Operational Reactor Safety
22.091 /22.903
Lecture 18 Pilgrim Nuclear Power Station Background Information
Mark Santiago – Pilgrim Training
1
Welcome to Pilgrim Station and the Chiltonville Training Center
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Pilgrim Station Facts
700 MWe Boiling Water Reactor
2028 MWth
Nominal Operating pressure 1030 psig
145 control rods
580 fuel bundles
Mark 1 Containment
Pilgrim Station Facts
Went commercial in 1972
License will currently expire in Aug 2012
Application for 20 Year license renewal submitted
– Expect approval later in 2008.
Operates on a 24 month refueling cycle
Owned by Entergy
Part of a twelve unit nuclear fleet
Entergy has filed for a permit for new BWR in Mississippi.
Preaa«sañze d Wate v Reacto: r
PRESSURIZER
NUCLEAR HEAT GENERATION
STEAM GENERATION
WATER TRANSFER
STEAM CONDENSATION
TURBINE GENERATOR OPERATI O N
WATER
F¥EACTOR
STEAM GENERATOR
FEED PUMP
REACTOR COOLANT PUMP
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Bo:itJog Wate:r Reasto:r
STEAM FLOW TO TURBINE
NUCLEAR HEAD GENERATON
TURBINE GENERATOR OPERATION
WATER SUPPLY FEED PUMP
STEAM CONDENSATION
REACTOR
REClRCULATlOf4 PUMP
CONDENSATE
PUMP
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Beacto r an d T u rbin e Building s
ne cTon BuiLDlNc
T UHOINE BUILDING
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Reactivity Coefficients
Void Coefficient
(~ -1X 10 -3 ǻ k/k / % Voids)
Moderator Temperature Coefficient (~ -1X 10 -4 ǻ k/k / o F)
Doppler Coefficient
(~ -1X 10 -5 ǻ k/k / o Fuel Temperature)
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Critical Power
FORCED CO NVECTIO N HEATING
7
CR ITIC AL POWER
6
2
3
4
5
1
NUCLEATE BOILING
TRANS ITIO N BOILING
FILM BOILING
FUEL ROD SURFACE SUPERHEAT ( T WALL - T SA T )
FUEL ROD SURFACE HEAT FLUX OR
Q ˙ / A
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Critical Power Ratio (CPR)
CPR CP
A P
1.0
Where:
CPR = critical power ratio
CP = bundle power at which OTB occurs AP = a ctual bundle power
MCPR LIMITS
|
MARGIN FOR WORST CORE FUEL TRANSIENT |
|
MARGIN FOR UNCERTAINTY IN CORE OPERATING STATE |
|
MARGIN FOR UNCERTAINTY IN ANALYSIS DATA |
STEADY STATE CPR
OPERATING LIMIT
|
MCPR |
= |
1.06 |
|
MCPR |
= |
1.05 |
MCPR = 1.0
99.9% OF RODS AVOID OTB
50% OF RODS AVOID OTB
|
RADIOACTIVE RELEASE FROM THE PLANT WITHIN LIMITS |
|||||||||
|
FUE L CL ADDING CRACKING DUE TO HI GH ST RES S |
GROS S CL A DDING FAI LURE DUE TO LACK OF COOLING |
FUE L CL ADDING CRACKING DUE T O LOSS OF COOLING |
|||||||
|
F U EL PELLE T EX PANSI ON |
DECA Y HE A T AND STORED HE AT FOLLO W I NG LO CA |
L O SS OF NUCL E A TE BOI LING AROUND C L AD DING |
|||||||
|
1 % PLAS T I C S T R A IN O N C L AD DING |
CL AD TEMPERATURE 2200°F |
BOILING TRANS ITIO N |
|||||||
|
LO CAL F U EL PIN POWER IN NO DE |
AV ERA GE FUE L PIN POWER IN NO DE |
TOTA L FUE L BUNDL E P O WER |
|||||||
|
FUL L POWER |
LO CA |
TRANI ENT OP ERATI ON |
|||||||
|
LHGR |
AP LHGR |
CPR |
|||||||
|
FLPD < 1. 0 |
MAPRAT < 1. 0 |
MFLCP R < 1. 0 |
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PURPOSE
FAI LURE MECHANISM
CAUSE OF FAI LURE
LIMI TING CONDITIO N
ITEM MEASURED
LIMI TING OPERAT I O N
LIMI TING PARAMET ER
CALCULATED PARAMET ER
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Abnormal Operational Transients
Abnormal Operating Transients include the events following a single equipment malfunction or a single operator error that is reasonably expected during the course of planned operations.
