EOP

Question 1

What is adverse containment?

Answer 1

5 psig

10E5 R/hr

During ELAP Unit PRZ and SG temps verified below 196.8*F

Question 2

If rad levels exceed 10E5 R/hr and eventually come back down, do you still have to use adverse containment values?

Answer 2

YES, until evaluated for integral dose

Question 3

What is the order of priority of the Critical Safety Functions?

Answer 3

Subcriticality

Core Cooling

Heat Sink

Integrity

Containment

Inventory

Question 4

Which CSFs require continuous monitoring?

Answer 4

Red or Orange

Question 5

What are the fission product barriers?

Answer 5

Fuel Cladding

RCS

Containment

E-Plan

Question 6

What are the methods of heat removal for a SBLOCA?

Answer 6

ECCS Flow / Breaker Flow

AFW / SGs

Question 7

Why is a CL Break considered the worst scenario for a SBLOCA?

Answer 7

More mass is lost prior to ECCS flow equaling break flow. The cross under loop seal must be clear before steam can be vented from the break

Question 8

What are indications of a faulted SG?

Answer 8

Tave lowers

Rx Power Rises

Possible turbine load lowering

SF > FF

Question 9

What are indications of SGTR?

Answer 9

SJAE / GSLO Rad monitors high

SG Level rising uncontrollably

PRZ Pressure and Level Lowering

Question 10

What are indications of a LOCA?

Answer 10

Containment Rad Monitor & Dew Point rising

PRZ Level and Pressure lowering

Question 11

What is the SI Termination Criteria found in ES-1.1

Answer 11

Subcooling > 40*F

Heat Sink by SG level >13% OR > 240K ppm

RCS Pressure stable / rising

PRZ Level 16% (20%)

Question 12

What does meeting your SI termination subcooling criteria tell you?

Answer 12

Adequate core cooling and secondary heat sink

Question 13

What does meeting your heat sink SI termination criteria tell you?

Answer 13

Ensure subcooling will be maintained following termination

Question 14

What does meeting your RCS Pressure SI Termination criteria tell you?

Answer 14

Ensures subcooling will be stable / rising and SI flow is effective in raising RCS Inventory

Question 15

What does meeting your PRZ Level SI Termination Criteria tell you?

Answer 15

Sufficient RCS Inventory

Only valid if RC is subcooled

Ensures ability to maintain pressure following termination

Question 16

Why do RCPs need to be tripped on a phase B?

Answer 16

Loss of CCW flow to RCP LO Coolers

Question 17

Where do you transition from in E-0 if a Rx Trip is not successful?

Answer 17

FR-S.1

Question 18

What is the order of diagnostic transitions in E-0 and why ?

Answer 18

E-2, easy to find/fix and can mask other issues

E-3, stops offsite dose. Lots of TCAs

E-1, auto actions can handle it

Question 19

In E-0, why do we lower AW to < 450K pph?

Answer 19

Limits overcooling the RCS

Question 20

In E-0, why is the minimum AFW 240K pph until the minimum SG water level is maintained?

Answer 20

ENsures enough FW flow for decay heat removal. Also, min # for Heat Sink CSF Status Tree

Question 21

What are the entry conditions for ES-0.0, Rediagnosis?

Answer 21

ALL of the following:

SI is I/S or Required

E-0 has been exited

E-Series procedure in progress

Question 22

What must be done after a reactor trip for each control rod not fully inserted?

Answer 22

Borate 160 (150) ppm for each rod

Question 23

If in ES-0.1, Reactor Trip Response, what do you do if you get an SI?

Answer 23

Return to Step 1 of E-0

Question 24

Why would you transition from ES-0.2, Natural Circ Cooldown to ES-0.3, NC Cooldown w Steam Void?

Answer 24

If CST Inventory is low

After LOOP when a high rate of planned Cooldown and depressurization is required due to reduced CST inventory

Question 25

What removes most of the heat from the head on NC?

Answer 25

CRDMs

Question 26

In ES-0.3, Natural Circ Cooldown with Steam odd, when should you not try to start an RCP?

Answer 26

If cooling had been previously lost

Question 27

In ES-0.3, NC Cooldown w steam void, why is it required to raise PRZ Level to 84% prior to starting a RCP?

