{{#Wiki_filter:ES-401 Written Examination Question Worksheet Form ES-401-6 Examination Outline Cross-reference:

Question # 1 Tier# 1 Group# I K/A # 001.AK3.02 Importance Rating 4.3 Proposed Question: With the plant at 50% power, the following sequence of events occurs: 1. A single Control Bank "D" rod starts to withdraw with no demand signal present.2. The RO places the rod bank selector switch in MANUAL, and the rod motion stops.3. The US enters AOP 3552 "Malfunction of the Rod Drive System".4. The SM refers to Technical Specification section 3/4.1.3 "Movable Control Assemblies".

What is one of the items ensured by the specifications of section 3/4.1.3?A. Acceptable power distribution limits are maintained.

D. Moderator Temperature Coefficient remains within its analyzed range.Proposed Answer: A Explanation (Optional):

The movable control assemblies section of Technical Specifications ensures that: 1) acceptable power distribution limits are maintained

("A" correct).

: 2) minimum SHUTDOWN MARGIN is maintained.

: 3) potential effects of rod misalignment on associated accident analysis are limited ("B", "C" and "D" wrong). "B" is the basis of section 3/4.2.5 "DNB Parameters". "D" is a basis for section 3/4.1.1.4 "Minimum Temperature for Criticality".

Technical Reference(s):

Tech.Spec.

3/4.1.3 Basis (Attach if not previously provided)Proposed references to be provided to applicants during examination:

None Learning MC-05478 Describe the major administrative or procedural precautions and limitations placed on the Objective:

operation, of the Rod Control System, and the basis for each.Question Source: New Question Cognitive Level: Memory or Fundamental Knowledge 10 CFR Part 55 Content: 55.43.2 Comments: 41 of 46 NUREG-1021, Revision 8, Supplement 1

I REACTIVITY CONTROL SYSTEMS August 27, 2001 BASES I 3/4.1.3 MOVABLE CONTROL ASSEMBLIES The specifications of this section ensure that: (1) acceptable power distribution limits are maintained, (2) the minimum SHUTDOWN MARGIN is maintained, and (3) the potential effects of rod misalignment on associated accident analyses are limited. OPERABILITY of the control rod position indicators is required to determine control rod positions and thereby ensure compliance with the control MILLSTONE  

-UNIT 3 B 3/4 1-3 Amendment No. JZ, 00, Ah, 7J7, ,Yf7, XPO, 197 REACTIVITY CONTROL SYSTEMS LBDCR 3-17-01 February 14, 2002 BASES MOVABLE CONTROL ASSEMBLIES (Continued) rod alignment and insertion limits. Verification that the Digital Rod Position Indicator agrees with the demanded position within +12 steps at 24, 48, 120, and fully withdrawn position for the Control Banks and 18, 210, and fully withdrawn position for the Shutdown Banks provides assururances that the Digital Rod Position Indicator is operating correctly over the full range of indication.

Since the Digital. Rod Position Indication System does not indicate the actual shutdown rod position between 18 step.s and 210 steps, only points in the indicated ranges are picked for verification of agreement with demanded position.The ACTION statements which permit limited variations from the basic requirements are accompanied by additional restrictions which ensure that the original design criteria are met. Misalignment of a rod requires measurement of peaking, factors and a restriction in THERMAL POWER. These restrictions provide assurance of fuel rod integrity during continued operation.

In addition, those safety analyses affected by a misaligned rod are reevaluated to confirm that the results remain valid during future operation.

The maximum rod drop time restriction is consistent with the assumed rod drop time used in the safety analyses.

Measurement with Tavg greater than or equal to 551'F and with all reactor coolant pumps operating ensures that the measured drop times will be representative of insertion times experienced during a Reactor trip at operating conditions.

Control rod positions and OPERABILITY of the rod position indicators are required to be verified on a nominal basis of once per 12 hours with more fre-quent verifications required if an automatic monitoring channel is inoperable.

These verification frequencies are adequate for assuring that the applicable LCOs are satisfied.

The Digital Rod Position Indication (DRPI) System is defined as follows:* Rod position indication as displayed on DRPI display panel (MB4), or* Rod position indication as displayed by the Plant Process Computer System With the above definition, LCO, 3.1.3.2, "ACTION a." is not applicable with either DRPI display panel or the plant process computer points OPERABLE.The plant process computer may be utilized to satisfy DRPI System requirements which meets LCO 3.1.3.2, in requiring diversity for determining digital rod position indication.

Technical Specification SR 4.1.3.2 determines each digital rod position indicator to be OPERABLE by verifying the Demand Position Indication System and the DRPI System agree within 12 steps at least once each 12 hours, except during the time when the rod position deviation monitor is inoperable, then compare the Demand Position Indication System and the DRPI System at least once each 4 hours.The Rod Deviation Monitor is generated only from the DRPI panel at MB4.Therefore, when rod position indication as displayed by the plant process computer is the only available indication, then perform SURVEILLANCE REQUIREMENTS every 4 hours.MILLSTONE  

-UNIT 3 0884 B 3/4 1-4 Amendment No. fg, REACTIVITY CONTROL SYSTEMS LBDCR 3-17-01 February 14, 2002 BASES MOVABLE CONTROL ASSEMBLIES (Continued)

Additional surveillance is required to ensure the plant process computer indications are in agreement with those displayed on the DRPI. This additional SURVEILLANCE REQUIREMENT is as follows: Each rod position, indication as. displayed by the plant process computer shall be determined to be OPERABLE by verifying the rod position indication as displayed on the DRPI display panel agrees with the rod position indication as displayed by the plant process computer at least once per 12 hours.The rod position indication, as displayed by DRPI display panel (MB4), is a non-QA system, calibrated on a refueling interval, and used to implement T/S 3.1.3.2. Because the plant process computer receives field data from the same source as the DRPI System (MB4), and is also calibrated on a refueling interval, it fully meets all requirements specified in T/S 3.1.3.2 for rod position.

Additionally, the plant process computer provides the same type and level of accuracy as the DRPI System (MB4). The plant process computer does not provide any alarm or rod position.

deviation monitoring as does DRPI display panel (MB4).For Specification 3.1.3.3, the ACTION states to immediately open the reactor trip breakers if the LCO is not satisfied, however, it is appropriate to select Data A and Data B individually, to verify satisfactory rod position indication is not available before opening the reactor trip breakers.For Specification 3.1.3.1 ACTIONS b. and c., it is incumbent upon the plant to verify the trippability of the inoperable control rod(s).Trippability is defined in Attachment C to a letter dated December 21, 1984, from E. P. Rahe (Westinghouse) to C. 0. Thomas (NRC). This may be by verification of a control system failure, usually electrical in nature, or that the failure is associated with the control rod stepping mechanism.

In the event the plant is unable to verify the rod(s) trippability, it must be assumed to be untrippable and thus falls under the requirements of ACTION a.Assuming a controlled shutdown from 100% RATED THERMAL POWER, this allows approximately 4 hours for this verification.

The applicable I&C calibration procedure (Reference 1.) being current indicates the associated circuitry is OPERABLE.There are conditions when the Lo-Lo and Lo alarms of the RIL Monitor are limited below the RIL, as indicated in COLR Section 2.3, Control Rod Insertion Limits. The RIL Monitor remains OPERABLE because the lead control rod bank still has the Lo and Lo-Lo alarms greater than or equal to the RIL.When rods are at the top of the core, the Lo-Lo alarm is limited below the RIL to prevent spurious alarms. The RIL is equal to the Lo-Lo alarm until the adjustable upper limit setpoint on the RIL Monitor is reached, then the alarm remains at the adjustable upper limit setpoint.

When the RIL is in the region above the adjustable upper limit setpoint, the Lo-Lo alarm is below the RIL.MILLSTONE  

-UNIT 3 0884 B 3/4 1-5 Amendment No. Po, ES-401 Written Examination Question Worksheet Form ES-401-6 Examination Outline Cross-reference:

Question # 2 Tier # I Group# I K/A # 003.AKI.19 Importance Rating 2.9 Proposed Question: Initial conditions:

* The Plant has been steady at 80% power for several days.* The core is at middle of life conditions.

* Control bank D rods are at 170 steps.The following sequence of events occurs: 1. One Shutdown Bank A rod drops into the core.2. The dropped rod adds -100 pcm of reactivity.

