{{#Wiki_filter:PROPOSED CHANGES TO THE COOK NUCLEAR PLANT UNIT NO.1 TECHNICAL SPECIFICATIONS VSO7i50009 9SO7ia PDR ADOCK 050003i5 P PDR  

3/4 LIMITING CONDITIONS FOR OPERATION AND SURVEILLANCE REQUIREMENTS 3/4.7 PLANT SYSTEMS CONDENSATE STORAGE TANK LIMITING CONDITION FOR OPERATION 3.7.1.3 The condensate storage tank (CST)shall be OPERABLE with a minimum useable volume of 175,000 gallons of water.APPLICABILITY:

MODES 1, 2 and 3.ACTION: With the condensate storage tank inoperable, within 4 hours either: Restore the CST to OPERABLE status or be in HOT SHUTDOWN within the next 12 hours, or Demonstrate the OPERABILITY of the Essential Service Water System as a backup supply to the auxiliary feedwater pumps and restore the condensate storage tank to OPERABLE status within 7 days or be in HOT SHUTDOWN within the next 12 hours.SURVEILLANCE RE UIREMENTS 4.7.1.3.1 4.7.1.3.2 The condensate storage tank shall be demonstrated OPERABLE at least once per 12 hours by verifying the useable water volume is within its limits when the tank is the supply source for the auxiliary feedwater pumps.The Essential Service Water System shall be demonstrated OPERABLE at least once per 12 hours by verifying that the Essential Service Water System is in operation whenever the Essential Service Water System is the supply source ior the auxiliary feedwater pumps.COOK NUCLEAR PLANT-UNIT 1 Page 3/4 7-7 AIKNDMENT 3/4 BASES 3/4.6 CONTAINMENT SYSTEMS 3/4.6.1.4 INTERNAL PRESSURE The limitations on containment internal pressure ensure that 1)the containment structure is prevented from exceeding its design negative pressure differential with respect to the outside atmosphere of 8 psig and 2)the containment peak pressure does not exceed the design pressure of 12 psig during LOCA conditions.

The maximum peak pressure resulting from a LOCA event is calculated to be less than the design limit of 12 psig, which includes 0.3 psig for initial positive containment pressure.3/4.6.1.5 AIR TEMPERATURE The limitations on containment average air temperature ensure that 1)the containment air mass is limited to an initial mass sufficiently low to prevent exceeding the design pressure during LOCA conditions and 2)the ambient air temperature does not exceed that temperature allowable for the continuous duty rating specified for equipment and instrumentation located within containment.

The containment pressure transient is sensitive to the initially contained air mass during a LOCA.The contained air mass increases with decreasing temperature.

The lower temperature limit of 60'F will limit the peak pressure to less than the containment design pressure of 12 psig.The upper temperature limit influences the peak accident temperature slightly during a LOCA;however, this limit is based primarily upon equipment protection and anticipated operating conditions.

Both the upper and lower temperature limits are consistent with the parameters used in the accident analyses.3/4.6.1.6 CONTAINMENT VESSEL STRUCTURAL INTEGRITY This limitation ensures that the structural integrity of the containment steel vessel will be maintained comparable to the original design standards for the life of the facility.Structural integrity is required to ensure that (1)the steel liner remains leak tight and (2)the concrete surrounding the steel liner remains capable of providing external missile protection for the steel liner and radiation shielding in the event of a LOCA.A visual inspection in conjunction with Type A leakage tests is sufficient to demonstrate this capability.

COOK NUCLEAR PLANT-UNIT 1 Page B 3/4 6-2

3/4 BASES 3/4.7 PLANT SYSTEMS 3/4.7.1.3 CONDENSATE STORAGE TANK The OPERABILITY of the condensate storage tank with the minimum water volume ensures that sufficient water is available to maintain the RCS at HOT STANDBY conditions for 9 hours with steam discharge to the atmosphere concurrent with total loss of off-site power.The useable water volume limit reflects the volume of water above the centerline of the discharge pipe.An allowance for water not useable because of tank discharge line location or other physical characteristics is not required.3/4.7.1.4 ACTIVITY The limitations on secondary system specific activity ensure that the resultant off-site radiation dose will be limited to a small fraction of 10 CFR Part 100 limits in the event of a steam line rupture.This dose also includes the effects of a coincident 1.0 gpm primary to secondary tube leak in the steam generator of the affected steam line.These values are consistent with the assumptions used in the accident analyses.3/4.7.1.5 STEAM GENERATOR STOP VALVES The OPERABILITY of the steam generator stop valves ensures that no more than one steam generator will blowdown in the event of a steam line rupture.This restriction is required to 1)minimize the positive reactivity effects of the Reactor Coolant System cooldown associated with the blowdown, and 2)limit the pressure rise within containment in the event the steam line rupture occurs within containment.

