Main Steam

Question 1

LCO 3.3.1 “Reactor Protective System (RPS) Instrumentation” requirements

Answer 1

4 RPS trip units, associated instrument channels, and associated Zero Power Mode (ZPM) Bypass removal channels for each Low Steam Generator Level Trip and each Low Steam Generator Pressure Trip shall be operable.

Question 2

LCO 3.3.1 “Reactor Protective System (RPS) Instrumentation” applicability

Answer 2

Modes 1 & 2, and Modes 3-5 with more than 1 full-length control rod capable of being withdrawn and PCS boron concentration less than refueling boron concentration.

Question 3

LCO 3.3.1 “Reactor Protective System (RPS) Instrumentation” required actions if 1 or more ZPM Bypass Removal channels inoperable.

Answer 3

IMMEDIATELY
Remove the affected ZPM Bypasses
OR
Declare affected trip units inoperable

Question 4

LCO 3.3.1 “Reactor Protective System (RPS) Instrumentation” required actions if 1 or more functions with 2 RPS trip units or associated instrument channels inoperable.

Answer 4

WITHIN 1 HOUR

Place one unit in trip

Question 5

LCO 3.3.3 “Engineered Safety Features (ESF) Instrumentation” requirements

Answer 5

4 ESF Bistables and associated instrument channels for each Steam Generator Low Pressure Signal shall be operable

Question 6

LCO 3.3.3 “Engineered Safety Features (ESF) Instrumentation” applicability

Answer 6

Modes 1-3
Not required in Modes 2 & 3 when all MSIVs are closed and deactivated, and all MFRVs and MFRV Bypasses are either closed and deactivated, or isolated by closed manual valves.

Question 7

LCO 3.3.4 “Engineered Safety Features (ESF) Logic and Manual Initiation” requirements

Answer 7

2 ESF Manual Initiation and 2 ESF Actuation Logic channels and associated bypass removal channels shall be operable for each Steam Generator Low Pressure Signal

Question 8

LCO 3.3.7 “Post Accident Monitoring (PAM) Instrumentation” requirements

Answer 8

The PAM instrumentation for each Steam Generator Water Level and Pressure shall be operable

Question 9

LCO 3.3.7 “Post Accident Monitoring (PAM) Instrumentation” applicability

Answer 9

Modes 1-3

Question 10

LCO 3.3.8 “Alternate Shutdown System” requirements

Answer 10

The Alternate Shutdown System function Steam Generator Pressure and Wide Range Level shall be operable

Question 11

LCO 3.3.8 “Alternate Shutdown System” applicability

Answer 11

Modes 1-3

Question 12

LCO 3.7.1 “Main Steam Safety Valves (MSSVs)” requirements

Answer 12

23 MSSVs shall be operable with lift settings of 1000 psia, 1020 psia, and 1040 psia

Question 13

LCO 3.7.1 “Main Steam Safety Valves (MSSVs)” applicability

Answer 13

Modes 1-3

Question 14

LCO 3.7.2 “Main Steam Isolation Valves (MSIVs)” requirements

Answer 14

2 MSIVs shall be operable

Question 15

LCO 3.7.2 “Main Steam Isolation Valves (MSIVs)” applicability

Answer 15

Mode 1

Modes 2 & 3 except when both MSIVs are closed and de-activated

Question 16

LCO 3.7.4 “Atmospheric Dump Valves (ADVs)” requirements

Answer 16

1 ADV per steam generator shall be operable

Question 17

LCO 3.7.4 “Atmospheric Dump Valves (ADVs)” applicability

Answer 17

Modes 1-3

Mode 4 when steam generator is being relied upon for heat removal

Question 18

What is the purpose of the MSIVs?

Answer 18

• Isolates steam generators to prevent uncontrolled release of radioactivity to environment in the event of a steam generator tube rupture
• prevent blowing down the good steam generator into containment in the event of a steam line rupture in containment
• prevent uncontrolled cooldown of the PCS

Question 19

What are the power supplies for the MSIVs?

Answer 19

Left channel solenoids - D11-1
Right channel solenoids - D21-1
Each MSIV has 2 solenoids (1 air supply, 1 vent) from each channel

Question 20

What is the process for latching the MSIVs?

Answer 20

• Handswitch in control is taken to open, which de-energizes the solenoids, allowing manual latching of MSIV.
• Both handswitches need to be in open to open MSIV. This allows latching all vents closed and air supplies open

Question 21

What happens when either MSIV handswitch is taken to close?

Answer 21

Both MSIVs close because solenoids energize, causing air supplies to close, and vents to open

Question 22

What is a precaution to be taken after an MSIV handswitch is taken to close?

Answer 22

Take handswitch back to open to de-energize the solenoids to prevent them from burning up. Solenoids won’t reposition at this point because they are unlatched.

Question 23

What are the automatic actions that occur on steam generator low pressure, and what is the setpoint?