: 3. The operators fail to take rods to MANUAL 4. Bank D rods withdraw 25 steps and restore Tave to program.What would have been the results if initial control bank D rod height had been 200 steps?A. Rods would withdraw 28 steps and restore Tave to program.B. Rods would withdraw 28 steps, failing to restore Tave to program.C. Rods would withdraw 23 steps, failing to restore Tave to program.D. Rods would withdraw 18 steps and restore Tave to program.Proposed Answer: C Explanation (Optional):

When the rod drops, reactor power will decrease, and Tave will decrease since steam demand has not changed. This results in rods moving out, restoring temperature.

Differential rod worth for rods below 200 steps is approximately 4 pcm/step.

Above 200 steps, differential rod worth is approximately 3 pcm/step, requiring rods to move out about 33 steps ("A" and "D" wrong). Automatic rod withdrawal is blocked at 223 steps by C- 11 ("C" correct, "B" wrong).Technical Differential Rod Worth Curve RE-D-02 (Attach if not previously provided)Reference(s):

Monthly Reactivity Data Sheet Proposed references to be provided to applicants during examination:

None Learning MC-0000 15 Given one of the below listed failures (partial or complete) of the Rod Control System, Objective:

determine the effects on the system and on interrelated systems...

Dropped Rod...Question Source: New Question Cognitive Level: Comprehension or Analysis 10 CFR Part 55 Content: 55.41.5 Comments: 41 of 46 NUREG-1021, Revision 8, Supplement I

MONTHLY REACTIVITY DATA SHEET Millstone Unit 3 Cycle 8 Median Values for June 2002 (Sheet 1 of 1)Guideline Values: Moderator Temperature Coefficient  

.............  

-36 porn / OF Power Coefficient  

...........................................  

-28 porn / % Power Boron Worth Differential Boron Worth (DBW) ............................  

-7.3 porn / ppm Inverse Boron Worth per % Power ............................

4 ppm / % Power Rod Worth Approximate Differential Rod Worth (above 200 steps) -3.0 pcm / step Approximate Differential Rod Worth (125 to 200 Steps) -4.0 porn / step Boration Gallons Boric acid per ppm RCS [B] increase ...........

9.0 gal BA / ppm Gallons Boric acid per % Power reduction  

.............

34 gal BA / % Power Gallons Boric acid per MWe reduction  

.............

2.9 gal BA / MWe Dilution Gallons PGS per ppm RCS [B] decrease .............

244.0 gal PGS / ppm Gallons PGS per % Power increase .............

932 gal PGS / % Power Gallons PGS per MWe increase .............

77.6 gal PGS / MWe Auto Makeup Reactivity Correction Factor ............

0.893 Note: Guideline values are approximate reactivity coefficients intended for licensed operator use at Hot Full Power in performing rapid and real time assessments of reactor responses.

Plant curves should be consulted for increased accuracy as time permits.Preparer/Date Reviewer/Date Approver/Date RE-D-02 25 MP3-08-02 F Differential Rod Worth versus Steps Withdrawn Control Bank D and C in Overlap EOL HFP Equilibrium Xenon 212-ER-01-0030, Rev. 17'age \ of Si , 10 9..........I 1- 1 I I TiptoTip =115 Steps 71 11 11 L -- I I.J...-4-L.  

.I I -i .--i _F -F -F -i .h -I II-F-F- I I I- F--1 I-iT IT_ 7_V L U 8 I X-J CL C,-I-0 a 0 I-P: z w U-LI-U.7 6 5 4 3---- -- ---------- --------------------  

----- ------------------  

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2 1 c 0 25 115 140lBANK C 50 165 75 100 125 150 190 215 CONTROL BANK POSITION ( STEPS)175 200 225lBANK DlPreparer/Dat~

p 3/00 Reviewer/Date Approver/Da Page 2 of 3 ES-401 Written Examination Question Worksheet Form ES-401-6 Examination Outline Cross-reference:

Question # 3 Tier # I Group# 1 K/A # 005.AK2.02 Importance Rating 2.6 Proposed Question: With the plant initially at 100% power, the following sequence of events occurs: 1. A Control Bank "C" Group 1 rod drops.2. The crew prepares to recover the rod.3. The US directs the RO to operate the ROD DISCONNECT switches in accordance with AOP 3552 "Malfunction of the Rod Drive System".The RO reports that he placed the lift coil disconnect switches for the unaffected rods in Control Bank "C" Group 1 in the ROD DISCONNECTED position, and left the switch for the dropped rod in the ROD CONNECTED position.Which of the following actions should be taken?A. Continue to recover the dropped rod in accordance with the procedure.

B. Direct the RO to also place all Control Bank "C" Group 2 rods in ROD DISCONNECTED.

C. Direct the RO to place the dropped rod disconnect switch in ROD DISCONNECTED and return the group 1 rods to ROD CONNECTED.

D. Direct the RO to place the Group 2 rods and the dropped rod disconnect switches in ROD DISCONNECTED and return the Group 1 rods to ROD CONNECTED.

Proposed Answer: B Explanation (Optional):

Step in procedure states, "EXCEPT for the dropped rod, place all the lift coil disconnect switches for the affected bank to -ROD DISCONNECTED".

A incorrect the Group 2 rods also must be switched.

B correct, group 2 rods to ROD DISCONNECTED.

C incorrect, step states unaffected rods placed in ROD DISCONNECTED.

D incorrect, group 1 rods, except dropped rod to remain in DISCONNECTED.

Technical Reference(s):

AOP 3552, Attachment A, step 5.Proposed references to be provided to applicants during examination:

None Learning Objective:

MC-03901 Describe the major action categories contained within AOP 3552.Question Source: Bank # 75456 Question Cognitive Level: Memory or Fundamental Knowledge 10 CFR Part 55 Content: 55.41.7 Comments: 41 of 46 NUREG-1021, Revision 8, Supplement 1

3 MALFUNCTION OF THE AOP 3552 Page 6 of 10 ROD DRIVE SYSTEM Rev. 3 Attachment A Misaligned Rod NOTE* A ROD CONTROL URGENT FAILURE (MB4C 4-8)alarm will occur during recovery unless the affected rod is in Shutdown Bank C, D, or E.* If the affected rod is in a Control Bank, a ROD CONTROL BANKS LIMIT LO (MB4C 3-9) alarm and ROD CONTROL BANKS LIMIT LO LO (MB4C 4-9) alarm may occur during recovery and remain in alarm until the P/A converter is reset. Therefore, response to these alarms is not appropriate during this period.5. Establish Conditions For Rod Alignment a. Verify fuse check of affected rod -COMPLETE a. WHEN fuse check complete, THEN Proceed to step 5.b.b. Record affected group step counter position c. Align control rod disconnect switches: 1) Unlock and Open control rod disconnect switch box (Box 3RDS-HDSBOX1, CAT 60, Key #18 in CO key locker)2) Place each rod disconnect switch for the affected bank, except the misaligned rod, to the ROD DISCONNECTED position d. Place control rod bank SEL switch to affected bank position ES-401 Written Examination Question Worksheet Form ES-401-6 Examination Outline Cross-reference:

Question # 4 Tier # I Group # I K/A # 011.EKI.0I Importance Rating 4.4 Proposed Question: Current conditions:

* The crew is responding to a large break LOCA per E-1, "Loss of Reactor or Secondary Coolant".* RCS pressure is stable at 200 psia.* All ECCS pumps are running.What currently is the primary method of decay heat removal?A. Heat transfer between the RCS and the S/Gs due to subcooled natural circulation flow.B. Condensation of reflux boiling in the S/Gs, flowing back to the vessel via the hot legs.C. Injection of ECCS water from the RWST and the removal of steam/water out of the break.D. Injection of water from the CTMT sump and the removal of steam/water out of the break.Proposed Answer: C Explanation (Optional): "A" and "B" incorrect, since during a large break LOCA, the SGs are at higher temperatures than the RCS steam/water mixture. "A" and "B" are plausible since natural circulation is a vital cooling mechanism during small break LOCAs. "C" is correct, since during large break LOCAs, the break is large enough to remove all of the decay heat from the core. "D" is wrong, since the switchover to cold leg recirculation is not performed until the RHR pumps have tripped.Technical Reference(s):

E- I background (Attach if not previously provided)ES-1.3, step 2.Proposed references to be provided to applicants during examination:

None Learning MC-04912 For a Large Break LOCA, EXPLAIN Core Cooling during the (As available)

Objective:

4 major stages of the Event...Question Source: Modified Bank # 70054 Parent attached Question Cognitive Level: Comprehension or Analysis 10 CFR Part 55 Content: 55.41.5, 41.8, and 41.10 Comments: 4 1 of 46 NUREG-1021, Revision 8, Supplement 1

ES-401 Written Examination Question Worksheet Form ES-401-6 Original 70054 Given the following conditions:

* A LOCA has occurred.* Appropriate actions in accordance with E-0, "Reactor Trip and Safety Injection", and E-1,"Loss of Reactor or Secondary Coolant", have been completed.

