Power Operations 20-100%

Question 1

Why should you slowly place MSRs in service?

Answer 1

avoids excessive temp transients which minimizes Turbine vibrations.

Question 2

What operator actions with MSRs helps maintain LP Turbine dTemperature < 50F?

Answer 2

• Operate MSRs in the same Mode to maintain LP Turbine ∆T’s < 50°F.

Question 3

State several items that can affect the intensity of MT vibrations during operation.

Answer 3

• Lubricating oil temperature
• Low turbine loading
• High rates of power change
• High rates of condenser vacuum change or approaching 2” HgA
• ∆T across the condenser section
• MSR operation
• Steam drain operation
• Thermal transients (Equipment malfunctions that direct steam or drains to the condenser)

Question 4

What steady state method of turbine control maintains plant stability?

What else does this minimize with respect to the TCVs.

Answer 4

• Steady state: turbine control on the load limiter. Maintains plant stability and minimize pressure surges on control valves.

Question 5

What is the normal MT vibration threshold?

What is the MT trip criteria for high vibrations?

When should a reactor trip be performed with regard to high vibrations in the MT?

Answer 5

• 5 mils (normal Turbine vibration)
  
  • Auto turbine trip at 12 mils unfiltered
• Turbine trip criteria:
  
  • Filtered journal vibration > 10 mils and rapidly ↑ towards 12 mils at rated speed
  • Filtered vibration > 10 mils with a slow ↑ towards 12 mils after a 15 minute time span at rated speed
• Reactor trip criteria (if during normal power reduction with a planned reactor trip):
  
  • Sudden step ↑ of 2 mils
  • Vibration ≥ 10 mils

Question 6

What is the temperature limit for the following:

MT oil drain temp.

MT bearing metal temp.

LP turbine steam inlet temp change limit.

Answer 6

• ≤ 170°F: Limit for Turbine oil drains during continuous operation at the hottest bearing.
• ≤ 225°F: Normal turbine bearing metal temperature.
• < 125°F/hour: Normal LP turbine steam inlet temperature change limit. Short term changes limited to 250°F/hour.

Question 7

What operations should be avoided to minimize MT damage with regards to vibrations?

Answer 7

• < 40% load with C shell ≥ 5 inches HgA (vibrations)
• < 40% load (410 MW) and C shell > 4” to < 5” HgA for 1 hour max (vibrations)

Question 8

How can breaking vacuum above 1200rpm affect the turbine?

When is it allowed?

Answer 8

• Breaking vacuum > 1200 rpm (excessive loading on Last Stage Buckets)
• In emergencies only.

Question 9

What is detrimental about maintaining vacuum without GS in service?

Answer 9

• Maintaining vacuum after gland seal steam lost can cause thermal shock to rotor by intake of cold air.

Question 10

What can happen if excessive use of exhaust hood Sprays at low speeds and low loads is allowed?

Answer 10

erosion of last stage buckets

Question 11

What minimum speed and load should be avoided with regards to the MT?

Answer 11

• Operating < 800 rpm (> 5 min). (Cause packing rub, high vibes not indicated, or bowed rotor)
• Minimize operation < 5% load (moisture erosion on last stage buckets)

Question 12

What are teh exhaust hood temperature limits and what coudl happen if they are violated?

Answer 12

• ≤ 125°F: rapid load changes allowed
• 125 - 175°F: may operate continuously but change load slowly (0.5%/min) (avoids unnecessary thermal stress)
• 200-225°F: 15 minute max operations (turbine trips at 225°F)

Question 13

State the following:

rate of turbine load reductions

normal power reductions

TG operation prior to start

continuous TG operations.

Answer 13

• ≤ 10%/min load reductions minimizes turbine thermal stresses.
• Limiting normal power reductions to 20%/hour (4 hour normal shutdown) will minimize turbine vibration.
• < 48 hours TG operation prior to turbine start may cause shaft bowing
• Avoid long periods of TG operations. Generator field grounds may occur from copper dust build-up. (galling of windings)

Question 14

With regard to Condenser backpressure:

1. State the C shell max backpressure
2. C shell operations that minimizes MT vibrations
3. Reactor trip setpoints

Answer 14

1. C shell max backpressure is < 5.0” HgA.
2. C shell > 2” HgA and ≤ 4” HgA minimizes Turbine vibration.
3. Trip reactor if load < 410 MW and > 4” HgA for > 1 hour
   
   • Trip reactor if load < 410 MW and > 5” HgA

Question 15

Why should the condenser vacuum be maintained as close as possible to table values?

> 40% pwr

Answer 15

• > 40% power: maintain average pressure as close to table values as possible (↑ turb efficiency / ↑ MWe)
• Maintain A shell pressure above the table values (↓ erosion of condenser internals from excess steam velocities)

Question 16

What actions are taken to prevent exceeding 5” HgA?

Answer 16

• Reduce turbine load to prevent exceeding 5” HgA

Question 17

State the ASI limits associated with LCO 3.2.5.