Answer 27

Ensures PRZ level doesn’t lower causing a loss of subcooling when the RCP is started due to void collapsing / lowering PRZ level

Question 28

What are the benefits of restarting RCPs?

Answer 28

Enhances core heat removal

Improves RCS Pressure and Temp Control

Improves PRZ Level Control

Question 29

Which RCP is the most effective?

Answer 29

3 bc it has the most dP

Question 30

What are the 3 factors affecting spray flow?

Answer 30

Vessel and RCS piping DP

Coolant Velocity head at spray flow scoop located at spray flow penetration in CL

PRZ Level

Question 31

What are the indications of NC?

Answer 31

Subcooling ? 40*F

Stable or Lowering:

• SG Pressures
• CETCs
• RCS HL Temps

RCS CL Temps at saturation temp for SG Pressure

Question 32

What should be done if NC cannot be verified?

Answer 32

Raise steam dump flow

Question 33

For a SBLOCA, why is 1300# trip criteria?

Answer 33

Ensures RCPs are stopped before the break is uncovered so no additional mass is lost

Question 34

Why is CCW to RHR adjusted to 5,000 gpm during CL Recirc?

Answer 34

Prevents pump Runout if 1 pump fails

Question 35

When is RHR Spray placed in service?

Answer 35

50 mins (allows decay heat removal) - 70 mins (containment peak pressure)

Question 36

What are the 10CFR100 Limits at the site boundary?

Answer 36

25 REM Whole Body, 300 REM Thyroid for 2 hours

Question 37

While in ES-1.1, SI termination, what if you are unable to maintain 40*F subcooling and PRZ LeveL?

Answer 37

Go to E-1 bc there must be another issues. If you just add another CCP back on, you’d meet the SI Termination Criteria again

Question 38

For a Faulted SG, when will you have a SI?

Answer 38

Upstream of the MSIVs for a steam break or downstream of check valve for a feed break.

Question 39

In E-2, faulted SG Isolation, why will AFW have to be periodically reduced to maintain SG Levels after RCS Temp is stabilized?

Answer 39

Lowering Decay Heat Levels

Question 40

In E-2, Faulted SG Isolation, why do we control AFW Flow?

Answer 40

Prevent SG Dryout

Minimize RCS Cooldown

Prevent SG Overfill

Control RCS Temp after Cooldown is stopped

Question 41

During E-3, SGTR, why do we want to terminate SI?

Answer 41

Helps control primary to secondary leakage

Question 42

What could be a potential problem if the SG is overfilled during a SGTR?

Answer 42

Rupture of MS Line from weight of the water

Damage to PORVs, Safeties and TDAFP

Question 43

During a SGTR, what is the affected SG PORV set point changed to and why?

Answer 43

1040 psig to minimize the release

Question 44

Why do we ensure the ruptured SG level reaches 13% before isolated AFW to it?

Answer 44

To ensure SG Tubes are covered, which will prevent depressurization

Question 45

What does the UFSAR assume for a SGTR?

Answer 45

Operator actions are taken to isolate ruptured SG efficiently

Question 46

What are the advantages and disadvantages of ES-3.1, Cooldown using backfill?

Answer 46

+ Minimizes radiological releases and allows processing of RCS

• Potential boring dilution, secondary chemistry effects on RCS, Slow

Question 47

What are the advantages and disadvantages of using ES-3.2, Cooldown using blowdown?

Answer 47

+ Minimizes radiological releases, NO boron dilutions or chemistry effects

• storage / processing capabilities, spreads contamination, SLOW

Question 48

What are the advantages / disadvantages of using ES-3.3, cooldown using steam dump method?

Answer 48

+ FAST

• Contamination / radiation, potential water hammer on secondary components.

Question 49

When would you transition back to E-2 from ECA-2.1, Uncontrolled depressurization of all SGs?

Answer 49

If any SG pressure boundary is restored, except while performing SI Term steps 10-20

Question 50

During ECA-2.1, what is AFW lowered to and why?

Answer 50

25K per SG to prevent boiling dry and minimize thermal shock effects if FF is later raised

Question 51

What is the minimum DP that should be maintained between the ruptured and intact SGs?

Answer 51

250#

Question 52

When would you enter ECA-3.1, SGTR w loss of RC, subcooled recovery?

