AR- Condenser Air Removal

Question 1

What is the purpose of the AR system?

Answer 1

Establishes and helps maintain a vacuum on the shell side of the main condenser by removing air and non-condensable gases during plant startup and power operations

Reduces oxygen concentration in the condensate by deaeration to aid in water chemistry

Question 2

What system cools the AR pump seal water coolers?

Answer 2

Plant cooling water

Question 3

What system provides makeup seal water to the AR vacuum pumps?

Answer 3

Condensate Service Header

Question 4

When would AR discharge valves realign and redirect flow through the post filter unit?

Answer 4

When Radiation Monitoring System detects high radiation in the AR discharge

Question 5

Where are the AR pumps located?

Answer 5

100’ south side of the turbine building

Question 6

The AR vacuum pumps are sized to lower condenser pressure to what value and in what amount of time?

Answer 6

5” HgA in ~1.5 hours

Question 7

What powers the AR pumps?

Answer 7

NG

Question 8

Which of the four AR pumps is the standby pump?

Answer 8

‘D’ Pump

Question 9

What is “hogging” mode?

Answer 9

During plant startup operation, inlet gas is compressed in the first stage and discharged directly to the moisture separator, bypassing the second stage

A check valve in the first stage discharge line allows the vacuum pump to automatically shift to the “hogging” mode when the first stage discharge volume exceeds the capacity of the second stage

Question 10

What is the purpose of the moisture separator in the AR pumps?

Answer 10

Separate vacuum pump discharge gas from the sealant accompanying it

Provide a surge volume and reservoir for the sealant

Question 11

Where does seal water flow in the Seal Water Cooler?

Answer 11

Shell side

Question 12

When is sealant sprayed in the inlet manifold?

Answer 12

During high vacuum operation to cool incoming gasses and condense any accompanying steam

Question 13

Where is the post filter unit located?

Answer 13

140’ south side of the Turbine Building

Question 14

The post filter unit consists of what components?

Answer 14

Moisture separators

Electric heating coil

Exhaust pre-filter (HEPA)

Activated Charcoal filter

Exhaust post-filter (HEPA)

Question 15

How is the electric heating coil sized?

Answer 15

To reduce the exhaust gas relative humidity below 70% to maintain the charcoal filter’s absorption ability

Question 16

What is required in order to enter the Post Filter Unit?

Answer 16

Radiation Exposure Permit

Question 17

What does the NH system power?

Answer 17

AR pump motor space heaters

post filter blower

charcoal adsorption train heating coil

Question 18

Where is the motor of the Post Filter Blower started from?

Answer 18

Either manually from the Control Room or automatically in response to a high radiation signal

Question 19

What condenser setpoints would automatically start the ‘D’ Air removal pump?

Answer 19

“A” Condenser – 4.2” HgA
“B” Condenser – 4.8” HgA
“C” Condenser – 5.3” HgA

Question 20

What systems must be in service prior to starting the AR system?

Answer 20

Plant Cooling Water, Instrument Air, Condensate Service Header, Gland Steam Seal and drain systems

Question 21

What would happen up on a loss of AR?

Answer 21

During normal operation, would not have an immediate effect since the condensing steam will maintain vacuum

Non-condensable gases will build over time, causing a loss of vacuum that could require a turbine shutdown

Oxygen will increase in the condensate which could also require a power reduction

Question 22

How long would it take before we see signs of a degraded vacuum after a loss of AR?

Answer 22

10-20 minutes

Question 23

What three support systems are needed for AR system operation?

Answer 23

Plant Cooling Water, Instrument Air, and Condensate Service Header

Question 24

How is the system affected by a loss of PW?

Answer 24

Overheating of any operating AR vacuum pumps due to buildup of excess heat

High vacuum pump seal water temperature would result in a loss of pumping capability as the seal water flashes to steam

Question 25

How is the system affected by a loss of IA?

Answer 25

All suction isolation valves to vacuum pumps will fail closed

An effluent path will be maintained through the post filter unit, along with vented gases

Question 26

How is the system affected by a loss of the Condensate Service Header?

Answer 26

Could result in a low level in the ‘on-skid’ moisture separator if there is insufficient moisture carryover from the main condenser

Question 27

What is the normal line up for the AR pump exhaust?

Answer 27

bypassing the charcoal adsorption train and the post filter blower via the bypass valve and straight to the plant vent stack

Question 28

How many AR pumps are used in Hogging mode to draw the initial vacuum in the condenser?

Answer 28

all four

Question 29

There should always be some leakage from the AR pump seals. What are the two places the seal leakage can be directed to? What is the preferred line up and why?

Answer 29

main condenser or OW via the floor drain

OW via the floor drain because if there was an AR pump seal water cooler tube leak, PW would be introduced to the main condenser if directed there

Question 30

How does the GS (Main turbine Gland steam seals and drains) system interface with the AR system?

Answer 30

gland sealing steam packing exhauster discharge is directed to the AR system and the drain tank vents to the AR system

Question 31

How does IA interface with the AR system?

Answer 31

pneumatic valves

Question 32

Where does each AR pump connect to the condenser?

Answer 32

A, B, C all connect to their respective shells and D can automatically connect to all three shells

Question 33

What is “holding” mode?

Answer 33

inlet gas is partially compressed in the first stage and is discharged (along with the liquid sealant) to the second stage inlet. The second stage of the pump compresses the gas to slightly above atmospheric pressure, and discharges it and the liquid sealant to the moisture separator.

Question 34

What is the difference between the bearings in AR pumps before and after a rebuild of the pump?

Answer 34

rebuilt pumps will have sealed grease bearings instead of oil lubricated bearings

sealed grease bearings should not have any evidence of leakage

Question 35

Concerning the AR system, who is responsible for measuring the condenser in-leakage and how is it measured?

Answer 35

area operator

through a rotameter

Question 36

Regarding the AR system, where does the seal water recirculation pump take suction from?

Answer 36

separator tank

Question 37

what is the purpose of the charcoal adsorption train in the AR system? When is it used?

Answer 37

removes moisture, particulate contamination and gaseous iodine and methyl iodide

when high levels of radioactivity are detected in the combined air removal and gland sealing steam packing exhauster discharge

Question 38

In the AR system, what will the charcoal adsorption train alarm on?

Answer 38

high D/P

Question 39

What RU monitor is in service to monitor the exhaust of the air removal pumps during normal operation? What happens when high radiation is detected?

Answer 39

141

charcoal adsorption train bypass valve closes, inlet and outlet open and the post filter blower will start

Question 40

What would happen on a loss of the Condensate (CD) system to the AR system?

Answer 40

low level in “on-skid” moisture separator (the source of water pumped into the vacuum pump spray header by the seal
water recirculation pump) if there is insufficient moisture carryover from the Main
Condenser.

Question 41

What happens in the AR system when there is a loss IA?

Answer 41

all vacuum pump suction isolation valves will fail closed

AR pump discharge will be directed to the charcoal adsorption train

Question 42

Regarding the AR system, why must the AR pumps be manually shutdown after a loss of IA?

Answer 42

when IA is lost, the suction valves close and there is no automatic trip for the pump

Question 43

What happens in the AR system when there is a loss of GS (main turbine gland sealing steam and drains)?

Answer 43

excessive air intrusion into the secondary which would raise condenser pressure, start the ‘D’ AR Pump, and could threaten the Condenser AR
Pump capacity.