plant conditions:

- A plant heatup from a refueling outage is currently in progress.

- Highest available RCS temperature is 325° F and rising.

- The A MDAFW Pump has been declared OOS.

Which ONE (1) of the following completes the statement below?

The current technical specification operational MODE is (1) and lAW the technical specifications a change to the next higher MODE based on conditions given is (2)

A. (1)3 (2) allowed as long as a risk assessment addressing the inoperable MDAFW Pump is performed B. (1)4 (2) allowed as long as a risk assessment addressing the inoperable MDAFW Pump is performed C. (1)3 (2) NOT allowed D (1)4 (2) NOT allowed Page: 177 of 187 10/13/2011

The correct answer is D.

A. Incorrect. LCO 3.0.4b (risk assessment evaluation) is not applicable for ITS 3.7.4, Auxiliary Feedwater (AFW) System. Mode is incorrect.

B. Incorrect. LCO 3.0.4b (risk assessment evaluation) is not applicable for ITS 3.7.4, Auxiliary Feedwater (AFW) System. Mode is correct.

C. Incorrect. Mode is incorrect. Mode 3 is not entered until temperature is greater than or equal to 350°F.

D. Correct. LCO 3.0.4b (risk assessment evaluation) is not applicable for ITS 3.7.4, Auxiliary Feedwater (AFW) System.

Exert from LCO 3.0.4 LCO 3.0.4 When an LCO is not met, entiy into a MODE or other specified condition in the Applicability shall only be made:

a. When the associated ACTIONS to be entered permit continued operation in the MODE or other specified condition in the Applicability for an unlimited period of time, or

b. After performance of a risk assessment addressing inoperable systems and components, consideration of the results, determination of the acceptability of entering the MODE or other specified condition in the Applicability, and establishment of risk management actions, if appropriate; exceptions to this Specification are stated in the individual Specifications, or

c. When an allowance is stated in the individual value, parameter, or other Specification.

This Specification shall not prevent changes in MODES or other specified conditions in the Applicability that are required to comply with ACTIONS or that are part of a shutdown of the unit.

Page: 178 of 187 10/13/2011

Question 96 Tier 3 K/A Importance Rating - RO 3.6 SRO 4.5 Ability to determine Technical Specification Mode of Operation.

Reference(s) Sim/Plant design, ITS Section 1.1, 3.0, 3.7.4 Proposed References to be provided to applicants during examination - None Learning Objective Intro to Tech Specs 001, 005; AFW 012 Question Source NEW-Question Cognitive Level H -

10 CFR Part 55 Content- 41.7/41.10/43.2/45.13 Comments -

SRO: Application of generic Limiting Condition of Operation requirements (LCO 3.0.1 thru 3.0.7)

Page: 179 of 187 10/13/2011

Definitions 1.1 Table 1.1-1 (page 1 of 1)

MODES REACTIVITY X RATED AVERAGE CONDITION THERMAL REACTOR COOLANT MODE TITLE (keff) TEMPERATURE

(°F) 1 Power Operation 0.99 > 5 NA 2 Startup 0.99 5 NA

. 3 Hot Standby < 0.99 NA 350 4 Hot Shutdown < 0.99 NA 350 > > 200 5 Cold Shutdown(b) < 0.99 NA 200 6 Refueling(C) NA NA NA (a) Excluding decay heat.

(b) All reactor vessel head closure bolts fully tensioned.

Cc) One or more reactor vessel head closure bolts less than fully tensioned.

HBRSEP Unit No. 2 1.16 Amendment No. 176

LCO Applicability 3.0 3.0 LIMITING CONDITION FOR OPERATION (LCO) APPLICABILITY LCD 3.0.1 LCOs shall be met during the MODES or other specified conditions in the Applicability, except as provided in LCD 3.0.2 and 3.0.7.

LCO 3.0.2 Upon discoveryofafailuretomeetan LCO, theRequiredActions of the associated Conditions shall be met, except as provided in LCD 3.0.5 and LCO 3.0.6.

If the LCO is met or is no longer applicable prior to expiration of the specified Completion Time(s), completion of the Required Action(s) is not required unless otherwise stated.

LCO 3.0.3 When an LCD is not met and the associated ACTIONS are not met, an associated ACTION is not provided, or if directed by the associated ACTIONS, the unit shall be placed in a MODE or other specified condition in which the LCD is not applicable. Action shall be initiated within 1 hour1.157407e-5 days 2.777778e-4 hours 1.653439e-6 weeks 3.805e-7 months to place the unit, as applicable, in:

a. MODE 3 within 7 hours8.101852e-5 days 0.00194 hours 1.157407e-5 weeks 2.6635e-6 months ;

b. MODE 4 within 13 hours1.50463e-4 days 0.00361 hours 2.149471e-5 weeks 4.9465e-6 months ; and

c. MODE 5 within 37 hours4.282407e-4 days 0.0103 hours 6.117725e-5 weeks 1.40785e-5 months .

Exceptions to this Specification are stated in the individual Specifications.

Where corrective measures are completed that permit operation in accordance with the LCO or ACTIONS, completion of the actions required by LCD 3.0.3 is not required.

LCO 3.0.3 is only applicable in MODES 1, 2, 3, and 4.

LCD 3.0.4 When an LCD is not met, entry into a MODE or other specified condition in the Applicability shall only be made:

(continued)

HBRSEP Unit No. 2 3.0-1 Amendment No. 203

LCO Applicability 3.0 3.0 LCO APPLICABILITY LCO 3.0.4 a. When the associated ACTIONS to be entered permit continued (continued) operation in the MODE or other specified condition in the Applicability for an unlimited period of time, or

b. After performance of a risk assessment addressing inoperable systems and components, consideration of the results, determination of the acceptability of entering the MODEorotherspecifiedcondition in theApplicability, and establishment of risk management actions, if appropriate; exceptionstothisSpecificationarestated inthe individual Specifications, or

c. When an allowance is stated in the individual value, parameter, or other Specification.

This Specification shall not prevent changes in MODES or other specified conditions in the Applicability that are required to comply with ACTIONS or that are part of a shutdown of the Ufl i t.

LCO 3.0.5 Equipment removed from service or declared inoperable to comply with ACTIONS may be returned to service under administrative control solely to perform testing required to demonstrate its OPERABILITY or the OPERABILITY of other equipment. This is an exception to LCO 3.0.2 for the system returned to service under administrative control to perform the testing required to demonstrate OPERABILITY.

LCO 3.0.6 When a supported system LCO is not met solely due to a support system LCO not being met, the Conditions and Required Actions associated with this supported system are not required to be entered. Only the support system LCO ACTIONS are required to be entered. This is an exception to LCO 3.0.2 for the supported system. In this event, additional evaluations and limitations may be required in accordance with Specification 5.5.15, Safety Function Determination Program (SFDP). If a loss of safety function is determined to exist by this program, the appropriate Conditions and Required Actions of the LCO in which (continued)

HBRSEP Unit No. 2 3.0-2 Amendment No. 203

LCO Applicability 3.0 3.0 LCO APPLICABILITY LCO 3.0.6 the loss of safety function exists are required to be entered.

(continued)

When a support systems Required Action directs a supported system to be declared inoperable or directs entry into Conditions and Required Actions for a supported system, the applicable Conditions and Required Actions shall be entered in accordance with LCO 3.0.2.

LCO 3.0.7 Test Exception LCO 3.1.8 allows specified Technical Specification (TS) requirements to be changed to permit performance of special tests and operations. Unless otherwise specified, all other TS requirements remain unchanged.

Compliance with Test Exception LCO5 is optional. When a Test Exception LCO is desired to be met but is not met, the ACTIONS of the Test Exception LCO shal I be met. When a Test Exception LCO is not desired to be met, entry into a MODE or other specified condition in theApplicability shall be made in accordance with the other applicable Specifications.

HBRSEP Unit No. 2 3.0-3 Amendment No. 203

AFW System 3.7.4 3.7 PLANT SYSTEMS 3.7.4 Auxiliary Feedwater (AFW) System LCO 3.7.4 Four AFW flow paths and three AFW pumps shall be OPERABLE.

NOTE Only one AFW flow path with one motor driven pump is required to be OPERABLE in MODE 4.

APPLICABILITY: MODES 1, 2, and 3, MODE 4 when steam generator is being used for heat removal.

ACTIONS NOTE LCO 3.O.4.b is not applicable.

CONDITION REQUIRED ACTION COMPLETION TIME A. One AFW pump A.1 Restore AFW pump or 7 days inoperable in MODE 1, flow path(s) to 2, or 3. OPERABLE status. AND 8 days from discovery of One or two AFiN flow failure to paths inoperable in meet the LCO MODE 1, 2, or 3.