Answer 52

Cannot isolate ruptured SG from any intact SGs

Faulted and Ruptured SG

Min DP cannot be maintained

SGTR w LOCA

Question 53

When would you transition from ECA-3.1 to ECA-3.2, SGTR w Loss of RC, saturated Recover?

Answer 53

RWST level is low with NO corresponding rise in Containment water level

Question 54

What are the immediate actions for FR-S.1?

Answer 54

1. Trip Rx
2. Insert Rods > 48 spm
3. Manually actuate AMSAC
4. Trip Turbine
   
   • ATWS Runback
   • MSICs close

Question 55

What is the purpose for tripping the turbine in FR-S.1?

Answer 55

Prevents excessive cooldown and conserves SG Water

Question 56

Why do you NOT trip RCPs if power is >5%?

Answer 56

Provides core cooling and keeps fuel integrity in tact

Question 57

Is an ATWS worse at BOL or EOL?

Answer 57

BOL due to less temperature feedback

Question 58

Why is RCS pressure checked less than PRZ PORV setpoint in FR-S.1?

Answer 58

ensures ability to emergency borate

Question 59

What is the minimum AFW flow during ATWS?

Answer 59

450K LBLOCA until 13% NR Level

Question 60

How could an unneeded SI complicate an ATWS?

Answer 60

FWI and MFPs will trip which will mean SGs could dryout

Question 61

What are the possible ways to lose subcriticality during an ATWS?

Answer 61

Dilution

Cooldown

Rods do not fully insert

Question 62

Is it necessary to have adequate SDM to exit from FR-S.2?

Answer 62

No, however a boration is expected to be continued after the transition to ensure adequate SDM

Question 63

What containment pressures put you into a red and orange path for Containment CSF?

Answer 63

Red - 12 psig

Orange - 2.8 psig

Question 64

While in ECA-1.2, LOCA Outside of containment, what is the indication that your leak has been isolated?

Answer 64

RCS Pressure Rising

Question 65

Why does ECA-1.1, Loss of emergency coolant recirc, direct depressurizing the SGs to 670 psig?

Answer 65

To prepare for a controlled accumulator injection to keep the core covered

Question 66

What are the assumptions concerning the LBLOCA analysis?

Answer 66

Some zirc-water reaction is expected

ECCS flow to the faulted loop and the accumulator injection for that loop spills to containment

RHR pumps must not be aligned for spray prior to 50 mins after the onset to ensure decay heat levels are within the heat removal capability of 1 CCP and 1 SI pump

Core safety could be challenged if RHR and CTS flow is interrupted for more than 5 mins while transferring over to CL Recirc

Question 67

What is the EOP basis for tripping the turbine in FR-S.1 when there is a loss of MFPs but no reactor trip?

Answer 67

Maintain/Extend SG Inventory

Question 68

When should you not restart RCPs for ES-1.2, Post LOCA Cooldown and Depressurization?

Answer 68

When all seal cooling has been lost long enough that maximum RCP seal parameters have been exceeded. Instead, cool the RCS to reduce temp of the water flowing thru the pump seals

This removes the potential thermal shock damage to the seals

Question 69

While in ES-1.2, Post LOCA Cooldown and Depressurization, you’re doing ECCS flow reduction. You’re ready to stop the first CCP. RCS Subcooling exactly meets subcooling table requirements. After you stop the pump, what do you expect?

Answer 69

Subcooling will lower to the minimum required value then recover with the cooldown

Question 70

In ECA-1.1, Loss of Emergency Coolant, what is the basis for cooling the RCS at a maximum cooldown rate (after a LOCA outside containment that has not been isolated)

Answer 70

The cooldown rate will minimize offsite releases due to the event by reducing the need for supporting systems and equipment

Question 71

If we have inadequate core cooling, what could happen?

Answer 71

Core uncovers

Fuel damage could occur

Question 72

What are the red path entries into FR-C.1?

Answer 72

5 highest CETs all > 1200*F

RVLIS NR < 46% with all 5 highest CETs > 757F with no RCPs running and SC < 40F

Question 73

What’s the most effective strategy of FR-C.1?

Answer 73

Establish ECCS Flow

Question 74

What are the 4 Major Action Categories of FR-C.1?