'sed in the accident analyses With one steam generator stop valve inoperable in MODE I, action must be taken to restore OPERABLE status within 8 hours.Some repairs to the valves can be made with the unit hot.The 8 hour completion time is reasonable, considering the low probability of an accident occurring during this time period that would require a closure of the steam generator stop valves.If the steam generator stop valve cannot be restored to OPERABLE status within 8 hours, the unit must be placed in a MODE in which the LCO does not apply.To achieve this status, the.unit must be placed in MODE 2 within 6 hours and the MODES 2 and 3 action statement entered.The completion times are reasonable, based on operating experience, to reach MODE 2 and to close the steam generator stop valves in an orderly manner and without challenging unit systems.Since the steam generator stop valves are required to be OPERABLE in MODES 2 and 3, the inoperable valves may either be restored to OPERABLE status or closed.When closed, the valves are already in the position required by the assumptions in the safety analysis.The 8 hour completion time is consistent with the MODE 1 action statement requirement.

For inoperable steam generator stop valves that cannot be restored to OPERABLE status within the specified completion time, but are closed, the inoperable valves must be verified on a periodic basis to be closed.This is necessary to ensure that the assumptions in the safety analysis remain valid.The 7 day completion time is reasonable, based on engineering judgement, in view of steam generator stop valve status indications available in the control room, and other administrative controls, to ensure that these valves are in the closed position.If in MODES 2 or 3 the steam generator stop valves cannot be restored to OPERABLE status or are not closed within the associated completion time, the unit must be placed in a MODE in which the LCO does not apply.To achieve this status, the unit must be placed at least in MODE 3 within 6 hours, and in MODE 4 within 12 hours.The allowed completion times are reasonable, based on operating experience, to reach the required unit conditions from MODE 2 conditions in an orderly manner and without challenging unit systems.COOK NUCLEAR PLANT-UNIT 1 Page B 3/4 7-3 AMENDMENT$Q, 48$

This page intentionally left blank COOK NUCLEAR PLANT-UNIT I Page 8 3/4 7-3a f

==1.0 DEFINITIONS==

DEFINED TERMS 1.1 The DEFINED TERMS of this section appear in capitalized type and are applicable throughout these Technical Specifications.

THERMAL POWER 1.2 THERMAL POWER shall be the total reactor core heat transfer rate to the reactor coolant.RATED THERMAL POWER 1.3 RATED THERMAL POWER shall be a total reactor core heat transfer rate to the reactor coolant of 3588 MWt.OPERATIONAL MODE 1.4 An OPERATIONAL MODE shall correspond to any one inclusive combination of core reactivity condition, power level and average reactor coolant temperature specified in Table 1.1.ACTION 1.5 ACTION shall be those additional requirements specified as corollary statements to each principle specification and shall be part of the specifications.

OPERABLE-OPERABILITY 1.6 A system, subsystem, train, component or device shall be OPERABLE or have OPERABILITY when it is capable of performing its specified function(s).

Implicit in this definition shall be the assumption that all necessary attendant instrumentation, controls, normal and emergency elecuical power sources, cooling or seal water, lubrication or other auxiliary equipment that are required for the system, subsystem, train, component or device to perform its function(s) are also capable of performing their related support function(s).

2.0 SAFETY LIMITS AND LIMITING SAFETY SYSTEM SETI1NGS 660 650-~640-8 630:-O Q>620-I 610-'400 PSIA 2250 PSI 2100 PSI 2000 600-1775 PSIA" 590-580.-570'0,2 0.4 0.6 FRACTION OF THERMAI POWER t8588MWI 1.0)0.8 1.2 Pressure (psia)Power (frac)Descri tion of Safe Limits av~Power Tav~Power Tav~Power Tave ('FJ (frac)(FII (frac)('Fj (frac)('Fj 1775 0.00 615.1 1.10 2000 0.00 632.2 1.12 2100 0.00 639.2 1.08 2250 0.00 649.4 1.02 2400 0.00 659.0 0.96 Flow Rate=91,600 gpm/loop 580.0 1.18 577.4 1.2, 576.4 597.6 1.14 596.0 1.2 589A 606.5 1.10 604.8 1.2 593.5 619.5 1.10 610.9 1.2 599.7 631.9 1.1 616.7 1.2 605.7 Figure 2.1-1 Reactor Core Safety Limits Four Loops in Operations COOK NUCLEAR PLANT-UNIT 2 Page 2-2 AMENDMENT 2, 4Ã, 434,