B. Two motor driven AFW B.1 Restore one motor 24 hours2.777778e-4 days 0.00667 hours 3.968254e-5 weeks 9.132e-6 months pumps inoperable in driven AFW pump or MODE 1, 2, or 3. one flow path to AND OPERABLE status.

8 days from discovery of Three motor driven AFW failure to flow paths inoperable meet the LCO in MODE 1, 2, or 3.

(contInued)

HBRSEP Unit No. 2 3.7-10 Amendment No. 203

AFW System 3.7.4 ACTIONS (continued)

CONDITION REQUIRED ACTION COMPLETION TIME C. Required Action and C.1 Be in MODE 3. 6 hours6.944444e-5 days 0.00167 hours 9.920635e-6 weeks 2.283e-6 months associated Completion Time for Condition A AND or B not met.

C.2 Be in MODE 4. 18 hours2.083333e-4 days 0.005 hours 2.97619e-5 weeks 6.849e-6 months D. Steam driven AFW pump D.1 Be in MODE 3. 6 hours6.944444e-5 days 0.00167 hours 9.920635e-6 weeks 2.283e-6 months or flow path inoperable in MODE 1, AND 2, or 3.

D.2 Be in MODE 4. 18 hours2.083333e-4 days 0.005 hours 2.97619e-5 weeks 6.849e-6 months AND One motor driven AFW pump or flow path inoperable in MODE 1, 2, or 3.

E. Four AFW flow paths E.1 NOTE inoperable in MODE 1, LCO 3.0.3 and all 2, or 3. other LCO Required Actions requiring OR MODE changes are suspended until Three AFW pumps one AFW pump and flow inoperable in MODE 1, path are restored to 2, or 3. OPERABLE status.

Initiate action to Immediately restore one AFW pump and flow path to OPERABLE status.

F. Required AFW pump and F.1 Initiate action to Immediately flow path inoperable restore AFW pump and in MODE 4. flow path to OPERABLE status.

HBRSEP Unit No. 2 3.7-11 Amendment No. 218

97. G2.2.42 SRO 001 Given the following plant conditions:

- The plant is at 100% RTP.

- Chemistry reports the following results from a primary to secondary leakage rate determination:

- A SIG leakage is 0.04 gpm

- B SIG leakage is 0.05 gpm

- C SIG leakage is 0.06 gpm Which ONE (1) of the following completes the statement below?

Technical Specification 3.4.13, RCS Operational Leakage, is required to be entered due to (1) S/G primary to secondary LEAKAGE being exceeded.

Entry into Mode 3 is required within (2) hours.

A. (1)total (2) 6 B (1) any one (2) 6 C. (1) total (2) 36 D. (1)anyone (2) 36 The correct answer is B.

A. Incorrect Although all three S/Gs have tube leakage, only C S/G is greater than the ITS limit of 75 gpd. A S/G is 43.2 gpd and B S/G is 57.6 gpd. C S/G has primary to secondary leakage of 100.8 gpd. Second half of the answer is correct.

B. Correct.

C. Incorrect Although all three S/Gs have tube leakage, only C S/G is greater than the ITS limit of 75 gpd. A S/G is 43.2 gpd and B S/G is 57.6 gpd. C S/G has primary to secondary leakage of 100.8 gpd. The second half of the distractor is valid for primary to secondary leakage greater than 75 gpd but less than 100 gpd.

D. Incorrect. The first part of the distractor is correct. The second half of the distractor is valid for primary to secondary leakage greater than 75 gpd but less than 100 gpd.

Page: 180 of 187 10/13/2011

Question 97 Tier 3 K/A Importance Rating - RD 3.9 SRO 4.6 Ability to recognize system parameters that are entry-level conditions for Technical Specifications.

Reference(s) Sim/Plant design, ITS 3.4.13, AOP-035 Proposed References to be provided to applicants during examination - None Learning Objective Intro to Tech Specs 005, RCS 013 Question Source NEW-Question Cognitive Level H -

10 CFR Part 55 Content 41.7/41.10/43.2/43.3/45.3 Comments -

SRO: Application of required actions in ITS.

Page: 181 of 187 10/13/2011

RCS Operational LEAKAGE 3.4.13 3.4 REACTOR COOLANT SYSTEM (RCS) 3.4.13 RCS Operational LEAKAGE LCO 3.4.13 RCS operational LEAKAGE shall be limited to:

a. No pressure boundary LEAKAGE;

b. 1 gpm unidentified LEAKAGE; APPLICABILITY: MODES 1, 2, 3, and 4.

ACTIONS CONDITION REQUIRED ACTION COMPLETION TIME A. RCS operational A.1 Reduce LEAKAGE to 4 hours4.62963e-5 days 0.00111 hours 6.613757e-6 weeks 1.522e-6 months LEAKAGE not within within limits.

limits for reasons other than pressure boundary LEAKAGE or primary to secondary LEAKAGE.

B. Required Action and B 1 Be in MODE 3 associated Completion Time of Condition A not met.

B.2 Be in MODE 5. 36 hours4.166667e-4 days 0.01 hours 5.952381e-5 weeks 1.3698e-5 months g

Pressure boundary LEAKAGE exists.

P!

Primary to secondary LEAKAGE not within I imit.

HBRSEP Unit No. 2 3.4-35 Amendment No. 212

RCS Operational LEAKAGE 3.4.13 SURVE I LLANCE REQU I REMENTS SURVE I LLANCE FREQUENCY SR 3.4.13.1 NOTES

1. Not required to be performed until 12 hours1.388889e-4 days 0.00333 hours 1.984127e-5 weeks 4.566e-6 months after establishment of steady state operation.

2. Not applicable to primary to secondary LEAKAGE.

Verify RCS operational LEAKAGE is within 72 hours8.333333e-4 days 0.02 hours 1.190476e-4 weeks 2.7396e-5 months limits by performance of RCS water inventory ba lance.

SR 3.4.13.2 NOTE Not required to be performed until 12 hours1.388889e-4 days 0.00333 hours 1.984127e-5 weeks 4.566e-6 months after establishment of steady state operation.

Verify primary to secondary LEAKAGE is 75 72 hours8.333333e-4 days 0.02 hours 1.190476e-4 weeks 2.7396e-5 months gal Ions per day through any one SG.

HBRSEP Unit No. 2 3.4-36 Amendment No. 212

98. G2.3.4 SRO 001 Given the following plant conditions:

- A manual reactor trip and safety injection were initiated from 100% RTP.

- The crew has transitioned to PATH-2 due to a tube rupture on B S/G.

- MS-V1-8B, SDAFW Steam Shutoff Valve, MOV breaker tripped.

- R-31 B, Steamline Radiation Monitor, has indicated approximately 250 mremlhr throughout the event.

- The OAO has been directed by the CRS to locally close MS-V1-8B to isolate the potential radioactive release path.

- The OAO currently has an accumulated annual dose of 1000 mrem TEDE from Progress Energy and 500 mrem TEDE while employed by another utility.

Which ONE(1) of the following completes the statement below?

Based on DOS-NGGC-0004, Administrative Dose Limits, (1) is the maximum dose that the operator can receive to isolate this release path and based on the conditions given a(n) (2) should be declared.

(REFERENCE PROVIDED)

Av (1) 1000 mrem (2) Site Area Emergency B. (1) 500 mrem (2) Site Area Emergency C. (1) 1000 mrem (2) Alert D. (1) 500 mrem (2) Alert Page: 182 of 187 10/13/2011

The correct answer is A.

A. Correct The dose given would place the worker at the 2000 mrem Progress Energy Annual Administrative limit. The SAE is correct.

B. Incorrect The dose given would place the worker at 2000 mrem dose from all sources. The Progress Energy Annual Administrative limit is 2000 mrem from Progress Energy not to exceed 4000 mrem total.

C. Incorrect. The dose given would place the worker at the 2000 mrem Progress Energy Annual Administrative limit. If the candidate only evaluated the Fission Product Barrier Matrix he/she would determine that only the RCS Barrier is lost and this would meet the criteria for an Alert declaration. However, R-31 B indication of 250 mrem/hr exceeds the SAE limit of 220 mr/hr as specified in Table R-1, Effluent Monitor Classification Thresholds.

D. Incorrect The dose given would place the worker at 2000 mrem dose from all sources. The Progress Energy Annual Administrative limit is 2000 mrem from Progress Energy not to exceed 4000 mrem total. If the candidate only evaluated the Fission Product Barrier Matrix he/she would determine that only the RCS Barrier is lost and this would meet the criteria for an Alert declaration. However, R-31 B indication of 250 mrem/hr exceeds the SAE limit of 220 mr/hr as specified in Table R-1, Effluent Monitor Classification Thresholds.