Answer 74

Establish ECCS Flow

Rapidly Depressurize SGs to Depressurize RCS

Start RCPs

Open all RCS Vent Paths to containment

Question 75

What is the purpose of rapidly Depressurize go SGs in FR-C.1?

Answer 75

Allows accumulator and RHR pump injection

Question 76

In FR-C.1, when would you not start a RCP?

Answer 76

If SG depressurization was ineffective due to loss of heat sink bc creep failure of the SG tubes

Question 77

In FR-C.1, would you start RCPs without support conditions?

Answer 77

YES! Start 1 RCP at a time until CETCs are < 1200*F

Question 78

What do CET temps of 757*F indicate?

Answer 78

Superheated core exit

Question 79

Why is a 1” SBLOCA the worst scenario for FR-C.1?

Answer 79

Loop seal never clears, so steam mass loss rate out the break isn’t reduced.

Question 80

What is indicative of superheated conditions?

Answer 80

High CETCs

Question 81

What is indicative of core uncovery?

Answer 81

Low RVLIS

Question 82

What is significant about 46% RVLIS level?

Answer 82

COre covered…. 3.5 ft from bottom of core

Question 83

Why are RCPs stopped in FR-C.1 after SGs are Depressurize to 160 psi?

Answer 83

Loss of #1 seal requirements

Question 84

Why are RCPs so important in FR-C.1?

Answer 84

They provide forced 2 phase flow to prevent inadequate core cooling

Question 85

In FR-C.2, if all RCPs are running, what must be done?

Answer 85

Stop #3 for later use

Question 86

What are the Major Action Categories for FR-H.1?

Answer 86

Attempt to restore FF to SGs

Initiate RCS Bleed and Feed

Restore and verify Heat Sink

Terminate RCS Bleed and feed

Question 87

When would the secondary heat sink not be required?

Answer 87

LBLOCA

RCS Temp <350*F bc RHR can be used

Question 88

What must be done during FR-H.1 if NO CCPs are available?

Answer 88

Stop all RCPs and initiate feed and bleed immediately to Depressurize to SI pressure

Question 89

How can you tell if secondary heat sink has been restored?

Answer 89

Lowering RCS Temps and rising SG Level

Question 90

What are the feeding guidelines after bleed and feed initiation per FR-H.1 FOP if CETCs are rising?

Answer 90

1. Feed any SGs that are NOT dry at max Rate
2. If ALL SGs are dry, feed 1 SG at max rate. When CETCs lower, check for fault or rupture. IF it is, then establish FF to INTACT SG at < 50E3 ppm

Question 91

What are the feeding criteria after bleed and feed initiation in FR-H.1 if CETCs are stable or lowering?

Answer 91

Feed any SGs that are not dry as necessary to restore NR level

If all SGs are try, then feed 1 SG at a time less than 50E3 ppm.

Question 92

What is considered a dry SG?

Answer 92

WR < 17%

Question 93

If SI termination criteria is not satisfied in FR-P.1, what should be done?

Answer 93

Start RCP to mix ECCS flow w RC to minimize thermal stresses not he vessel and then soak for 1 hr

Question 94

What is looked at for SI Termination criteria in FR-P.1?

Answer 94

Less Restricitive

SC > 90*F and RVLIS Level

Question 95

What is the operator error assumption made in FR-P.1 to make a PTS concern possible?

Answer 95

SI termination is delayed 30 mins

Question 96

In FR-P.1, how long do you soak and when does the clock start?

Answer 96

1 hr when temps is stable

Question 97

What is the cooldown limit in FR-P.1 after the soak?

Answer 97

50*F/hr

Question 98

How can you exit FR-P.1 without any actions?

Answer 98

RCS Pressure < 300# and RHR Flow > 400 gpm

LBLOCA

Question 99

Is a cooldown or heatup more limiting for RCS Integrity and why?

Answer 99

Cooldown bc of tensile stress on the inner wall

Question 100

What’s the worst case PTS accident and why?

Answer 100

3” SBLOCA when both RCS forced flow and NC are lost and cold RWST water streams to vessel belt line welds.

Question 101

What is the cooldown rate in FR-P.1?

Answer 101

100*F per hour

Question 102

WHat should have happened before implementing FR-P.2, yellow path?

Answer 102

SI should have been terminated

Question 103

When would you not perform FR-I.1?

