Containment Building

Question 1

LCO 3.3.3 “ESF Instrumentation” requirement

Answer 1

4 ESF bistables and associated instrument channels for CHP (3.7-4.3 psig) and CHR (<= 20 R/hr) shall be operable.

Question 2

LCO 3.3.3 “ESF Instrumentation” applicability for CHP/CHR

Answer 2

Modes 1-4

Question 3

LCO 3.3.4 “ESF Logic and Manual Initiation” requirement

Answer 3

2 ESF manual and 2 ESF actuation logic channels and associated bypass removal channels shall be operable for CHP and CHR.

Question 4

LCO 3.3.4 “ESF Logic and Manual Initiation” applicability for CHP/CHR

Answer 4

Modes 1-4

Question 5

LCO 3.3.6 “Refueling CHR Instrumentation” requirement

Answer 5

2 refueling CHR auto actuation function channels and 2 CHR manual actuation function channels shall be operable.

Question 6

LCO 3.3.6 “Refueling CHR Instrumentation” applicability

Answer 6

During core alterations and during movement of irradiated fuel assemblies within containment

Question 7

LCO 3.3.6 “Refueling CHR Instrumentation” required actions if 1 or more functions with 2 channels inoperable

Answer 7

IMMEDIATELY suspend core alterations and movement of irradiated fuel assemblies within containment

Question 8

LCO 3.3.7 “PAM Instrumentation” requirement

Answer 8

The PAM Instrumentation for Containment Pressure (Wide Range, 2 channels req’d), Containment Isolation Valve Position (1 per valve), and Containment Area Radiation Monitor (High Range) shall be operable

Question 9

LCO 3.3.7 “PAM Instrumentation” applicability

Answer 9

Modes 1-3

Question 10

LCO 3.6.1 “Containment” requirement

Answer 10

Containment shall be operable

Question 11

LCO 3.6.1 “Containment” applicability

Answer 11

Modes 1-4

Question 12

LCO 3.6.1 “Containment” required actions if containment is inoperable

Answer 12

WITHIN 1 HOUR, restore containment to operable status.

Question 13

LCO 3.6.2 “Containment Air Locks” requirement

Answer 13

2 containment air locks shall be operable

Question 14

LCO 3.6.2 “Containment Air Locks” applicability

Answer 14

Modes 1-4

Question 15

LCO 3.6.2 “Containment Air Locks” notes/exceptions

Answer 15

• Entry/exit is permissible through a “locked” air lock door to perform repairs on the affected air lock components
• Separate condition entry is allowed for each air lock
• Enter applicable conditions and required actions of LCO 3.6.1 “Containment” when leakage results in exceeding the overall containment leakage rate acceptance criteria

Question 16

LCO 3.6.2 “Containment Air Locks” required actions if 1 or more air locks with 1 or more air lock door inoperable

Answer 16

WITHIN 1 HOUR verify the operable door is closed in the affected air lock

Question 17

LCO 3.6.2 “Containment Air Locks” required actions if 1 or more air locks with interlock mechanism inoperable

Answer 17

WITHIN 1 HOUR verify an operable door is closed in the affected air lock

Question 18

LCO 3.6.2 “Containment Air Locks” required actions if 1 or more air locks inoperable for reasons other than a door or interlock mechanism inoperable

Answer 18

IMMEDIATELY initiate action to evaluate overall containment leakage rate per LCO 3.6.1
AND
WITHIN 1 HOUR verify a door is closed in the affected air lock.

Question 19

LCO 3.6.3 “Containment Isolation Valves” requirement

Answer 19

Each containment isolation valve shall be operable

Question 20

LCO 3.6.3 “Containment Isolation Valves” applicability

Answer 20

Modes 1-4

Question 21

LCO 3.6.3 “Containment Isolation Valve” notes/exceptions

Answer 21

• penetration flow paths, except for 8” purge exhaust valves and 12” air room supply valves penetration flow paths, may be unisolated intermittently under admin controls
• separate condition entry is allowed for each penetration flow path
• enter applicable conditions and required actions for system(s) made inoperable by containment isolation valves
• enter applicable conditions and required actions of LCO 3.6.1 “Containment” when leakage results in exceeding overall containment leakage rate acceptance criteria

Question 22

LCO 3.6.3 “Containment Isolation Valves” required actions if 1 or more penetration flow paths with 2 isolation valves inoperable (except for purge exhaust valve or air room supply valve not locked closed)

Answer 22

WITHIN 1 HOUR isolate the affected penetration flow path by use of at least 1 closed and de-activated automatic valve, closed manual valve, or blind flange

Question 23

LCO 3.6.3 “Containment Isolation Valves” required actions if 1 or more purge exhaust or air room supply valves not locked closed

Answer 23

WITHIN 1 HOUR lock closed the affected valves

Question 24

LCO 3.6.4 “Containment Pressure” requirement

Answer 24

Containment pressure shall be <= 1 psig in Modes 1-2, and <= 1.5 psig in Modes 3-4