, Question 98 Tier 3 K/A Importance Rating - RO 3.2 SRO 3.7 Knowledge of radiation exposure limits under normal or emergency conditions.

Reference(s) Sim/Plant design, EALs, DOS-NGGC-0004 Proposed References to be provided to applicants during examination - EAL Matrix Learning Objective EAL 004 Question Source BANK Question Cognitive Level H -

10CFRPart55Content- 41.12/43.4/45.10 Comments -

SRO: Emergency Action Level Classification and determination of administrative dose limits.

Page: 183 of 187 10/13/2011

NUCLEAR GENERATION GROUP STANDARD PROCEDURE Volume 99 Book/Part 99 DOS-NGGC-0004 ADMINISTRATIVE DOSE LIMITS REVISION 12 DOS-NGGC-0004 Rev. 12 Page 1 of 9

5.0 PREREQUISITES N/A 6.0 PRECAUTIONS AND LIMITATIONS N/A 7M SPECIAL TOOLS AND EQUIPMENT N/A 8.0 ACCEPTANCE CRITERIA N/A 9.0 INSTRUCTIONS R2.1 9.1 Adult Occupational Dose Limits 9.1.1 Whole Body The more limiting of a total effective dose equiva lent equal to 5 rem or the sum of the deep dose equivalent and the committed dose equivalent to any individual organ or tissue other than the lens of the eye equal to 50 rem.

9.1.2 Skin - A shallow dose equivalent equal to 50 rem.

9.1.3 Lens of Eye A lens dose equivalent equal to 15 rem.

9.1.4 Extremities A shallow dose equivalent equal to 50 rem.

9.2 Occupational Dose to Minors Minors shall not be employed to work in radiation control areas, although they may enter as visitors.

9.3 Progress Energy Annual Administrative Dose Limits 9.3.1 0.5 rem Progress Energy dose if non-Progress Energy dose for the current ear as not been determi d. No dose extension is permitted.

9.3.2 2 rem Progress Energy dose not to exceed 4 rem total dose if non Progress Energy dose for the current year has been determined.

DOS-NGGC-0004 Rev. 12 Page 4 of 9

ATTACHMENT 5.1 Page 13 of 204 EMERGENCY ACTION LEVEL TECHNICAL BASES Category: R Abnormal Rad Release I Rad Effluent Sub-category: 1 Offsite Rad Conditions Initiating Condition: Offsite dose resulting from an actual or imminent release of gaseous radioactivity exceeds 100 mRem TEDE or 500 mRem thyroid ODE for the actual or projected duration of the release EAL:

RSI.1 Site Area Emergency Valid reading on any radiation monitors that exceeds or is expect ed to exceed Table R-1 column SAE for 15 minutes (Note 1)

Note 1: If dose assessment results are available at the time of declaration, the classification should be based on dose assessment instead of radiati on monitor readings. While necessary declarations should not be delayed awaitin g results, the dose assessment should be initiated I completed in order to determ ine if the classification is warranted, should be subsequently escalated, or if protective actions should be revised.

Table R-1 Effluent Monitor Classification Thresholds Release Point Monitor GE (SJ Alert liE Plant Vent R-14C U, 2 X alarm R-14D 2.3E5 cpm 2.3E4 cpm 2.3E3 cpm 0)

R-14E 1.5E3 cpm 1.5E2 cpm 15E1 cpm 0

FHB Exhaust R-20 2 X alarm FHB Exhaust HR R-30 1.0E4 mR/hr 1.OE3mR/ r 10E2 mR/hr Main Steamline R-31 AID/C 2.2E3 mR/hr 2.2E1 mR/hr Liquid Waste Disposal R-18 200 X alarm* 2 X alarm*

SGBD Effluent R-19AIB!C C 200 X alarm* 2 X alarm*

Condensate Polisher R-37 200 X alarm 2 X alarm

With effluent discharge not isolated Mode Applicability:

All EPCLA-04 Rev. 2 Page 36 of 251

99. G2.4.30 SRO 001 Given the following plant conditions:

- The plant was operating at 100% RTP when C RCP trips.

- All AFW pumps received an Auto-start signal.

Which one of the following completes the statement below?

lAW AP-030, NRC Reporting Requirements, the NRC is required to be notified within (1) hour(s) due to the automatic RPS initiation and within (2) hours for the ESFAS actuation.

A. (1)1 (2) 4 B. (1)1 (2) 8 C. (1)4 (2) 4 D (1)4 (2) 8 The correct answer is D.

A. Incorrect. Candidate may think that the NRC must be notified via AP-030 due to a reactor trip and four hours for the ESFAS notification.

B. Incorrect. Candidate may think that the NRC must be notified via AP-030 due to a reactor trip. The second half of distractor is correct.

C. Incorrect. Candidate may think that both actions require a four hour notification.

C. Correct.

Page: 184 of 187 10/13/2011

Question 99 Tier 3 K/A Importance Rating - RO 2.7 SRO 4.1 Knowledge of events related to system operation/status that must be reported to internal organizations or external agencies, such as the State, the NRC, or the transmission system operator.

Reference(s) AP-030 Proposed References to be provided to applicants during examination - None Learning Objective AOP-030-003 Question Source New Question Cognitive Level H -

10 CFR Part 55 Content- 41.10 /43.5/45.11 Comments -

SRO: Off-site reporting requirements.

Page: 185 of 187 10/13/2011

p ATTACHMENT 11.1 Page 1 of 9 IMMEDIATE (ONE HOUR) NOTIFICATIONS TO THE NRC IMMEDIATE (ONE HOUR) NOTIFICATIONS TO THE NRC 10 CFR 50.72 states that immediate reports shall be made to the NRC Operations Center of these Emergency Events via the NRC Emergency Telecommunications System (ETS) as specified in the Emergency Plan. 10 CFR 50.72 additionally identifies Non-Emergency Events which are to be reported within one-hour, four-hours, or eight hours to the NRC. ETS Telephones, which are identified, are located in the Control Room, the TSC, and the EOF.

event that the ETS is not available, 10 CFR 50.72(a)(2) permits the use of commercial In the telephone.

EVENT KEY WORDS REQUIREMENT EXAMPLES NOTE: 10 CFR 50.72 recognizes the Emergency Plan and its four Emergency Classes of Unusual Event, Alert, Site Area Emergency and General

.---rgency.

ECIES Emergency HBRSEP shall notify the NRC of the Declaration of an Unusual Event, Alert, Site

( Unusual Event declaration of any of the Emergency Classes Alert Area Emergency, or General Emergency.

specified in the Emergency Plan.

Site Area Discovery of an event that should have Emergency (See EPNOT-01) resulted in an Emergency Classification, but General no emergency was declared.

10 CFR 50.72(a)(i) Emergency Discovery that a declared emergency 10 CFR 30.32(i)(3)(viii) ISFSI exceeded the Emergency Action Levels for a 10 CFR 40.31(i)(3)(viii) higher emergency declaration, but the higher 10 CFR 72.75(a) classification was not declared.

ERDS ACTIVATION ERDS HBRSEP shall activate the ERDS as soon as An Alert, Site Area Emergency, or General Emergency possible but not later than one hour after Emergency is declared.

declaring an Alert, Site Area Emergency, or General Emergency.

10 CFR 50.72(a)(4)

DEVIATION FROM TS (10 CFR Deviation Any deviation from the TS authorized Intentional deviation from an approved plant 50.54(X)) Departure pursuant to 10 CFR 50.54(x). procedure in order to preserve plant safety License 10 CFR 50.54(x).

10 CFR 50.72(b)(1) Condition AP-030 Rev. 45 Page 14 of 56

U e ATTACHMENT 11.1 e

Page 2 of 9 IMMEDIATE (ONE HOUR) NOTIFICATIONS TO THE NRC IMMEDIATE (ONE HOUR) NOTIFICATIONS TO THE NRC HBRSEP shall immediately notify the NRC Operations Center via ETS as soon as practical and in all cases within one following: hour of the occurrence of any of the EVENT KEY WORDS REQUIREMENT EXAMPLES SAFETY LIMIT, LIMITING SAFETY Safety Limit If any safety limit is exceeded, shut down The limits of TS Figure 2.1.1-1 are exceeded.

SYSTEM SETTING EXCEEDED Limiting Safety the reactor. HBRSEP shall notify the NRC System Setting [within 1 hour1.157407e-5 days 2.777778e-4 hours 1.653439e-6 weeks 3.805e-7 months via ETS per 10 CFR 50.72(a)(1), See Emergency Plan Procedures]. Operation must not be resumed until authorized by the NRC.