Answer 17

• LCO 3.2.5 ASI limits:
  
  • COLSS Operable
    
    • -0.18 ≤ ASΙ ≤ 0.17 (> 50%)
    • -0.28 < ASI < 0.17 (> 20% and < 50%)
  • COLSS out of service (CPC)
    
    • ± 0.10 ASI (>20%)

Question 18

When should ASI dampening be performed?

Answer 18

• ASI dampening performed if ASI will exceed ESI by ± 0.1.

Question 19

At what ASI threshold is a reactor trip performed?

Answer 19

• Trip the reactor if exceeded or trending to ± 0.5 (CPC Hot Pin ASI Aux Trip).
  
  • ASI input to CPC aux trip depends on power
  • ≥ 51% (sum of the 3 NIs): uses actual power distribution (during power ascension)
  • ≤ 45% (sum of the 3 NIs): uses a canned value (during power reduction)

Question 20

Which of the following should be used during a downpower?

Colss asi or CPC asi?

Answer 20

• CPC and COLSS can calculate a large ASI difference due to design differences and calculation processes. CPCs generate an auxiliary trip prior to COLSS indicating a problem with ASI.

Question 21

When is PZR boron equalization performed?

Answer 21

• ≥ 50 ppm RCS Boron conc. change: perform PZR boron equalization
  
  • Maintain until ≤ 10 ppm difference (RCS vs PZR)

Question 22

Who is notified if Rx power is < 85% for more than 10 days?

Answer 22

• Power < 85% for > 10 days: notify nuclear fuel groups for evaluation.

Question 23

Who is notified if a power change is required or ASI dampening is performed and why?

When is the sample required?

Answer 23

• Chemistry notified of any power change or ASI dampening (sample for iodine spikes)
• LCO requires sample within 2-6 hours of a ≥ 15% / hour power change

Question 24

What is required from section 6.1 prior to raising power > 20%?

Answer 24

• 20% mode change checklist complete (ZZ11)
• Maintain Power Ascension Rate Limits (App. A)
• Unit Ops Manager permission required if SBCS, PLCS, PPCS, or FWCS are NOT in Auto.
• Monitor AZTILT (LOC limit and CPC value < actual tilt)
• Place MSRs in-service

Question 25

When are both HDPs placed in service?

Answer 25

• 20-25% plant power: place both HDTPs in-service

Question 26

When are extr steam drains and turbine drains closed?

Answer 26

• 250 MWe: close extraction steam drains and turbine drains

Question 27

What happens at 30, 50 and 90% on power ascension?

Answer 27

• 30%, 50%, 90%: chemistry hold points

Question 28

When is the 3rd CDP started?

Answer 28

40%

Question 29

When is the second MFP started?

Answer 29

40-60% reactor power

Question 30

When is RPCB placed in service and when are subgroups selected?

Answer 30

• 70% reactor power: place RPCB in-service with NO subgroups selected
• 74% reactor power: select RPCB subgroups

Question 31

When is SBCS placed in remote auto?

Answer 31

75%

Question 32

Define Axial Offset Anomoly and what adverse effects it will cause core operations.

Answer 32

• Axial Offset Anomaly (CIPS): CRUD builds up on the high power fuel pins. Lithium boron absorbed in the CRUD (plates out). Causes power shifts to bottom of core.
  
  • – AOA: more flux in bottom of core (opposite of ASI)
  • ↓ SDM and ↑ power peaking

Question 33

State the following Generator limits for normal operations:

1. Vterm
2. Buck
3. Boost
4. ECC max voltage
5. max H2 cold gas temp
6. H2 min/max press
7. limits associated with the capability curve.

Answer 33

1. 22.8 – 25.2 kV (Generator Terminal Voltage band 24 kV ± 5%)
2. - 310 MVARs (max Buck Limit to minimize low voltage conditions on the buses)
3. + 560 MVAR (max Boost Limit)
4. 535.5 kV: ECC max voltage limit
5. ≤ 48°C (118.4°F): Max inlet H2 cold gas temp. Ensure adequate generator cooling.
6. 30 psig: Min H2 pressure. Ensure adequate density of the gas for cooling the generator. (Max load 940 MW (~ 67%))
7. 75 psig: Max H2 pressure.
8. Capability curve: AB (field heating), BC (armature heating), CD (armature core end heating)

Question 34

How can RG 4 be used to control ASI?

Answer 34

• Use RG 4 to control ASI if heavily top peaked
  
  • ASI cannot be maintain with ± 0.05 of ESI and < 70% (< 55% if COLSS OOS)
  • RG4 can be inserted beyond normal overlap
  • Maintain RG 5 > 75”
  • Maintain RG 4 ≥ 10” above RG 5 (if RG4 < RG5, an out of sequence CPC trip will occur)
  • Track time that RG 4 is between ARO and transient RIL

Question 35

What is the desired band for RTP and by what indication?

What is licensed power based on?

How should the crew adjust hourly power if 100% is exceeded?

Answer 35

• Desired control band for RTP is between 99.8% and 100% using hourly average calorimetric power (JSCALORH).
• License limit is the 12 hour average
• If hourly exceeds 100%, reduce to < 100% in the next hour. Monitor 10 minute average.