* ECCS is operating in cold leg recirculation mode.* RCS pressure is stable at 200 psia.Which of the following statements describes the primary method of decay heat removal?A. The condensation of reflux boiling in the S/Gs.B. Heat transfer between the RCS and the S/Gs due to natural circulation flow C. Heat transfer between the RCS and the S/Gs due to forced circulation flow D. The injection of water from the containment sump and the removal of steam/water out from the break.Answer: D 41 of 46 NUREG-1 021, Revision 8, Supplement I  

'1 Breaks <. 3/8" equivalent diameter hole Breaks in this range are considered to be leaks, rather than small LOCA's, since the normal charging system can maintain reactor coolant inventory so that RCS pressure and pressurizer level do not decrease.

Very slight system depressurization may occur but no automatic trip or safety injection signal would be generated.

The core will remain fully covered provided that the steam generators are available to remove energy, and makeup flow is continuously delivered to the RCS. If charging flow is not available, the RCS transient behavior would be similar to the response described for Category 2.If the leak is within Technical Specification limits or it can be isolated, the plant could remain in power operation.

If the leak is above Technical Specification limits and cannot be isolated, then the plant should go to a cold shutdown condition utilizing the normal shutdown procedures.

During cooldown the charging system should maintain pressurizer level and the RCS depressurization should be controlled to conform to the normal cooldown limits.Breaks 3/8" < diameter <- 1", minimum safety injection, or Category 1 breaks above with no charging flow assumed For these break sizes the normal makeup system cannot maintain level and pressure.

The RCS will depressurize and an automatic reactor trip and safety injection signal will be generated.

Provided that a secondary side heat sink exists, the RCS will reach an equilibrium pressure which corresponds to the pressure at which the liquid phase break flow equals the high pressure pumped safety injection flow. It has been verified that this equilibrium pressure condition will be established for plants with charging/SI pumps. This effect is described here by the presentation of a specific plant analysis for break sizes within this range. A general description of system behavior applicable to the sample transient is provided first, then specific comments concerning the sample analysis are provided.E-1 5 HP-Rev. 1 6998B:lb Early in the transient a loss of subcooled liquid in the RCS occurs which results in a moderate depressurization to the pressure which corresponds to saturation pressure in the core and hot legs. At this point the upper head, upper plenum, hot legs, and core begin to experience some slight voiding, but more than enough liquid flow exists through the core to keep it covered and cooled. During this period of voiding, however, RCS depressurization occurs at a much slower rate than during the time when the entire system was subcooled.

Eventually the RCS depressurizes to the point of the reactor trip signal. Immediately following reactor trip, the RCS rapidly depressurizes, since only a fraction of the heat previous to trip is now being transferred to the primary fluid. Due to this rapid depressurization follbwing reactor trip, a safety injection signal is quickly generated.

Within a few minutes of the reactor trip time, an equilibrium pressure is established which is above the steam generator pressure.

The fluid conditions in the RCS at the time of equilibrium pressure establishment may be characterized by slight voiding in the core and upper plenum and hot legs, and saturated or slightly subcooled liquid in the cold legs. Core heat is removed through the steam generators by continuous single or two-phase natural circulation.

The primary mixture level in the steam generators does not drain for breaks of this size, and the core remains covered throughout the entire transient provided that SI is not interrupted.

Once equilibrium pressure is established there is no further net loss of liquid volume in the RCS. The natural circulation heat removal mode continues until the time that the break can remove all the decay heat ( 1 day for a 1" break). Prior to this time, auxiliary feedwater is required to maintain the heat sink. Since the equilibrium pressure established is determined by means of a volume balance of SI flow and break flow, the 0P and AT from primary to secondary side, together with the cold safety Injection water, may provide a total heat sink greater than the decay heat generated and a cooling of the primary fluid can occur.E-1 6 HP-Rev. 1 6998B:lb would correspond to an event which is approaching the design basis assump-tions. It should be noted that more probable delivery rates for the safety injection system (e.g., maximum safeguards or minimum safeguards with no spilling line) will yield less core uncovery or no core uncovery.For break locations other than at the cold leg, little or no core uncovery is calculated.

For breaks in the crossover leg there could be an uncovery similar to the uncovery experienced for the cold leg break when steam was vented through the crossover legs. Since for crossover leg breaks safety injection is injected into all RCS cold legs and steam does not have to pass through the broken loop RCP, there is no subsequent core uncovery.

For breaks in the RCS hot leg or pressurizer vapor space, steam is vented earlier then for other locations (immediately for vapor space breaks) so that essentially no core uncovery is experienced.

The method used for long-term plant recovery for breaks in this category depends upon the RCS pressure at the time that the operator determines if further RCS cooldown and depressurization is required (step 13 in the E-1 guideline)  

.If at this time the RCS pressure is greater than the low-head S: pumps shutoff head pressure, ES-1.2, POST LOCA COOLDOWN AND DEPRESSURIZATION.

is used for long-term plant recovery.

Even if the RCS pressure is less than the shutoff head pressure of the low-head SI pumps but it cannot be verifiec that the low-head SI pumps are injecting flow into the RCS, the operator should transfer to ES-1.2 for long-term plant recovery.

The operator would stay in E-1 if the RCS pressure is less than the shutoff head pressure of tne low-head SI pumps and flow into the RCS from the low-head SI pumps has been verified.Large Break LOCA, 1 FT 2 < Area < Double-Ended, Minimum Safeguards A large break LOCA is the design basis for many aspects of the NSSS design.Some of the major design considerations impacted by the large break LOCA are peak core power, containment sizing, and loop/vessel internal forces. In order to describe the large break LOCA hydraulic transient a typical SAR safety analysis for a 4-loop plant will be utilized.

The phenomena descrioec here are similar for all Westinghouse plants.E-1 27 HP-Rev. 1 6998B:lb A large break LOCA (one square foot total area up to the double-ended break)has four characteristic stages: blowdown, refill, reflood, and long-term recirculation.

Blowdown starts with the assumed initiation of the LOCA and ends when the reactor coolant system pressure (initially 2250 psig) falls to essentially that of the containment atmosphere.

Refill starts at the end of blowdown and ends when the addition of emergency core cooling water fills the bottom of the reactor vessel and reaches the elevation of the bottom of the fuel rods. Reflood is defined as the time from the end of refill until the reactor vessel has been filled with water to the extent that core temperature rise has been terminated and core temperatures subsequently have been reduced to their long-term steady-state levels associated with dissipating decay heat.These time divisions are established mainly for analytical convenience.

Figure 11 illustrates the primary system pressure transient occurring during the blowdown phase of the LOCA for a double-ended cold leg guillotine break.The primary pressure rapidly drops from an initial value of 2250 psig to a low value of 40-50 psig by the end of blowdown (-1/2 minute). Also shown on Figure 11 is the break flow transient occurring during blowdown.

The break flow starts at a very high value (critical flow, -70,000 lbm/sec) and is reduced to zero by the end of blowdown.Figure 11 also includes a plot of the SI accumulators mass flow rate. Note that accumulator flow is initiated approximately 16 seconds after the break occurs. This corresponds to the time when the RCS pressure has decreased to 600 psig, which corresponds to a minimum accumulator pressure set point.E-1 28 HP-Rev. 1 6998B:lb The containment pressure transient is shown on Figure 12. As shown, the containment pressure reaches a peak value early in the transient during the blowdown phase of the transient.

A safety injection signal will be initiated on a containment High-l pressure signal in a matter of seconds after the break and containment spray may be initiated on a containment High-3 pressure signal depending on the magnitude of the break and the specific plant's containment design.The important hydraulic transient parameters during the reflood phase are downcomer water level (ZD), core water level (ZC), and the core inlet flooding rate (VIN) as shown in Figure 12.During refill the ECCS cooling water from the SI accumulators and safety Injection pumps enters the top of the reactor vessel downcomer annulus and starts to fill the reactor vessel lower plenum, which is filled after 45 seconds. This is commonly called bottom of core (BOC) recovery time. After BOC occurs, the downcomer annulus starts to fill rapidly and thus provides a.static head for pushing cooling water into the core. A core inlet flooding rate (inches/second) is established and the water starts to move up into the core, thus providing the mechanism for core cooling during reflood.Table 1 presents a time sequence of events for the double-ended cold leg guillotine break.After successful initial operation of the ECCS, the reactor core is once again covered with borated water. This water has enough boron concentration to maintain the core in a shutdown condition.