10 CFR 50.36(c)(1)(i)(A)

UFSAR Section 1 7.3A, Paragraph NRC Region II must also be notified within 1 3.1 .a hour and the Vice President Robinson Nuclear Plant within 24 hours2.777778e-4 days 0.00667 hours 3.968254e-5 weeks 9.132e-6 months SAFETY SYSTEM DOES NOT ESF HBRSEP shall notify the NRC if the A failure mechanism is discovered that FUNCTION AS REQUIRED RPS automatic safety system [to correct an indicates that the RPS will not function to trip Limiting Safety abnormal situation before a safety limit is the reactor under certain required conditions.

10 CFR 50.36(c)(1)(ii)(A) System Setting exceeded] has been determined not to function as required.

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(-3 0 0 ATTACHMENT 11.1 Page 3 of 9 IMMEDIATE (ONE HOUR) NOTIFICATIONS TO THE NRC IMMEDIATE (ONE HOUR) NOTIFICATIONS TO THE NRC SECURITY SAFEGUARDS EVENTS HBRSEP shall notify the NRC Operations Center via the ETS within one hour*

after discovery of the safeguards events described as follows (10 CFR 73.71(b)(1)):

EVENT KEY WORDS REQUIREMENT EXAMPLES THEFT/UNLAWFUL DIVERSION OF SNM Any discovery of the loss of any shipment of Shipment Emergency Event SNM OR SPENT FUEL SHIPMENT Spent Fuel SNM or spent fuel, and within one hour after Security recovery of or accounting for such lost Safeguards shipment 10 CFR 73.71(a)(1)

THEFTIUNLAWFUL DIVERSION OF Theft of SNM Any event in which there is reason to Shipment Emergency Event SNM Diversion believe that a person has committed or Security caused, or attempted to commit or cause, or Safeguards has made a credible threat to commit or 10 CFR 73.71(b)(1) cause:

10 CFR 73, Appendix G, l(a)(1)

(1) A theft or unlawful diversion of SNM SABOTAGE OF PLANT Sabotage

[Any event in which there is reason to Shipment Emergency Event EQUIPMENT Damage to Plant believe that a person has committed or Security Event (SEC-NGGC-2147)

SNM caused, or attempted to commit or cause, or Spent Fuel has made a credible threat to commit or Security cause:]

Safeguards (2) Significant physical damage to a power reactor...or its equipment or carrier equipment transporting nuclear fuel or spent 10 CFR 73.71(b)(1) nuclear fuel, or to the nuclear fuel or spent 10 CFR 73, Appendix G, l(a)(2) fuel a facility or carrier possesses.

In response to NRC Bulletin 2005-02, RNP committed to make an accelerated call to the NRC within approximately 15 minutes following discovery of an imminent threat or attack against the station. The primary purpose is to allow for the NRC to timely notify other licensees of a potential common threat.

accelerated call should not be allowed to interfere with plant or personnel safety, The physical security response, or notification of local law enforcement agenci The information provided in the accelerated call can be limited to: es.

Site name Emergency Classification if already determined do not delay call for the purpos e of classifying

Nature of the threat briefly described, if known, including the type of attack (e.g.,

armed assault by land, water or aircraft) and the attack status (e.g.,

imminent, in progress, or repelled)

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0 0 ATTACHMENT 11.1 Page 4 of 9 IMMEDIATE (ONE HOUR) NOTIFICATIONS TO THE NRC IMMEDIATE (ONE HOUR) NOTIFICATIONS TO THE NRC SECURITY SAFEGUARDS EVENTS HBRSEP shall notify the NRC Operations Center via the ETS within one hour* after discovery of the safegu (10 CFR 73.71(b)(1)): ards events described as follows EVENT KEY WORDS REQUIREMENT UNAUTHORIZED TAMPERING EXAMPLES Unauthorized

[Any event in which there is reason to WITH PLANT EQUIPMENT Use Security Event (SEC-NGGC-2 147) believe that a person has committed or Tampering caused, or attempted to commit or cause, or Security System has made a credible threat to commit or Safeguards cause:]

(3) Interruption of normal operation of HBRSEP through the unauthorized use of or tampering with its machinery, components, or controls including the 10 CFR 73, Appendix G, I(a)(3) security system.

ENTRY OF UNAUTHORIZED Unauthorized An actual entry of an unauthorized person PERSON INTO PROTECTED OR Entry Security Event (SEC-NGGC-2 147) into a protected area, material access area, VITAL AREA Security controlled access area, vital area, or 10 CFR 73, Appendix G, 1(b) Safeguards transport.

FAILURE, DEGRADATION, OR Degradation Any failure, degradation, or the discovered Procedure SEC-NGGC-2147 DISCOVERED VULNERABILITY OF Vulnerability vulnerability in a safeguard system that SAFEGUARD SYSTEM Safeguards could allow unauthorized or undetected Unauthorized access to a protected area, material access Undetected area, controlled access area, vital area or Access transport for which compensatory measures 10 CFR 73, Appendix G, 1(c) Security have not been employed.

INTRODUCTION OF Contraband The actual or attempted introduction of CONTRABAND INTO VITAL OR Unauthorized Contraband applies to items that could be contraband into a protected area, material PROTECTED AREA Security used to commit radiological sabotage as process area, vital area, or transport.

10 CFR 73, Appendix G, 1(d) Safeguards defined in 10 CFR 73.2.

See footnote on the previous page regarding a goal for a 15 minute call to the NRC in regard to an imminent securit y threat or attack.

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0 ATTACHMENT 11.1 Page 5 of 9 IMMEDIATE (ONE HOUR) NOTIFICATIONS TO THE NRC IMMEDIATE (ONE HOUR) NOTIFICATIONS TO THE NRC SOURCE, BYPRODUCT AND SNM HBRSEP shall immediately notify the NRC Operations Center via ETS, when:

EVENT KEY WORDS REQUIREMENT EXAMPLES EXTERNAL EXPOSURE FROM Byproduct Notwithstanding any other requirements for BYPRODUCT, SOURCE, OR SNM Source notification, immediately notify the NRC of any (5X ANNUAL LIMIT) SNM event involving byproduct, source, or SNM Exposure possessed by HBRSEP that may have caused or Dose threatens to cause any of the following Release conditions:

Occupational 1. An individual to receive:

(i) A total effective dose equivalent of 25 rems or more; or (ii) An eye dose equivalent of 75 rems or more; or (iii) A shallow dose equivalent to the skin or extremities of 250 rads or more; or

2. The release of radioactive material, inside or outside the restricted area, so that, had an 10 CFR 20.2202(a)(1) individual been present for 24 hours2.777778e-4 days 0.00667 hours 3.968254e-5 weeks 9.132e-6 months , the individual could have received an intake five times the occupational annual limit on intake.

AP-030 Rev. 45 Page 18 of 56

ATTACHMENT 11.1 Page 6 of 9 IMMEDIATE (ONE HOUR) NOTIFICATIONS TO THE NRC IMMEDIATE (ONE HOUR) NOTIFICATIONS TO THE NRC SOURCE, BYPRODUCT AND SNM HBRSEP shall immediately notify the NRC Operat ions Center via ETS, when:

EVENT KEY WORDS REQUIREMENT INTERNAL EXPOSURE FROM EXAMPLES Intake The release of radioactive material, inside or BYPRODUCT, SOURCE, SNM (>5X Ingestion outside the restricted area, so that, had an OCCUPATIONAL LIMIT) Release individual been present for 24 hours2.777778e-4 days 0.00667 hours 3.968254e-5 weeks 9.132e-6 months , the Source individual could have received an intake five times 10 CFR 20.2202(a)(2) Byproduct the occupational annual limit on intake.

SNM IMMEDIATE (ONE HOUR) NOTIFICATIONS TO THE NRC ISFSI HBRSEP shall immediately notify the NRC Operat ions Center via ETS, when:

EVENT KEY WORDS REQUIREMENT ISFSI ACCIDENTAL CRITICALITY EXAMPLES ISFSI The licensee shall notify the NRC Operations OR LOSS OF SNM Criticality Unusually high radiation readings Center via ETS within one hour of discovery of 10 CFR 72 74 SNM accidental criticality or any loss of SNM.

discovered in the vicinity of the ISFSI that Loss could indicate possibility of a criticality event IMMEDIATE (ONE HOUR) NOTIFICATIONS TO THE NRC SNM SHIPMENTS HBRSEP shall immediately notify the NRC Operat ions Cen er via ETS, when:

EVENT KEY WORDS REQUIREMENT LOST OR UNACCOUNTED EXAMPLES Shipment HBRSEP shall notify the NRC Operations Center SHIPMENT OF SNM Loss Shipment Emergency Event via the ETS within one hour after discovery of any SNM Securi loss of any shipment of SNM or spent fuel or any ty Event (SEC-NGGC-2147)

Spent Fuel incident in which an attempt has been made, or Diversion is 10 CFR 70.52(b) believed to have been made, to commit a theft or Safeguards unlawful diversion of SNM.