Question 36

What minimizes MFW imbalances?

Answer 36

maintaining MFP biasing ≤ 100 rpm difference minimizes MFW imbalances

Question 37

What is MFP bias adjustment based on?

Why is 100 psid at 100% maintained?

Answer 37

• Lower MFP speed (- bias) until MFP discharge pressure is 100 psig > SG pressure or – 500 rpm
• Maintain ~ 100 psid at 100% (sufficient FF to SGs, low enough to minimize ECCV oscillations, low enough to improve MWe output / efficiency)

Question 38

What limit to rated power exists if using NKBDELTC for > 12 hrs?

Answer 38

• If controlling power with NKBDELTC for > 12 hours, reduce power to 96.6%

Question 39

When is CEDMCS placed in AS?

Answer 39

• Placed in AS when > 40%

Question 40

How is EOL coastdown performed, big picture?

Answer 40

• EOL Coast down (↓ turbine load as Tavg drops OR Tcold coastdown)
  
  • CEDMCS Not in AS if performing Tcold coastdown

Question 41

How should Tave-Tref be maintained when >90% power?

What does this accomplish?

Answer 41

• Maintain Tavg/Tref ± 3°F
  
  • When > 90%, maintain Tavg as close to Tref as possible.
  • Minimize potential for VOPT pre-trip alarms when Tavg is high or MSIS pre-trip alarm when Tavg is low.

Question 42

What must be met to stop HDPs after taking the turbine off-line?

Answer 42

HDT level are stable and pumps are operating on mini-flow

Question 43

Whose permission does it take to go above 20% if SBCS, PLCS< PPCS, FWCS are not in AUTO?

Answer 43

• Unit Ops Manager permission required if SBCS, PLCS, PPCS, or FWCS are NOT in Auto.

Question 44

When is the UFM placed in service on power ascension?

Answer 44

• 93%: UFM placed in-service

Question 45

Why must power ascension rates be strictly adhered to and when do they apply?

Answer 45

• Prevents fuel damage / voiding fuel warrenties. Applies > 20%.
  
  • Initial start-up limits below 20% are covered by 72PA-9ZZ07, “Reload Power Ascension Test.”

Question 46

Whose permission is requried for the following:

• Maneuvering plan predicts ASI will exceed LCO limit during power reduction.
• SBCS, PLCS, PPCS, or FWCS are NOT in Auto.

Answer 46

• Unit Ops Manager permission required if plan predicts ASI will exceed LCO limit during power reduction.
• Unit Ops Manager permission required if SBCS, PLCS, PPCS, or FWCS are NOT in Auto.

Question 47

At what hotwell level should HDPs be stopped?

Answer 47

• 46-48” Hotwell level prior to stopping HDTPs

Question 48

How are NAN-S01 and S02 powered if reactor power is to be reduced < 20%?

Answer 48

From offsite power via the SU XFMRs

Ensure not more than 1 Unit is powered from 1 SU XFMR.

Ensure other unit’s DG’s are not in parallel with off-site power.

Question 49

What actions are taken at < 70% on shutdown?

Answer 49

• < 70%: remove RPCB from service (40OP-9SF04 - Auto Actuate OOS and Test/Reset PBs)
• < 70%: place HDT LICs in Local-Auto (7’ setpoint)

Question 50

When <60% power, which MFP is removed from service first and why?

Answer 50

• < 60%: stop 1^st MFP (preferably A MFP due to water intrusion issues)

Question 51

What should be removed from service if the MT is being shutdown?

Answer 51

• Remove MSRs from service if generator is being shutdown

Question 52

With regards to the SGBDs, what must be ensured at ~ 25%?

Answer 52

• < 25%: ensure SGBD is NOT aligned to the SGBD demins

Question 53

How is the plant stabilized if 20-30% power is to be maintained with the MT tripped?

Answer 53

• Place one SBCV in Manual permissive (1001)
• Place SBCS in Local-Auto. Adjust SBCS master controller to open 1001
• ↓ turbine load to 50 MWe
• Place more SBCVs in manual as needed for load reduction
• Trip the turbine when ≤ 50 MWe
• Shutdown the generator (open disconnects)
• Reclose the generator PCBs within 2 hours

Question 54

Why should only 2 charging pumps be running prior to tripping the reactor?

Answer 54

prevent lifting the letdown relief CHN-PSV-345.

Question 55

Briefly describe the process to stop Condensate pumps per 40OP-9ZZ14.

Answer 55

• Throttle open SGBD HX condensate outlet valves to maximize flow (suction pressure) to MFPs (500 gpm max per path)
• Throttle open Cond Demin bypass (PDV-195) to maximize MFP suction pressure
• Close the Condensate pump discharge valve and stop the pump

Question 56

Briefly describe the process of stopping the first MFP per 40OP-9FT01/02.

Answer 56

• Reduce speed on the MFP (use Bias or manual speed control) until discharge pressure is below the other MFP
• Close the MFP discharge MOV
• Trip the MFP
• Place on turning gear, re-open discharge MOV, adjust lube oil and seal pressures