Power failures, pump trips, and rod withdrawal errors are typical of the single malfunctions or errors initiating the events in this category.
Reactor Limits
To avoid the unacceptable safety results for abnormal operational transients, reactor operating limits are specified. Operating limits are specified to maintain adequate margin to the onset of boiling transition and failure due to cladding strain (CPR & LHGR). To ensure that adequate margin is maintained and an unacceptable result is avoided, a design requirement based on a statistical analysis was selected. This requirement would ensure that during an abnormal operational transient, 99.9% of the fuel rods would be expected to avoid boiling transition.
Abnormal Operational Transients Event Categories
Events Resulting in a Nuclear System Pressure Increase
– Ex: Turbine trip (turbine stop valve closure)
Events Resulting in a Reactor Vessel Water Temperature Decrease
– Ex: Inadvertent Pump Start
Events Resulting in a Positive Reactivity Insertion
– Ex: Continuous, inadvertent rod withdrawal
Abnormal Operational Transients Event Categories Cont.
Events Resulting in a Reactor Vessel Coolant Inventory Decrease
– Ex: Loss of feedwater flow
Events Resulting in a Core Coolant Flow Decrease
– Ex: Recirculation pump seizure
Events Resulting in a Core Coolant Flow Increase
– Ex: Recirculation Flow Control Failure - I ncreasing Flow
DESIGN BASIS ACCIDENTS
A design basis accident is a hypothesized accident; the characteristics and consequences of which are utilized in the design of those systems and components pertinent to the preservation of radioactive materials barriers, and the restriction of radioactive material release from the barriers.
Unacceptable Results
radioactive material release which results in dose consequences that exceeds the guideline values of 10CFR100
failure of fuel cladding which would cause changes in core geometry such that core cooling would be inhibited
nuclear system stress in excess of those allowed for the accident classification by applicable codes
containment stresses in excess of those allowed for the accident classification by applicable industry codes when containment is required
overexposure to radiation of st ation personnel in the control room
DESIGN BASIS ACCIDENTS
Control Rod Drop Accident
Loss of Coolant Accident
Main Steam Line Break Accident
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Minus a few hundred thousand gallons of water….
Drywell
Steel ASME Code pressure vessel
Shaped like an inverted light bulb
Design Pressure
+ 56 psig
- 2 p s i g
34’ in Diameter 110% overpressure
Vessel
64’ in Diameter
+ 62 psig
Design Temp (Tsat)
281 F.
110’ Tall
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Pressure Suppression Chamber
and Pool
Energ y Transfe r Paths
• R elief valve discharge piping
• H P C I
• R C I C
• D rywell Vent system
• R esidual Heat Removal
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Hydrogen Event At TMI
The first warning of the presence of hydrogen in the system was quite violent, but thanks to the heavily over engineered containment structure, it was almost anticlimactic save for its implications. A poorly shielded relay sparked, detonating the hydrogen in the containment. Containment building pressure zoomed to a frightening 28 pounds per square inch, and stayed there for nearly eight seconds as the hydrogen burned. The force shook the control room floor noticeably, and was thought to be equivalent to the explosion of several modern 1,000 pound bombs.
Hydrogen Combustion The Burn
Deflagrations are combustion waves which heat the gas by thermal conduction
Travel Subsonically and cause low pressure loads on the containment
Hydrogen Event At TMI Burnt crane controls
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Hydrogen Combustion The Boom
Detonation heats the unburned gas by compression from shock waves.
The waves travel supersonically and produce high pressure loads on the containment.
Containment Damage
Hydrogen can create excessive drywell pressure
Containment design pressure =
56 psi
Estimated failure pressure =
~ 200 psi
Estimated pressure with 30% metal-water reaction with a burn
>> 200psi
Hydrogen Event At TMI ‘Nuf said’
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Drywell head
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22.091 Nuclear Reactor Safety
Spring 200 8
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