10 CFR 73.71(a)(1)

Security LOST OR UNACCOUNTED Recovery HBRSEP shall notify the NRC Operations Center SHIPMENT OF SNM RECOVERY Accounting via the ETS within one hour after recovery of, or Shipment accounting for, any lost shipment of SNM.

SNM 10 CFR 73.71(a)(1) Security Safeguards AP-030 Rev. 45 Page 19 of 56

ATTACHMENT 11.1 Page 7 of 9 IMMEDIATE (ONE HOUR) NOTIFICATIONS TO THE NRC IMMEDIATE (ONE HOUR) NOTIFICATIONS TO THE NRC FOLLOW-UP With respect to the telephone notifications made under paragraphs (a) and (b) of 10 CFR 50.72 or paragraphs (a), (b), (c), or (d) of 10 CFR 72.75, in addition to making the required initial notification, HBRSEP shall duri9g the course of the event immediately report:

EVENT KEY WORDS REQUIREMENT EXAMPLES FOLLOW-UP NOTIFICATION Degradation (i) any further degradation in the level of Refer to EPNOT-01 Emergency Class safety of the plant or ISFSI or other Change worsening conditions, including those that Update require the declaration of any of the Termination Emergency Classes, if such a declaration ISFSI has not been previously made, or 10 CFR 50.72(c)(1) (ii) any change from one Emergency Class 10 CFR 72.75(f)(1) to another, or(iii)a termination of the Emergency Class.

FOLLOW-UP NOTIFICATION Result (i) the results of ensuing evaluations or Evaluation assessments of plant or ISFSI conditions, Effectiveness (ii) the effectiveness of response or Unknown protective measures taken, and 10 CFR 50.72(c)(2) ISFSI (iii) information related to plant or ISFSI 10 CFR 72.75(f)(2) behavior that is not understood.

FOLLOW-UP NOTIFICATION Open Maintain an open, continuous Refer to EPNOT-01 Continuous communication channel with the NRC 10 CFR 50.72(c)(3) Communication Operations Center upon request by the 10 CFR 50.72.75(f)(3) ISFSI NRC.

AP-030 Rev. 45 Page 20 of 56

ATTACHMENT 11.1 Page 8 of 9 IMMEDIATE (ONE HOUR) NOTIFICATIONS TO THE NRC IMMEDIATE (ONE HOUR) NOTIFICATIONS NRC REGION II OFFICE HBRSEP shall immediately notify the final delivery carrier and, by telephone and telegram, mailgram, or facsimile, the NRC Region II Office when:

EVENT KEY WORDS REQUIREMENT EXAMPLES THEFT/UNLAWFUL DIVERSION OF Incident Any incident in which an attempt has been 10 Curies of tritium discovered missing from TRITIUM Theft made or is believed to have been made to the Chemistry Laboratory, and reason exists Tritium commit a theft of more than 10 curies of to suspect that the tritium was stolen Attempt tritium (outside of spent fuel) at any one Security time or more than 100 curies of tritium in 10 CFR 30.55(c)

Safeguards one calendar year THEFT/UNLAWFUL DIVERSION OF Incident Any incident in which an attempt has been A source assembly is discovered missing SOURCE MATERIAL Attempt made or is believed to have been made to from a new fuel shipment.

Theft commit a theft or unlawful diversion of more Diversion than 15 pounds of Source Material at any Source one time or 150 pounds of Source Material 10 CFR 40.64(c) Security in any one calendar year Safeguards SHIPPING PACKAGE Contamination Removable radioactive surface New or Spent Fuel Shipment Cask arrives RADIOACTIVELY CONTAMINATED Shipment contamination exceeds the limits of with surface contamination in excess of limits.

10 CFR 20.1906(d)(1) 10 CFR 71.87 SHIPPING PACKAGE EXCEEDING Radiation External radiation levels exceeds of the New or Spent Fuel Shipment Cask arrives EXTERNAL DOSE RATE LIMITS Dose Rate limits of 10 CFR 71.47 with external radiation levels in excess of 10 CFR 20.1906(d)(2) Shipment limits.

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ATTACHMENT 11.1 Page 9 of 9 IMMEDIATE (ONE HOUR) NOTIFICATIONS TO THE NRC IMMEDIATE (ONE HOUR) NOTIFICATIONS TO THE NRC FFD The NRC Reqion II Administrator must be notifie immed d iately by telephone of the followinq:

EVENT KEY WORDS REQUIREMENT NRC EMPLOYEE NOT FIT FOR EXAMPLES Alcohol If HBRSEP has a reasonable belief that an DUTY Influence NRC employee or NRC contractor may be Substance under the influence of any substance, or is NRC employee otherwise unfit for duty, the licensee or FFD other entity may not deny access but shall 10 CFR 26.77(c) Fitness for Duty escort the individual. In any such instance, the licensee or other entity shall immediately notify the Region II Administrator by telephone, followed by written notification (e.g., e-mail or fax) to document the oral notification. If the Region II Administrator cannot be reached, the licensee or other entity shall notify the NRC Operations Center.

IMMEDIATE (ONE HOUR) NOTIFICATIONS TO THE NRC IAEA The NRC Director, NRR or Director, NMSS must be notified immediately by telephone of the follow ing:

SURPRISE VISIT OF IAEA IAEA HBRSEP shall immediately communicate OFFICIAL International If the IAEA representatives credentials have by telephone, within one hour with respect Atomic not been confirmed by the NRC, the license to the credentials of any person who claims e Energy to be an IAEA representative and shall shall not admit the person until the NRC has Agency confirmed the persons credentials. The 10 CFR 75.8(c) accept written or electronic confirmation of licensee, shall notify the Commission Credential the credentials from the NRC.

promptly, by telephone, whenever an IAEA representative arrives at a facility or location without advance notification.

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e ATTACHMENT 11.2 Page 1 of 3 FOUR HOUR NOTIFICATIONS TO THE NRC FOUR HOUR NOTIFICATIONS TO THE NRC If not reported under paragraphs (a) or (b)(1) of 10 CFR 50.72, HBRSEP shall notify the NRC Operations Center via ETS as soon as practical and in all within four hours of the occurrence of any of the follow ing: cases, EVENT KEY WORDS REQUIREMENT SHUTDOWN REQUIRED BY TS EXAMPLES Shutdown The initiation of any shutdown required by Reactor is in MODEs 1 or 2 and the Control TS Shutdown the TS.

Power Room takes action to reduce power (i.e.,

Reduction negative reactivity insertion) in order to comply with a Required Action to be in MODE 3 within a Completion Time. Reduction in power for some other purpose than compliance with the shutdown requirement is not reportable. MODE changes required by TS when reactor is in MODEs 3, 4, or other non-power conditions, are not reportable.

If allowed outage time plus required shutdown time to MODE 3 is less than the expected 10 CFR 50.72(b)(2)(i) restoration time of the LCO and power is reduced in anticipation of the required shutdown, the shutdown is reportable.

ECCS DISCHARGE INTO RCS ECCS Any event that results or should have Manual or automatic Safety Injection System Actuation resulted in emergency core cooling Safety system (ECCS) discharge into the reactor actuation in response to a valid signal that Injection coolant system as a result of a valid signal resulted in or should have resulted in except when the actuation results from and discharge into the reactor coolant system.

is part of a pre-planned sequence during testing or reactor operation.

RPS INITIATION RPS Actuation Any event or condition that results in (MANUAL/AUTOMATIC) Manual or automatic reactor trip from critical Reactor actuation of the reactor protection system DURING OPERATION through RTP of 100%. Trips which occur as Protection (RPS) when the reactor is critical except part of planned evolutions in accordance with System when the actuation results from and is part procedures are not reportable.

10 CFR 50.72(b)(2)(iv)(B) RPS of a pre-planned sequence during testing c Reactor Trip or reactor operation.

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3 0

ATTACHMENT 11.2 Page 2 of 3 FOUR HOUR NOTIFICATIONS TO THE NRC FOUR HOUR NOTIFICATIONS TO THE NRC If not reported under paragraphs (a) or (b)(1) of 10 CFR 50.72, HBRS EP shall notify the NRC Operations Center via ETS as soon as practic within four hours of the occurrence of any of the following: al and in all cases, EVENT KEY WORDS REQUIREMENT EXAMPLES PRESS RELEASES AND News Release Any event or situation, related to the health Any News release concerning GOVERNMENT NOTIFICATIONS Press and safety of the public or on-site - A fatality, Radio personnel, or protection of the - Inadvertent release of radioactively Television environment, for which a news release is Fatality contaminated materials to public areas planned or notification to other government unusual or abnormal releases of radioactive Environment agencies has been or will be made. Such Public effluents, or an event may include an on-site fatality or Information associated with an Emergency Health and Safety inadvertent release of radioactively Release Event except when the ERO is activated contaminated materials. (EPNOT-01).