Decay heat is removed by a continuous supply of water from the ECCS. This supply initially comes from the refueling water storage tank (RWST). When the RWST level reaches the switchover setpoint the ECCS pumps are transferred into the recirculation mode (using ES-1.3, TRANSFER TO COLD LEG RECIRCULATION) wherein water is drawn from the containment sump and is cooled in the residual heat removal heat exchangers.

Thus, long-term cooling of the core is maintained by the ECCS in sump recirculation mode. The core is maintained in a shutdown state by borated water.E-l 30 HP-Rev. lA 6998B:lb TRANSFER TO COLD LEG EOP 35 ES-1.3 Page 3 of 14 RECIRCULATION Rev. 010 q-STP ACTION/EXPECTED RESPONS RESPONSE NOT OBTAINED E CQ A U T I 0 N* SI recirculation flow to RCS must be maintained at all times.* If offsite power is lost after SI reset, manual action to restart safeguards equipment may be required.* High radiation levels may be experienced in the Auxiliary and ESF buildings following the transfer to cold leg recirculation.

I I NOTE Functional Response procedures should not be implemented until completion of step 5..1. RESET ESF Actuation Signals, If Required* SI* CDA* LOP* CIA* CIB 2. STOP Both RHR Pumps And Place Control Switches In PULL-TO-LOCK ES-401 Written Examination Question Worksheet Form ES-401-6 Examination Outline Cross-reference:

Question # 5 (SRO)Tier # I Group# I K/A # W/E04.EA2.01 Importance Rating 4.3 Proposed Question: With the plant at 100% power, the following sequence of events occurs: 1. The reactor trips and safety injection actuates.2. Over the next 10 minutes, RCS pressure decreases to and stabilizes at 1600 psia.3. The crew is responding using ECA- 1.2, "LOCA Outside Containment".

: 4. While attempting to isolate the break, the final valve the crew closes is the "A" RHR pump cold leg injection valve 3SIL*MV8809A.

: 5. After 3SIL*MV8809A closes, RCS pressure starts increasing.

Which procedure will the crew transition to from ECA- 1.2?A. E- 1 "Loss of Reactor or Secondary Coolant".B. ES-1.1 "SI Termination".

D. ECA- 1. 1 "Loss of Emergency Coolant Recirculation".

Proposed Answer: A Explanation (Optional):

JUSTIFICATION:

It can be determined that the break is isolated since RCS pressure increases. "A" is correct, and"B" is wrong, but plausible, since with the break isolated, the crew transitions to E- I and subsequently to ES- 1. 1."B" is plausible since with the leak isolated, this procedure will be used to terminate SI. "C" is wrong because there is no entry into ES-1.2 from ECA-1.2. "C" is plausible since the break size is small, and ES-1.2 is designed to mitigate small break LOCAs. "D" is wrong, since if the break is isolated, the crew would transition to ECA- .1.Technical Reference(s):

ECA-1.2, steps 4 and 5 (Attach if not previously provided)Proposed references to be provided to applicants during examination:

None Learning 03878, Discuss conditions which require transition to other procedures (As available)

Objective:

from EOP 35 ECA-1.2.Question Source: Modified Bank # 75669 Question Cognitive Level: Comprehension or Analysis 10 CFR Part 55 Content: 55.41.10 55.43.5 Comments: NUREG-1021, Revision 8, Supplement 1 41 of 46 ES-401 Written Examination Question Worksheet Form ES-401-6 Original question 75669 With the plant at 100% power, the following sequence of events occurs: 1. The reactor trips and safety injection actuates.2. Over the next 10 minutes, RCS pressure decreases to and stabilizes at 1600 psia.3. The crew is responding using ECA-1.2, "LOCA Outside Containment." 4. While attempting to isolate the break, the final valve the crew closes in attempt to isolate the leak is RHR pump "A" cold leg injection valve (3SIL*MV8809A).

: 5. After 3SIL*MV8809A closes, RCS pressure remains stable.Which procedure will the crew transition to from ECA-1.2?A. E-1 "Loss of Reactor or Secondary Coolant".B. ES-1.1 "SI Termination".

Answer: D NUREG-1021, Revision 8, Supplement 1 41 of 46 LOCA OUTSIDE EOP 35 ECA-1.2 Page 6 of 7 CONTAINMENT Rev. 007 STEP ACTION/EXPECTED RESPONS RESPONSE NOT OBTAINED 4. Try To Identify And Isolate Break a. Tmrn the power lockout switch to ON for the following valves (MB2R):* RHR pump A (3SIL* MV8809A)* RHRpump B (3SIL MV8809B)* SI injection (3SIH*MV8835)

: b. CLOSE o of the following:

: c. Check RCS pressure -INCREASING

: c. Perform the following:

: 1) OPEN valve closed in step 4.b.2) IF all lines have been checked, THEN Proceed to step 4.d.3) Return to step 4.b.  

-)LOCA OUTSIDE CONTAINMENT EOP 35 ECA-1.2 Rev. 007 Page7of77 I 4. (continued)

: d. Turn the power lockout switch to OFF for the following valves (MB2R):* RHR pump A (3SIL MV8809A)* RHR pump B (3SIL*MV8809B)

: 5. Check If Break Is Isolated a. Check RCS pressure -INCREASING

: a. Go to ECA-1.1, Loss of Emergency Coolant Recirculation.

: b. Go to E-1, Loss of Reactor or Secondary Coolant-FINAL-ES-401 Written Examination Question Worksheet Form ES-401-6 Examination Outline Cross-reference:

Question #Tier #Group #K/A #Importance Rating 6 (SRO)I W/EO 1 .EK 1.03 3.5 Proposed Question: Initial conditions:

* The plant tripped due to a fault in the "A" SG.* The crew has isolated the SG per E-2 "Faulted Steam Generator Isolation".

The following sequence of events occurs: 1. RCS Pressure starts decreasing.

: 2. Numerous Auxiliary Building radiation monitors go into alarm.3. The US desires to enter ES-0.0 "Rediagnosis".

Based on current conditions, what action will the crew take?A. The crew will NOT enter ES-0.0, since SIS has already actuated.B. The crew will NOT enter ES-0.0, since E-0 has already been exited.C. The crew will perform ES-0.0 and then transition to ECA-1.2 "LOCA Outside Containment".

D. The crew will perform ES-0.0 and then transition to E-2 "Faulted Steam Generator Isolation".

Proposed Answer: C Explanation (Optional):

Rediagnosis can only be used if SI is actuated ("A" wrong) after exiting E-0 ("B" wrong).ES-0.0 will send the crew to an E-I series procedure since the faulted SG has already been isolated ("D" wrong) and a SGTR is not occurring

("C" correct).Technical Reference(s):

OP 3272, section 1.2, pg 6 (Attach if not previously provided)ES-0.0 Rediagnosis Proposed references to be provided to applicants during examination:

None Learning MC-0445 1 Discuss the conditions under which ES-0.0 can be used. (As available)

Objective:

MC-06275 Describe the major action categories within ES-0.0.Question Source: New Question Cognitive Level: Comprehension or Analysis 10 CFR Part 55 Content: 55.41.8,41.10 55.43.5 Comments: 41 of 46 NUREG-1021, Revision 8, Supplement 1

ES-0.0, "Rediagnosis," is entered solely based on Operator judgement if SI is actuated.

This is a unique procedure which may be used as an aid to I determine the correct path through the EOP Network after exiting E-0,"PReactnr Trin nr Safety Injection," with SI actuated.-------- --- --., -- J OP 3272 Level of Use l .A- Rev. 008 Information  

.. ...6 of 44 (9 ESPONSE NOT OBTA I NOl This procedure should only be use(I if SI has been actuated.1. Check At Least One SG Is Intact a. Check pressures in all SGs -ANY STABLE OR INCREASING

: a. IF a controlled cooldown is in progress, THEN Proceed to step 2.IF a controlled cooldown is NOT in progress, THEN Perform the applicable action:* IF main steam lines are NOT isolated, THEN Go to E-2, Faulted Steam Generator Isolation.

OR* IF main steam lines are isolated, THEN Go to ECA-2.1, Uncontrolled Depressurization of All Steam Generators.