Answer 23

• 500 psia (2/4 logic) in either steam generator
• causes both MSIVs to close
• MFRV and MFRV Bypass on only the affected steam generator go closed

Question 24

When can MSIV closure on low steam generator pressure be blocked?

Answer 24

When 3 of 4 steam generator pressure channels between 512 and 548 psia

Question 25

Why is MSIV closure on low steam generator pressure block used?

Answer 25

Allows the MSIVs to remain open while using the TBV to cool down and conserves water inventory that is lost to atmosphere when the ADVs are used

Question 26

When does MSIV closure block clear?

Answer 26

When 2 of 4 channels are above 550 psia steam generator pressure

Question 27

How can the TBV be used to cool down when the MSIVs are closed?

Answer 27

In an emergency, MSIV Bypass Valves can be opened

Question 28

How does the main steam system respond to CHP?

Answer 28

• 2/4 logic closes both MSIVs
• if only 1 channel actuates, only its associated MFRV and MFRV Bypass close (left channel closes A S/G feed valves, right channel closes B S/G feed valves). So you need both channels to actuate to isolate feed to both S/Gs

Question 29

What is the function of the ENABLE/DEFEAT keyswitch next to the MSIV control switches?

Answer 29

Allows you to disable the turbine trip on MSIV out of position

Question 30

What are the MSIV Bypass Valves used for?

Answer 30

• normal use is for secondary side warm up and pressurization during plant startup
• can be used in an emergency to cool down using the TBV instead of the ADVs

Question 31

When must the MSIV Bypass Valves be closed, and why?

Answer 31

Above 2% reactor power because there is no auto closure for these valves on CHP or S/G low pressure

Question 32

What are the power supplies for the MSIV Bypass Valves?

Answer 32

MCC-3 for both

Question 33

What is the steam flow capacity of the ADVs?

Answer 33

7.5% total steam flow per valve (30% total)

Question 34

What is the motive force for operation of the ADVs?

Answer 34

• instrument air
• air accumulator
• nitrogen backup from bulk nitrogen tank

Question 35

What are the power supplies for the ADV solenoids?

Answer 35

CV-0779/0781 - D11-1
CV-0780/0782 - D21-1
Each DC power supply powers 1 valve on each steam line

Question 36

How do the ADVs fail on a loss of DC power?

Answer 36

closed, and light indication goes away

Question 37

How are the ADVs controlled?

Answer 37

All 4 ADVs are controlled by 1 controller in the control room, which sends its signal to C-33 through 2 controllers to the ADVs

Question 38

Where are the ADV controllers powered from?

Answer 38

All 3 powered from Y-10

Question 39

What are the modes of operation for the ADV controller?

Answer 39

Auto - upon turbine trip, contacts close in the ADV circuitry, then the controller modulates ADVs based on Tave.
Manual - operator controls output with slide bar

Question 40

How does the ADV quick open mode operate?

Answer 40

With a turbine trip and Tave > 556.9 F, ADVs and TBV get a quick open signal and stay full open until Tave < 556.9 F

Question 41

How does the ADV modulate mode operate?

Answer 41

With a turbine trip and Tave < 556.9 F, ADVs and TBV throttle based on Tave.
556.9 F = full open
535 F = full closed
If below 535 and rising, valves will start throttling open at 540 F

Question 42

What is the power supply for the TBV?

Answer 42

Controller is from Y-01

Solenoid valves are from D11-1

Question 43

What is the steam flow capacity of the TBV?

Answer 43

4.5% total steam flow

Question 44

What controls the TBV?

Answer 44

Receives signal from ADV controller and its own controller. The controller that is putting out the largest open signal will control the TBV

Question 45

What are the modes of operation for the TBV controller?

Answer 45

Manual - operator controls output with slide bar
Auto - controls S/G pressure at a selected setpoint (normally 900 psia). Valve is full open when S/G pressure is 5 psia above setpoint, and full closed when 5 psia below setpoint. TBV doesn’t need a turbine trip to operate, but S/G pressure is about 770 psia at full power, so TBV is receiving a full closed signal

Question 46

What is the TBV interlock with condenser vacuum?

Answer 46

TBV will auto close, or will not open if condenser vacuum < 5” Hg

Question 47

How does the TBV fail?

Answer 47

Fails closed on loss of air or D11-1

Question 48

What function does the TBV accumulator serve?

Answer 48

Allows TBV to quick open without air pressure, but it won’t be able to modulate

Question 49

How many code safeties do we have?

Answer 49

24 (12 per steam generator)

Question 50

What are the code safety lift setpoints?

Answer 50

4 @ 1000 psia
4 @ 1020 psia
4 @ 1040 psia

Question 51

Why are the code safety lift setpoints staggered?

Answer 51

To prevent chatter

Question 52

Where in the system are the main steam line rad monitors located?

Answer 52

Located between the MSIVs and ADVs, so they won’t be able to detect releases from the ADVs