ISFSI Notification to other government agencies concerning:

- A fatality on site,

- Health and safety of the public or site personnel,

- Inadvertent release of radioactively 10 CFR 50.72(b)(2)(xi) 10 CFR 72.75(b)(2) contaminated materials to public areas,

- Discovered endangered species kill.

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0 ATTACHMENT 11.2 Page 3of3 FOUR HOUR NOTIFICATIONS TO THE NRC FOUR HOUR NOTIFICATIONS TO THE NRC HBRSEP shall notify the NRC Operations Center via ETS as soon as possible but not later than 4 hours4.62963e-5 days 0.00111 hours 6.613757e-6 weeks 1.522e-6 months after the discovery of any conditions involving sources or spent fuel. of the following events or EVENT KEY WORDS REQUIREMENT EXAMPLES LOSS OR THEFT OF LICENSED Loss Immediately notify the NRC, after its A radiography source is discovered missing. The MATERIAL (>I000X 10 CFR 20 Theft occurrence becomes known, any lost, stolen, LIMITS) Missing source is licensed to the radiography contractor.

or missing licensed material in an aggregate If the contractor does not make the required Licensed quantity equal to or greater then 1000 times notification, HBRSEP should notify the NRC Radioactive the quantity specified in [10 CFR 20] Operations Center via ETS.

Material Appendix C under such circumstances that it Recovery appears to HBRSEP that an exposure could 10 CFR 20 2201 result to persons in unrestricted areas.

Follow-up written report required within subsequent 30 days.

Note If the lost, stolen, or missing source exceeds a Quantity of Concern as specified in HPP-018, then the NRC desires to be notified within 4 hours4.62963e-5 days 0.00111 hours 6.613757e-6 weeks 1.522e-6 months of any subsequent recovery of the source.

ISFSI DEPARTURE FROM ISFSI An action taken in an emergency that Action taken in an emergency that departs from LICENSE CONDITION Emergency departs from a condition or a technical procedure that is deemed necessary to prevent Departure specification contained in a license or releases or radiation doses to the public in Deviation certificate of compliance issued under excess of 10 CFR 20 limits (See Health and 10 CFR 72 when the action is immediately PRO-NGGC-0200).

Safety needed to protect the public health and License safety and no action consistent with license Condition conditions or technical specifications that can 10 CFR 72.75(b)(1) provide adequate or equivalent protection is immediately apparent. -

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U 0 0 ATTACHMENT 11.3 Page 1 of 5 EIGHT HOUR NOTIFICATIONS TO THE NRC EIGHT HOUR NOTIFICATIONS TO THE NRC If not reported as a declaration of an Emergency Class under paragraph (a) of 10 CFR 50.72, HBRSEP shall notify the NRC Operations Center via ETS practical and in all cases within eight hours of the occurrence of any of the following: as soon as EVENT KEY WORDS REQUIREMENT EXAMPLES PRINCIPAL SAFETY BARRIERS Degraded Any event or condition that results Fuel cladding failures in the reactor, or in the storage pool, that SERIOUSLY DEGRADED Safety in the condition of the nuclear exceed expected values, or that are unique or widespread, or Barriers power plant, including its principal that are caused by unexpected factors, and would involve a Fission safety barriers, being seriously release of significant quantities of fission products Product degraded:

Barrier Cracks and breaks in the piping or reactor vessel, or major components in the reactor coolant system that have safety relevance (steam generators, reactor coolant pumps, valves, etc.)

Significant welding or material defects in the RCS Low temperature overpressure transients where the pressure temperature limits are violated Loss of relief and/or safety valve functions during operation Loss of Containment function or integrity

- Complete loss of containment integrity function including (1) containment leakage rate greater than allowed value per SR 3.6.1.1 (i.e., entry into LCD 3.6.1 Condition A), (2) loss of containment penetration isolation functional capability (i.e., both 10 CFR 50.72(b)(3)(ii)(A) barriers), or loss of containment spray capability UNANALYZED PLANT Safety Any event or condition that results OTAT setpoints are declared inoperable due to summator CONDITION Function in the nuclear power plant being in module lag constants. The channel response time exceeded the Unanalyzed an unanalyzed condition that value assumed in the accident analysis (analytical limits).

Condition significantly degrades plant safety.

Accumulation of voids in systems designed to remove heat from the reactor that could inhibit the ability to adequately remove heat from the core, particularly under natural circulation conditions.

Any power level excursion above 2346 MWt should be evaluated to determine if the condition posed an unanalyzed condition that significantly degrades nuclear plant safety. Operation slightly in excess of 2346 MWt for short periods are not expected to trigger 10 CFR 50.72(b)(3)(ii)(B) the 10 CFR 50.72(b)(3)Oi)(B) criterion.

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0 0 0 ATTACHMENT 11.3 Page 2 of 5 EIGHT HOUR NOTIFICATIONS TO THE NRC EIGHT HOUR NOTIFICATIONS TO THE NRC If not reported as a declaration of an Emergency Class under paragraph (a) of 10 CFR 50.72, HBRSEP shall notify the NRC Operations Center via ETS as soon as practical and in all cases within eight hours of the occurrence of any of the following:

EVENT KEY WORDS REQUIREMENT EXAMPLES LOSS OF EMERGENCY Selective Any event that results in a major Loss of 15 or more of 59 Public Warning Sirens as indicated ASSESSMENT, OFF-SITE Signaling loss of emergency assessment on the siren activation system for a period of at least 30 RESPONSE, OR System capability, off-site response minutes at any one time COMMUNICATIONS CAPABILITY capability, or communications Loss of greater than 50% of communications capability (i.e.,

Sirens capability (e.g., significant portion offsite communications systems which include the Selective of control room indication, ETS, or ETS off-site notification system).

Signaling System, the Essex System and the Local Government Radio System)

ERFIS Loss of greater than 50% of the ability of the TSC or EOF to ERDS function Loss of instrumentation indication capability to the extent that an Emergency Action Level cannot be determined to exceed an emergency classification ETS communications function unavailable. This does not apply to minor interruptions in site or corporate telecommunications systems. It is intended to apply to serious conditions during which the telecommunication system can no longer fulfill the requirements of the Emergency Plan or provide ETS functionality. (1)

Loss of commercial telephone system to the extent that required communications could not be made to official offsite locations (e.g., EOCs, Warning Points)

Inoperability of ERFIS and ERDS is not capable of being 10 CFR 50.72(b)(3)(xiii) restored within one hour. (2)

(1) A loss of a single or multiple voice communications (ENS, HPN, or commercial phone) does NOT constitute a loss of ETS communications provided alternate telephone communication capability exists. The NRC Operations Center shall be notified as quickly as practical to use alternate means of phone communications.

This satisfies the guidance provided in previous Information Notices 85-44 Emergency Communication System Monthly Test, dated May 30, 1985 and 86-97 Emergency Communications System, dated November 28, 1986, to test the backup means of communication when the primary system is unavailable as well as the reporting requirements of § 50.72(b)(2)(xii). Loss of either ENS or HPN does not require additional event reporting under 10 CFR 50.72 or 10 CFR 50.73.

(2) IF ERDS is inoperable AND ERFIS is operable, THEN no reportable condition exists AP-030 Rev. 45 Page 27 of 56

C e ATTACHMENT 11.3 Page 3 of 5 EIGHT HOUR NOTIFICATIONS TO THE NRC EIGHT HOUR NOTIFICATIONS TO THE NRC If not reported as a declaration of an Emergency Class under paragraph (a) of 10 CFR 50.72, HBRSEP shall notify the NRC Operations Center via ETS as soon as practical and in all cases within eight hours of the occurrence of any of the following:

ENT_ KEY REQUIREMENT EXAMPLES WORDS RPS/SAFETY SYSTEM Manual Any event or condition that results in valid Automatic actuation of any of the systems listed below Reactor Trip (Manual/Automatic) while subcritical (MANUALIAUTOMATIC) Actuation except when the actuation results from and Reactor Trip while critical is reportable per Attachment 11.2

ATIO,__,...Ji Engineered is part of a pre-planned sequence during EDG start due to an undervoltage trip signal on emergency bus El or E2 Safety testing or reactor operation. A single train of Containment Isolation actuates Feature The systems to which the requirements of A valid signal for Containment Ventilation Isolation occurs ESF this paragraph apply are:

Valid (1) Reactor protection system (RPS) Valid actuations are those actuations that result from valid signals or Clearance including: reactor scram and reactor from intentional manual initiation, unless it is part of a preplanned test.