Question 25

LCO 3.6.4 “Containment Pressure” applicability

Answer 25

Modes 1-4

Question 26

LCO 3.6.4 “Containment Pressure” required actions if containment pressure not within limit

Answer 26

WITHIN 1 HOUR restore containment pressure to within limit

Question 27

LCO 3.6.5 “Containment Air Temperature” requirement

Answer 27

Containment average air temperature shall be <= 140 F

Question 28

LCO 3.6.5 “Containment Air Temperature” applicability

Answer 28

Modes 1-4

Question 29

LCO 3.9.3 “Containment Penetrations” requirement

Answer 29

• equipment hatch closed and held in place by 4 bolts (only required to be closed when fuel handling area ventilation system is not in compliance with LCO 3.7.12)
• 1 door in the personnel air lock closed (only required when the equipment hatch is closed)
• 1 door in the emergency air lock closed
• each penetration providing direct access from containment atmosphere to outside atmosphere either closed by a manual or auto isolation valve, blind flange, or equivalent; or capable of being closed by an operable refueling CHR signal

Question 30

LCO 3.9.3 “Containment Penetrations” applicability

Answer 30

During core alterations and during movement of irradiated fuel assemblies within containment

Question 31

LCO 3.9.3 “Containment Penetrations” required actions if 1 or more containment penetrations not in required status

Answer 31

IMMEDIATELY suspend core alterations and movement of irradiate fuel assemblies within containment

Question 32

What are containment building design features/specs?

Answer 32

• capable of withstanding the internal pressure from a DBA with no loss of integrity.
• designed to allow a leak rate of no more than 0.1 weight percent/day at 55 psig and 283 F.

Question 33

What are design features of the air locks that help ensure containment integrity?

Answer 33

• doors open into containment, so during an accident, high containment pressure will force the doors closed to aid in isolation.
• doors are interlocked so only 1 can be opened at a time so there can’t be a “hole” in containment.
• designed such that 1 door can withstand containment design pressure

Question 34

What is the admin limit on containment temperature?

Answer 34

130 F with TE-1815

135.96 with PPC

Question 35

What is the tech spec limit on containment temperature?

Answer 35

140 F

Question 36

What controls containment temperature?

Answer 36

Containment Air Coolers

Question 37

What is the admin limit on containment pressure?

Answer 37

Modes 1-2 - < 0.85 psig

Modes 3-5 - 1.35 psig

Question 38

What is the tech spec limit on containment pressure?

Answer 38

Modes 1-2 - < 1 psig

Modes 3-4 - < 1.5 psig

Question 39

How is containment pressure maintained?

Answer 39

Vented through ‘D’ CWRT to the stack through either the exhaust plenum or VGCH.

Question 40

Containment humidity relationship

Answer 40

• humidity is a function of temperature, so as temperature goes up, so does humidity
• a 10% step increase in humidity equates to 150 gallons of primary water leakage

Question 41

What are the 2 types of containment isolation devices?

Answer 41

Passive and active

Question 42

What are examples of passive containment isolation devices?

Answer 42

• manual valves
• de-activated automatic valves
• blind flanges
• closed systems
• personnel and emergency escape air locks

Question 43

What are examples of active containment isolation devices?

Answer 43

Check valves or other automatic devices designed to close without operator action

Question 44

What actuates CHP?

Answer 44

• Containment pressure 3.7-4.3 (4) psig

- 2/4 logic on either channel

Question 45

What equipment actuates on CHP?

Answer 45

• closes containment isolation valves
• CRHVAC goes to emergency mode
• receive “containment isolation” alarm
• SIS
• “arms” containment spray pumps. Pumps will start on SIS with a CHP signal

Question 46

What is required to reset CHP?

Answer 46

• CHP has a seal in circuit
• can be reset if 3/4 channels < 3 psig
• EOP gives directions to reset

Question 47

What happens to CHP actuated equipment when CHP is reset?

Answer 47

All valves stay in CHP position except:

• CCW to/from containment
• feedwater isolations
• containment spray CVs return to HS postion (normally closed). Precaution to be careful as to not dead head the spray pumps and thermal shock components because of this

Question 48

How do we re-position valves that don’t automatically re-position when CHP is reset?

Answer 48

control switch needs to be taken to “closed” before they can be re-opened

Question 49

What actuates CHR?

Answer 49

• 10 R/hr on any 2 of 4 containment rad monitors will result in both trains actuating
• 80 mR/hr above background on either containment refueling rad monitor (will not receive high rad alarm)

Question 50

What equipment actuates on CHR?

Answer 50

• Containment isolation valves close except MSIVs, MFRVs, MFRV bypasses, and CCW to/from containment
• CRHVAC goes to emergency mode
• receive “containment isolation” alarm
• ESS sump pumps won’t auto pump down

Question 51

What happens to CHR actuated equipment when CHR is reset?

Answer 51

Valves will not re-position automatically