SP ACTION/EXPECTED RESPONS RESPONSE NOT OBTAINED 2. Check If All SGs Are Intact a. Check pressures in all SGs* NO SG PRESSURE DECREASING IN AN UNCONTROLLED MANNER* NO SG COMPLETELY DEPRESSURIZED I a. Verify each faulted SG isolated* Main steam line* Main feed line* SG blowdown line* SG blowdown sample line* SG chemical feed line* Auxiliary feed line* Steam supply to TD AFW pump* Main steam line drains upstream of MSIVs and TD AFW pump* SG atmospheric dump lines IF the faulted SGs are NOT isolated, THEN Go to E-2, Faulted Steam Generator Isolation.

I I STEP ACTION/EXPECTED RESPONSH RESPONSE NOT OBTAINED 1- I ' n AP Rxpintured Go to one of the following:

I Ai.t'Inef'K U1 ;OJ kuxst;>as ai~ r- -* ANY SO LEVEL INCREASING IN AN UNCONTROLLED MANNER* ANY SG WITH HIGH RADIATION (by trend history, alarm status, or sample results)* E-1, Loss of Reactor or Secondary Coolant OR* ECA-1.1, Loss of Emergency Coolant Recirculation

* ECA-1.2, LOCA Outside Containment 4.Go To One Of The Following:

* E-3, Steam Generator Tube Rupture OR* ECA-3.1, SGTR With Loss of Reactor Coolant OR* ECA-3.2, SGTR With Loss of Reactor Coolant Saturated Recovery Desired OR* ECA-3.3, SGTR Without Pressurizer Pressure Control-FINAL-ES-401 Written Examination Question Worksheet Form ES-401-6 Examination Outline Cross-reference:

Question # 7 (SRO)Tier # I Group # I K/A # 015/17.AK1.02 Importance Rating 4.1 Proposed Question: Current Conditions:

* The plant is at 30% power.* "RCP HI RANGE LKG FLOW HI" annunciator is lit on Main Board 3.* "B" RCP #1 seal leakoff flow is 6.8 gallons per minute.* Both "B" RCP #1 seal inlet temperature indicators read 1 13 0 F and increasing.

What actions are the crew directed to take?A. Trip the reactor, stop the "B" RCP, and close its number 1 seal leakoff valve after the pump has been stopped for between 3 to 5 minutes.B. Commence an orderly plant shutdown, and remove the "B" RCP from service within 8 hours.C. Continue to monitor the "B" RCP, and request Engineering to evaluate the pump for continued operation.

D. Transition to AOP 3554 "RCP Trip or Stopping an RCP at Power" and initiate action to perform an immediate shutdown of the "B" RCP.Proposed Answer: D Explanation (Optional):

With RCP #1 seal leakoff flow >6 gpm AND #1 seal inlet temperatures increasing, MB3B 2-10 (Leakoff Flow high) directs the crew to AOP 3554 with power less than 37% (P-8), since the RCP can be stopped without tripping the unit ("A" is wrong). "A" is plausible since this would be the correct action if power was >P-8. OP 3554 requires tripping the RCP and closing the seal leakoff valve at least 3 minutes after the pump trip ("D" is correct). "B" is wrong, but plausible, since these actions would be required if seal inlet temperature is stable."C" is wrong, and plausible, since these actions are required if seal leakoff flow was < 6 gpm with seal inlet temperatures stable.Technical Reference(s):

OP3353.MB3B 2-10 (Attach if not previously provided)Proposed references to be provided to applicants during examination:

None Learning Objective:

MC-03905 IDENTIFY plant conditions that require entry into AOP-3554.Question Source: Bank # 64317 Question Cognitive Level: Comprehension or Analysis 10 CFR Part 55 Content: 55.41.10 55.43.5 Comments: 41 of 46 NUREG-1021, Revision 8, Supplement 1

Setpoint:

Greater than 5.7 gpm 2-10 RCP Hi RANGE LKG FLOW HI LI AUTOMATIC FUNCTIONS 1. None CORRECTIVE ACTIONS 1. CHECK the following to confirm alarm and determine affected RCP:* 3CHS-FR158 and 3CHS-FR160, high range RCP No. 1 seal leakoff flow recorders (MB3)* CHS-F161*, RCP A No. 1 seal leakoff flow computer point* CHS-F16O*, RCP B No. 1 seal leakoff flow computer point* CHS-F159*, RCP C No. 1 seal leakoff flow computer point* CHS-F158*, RCP D No. 1 seal leakoff flow computer point 2. DISPLAY "RCP Status" NSSS, picture 15.3. VERIFY leakage flow high indication by observing the following indications:

* Seal injection flow* Affected RCP #1 seal inlet temperatures

* VCT level* Charging header flow* Pressurizer level* 3CHS-FR158 and 3CHS-FR160, high range RCP No. 1 seal leakoff flow recorders (MB3)A 3CHS-PI 124, excess lID Hx outlet pressure OP 3353.MB3B Level of UseRe.062 ContinuousRe.06 2

: 4. Using Table 1, EVALUATE plant conditions for the affected RCP, and Go To indicated Step.I Level of Use Continuous III, WI OP 3353.MB3B Rev. 006-02 2-10 5. PERFORM the following:

5.1 TRIP reactor.5.2 STOP affected reactor coolant pumps.5.3 WHEN affected RCP has been tripped for between 3 and 5 minutes, CLOSE affected RCP No. 1 seal leakoff isolation valve.5.4 Go To E-0, "Reactor Trip or Safety Injection." 6. Go To AOP 3554, "RCP Trip or Stopping an RCP at Power," and INITIATE actions to perform an immediate RCP shutdown.7. PERFORM the following to remove affected RCP from service within 8 hours: 7.1 IF reactor power is greater than 25%, Refer To OP 3204, "At Power Operation," and COMMENCE an orderly plant shutdown while continuing with this step.7.2 IF reactor power is less than or equal to 25%, Refer To OP 3206, "Plant Shutdown," and COMMENCE an orderly plant shutdown while continuing with this step.7.3 IF, at any time, RCP No. 1 seal parameters degrade, IMPLEMENT steps as specified in Table 1.7.4 WHEN in MODE 3, Go To OP 3301D, "Reactor Coolant Pump Operation," and STOP the affected reactor coolant pump.8. PERFORM the following:

8.1 NOTIFY Duty Officer of alarm condition.

8.2 IF "VCT TEMP HI" (MB3A 5-10) is lit, Refer To OP 3353.MB3A 5-10,"VCT TEMP HI." 8.3 REQUEST Engineering Department evaluate continued pump operation.

8.4 IF at any time, affected RCP no. 1 seal parameters degrade, IMPLEMENT steps as specified in Table 1.9. IF total seal return flow from all four RCPs exceeds 16 gpm, Refer To 3TRM-7.4, Section I, "Fire Related Safe Shutdown Components," and PERFORM ACTION 2.Level of Use ,.- OP 3353.MB3B Continuous Rev. 006-02 40 of 97 2-10 SUPPORTING INFORMATION

: 1. Initiating Device (1 of 4) Setpoint 1.1 FY/161 1.1 > 5.7 gpm 1.2 FY/160 1.2 > 5.7 gpm 1.3 FY/159 1.3 > 5.7 gpm 1.4 FY/158 1.4 > 5.7 gpm 2. Computer Points 2.1 CHS-F161*, RCP A No. 1 seal leakoff flow 2.2 CHS-F160*, RCP B No. 1 seal leakoff flow 2.3 CHS-F159*, RCP C No. 1 seal leakoff flow 2.4 CHS-F158*, RCP D No. 1 seal leakoff flow 2.5 CHS-T172, RCP 1 No. 1 seal inlet temperature 2.6 CHS-T173, RCP 1 No. 1 seal inlet temperature 2.7 CHS-T170, RCP 2 No. 1 seal inlet temperature 2.8 CHS-T171, RCP 2 No. 1 seal inlet temperature 2.9 CHS-T168, RCP 3 No. 1 seal inlet temperature 2.10 CHS-T169, RCP 3 No. 1 seal inlet temperature 2.11 CHS-T166, RCP 4 No. 1 seal inlet temperature 2.12 CHS-T167, RCP 4 No. 1 seal inlet temperature

: 3. Possible Causes 3.1 Loss of seal injection 3.2 Seal injection water high temperature 3.3 RCP No. 1 seal damage 3.4 RCP No. 1 seal ring mispositioned

: 4. Procedures 4.1 E-0, "Reactor Trip or Safety Injection" 4.2 OP 3204, 'At Power Operation" 4.3 OP 3206, "Plant Shutdown" 4.4 AOP 3554, "RCP Trip or Stopping and RCP at Power" 4.5 OP 3353.MB3A, "Main Board 3A Annunciator Response" 5. Control Room Drawings 5.1 ESK 10HB 5.2 LSK 26-2.6B Level of Use O 3353.MBoB Rev. 006 -02 Continuous 4 f9 ES-401 Written Examination Question Worksheet Form ES-401-6 Examination Outline Cross-reference:

Question # 8 Tier# 1I Group # I K/A # W/EIO.EK1.02 Importance Rating 3.6 Proposed Question: What strategy is used in ES-0.4, "Natural Circulation with Steam Void in Vessel (without RVLMS)," to prevent excessive void growth?A. During RCS depressurization steps where void growth is possible, RCS temperature is held constant, and charging and letdown flows are equalized.