RPS trip. Valid signals are those signals that are initiated in response to actual Actuation (2) General containment isolation signals plant conditions or parameters satisfying the requirements for the Reactor affecting containment isolation valves initiation of the safety function of the system. They do not include Protection in more than one system or multiple actuations which are the result of other signals. (NUREG 1022)

System main steam isolation valves (MSIV5).

RPS (3) Emergency core cooling systems Invalid actuations are, by definition, those that do not meet the criteria for Reactor Trip (ECCS) for pressurized water reactors being valid. Thus invalid actuations include actuations that are not the (PWRs) including: high-head, result of valid signals and are not intentional manual actuations.

intermediate-head, and low-head injection systems and the low pressure Except for actuations of the Reactor Protection System (RPS) when the injection function of residual (decay) reactor is critical or in MODE 1, invalid actuations are not reportable by heat removal systems. telephone under 10 CFR 50.72. In addition, invalid actuations are not (4) PWR auxiliary or emergency feedwater reportable under 10 CFR 50.73 in any of the following:

system. - The invalid actuation occurred when the system is already properly (5) Containment heat removal and removed from service. This means all requirements of plant depressurization systems, including procedures for removing equipment from service have been met, It containment spray and fan cooler includes required clearance documentation, equipment and control systems. board tagging, and properly positioned valves and power supply (6) Emergency AC electrical power breakers.

systems, including: emergency diesel generators (EDG5) The invalid actuation occurs after the safety function has already 10 CFR 50.72(b)(3)(iv)(A)(B) been completed. An example would be RPS actuation after the control rods have already been inserted into the core.

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0 e ATTACHMENT 11.3 Page 4 of 5 EIGHT HOUR NOTIFICATIONS TO THE NRC EIGHT HOUR NOTIFICATIONS TO THE NRC If not reported as a declaration of an Emergency Class under paragraph (a) of 10 CFR 50.72, HBRSEP shall notify the NRC practical and in all cases within eight hours of the occurrence Operations Center via ETS as soon as of any of the following:

EVENT KEY WORDS REQUIREMENT EXAMPLES CONDITION THAT COULD Loss of Safety Any event or condition that at the Loss PREVENT FULFILLMENT OF time of discovery could have (inoperability) of both Trains, e.g., ECCS, Low Function SAFETY FUNCTIONS Residual Heat preven ted the fulfillm ent of the Temperature Overpressure Protection System, or Lake Robinson water level below LCO 3.7.8 limit Mitigation safety function of structures or system - Loss Shutdown s that are needed to: of one Train of required equipment, and the cause of the Generic (A) Shut down the reactor and failure could fail the other train, and there is a reasonable Setpoint Drift maintain it in a safe expectation that the other train would not fulfill its safety Engineering shutdo wn condition; functio n if required Evaluation (B) Remove residual heat; 1) Contaminated lubrication fluid degrades SI Pump Operability (C) Control the release of operation (a single condition could prevent fulfillment Determination radioactive material, or of a safety function if both trains could be reasonably Common Mode (D) Mitigate the consequences expected to be inoperable).

Failure of an accident.

2) EDO Air Start Solenoids (if it demonstrates a design procedural, or equipment deficiency that could preven Events covered in this section may t include one or more procedural the fulfillment of a safety function, i.e., if both diesels are errors, equipment failures, and/or susceptible to same problem) discovery of design, analysis, Multiple Control Rod failures (if failure prevented the fulfillm ent fabrication, construction, and/or of a safety function) procedural inadequacies. Operator action to inhibit the RPS (actions would preven However, individual component t fulfillment of a safety function) failures need not be reported in accordance with this paragraph if redundant equipment in the same system was operable and 10 CFR 50.72(b)(3)(v) available to perform the required safety function.

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ATTACHMENT 11.3 Page 5 of 5 EIGHT HOUR NOTIFICATIONS TO THE NRC EIGHT HOUR NOTIFICATIONS TO THE NRC If not reported as a declaration of an Emergency Class under paragraph (a) of 10 CFR 50.72, HBRSEP shall notify the practical and in all cases within eight hours of the occurr NRC Operations Center via ETS as soon as ence of any of the following:

EVENT KEY WORDS REQUIREMENT EXAMPLES ISFSI DEFECT IMPORTANT TO ISFSI A defect in any spent fuel storage A defect SAFETY Defect discovered in the design or construction of ISFSI structure, system, or component that units that could result in releases or radiation doses Safety is important to safety. to the public in excess of 10 CFR 20 limits.

10 CFR 72.75(c)(1)

ISFSI REDUCTION IN ISFSI A significant reduction in the EFFECTIVENESS Confinement Wear or degradation of ISFSI units that could result in effectiveness of any spent fuel releases or radiation doses to the public in excess Reduction storage cask confinement system of 10 CFR 20 limits.

10 CFR 72.75(c)(2) Effechveness during use.

TRANSPORT OF CONTAMINATED Contaminate Any event requiring the transport of a INJURED PATIENT Injured Any event requiring the transport of a radioactively radioactively contaminated person to Person contaminated or potentially contaminated (NURE G 1022) an off-site medical facility for Medical person to an off-site medical facility for treatment.

treatment.

Transport Rescue 10 CFR 50.72(b)(3)(xii) Hospital 10 CFR 72.75(c)(3) I AP-030 Rev. 45 Page 30 of 56

. e ATTACHMENT 11.4 Page 1 of 3 TWENTY-FOUR HOUR NOTIFICATIONS TO THE NRC TWENTY-FOUR HOUR NOTIFICATIONS TO THE NRC HBRSEP shall notify the NRC Operations Center via ETS not later than 24 hours2.777778e-4 days 0.00667 hours 3.968254e-5 weeks 9.132e-6 months after the discovery of any of the following events or conditions involving spent fuel.

EVENT KEYWORDS REQUIREMENT EXAMPLES FFD SIGNIFICANT EVENT REPORT Alcohol The use, sale, distribution, possession, or Influence presence of illegal drugs, or the Substance consumption or presence of alcohol within NRC employee the protected area and, FFD Any acts by any person licensed under Fitness for Duty 10 CFR part 55 to operate a power reactor or by any supervisory personnel assigned to perform duties within the scope of this part:

- involving the sale, use, or possession of a controlled substance,

- resulting in confirmed positive tests on such persons,

- involving use of alcohol within the protected area, or

- resulting in a determination of unfitness for scheduled work due to the 10 CFR 26.719 consumption of alcohol.

TWENTY-FOUR HOUR NOTIFICATIONS TO THE NRC FFD See SEC-NGGC-2140 for additional guidance. This will likely be reported by Corporate personnel.

FALSE POSITIVE ERROR ON FFD FFD Should a false positive error occur on a See SEC-NGGC-2140 for additional guidance.

SPECIMEN Fitness for Duty blind performance test specimen, HBRSEP This will likely be reported by Corporate personnel.

False Positive shall promptly notify the NRC.

Specimen 10 CFR 26.719(b)(4)(c)(2)

Laboratory FALSE NEGATIVE ERROR ON FFD FFD Should a false negative error occur on a SPECIMEN Fitness for Duty quality assurance check of validity False Negative screening tests, HBRSEP shall promptly Specimen notify the NRC.

10 CFR 26.719(b)(4)(c)(3)

Laboratory AP-030 Rev. 45 Page 31 of 56

e e e ATTACHMENT 11.4 Page 2 of 3 TWENTY-FOUR HOUR NOTIFICATIONS TO THE NRC TWENTY-FOUR HOUR NOTIFICATIONS TO THE NRC HBRSEP shall notify the NRC Operations Center via ETS as soon as practical and in all cases, within twenty-four hours of the occurrence of any of the following:

EVENT KEY WORDS REQUIREMENT EXAMPLES ISFSI SAFETY EQUIPMENT ISFSI Any event in which important to safety DISABLED OR FAILURE TO Disable equipment is disabled or fails to function FUNCTION Failure as designed when:

Safety Function i) The equipment is required by regulation, Mitigation license condition, or certificate of Accident compliance to be available and operable to Loss of Function prevent releases that could exceed regulatory limits, to prevent exposures to radiation or radioactive materials that could exceed regulatory limits, or to mitigate the consequences of an accident; and, ii) No redundant equipment was available 10 CFR 72.75(d)(1) and operable to perform the required safety function.