Answer 103

SI is in service and needed

Question 104

In FR-H.1, what must be done if less than 2 PORV flow paths are open or CETCs are rising?

Answer 104

Use additional vent paths…. NSOs

Question 105

What is the preferred order of the secondary heat sink sources?

Answer 105

AFW own unit
AFW cross tie
MFP
Condensate

Question 106

What’s key to determine if you have Nat Circ?

Answer 106

Large Delta T

Question 107

What are the benefits of feed and bleed?

Answer 107

Minimize core uncovery and prevent inadequate core cooling

Question 108

When is an ATWS worse?

Answer 108

BOL due to less feedback from a smaller MTC

Question 109

During an Emergency Remote Shutdown, how is Pressurizer Pressure Controlled?

Answer 109

On Safeties….. PRZ Block Valves should be closed

Question 110

What is the minimum that must be done before evacuating the control room?

Answer 110

Rx and Turbine should be tripped

Question 111

Should equipment placed I/S by EOPs be stopped by SACRGs?

Answer 111

Only if SACRG stops it or TSC recommends it

Question 112

What would be a RED path on FR-Z.1, Response to High Containment Pressure?

Answer 112

> 12 psig

Question 113

What would be an orange path on FR_Z.1, Response to High Containment Pressure?

Answer 113

> 2.8 psig

Question 114

When would RHR Spray be placed in service per FR-Z.1? Why this time?

Answer 114

50 mins after the accident with < 2 CTS Pumps I/S.

Low enough decay heat for 1 CCP and 1 SI Pump to handle

Question 115

What are the normal sources of water that are accounted for in FR-Z.2, Response to Containment Flooding?

Answer 115

RCS

RWST

Accumulators

Ice Bed Melt

LOCA / Secondary Break

Question 116

What are the modes of applicability for ECA-0.0?

Answer 116

Modes 1-4

Question 117

While attempting to restore power during ECA-0.0, which pump switches would you not take to PTL?

Answer 117

ESW to ensure EDG Cooling

Question 118

When would you transition out of ECA-0.0 without getting power back?

Answer 118

CETs > 1200*F, go to SACRG-1

Question 119

How many SDGs must be running in ECA-0.0 to start recovery actions?

Answer 119

2

Question 120

What would meet entry into the ECA-0.1 recovery path? (SI not required)

Answer 120

SC > 40*F

PRZ Level > 16 (20)%

ECCS Pumps not providing Flow

Question 121

What’s the criteria for entry into ECA-0.2, SI Require recovery?

Answer 121

SC <= 40*F

PRZ Level <= 16 (20)%

ECCS Pumps providing Flow

Question 122

What happens if steam voids for in the SG U-tubes during ECA-0.0 ?

Answer 122

NC will stop bc steam is preventing fluid flow (poor heat transfer)

Question 123

What’s the purpose of Secondary Depressurization in ECA-0.0?

Answer 123

Minimizes inventory loss thru RCP Seals to extend time to core uncovery

Question 124

During ECA-0.0, why would we not re-establish Seal Injection Flow after a prolonged lack of flow?

Answer 124

Prevents cracking he seals or warping the shaft

Question 125

If CCW is lost for an extended period of time due to a loss of power, how do we re-establish cooling to the RCPs?

Answer 125

Performed a cooldown, to cool the seals

Question 126

During a loss of all AC Power, ECA-0.0 directs the operators to do what to control CR Temperature ?

Answer 126

Open cabinet doors within 30 mins

Question 127

While recovering from a loss of all AC Power, why may a BAT Pump be use to pressurize the CCP Suction?

Answer 127

High VCT Temp

NPSH

Question 128

Where would you transition to when complete with ECA-0.1, Loss of All AC Power Recovery without SI Required?

Answer 128

ES-0.2, Nat Circ Cooldown

Question 129

Where would you transition to when complete with ECA-0.2, Loss of All AC Power Recovery with SI Required?

Answer 129

E-1, Loss of Reactor or Secondary Coolant

Question 130

What is the difference between a small and intermediate break in E-2?

Answer 130

Small Break - MFW System maintains SG Level

Inter Break - Rx trip will occur ~ 5 mins

Question 131

Why will AFW need to be reduced as time passes after a faulted SG Depressurizes all the way?

Answer 131

Lower decay heat levels