B. During RCS cooldown steps where void growth is possible, RCS pressure is held constant, and charging and letdown flows are equalized.

C. RCS Cooldown rate is limited to 50'F/hr based on WR cold leg temperature.

D. RCS subcooling is limited to a minimum of 1 32TF based on core exit TCs.Proposed Answer: A Explanation (Optional): "A" is correct, since void growth occurs during depressurization steps when RCS pressure drops less than saturation pressure for head temperature.

With charging and letdown matched, all PZR level increases are due to void growth, and PZR level it kept < 91%. "B" is wrong, since during cooldown steps, PZR level is maintained stable via charging to make up for shrinkage. "C" is wrong, since cooldown rate limit in ES-0.4 is 80 0 F/hr. "C" is plausible, since ES-0.2 "Natural Circulation Cooldown" limits cooldown rate to 50'F/hr to prevent void formation. "D" is wrong, since subcooling is maintained via discrete cooldown depressurization steps in ES-0.4. "D" is plausible, since ES-0.2 limits subcooling to 132 0 F to prevent void formation.

ES-0.4, steps 12-15 Proposed references to be provided to applicants during examination:

None Learning MC-05943 Describe the major action categories within EOP 35 ES-0.4, Natural Circulation Cooldown Objective:

with Steam Voids in Vessel (w/o RVLMS).Question Source: Bank # 67599 Question Cognitive Level: Memory or Fundamental Knowledge 10 CFR Part 55 Content: 55.41.8, 41.10 Comments: 41 Of 46 NUREG-1021, Revision 8, Supplement 1

NATURAL CIRCULATION EOP 35 ES-0.4 Page 12 of 18 COOLDOWN WITH STEAM VOID Rev. 011 IN VESSEL (WITHOUT RVLMS)STP ACTION/EXPECTED RESPONS RESPONSE NOT OBTAINED I NOTE To continue overall system depressurization, it may be necessary to cycle PZR level (pressure) to enhance upper head cooling.12. Check PZR Level -LESS THAN 90%Perform the following:

I a. Increase RCS pressure 100 psi using PZR heaters.b. Return to step 11.13. Decrease RCS Hot Leg WR Temperatures To 400'F-a. Maintain cooldown rate in RCS cold legs -LESS THAN 800F/hr b. Maintain RCS pressure -STABLE c. Maintain RCS temperature and pressure in the acceptable operation region of Technical Specification Figure 3.4-3, RCS Cooldown Limitations

-LESS THAN 400 0 F e. Return to step 13.a.f. Stop RCS cooldown NATURAL CIRCULATION EOP 35 ES-0.4 Page 13 of 18 COOLDOWN WITH STEAM VOID Rev. 011 IN VESSEL (WITIHOUT RVLMS)ACTIOIEXPCTEDRESPNSEHRESPONSE NOT OBTAINEDl14. Equalize Charging And Letdown Flows a. Place charging controls in manual b. Adjust charging and seal injection flows to equal letdown and seal leakoff flows 15. Depressurize RCS-a. Verify letdown -a. Perform the following:

IN SERVICE 1) OPEN one PZR PORV.2) Depressurize the RCS until one of the following is satisfied:

* RCS pressure is LESS THAN 650 psia OR* PZR level is GREATER THAN 90%3) CLOSE the PORV.4) Proceed to step 16.b. Unlock and OPEN auxiliary spray valve (3RCS*AV8145)

_ c. CLOSE charging header loop isolation valves* 3CHS*AV8146

* 3CHS*AV8147 NATURAL CIRCULATION EOP 35 ES-0.4 Page 14 of 18 COOLDOWN WITH STEAM VOID Rev. 011 IN VESSEL (WITHOUT RVLMS)ACTIO/EXPETED RSPON RESPONSE NOT OBTAINEDl15. (continued)

: d. Throttle the charging flow control valve to adjust and maintain auxiliary spray flow e. Check REGEN HX e. Proceed to step 15.g. and, LETDOWN TEMP HI (395 F) (MB3A 5-4) IF the annunciator actuates, annunciator

-LIT THEN Perform step 15.f.f. OPEN one charging header loop isolation valve g. Depressurize RCS until one of the following conditions is satisfied:

LESS THAN 90Yol a. Increase RCS pressure 100 psi using the PZR heaters.b. Return to step 15.

Question #Tier #Group #K/A #Importance Rating 9 I 024.AK2.04 2.5 Proposed Question: With the plant at 100% power, the following sequence of events occurs: 1. An unexplained positive reactivity addition event occurs.2. The crew enters AOP 3566 "Immediate Boration".

: 3. The RO reports that neither boric acid pump will start.4. The RO opens both gravity feed boration valves.5. The RO reports that net charging flow (Charging

-RCP Seal Return) is 80 gpm.What action is the crew required to take?A. Open emergency boration valve 3CHS*MV8104.

B. Decrease net charging flow to less than 75 gpm.C. Throttle open the charging line flow control valve to increase flow to greater than 100 gpm.D. Open both RWST to charging pump suction valves and one charging header SI valve.Proposed Answer: B Explanation (Optional): "B" is correct since when neither boric acid pump will start, charging flow is limited to < 75 gpm to prevent the loss of charging pump suction due to limited suction source. "A" is wrong, but plausible, since this action is taken if the crew had been able to start a boric acid pump. "C" and "D" are wrong, but plausible, since flow is aligned to the RWST and increased to > 100 gpm if boration flow is < 33 gpm.Technical Reference(s):

AOP 3566, steps I and 3. (Attach if not previously provided)Proposed references to be provided to applicants during examination:

N Learning MC-03961, Describe the major action categories contained within Objective:

AOP-3566, Immediate Boration.Question Source: New Question Cognitive Level: Comprehension or Analysis 10 CFR Part 55 Content: 55.41.7, 41.8 55.43.5 Comments: one (As available) 41 of 46 NUREG-1021, Revision 8, Supplement 1

STP ACTION/EXPECTED RESPONS H RESPONSE NOT OBTAINEDll 1.Initiate Immediate Boration Of RCS a. Check one charging pump -a. START one charging pump.RUNNING b. Align boration path: b. Perform the following:

o 1) OPEN at least one gravity 1) START at least one boric feed boration valve.acid transfer pump 2) Limit net charging flow to 2) OPEN emergency the RCS to LESS THAN boration valve 75 gpm (charging

-RCP seal return).3) CLOSE at least one VCT outlet isolation valve.-c. Check normal charging flow c. Position valves as required.-path aligned: IF the normal charging flow path can NOT be aligned, 1) Charging flow control N valve -THROTTLED Proceed to step 2.OR OPEN 2) Charging header loop isolation valve (3CHS*AV81 4 6 or 3CHS*AV81 4 7) -OPEN 3) Charging header isolation valves (3CHS*MV81 0 6 and 3CHS*MV8105)

-OPEN d. Place charging flow control valve in MANUAL e. Proceed to step 3.

STE ACTION/EXPECTED RESPONS E RESPONSE NOT OBTAINEDl3. Verify Boration Flowl a. Check PZR pressure -a. Check the PZR PORVs and LESS THAN 2350 psia block valves are open.IF the PORVs or block valves are closed, THEN OPEN as necessary until PZR pressure is LESS THAN 2150 psia.b. Adjust boration flow to the b. Perform the following:

RCS -EQUAL TO OR GREATER THAN 33 gpO 1) OPEN at least one RWST to charging pump suction isolation valve.2) IF suction flow path from a BAT is open, THEN Close the flow path.3) CLOSE at least one VCT outlet isolation valve.4) Adjust charging flow to obtain EQUAL TO OR GREATER THAN 100 gpm to the RCS using one of the following:

ES-401 Written Examination Question Worksheet Form ES-401-6 Examination Outline Cross-reference:

Question # 10 Tier # I Group # I K/A # 026.AA2.05 Importance Rating 2.5 Proposed Question: With the plant at 100% power, an "RPCCW SPLY FLOW HI" annunciator is received on MB 1.The crew enters AOP 3561 "Loss of Reactor Plant Component Cooling Water", and the RO reports RPCCW flow rates and surge tank levels are as follows: "A" Train "B" Train Safety Header: 0 gpm 2000 gpm Non-Safety Header: 2000 gpm 2000 gpm CTMT Header: 700 gpm 1450 gpm and increasing Surge Tank Level 92.5% and decreasing (Both trains)Have RPCCW heat exchanger flow limits been exceeded, and what is a potential source of the leak?A. The heat exchanger flow limits have been exceeded.