AP-030 Rev. 45 Page 32 of 56

ATTACHMENT 11.4 Page 3 of 3 TWENTY-FOUR HOUR NOTIFICATIONS TO THE NRC TWENTY-FOUR HOUR NOTIFICATIONS TO THE NRC HBRSEP shall notify the NRC Operations Center via ETS as soon as practical and in all cases, within twenty-four hours of the occurrence of any following: of the EVENT KEY WORDS REQUIREMENT EXAMPLES EXTERNAL EXPOSURE FROM External The discovery of any event involving loss BYPRODUCT, SOURCE, OR SNM Exposure of control of licensed material possessed

(> ANNUAL LIMITS) Release by HBRSEP that may have caused or Source threatens to cause any of the following Byproduct conditions:

SNM 1. An individual to receive in a period of 24 hour2.777778e-4 days 0.00667 hours 3.968254e-5 weeks 9.132e-6 months s:

(i) A total effective dose equivalent exceeding 5 rems; or (ii) An eye dose equivalent exceeding 15 rems; or (Ui) A shallow dose equivalent to the skin or extremities exceeding 50 rems; or

2. The release of radioactive material, inside or outside the restricted area, so that, had an individual been present for 24 hours2.777778e-4 days 0.00667 hours 3.968254e-5 weeks 9.132e-6 months , the individual 10 CFR 20.2202(b) could have received an intake in excess of one occupational annual limit on intake.

AP-030 Rev. 45 Page 33 of 56

100. G2.4.43 SRO 001 Which ONE (1) of the following correctly completes the statements below regarding the process for which the NRC Headquarters Operations Officer (H 00) will contact the control room with a notification of a Nuclear Power Plant Attack Message?

The HOO will contact the Unit 2 Control Room and state that he has a Nuclear Power Plant Attack Message and will (1) . If the incorrect code is given, JAW OMM-001-4, Communications, the SM or his designee is required to (2)

A. (1) provide the four digit alphanumeric authentication code (2) receive the message and contact security to validate the threat B. (1) ask if an authentication code is desired (2) receive the message and contact security to validate the threat C (1) provide the four digit alphanumeric authentication code (2) hang up and immediately call back the HOO D. (1) ask if an authentication code is desired (2) hang up and immediately call back the H0O The correct answer is C.

A. Incorrect The first part is correct. The second part are the actions if a threat was communicated to the control room via another source. These actions are lAW with Attachment 1 of AOP-034, Security Events. The question specifically states lAW OMM-001-4 with the call coming from the NRC.

B. Incorrect. The first distractor is the actions that the Emergency Communicator would take when contacting the State I Counties when performing an Emergency Notification of an Event declaration. The second part are the actions if a threat was communicated to the control room via another source. These actions are lAW with Attachment 1 of AOP-034, Security Events. The question specifically states lAW OMM-001-4 with the call coming from the NRC.

C. Correct.

D. Incorrect The first distractor is the actions that the Emergency Communicator would take when contacting the State I Counties when performing an Emergency Notification of an Event declaration. The second part of the answer is correct.

Page: 186 of 187 10/13/2011

Question 100 Tier 3 K/A Importance Rating - RO 3.2 SRO 3.8 Knowledge of emergency communications systems and techniques.

Reference(s) Sim/Plant design, OMM-001-4 Proposed References to be provided to applicants during examination - None Learning Objective OMM-001-4 Self Study Question Source NEW Question Cognitive Level F 10CFRPart55Content- 41.10/45.13 Comments -

SRO: Recieving emergency communications from the NRC is an SRO only function at RNP.

Page: 187 of 187 10/13/2011

Proqress Enerqy INFOTION H. B. ROBINSON STEAM ELECTRIC PLANT, UNIT NO. 2 PLANT OPERATING MANUAL VOLUME 3 PART I OMM-OO1 -4 COMMUNICATIONS REVISION 20

9.0 INSTRUCTIONS 9.1 Command and Control

1. During emergency conditions or anytime that the EALs are being reviewed, all requests for information from the COs should be made through the CRS to assure the communications flow is not confusing for the COs. However, the SM py directly request an available operator to place the VLC Switch to emergency and sound alarms.

2. Emergency Plan announcements should be mad e from the Shift Manager/Emergency Communicator area if the CRS is involved in directing emergency actions to avoid detracting from effor ts to place the plant in a safe condition.

9.2 NRC Authentication Codes

1. The NRC will provide a single, four digit alphanum eric code to the main control room during the daily plant status communication chec k at 0400 hours0.00463 days 0.111 hours 6.613757e-4 weeks 1.522e-4 months . The NRC will state the current authentication code and then give the new authentication code. These codes will go into effect each day at 0800 hour0.00926 days 0.222 hours 0.00132 weeks 3.044e-4 months s and are used to validate the caller identification during imminent threats and physical attacks. In the event of an imminent threat notification between 0400 hour0.00463 days 0.111 hours 6.613757e-4 weeks 1.522e-4 months s and 0800 hours0.00926 days 0.222 hours 0.00132 weeks 3.044e-4 months , the authentication code from the previous day shall be used. The authentication code is not classified as safeguards information but should be recorded

__ location and maintained in a discrete readily accessible to the Shift Manager or desig nee. The authentication c e hall not be entered into Aut61d

2. The call rocess o repo g an imminent threat is illustrated below:

a. NRC Headquarters Operations Officer (HOO) calls the Unit 2 Control Room and states that it has an Emergency Aircraft Thre at Warning Message or a Nuclear Power Plant Attack Message and give s the authentication code.

b. The Shift Manager or designee will verify the code and reply that they have confirmed the authentication code and are read y to receive the emergency message.

c. If an incorrect code is given, the SM or designee shall hang up and immediately call back the HOO. A code word is not required for the call back.

NRC HOO: This is the NRC Operations Officer, I have an Emergency Aircraft Imminent Threat Warning Message, the authentication code is Alpha One Bravo Yankee SM: Checks current authentication code, and if correct, responds: Authentication confirmed, standing by for warning message, go ahead NRC.

OMM-001-4 Rev.20 Page 4 of 8

AOP-034 Rev. 18 SECURITY EVENTS Page 18 of 62 ATTACHMENT 1 CREDIBILITY EVALUATION (Page 1 of 2)

NOTE at any time during performance of this attac hment verification of the threat is received from the NRC with the proper Authentication Code Plant Security, THEN the threat is considere d credible.

1. j the caller is from a Federal or State Agency other than OR the NRC Authentication Code was NOT valid the NRC

, THEN perform the following:

a. Obtain the following information from the calle r:

Name

Position/Title

Estimated time event will occur

b. Contact the NRC via NRC ENS phone A request assistance for verification of threat credibility.

2. IF the caller is NOT from a Federa] OR State Agency, THEN attempt to ascertain the following information via questioning the caller:

Is the caller rational OR sober?

Ask the caller when the event will occur.

Does the caller know the specifics concernin g the plant?

Ask the caller why they are making the call.

As a final question. ask the caller his/her name.

3. IF the call is received directly in the Con trol Room. THEN notify SecuriLy Lha a threat call has been received.

4. If time permits. THEN contact the Plant Gene ral Manager Q. On-Call Manager for consultation.

AOP-034 Rev. 18 SECURITY EVENTS Page 19 of 62 ATTACHMENT 1 CREDIBILITY EVALUATION (Page 2 of 2)

5. WHEN a determination for credibility is made, THEN return to the Main Body. Step in effect.

- END -

ATTACHMENT 10.5 Page 11 of 11 NUCLEAR POWER PLANT EMER GENCY NOTIFICATION FORM INSTRUCTIONS FOR COMPLETION Line 2:

CAUTION Chronological order of the times recorde d on the form is critical. The time liste (NOTIFICATION TIME) should be the d on Line 2 last time entered on the form. The Electronic Emergency Notification For times on the m should be completed as follows: first-(DECLARATION TIME), second- Line Line 10 17 (APPROVAL TIME), and last- Line (NOTIFICATION TIME). For example 2 Line 10 at 12:00 and Line 17 at 12:10 12:14. The first voice contact (NOTIFI and Line 2 at CATION TIME) time should not be approved form is available. documented until an NOTIFICATION TIMEIDATE: The Not ification Time/Date is completed when first voice contact is made during offs ite agency notification. First voice contact will be considered complete after site identification, type of message, and emergency classificati on is provided to the offsite agency RECORD the time of first voice contact with any offsite agency, as verified on the phone by roll call.

AUTHENTICATION #: ENTER the AU THENTICATION number in the space provided on the Electronic Emergency Notification Form. This information will be entered after the form is initially dev eloped and transmitted to offsite agencies. Authentication is not require d, but the State/County representatives should be asked, Would anyone like to authenticate this message? IF yes, THEN they will pick a number AND you respond with the corresponding wor (see the authentication code list or sele d ct the authentication code button on the a

electronic emergency notification log).

GOVERNMENT AGENCIES NOTIF IED After review of the ENF, RECORD the name of the individual from each agency and the date/time the information was provided.

Upon completion, transmit the informa tion electronically using the Send Form button. This will also automatically upd ate the ENF with the earliest notificatio time. n EPNOT-01 Rev. 37 Page 47 of 68

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