The code simu- l91;1 lates the neutron kinetics, RCS, pressurizer, pressurizer relief and safety valves, pressurizer spray, steam generator, steam generator safety valves, and feedwater system. The code computes pertinent plant variables including temperatures, pressures, and power level.Four cases are analyzed to demonstrate the plant behavior following a 10 percent step load increase from rated load. These cases are as follows.1. Reactor control in manual with minimum moderator reactivity feedback.2. Reactor control in manual with maximum moderator reactivity feedback.3. Reactor control in automatic with minimum moderator reactivity feedback.4. Reactor control in automatic with maximum moderator reactivity feedback.Based on results from safety analysis performed for complete core of standard fuel, it has been shown that four-loop operation is more limiting than three-loop operation.

For this reason, cases with three loops in operation were not explicitly reanalyzed for the conver-sion to V5H fuel. Results for four and three-loop operation with standard fuel are available for comparison in Appendix 1 5B.For the minimum moderator feedback cases, the core has the least negative moderator temperature coefficient of reactivity and therefore the least inherent transient capability.

For the maximum moderator feedback cases, the moderator temperature coefficient of reactivity has its highest absolute value. This results in the largest amount of reactivity feedback due to changes in coolant temperature.

For the cases with automatic rod control, no credit was taken for AT trips on overtemperature or overpower in order to demonstrate the inherent transient capability of the plant. Under actual operating condi-tions, such a trip may occur, after which the plant would quickly stabilize.

Plant characteristics and initial conditions are further discussed in Section 15.0.3.15S1.MP3 15.1-7 May 19981 MNPS-3 FSAR Normal reactor control systems and engineered safety systems are not required to )-function.

The reactor protection system is assumed to be operable; however, a reactor trip 114ia,l is not encountered for any case due to the error allowances assumed in the set points. No single active failure will prevent the reactor protection system from performing its intended function.The cases which assume automatic rod control are analyzed to ensure that the worst case is presented.

The automatic function is not required.Results Figures 15.1-3 through 15.1-6 illustrate the transient with the reactor in the manual control mode. As expected, for the minimum moderator feedback case there is a slight power increase, and the average core temperature shows a large decrease.

This results in a DNBR which increases above its initial value. For the maximum moderator feedback, manually controlled case there is a much larger increase in reactor power due to the moderator feedback.

A reduction in DNBR is experienced but DNBR remains above the safety analysis limit.Figures 15.1-7 through 1 5.1-10 illustrate the transient assuming the reactor is in the automatic control mode. Both the minimum and maximum moderator feedback cases show that core power-increases, thereby increasing the coolant average temperature and pressurizer pressure above their initial value. For both of these cases, the minimum DNBR (g-,)1 remains above the safety analysis limit.For all cases, the plant rapidly reaches a stabilized condition at the higher power level.Normal plant operating procedures would then be followed to reduce power. Note that due to the measurement errors assumed in the set points, it is possible that reactor trip could actually occur for the automatic control cases. The plant would then reach a stabilized condition following the trip.The excessive load increase incident is an overpower transient for which the fuel tempera-tures rise. Reactor trip does not occur for any of the cases analyzed, and the plant reaches a new equilibrium condition at a higher power level corresponding to the increase.

in steam flow.Since DNB does not occur at any time during the excessive load increase transients, the ability of the primary coolant to rem-ove heat from the fuel rod is not reduced. Thus, the fuel cladding temperature does not rise significantly above its initial value during the transient.

The calculated sequence of events for the excessive load increase incident is shown in Table 15.1-1.15.1.3.3 Conclusions The analysis presented above shows that for a 10 percent step load increase, the DNBR remains above the safety analysis limit; the design basis for DNBR as described in Section 4.4 is met. The plant reaches a stabilized condition rapidly following the load increase.I1l5S1l.MP3 15.1-8 May 1998 MNPS-3 FSAR 15.1.3.4 Radiological Consequences Since no fuel damage is postulated for this transient a specific radiological release l(q-sS9 calculation was not performed.

I 15.1 .4 Inadvertent Opening of a Steam Generator Relief or Safety Valve Causing a Depressurization of the Main Steam System 15.1.4.1 Identification of Causes and Accident Description The most severe core conditions resulting from an accidental depressurization of the main steam system are associated with an inadvertent opening, with failure to close, of the largest of any single steam dump, relief, or safety valve. The analyses performed assum-ing a rupture of a main steam line are given in Section 15.1.5.The steam release as a consequence of this accident results in an initial increase in steam flow which decreases during the accident as the steam pressure falls. The energy removal from the RCS causes a reduction of coolant temperature and pressure.

In the presence of a negative moderator temperature coefficient, the cooldown results in an insertion of positive reactivity.

Assuming a stuck rod cluster control assembly, with off-site power available, and assum-ing a single failure in the engineered safety features system there will be no consequential damage to the core or reactor coolant system after reactor trip for a steam release equivalent to the spurious opening, with failure to close, of the largest of any single steam dump, relief, or safety valve.Accidental depressurization of the secondary system is classified as an ANS Condition II event. See Section 15.0.1 for a discussion of Condition II events.The following systems provide the necessary protection against an accidental depressuri-zation of the main steam system due to the opening of a steam generator relief or safety valve.1. Safety injection system actuation from any of the following:

: a. two out of four pressurizer pressure signals;b. two out of three low steamline pressure signals in a loop.2. The overpower reactor trips (neutron flux and AT) and the reactor trip occurring in conjunction with receipt of the safety injection signal 3. Redundant isolation of the main feedwater lines Sustained high feedwater flow would cause additional cooldown.

Therefore, in addition to the normal control action which closes the main feedwater valves following reactor trip, a safety injection signal rapidly closes all ISS1.MP3 15.1-9 May 19981 ES-401 Written Examination Question Worksheet Form ES-401-6 Examination Outline Cross-reference:

Question #Tier #Group #K/A #Importance Rating 13 1 1 W/EO8.GEN.2.4.18 3.6 Proposed Question: While responding to a pressurized thermal shock (PTS) condition in accordance with FR-P. 1, the Operator is directed to check if ECCS can be terminated.

A. SI flow may have contributed to the RCS cooldown, and may cause excessive cycling of the pressurizer PORVs.B. SI flow may have contributed to thermal stresses in the reactor vessel Thot & Tcold nozzles, and may cause excessive cycling of the pressurizer PORVs.C. SI flow may have contributed to the RCS cooldown, or may prevent a subsequent RCS pressure reduction.

Proposed Answer: C Explanation (Optional):

SI flow may have contributed to the RCS cooldown, and may prevent a subsequent RCS pressure reduction

("C" correct).

Excessive PORV cycling is not the major concern ("A" and "B" wrong), and the vessel downcomer is the area of greatest concern during a PTS event ("B" and "D" wrong).Technical Reference(s):

WOG Bkgd FR-P. 1, step 6 (Attach if not previously provided)Proposed references to be provided to applicants during examination:

None Learning Objective:

MC-04553 Discuss the basis of major procedure steps and/or sequence of steps (As available) in EOP 35 FR-P.1.Question Source: Question Cognitive Level: 10 CFR Part 55 Content: Comments: Bank #65033 Memory or Fundamental Knowledge 55.41.10 41 of 46 NUREG-1021, Revision 8, Supplement 1

STEP DESCRI PTION TABLE FOR FR-P.1 Step 6 STEP: Check If SI Can Be Terminated PURPOSE: To determine if conditions have been, established which indicate that full SI flow is no longer required BASIS: Following SI actuation, RCS conditions may be restored to within acceptable limits for SI termination to be allowed. The combination of a minimum subcooling and sufficient liquid level in the vessel to cover the core represents less restrictive SI termination criteria in this guideline than those present in the ORGs since, for an imminent PTS condition, SI flow may have contributed to the RCS cooldown or may prevent a subsequent reduction in RCS pressure.The subcooling criterion will ensure subcooled conditions and the RVLIS indication ensures the existence of an adequate vessel inventory such that core cooling is ensured. Refer to document SI TERMINATION/REINITIATION in the Generic Issues section of the Executive Volume.If either of the termination criteria are not satisfied, then SI is required to ensure core cooling and should not be terminated.

Most likely the cold leg/downcomer low temperature condition is due to SI water mixing effects and an RCP restart is attempted.

Of the transients considered in PTS, the SBLOCA transient may result in a condition whereby Safety Injection (SI) flow cannot be terminated.

In Westinghouse Owners Group (WOG) reports OG-1lO and OG-117 titled "Evaluation of Alternate RCP Trip Criteria" and "Justification of Manual RCP Trip for J Small Break LOCA Events" respectively, a range of SBLOCAs were identified where continued RCP operation or conversely untimely RCP restart could result in increased RCS inventory loss. The loss of additional inventory could ultimately result in deeper core uncovery transients which could in turn result in fuel cladding temperatures in excess of the plant's design basis FSAR analysis result. Therefore, from a SBLOCA standpoint, RCP restart at an inopportune time could result in a degraded core cooling scenario.In WCAP-10319 titled "A Generic Assessment of Significant Flaw Extension, Including Stagnant Loop Conditions, from Pressurized Thermal Shock of Reactor Vessels on Westinghouse Nuclear Power Plants", numerous transient analyses including those of SBLOCA have been analyzed without RCP restart. The results FR-P.1 27 HP-Rev. IC HFRP1  

---r STEP DESCRIPTION TABLE FOR VR-P.1 Step D BASIS: of the stagnant loop evaluation demonstrate that the total expected frequency of significant flaw extension in a typical W PWR reactor vessel due to PTS, including the contributions from stagnant loop SBLOCA transients, does not exceed the NRC required Up., screening value of 270'F for axial flaws.Therefore, based on analyses results, RCP restart is not required to meet the NRC PTS risk goal for a typical W plant.Therefore, an additional support condition, RCS subcooling, in addition to plant specific minimum support conditions is recommended to assure that no potential RCS inventory aggravation will occur due to RCP restart.An analysis of the effect of an RCP restart has been made to ensure the safety of this action relative to vessel integrity.

For conservatism in the analysis the assumption was made that a small preexisting flaw had grown and arrested at 75 percent of wall thickness before RCP start. Starting an RCP was shown not to result in any further flaw propagation and loss of vessel integrity.

Therefore, in order to mix the cold incoming SI water and the warm reactor coolant water and thereby decrease the likelihood of a PTS condition, an RCP restart is attempted.

Whether an RCP is started or not, the next step performed (Step 24), if SI is still required, provides guidance on subsequent cooldown restrictions.

ACTIONS: o Determine if RCS subcooling (based on core exit TCs) is greater than (R.12)0 F [(R.13)0 F for adverse containment]

o Determine if RVLIS full range indication indicates greater than (K.02) if no RCP running o Determine if RVLIS dynamic head range indicates greater than (L.08) if one RCP running o Determine if RYLIS dynamic head range indicates greater than (L.07) if two RCPs running o Determine if RVLIS dynamic head range indicdtes greater than (L.06) if three RCPs running o Determine if RVLIS dynamic head range indicates greater than (L.05) if four RCPs running o Determine if RCS subcooling (based on core exit TCs) is greater than (R.01)0 F [(R.02)0 F for adverse containment]

o Determine if no RCP is running o Attempt to start one RCP FR-P.1 28 HP-Rev. IC HFRP1 ES-401 Written Examination Question Worksheet Form ES-401-6 Examination Outline Cross-reference:

Question # 14 Tier # 1 Group # 1 K/A # W/E08.EKI.3 Importance Rating 4.0 Proposed Question: A large steam break occurs inside CTMT on the "B" and "C" SGs. Current conditions are as follows:* "A" and "D" SG narrow range levels are 15%* AFW flow is 100 GPM to the "A" and "D" SGs* The "A" and "D" SG "STEAMLINE PRESSURE LO" and "LEVEL LO-LO" annunciators are lit on Main Board 5.* The crew is in FR-P. 1 "Response to Imminent Pressurized Thermal Shock Condition"* RCS temperature and pressure are stable* Only the control group of pressurizer heaters energized The crew has determined a 1 hour soak is required.Which of the following evolutions could be performed by the crew in the next hour?A. Energize additional pressurizer heaters.B. Place auxiliary spray in service.C. Increase AFW flow to 300GPM each to the "A" and "D" SGs.D. Recirc RHR to establish boron concentration and place it in service.Proposed Answer: B Explanation (Optional): "B" is correct, since soak requirements do not prohibit lowering RCS pressure. "A" is wrong since pressure can not be raised, and "C" and "D" are wrong, since temperature can not be lowered.Technical Reference(s):

FR-P. 1, step 23 (Attach if not previously provided)Proposed references to be provided to applicants during examination:

None Learning Objective:

MC-04552 Describe the major action categories within EOP 35 FR-P.l. (As available)

Question Source: 1997 Millstone 3 NRC SRO exam #88 Question History: 1997 Millstone 3 NRC SRO exam Question Cognitive Level: Memory or Fundamental Knowledge 10 CFR Part 55 Content: 55.41.8, 41.10 Comments: 41 of 46 NUREG-1021, Revision 8, Supplement 1  

-RESPONSE TO IMMINENT EOP 35 FR-PE1 Page20f 21 PRESSURIZED THERMAL Rev. 013 SHOCK CONDITION ok RESP~~~~RESPONSESOS NOT OTIE~~NOTE If ECCS flow can NOT be terminated, it is expected that RCS temperature will tend to decrease.23. Determine If RCS Temperature Soak Is Required a. Check cooldown rate in a. Go to procedure and step in any RCS cold leg -effect.GREATER THAN 100 0 F IN ANY 60 minute PERIOD b. Perform the following soak for 1 hr: 1) Maintain RCS temperature GREATER THAN OR EQUAL TO current temperature

: 2) Maintain RCS pressure LESS THAN OR EQUAL TO current pressure 3) Perform the actions of other procedures in effect which do NOT decrease RCS temperature or increase RCS pressure-c. Check RCS 1 hr soak -c. Return to step 23.b.COMPLETED-d. Maintain RCS pressure and cold leg temperature within the limits shown on Attachment A (Attachment B ADVERSE CTMT)  

'D THERMAL Rev. 013 DMON E NOT OBT-4 ACTIONIEXPECTED RE, RESPON itinued)Maintain cooldown rate in RCS cold legs -LESS THAN 50"F IN ANY 60 minute PERIOD;o To Procedure And Step In ffect-FINAL-ES-401 Written Examination Question Worksheet Form ES-401-6 Examination Outline Cross-reference:

Question # 15 (SRO)Tier # 1 Group# I K/A # PLANT SPECIFIC Importance Rating N/A Proposed Question: With the unit at full power, the following sequence of events occurs:* CONVEX orders a load reduction from Millstone Station due to a transmission system emergency.

* Unit 3 is directed to reduce total generation by 760 MWe (to 440 MWe) in the next 15 minutes.* The Crew enters AOP 3575, "Rapid DownpoWer," and commences reducing generator load accordingly.

* The Crew has just initiated the required boration for this load reduction from the BAT tanks.* Direct Boric Acid flow as read on 3CHS-FI183A is 75 gpm.How many gallons of Boric Acid should be added to the RCS to support this load reduction and how long should the boration last?A. Borate approximately 550 gal. of Boric Acid.Boration should last for 7.3 minutes.B. Borate approximately 550 gal. of Boric Acid.Boration should last for 15 minutes.C. Borate approximately 950 gal. of Boric Acid.Boration should last for 12.7 minutes.D. Borate approximately 950 gal. of Boric Acid.Boration should last for 15 minutes.Proposed Answer: C Explanation (Optional):

Per Step I of AOP 3575 all CONVEX requested load reductions shall be performed at 5%/omin. Step 5 has the operator borate using a BAT pump via MV8104 from the BAT tanks. The total amount of boration per Step 5.h is: Total Boration (gal) = [Total Power Change (A%/o)] x [ 15(gal/%/o)

I Total Boration (gal) = [(760 MWe)/120 0 MWe x 100% ] x [ 15 gal/% ] = 950 gal. of Boric Acid. Per Step 5.i the boration should last for: Time = [Total Boration (gal)] / [Direct Boric Acid Flowrate (gpm)]. Time = [ 950 gal. ] / [75 gpm ] = 12.7 min. "C" is correct. All others are incorrect.

550 gallons is plausible since this is the value obtained if the calculation is performed using the final power level of 440 MWe, rather than the change in power. 15 minutes is plausible since this is the time in which the crew is requested to complete the downpower.