2.0 SAggY LIMITS AND LHVIrrING SAFEIY SYSTEM SETTINGS TABLE 2.2-1 REACTOR TRIP SYSTEM INSTRUMENTATION TRIP SETPOINTS FUNCTIONAL UNIT l.Manual Reactor Trip 2.Power Range, Neutron Flux TRIP SETPOINT Not Applicable Low Setpoint-Less thaa or equal to 25%of RATED THERMAL POWER ALLOWABLE VALUES Not Applicable Low Setpoint-Less than or equal to 26%of RATED THERMAL POWER 3.Power Range, Neutron Flux, High Positive Rate 4.Power Raagc, Neutroa Flux, High Negative Rate 5.Intermediate Range, Neutron Flux 6.Source Range, Neutron Flux 7.Overtemperature Delta T 8.Overpower Delta T High Setpoint-Less than or equal to 109%of RATED THERMAL POWER Less than or equal to 5%of RATED THERMAL POWER with a time constant greater than or equal to 2 seconds Less than or equal to 5%of,.RATED THERMAL POWER with a time constaat greater thaa or equal to 2 seconds Less thaa or equal to 25%of RATED THERMAL POWER Less thaa or equal to 10 couats per second Sec Note 1 See Note 2 High Setpoint-Less than or equal to 110%of RATED THERMAL POWER Less than or equal to 5.5%of RATED THERMAL POWER with a time constant greater than or equal to 2 seconds Less than or equal to 5.5%of RATED THERMAL POWER with a time constant greater than or equal to 2 seconds Less than or equal to 30%of RATED THERMAL POWER Less thaa or equal to 1.3 x 10 counts pcr second See Note 3 See Note 4 Pressurizer Pressure-Low 10.Pressurizer Pressure-High Greater than or equal to 1950 psig Greater than or equal to 1940 psig Less than or.equal to 2385 psig Less than or equal to 2395 psig 11.Pressurizer Water Lcvel--High 12.Loss of Flow Less than or equal to 92%of Instrument span Greater than or equal to 90%of design flow per loop~Less than or equal to 93%of instrument span Greater than or equal to 89.1%of design flow per loop~Design flow is I/4 Reactor Coolant System total flow rate from LCO 3.2.5.COOK NUCLEAR PLANT-UNIT 2 Page 2-5 AMENDMENT A, 434,  

2.0 SAFETY LIMITS AND LIMI'I ING SAFETY SYSTEM SEXI'INGS TABLE 2.2-1 Continued REACTOR TRIP SYSTEM INSTRUMENTATION TRIP SETPOINTS NOTATION I+%'s Note 1: Overtemperature hT 6 hT[K-Ka[-](T-T')+Ks (P-P')-f (~01 o'+~s t 2 where: ETo Indtcated 6T at RATED THERMAL POWER T=Average temperature,'F T=Indicated T>>g at RATED THERMAL POWER less than or equal to 581.3'F.P=Pressurizer Pressure, psig P=Indicated RCS nominal operating pressure (2235 psig or 2085 psig).I+t s I+~as The function generated by the lead-lag controller for Tavg dynamic compensation s~a~Time constants utilized in the lead-Iag controller for Tavg,'t 22 secs, T>4 secs S=Laplace transform operator COOK NUCLEAR PLANT-UNIT 2 Page 2-7 AMENDMENT A, 434,

2.0 SAFEIY LIMITS AND LIMITING SAFETY SYSTEM SETTINGS k TABLE 2.2-1 Continued REACTOR TRIP SYSTEM INSTRUMENTATION TRIP SETPOINTS NOTATIONS Continued KI=1.17 K2=0.0268 K3=0.00111 and fi(d I)is a function of the indicated difference between top and bottom detectors of the power-range nuclear ion chambers;with gains to be selected based on measured instrument response during plant startup tests such that: (i)For qt-qb between-16 percent and+6 percent, fl(hl)=0 (where q, and qb are percent RATED THERMAL POWER in the top and bottom halves of the core respectively, and q,+qb is total THERMAL POWER in percent of RATED THERMAL POWER).(ii)For each percent that the magnitude of (q,-qb)exceeds-16 percent, the IT trip setpoint shall be automatically reduced by 2.05 percent of its value at RATED THERMAL POWER.(iii)For each percent that the magnitude of (qt-qb)exceeds+6 percent, the hT trip setpoint shall be automatically reduced by 2.7 percent of its value at RATED THERMAL POWER.COOK NUCLEAR PLANT-UNIT 2 Page 24 AMENDMENT 82, 434, 2.0 SAFETY LIKGTS AND LIMI'IONG SAFETY SYSTEM SEI f PIGS TABLE 2.2-1 Continued REACTOR TRIP SYSTEM INSTRUMENTATION TRIP SETPOINTS NOTATIONS Continued c>S Note 2: Overpower 4T 6 4To PC,-Ks[-]T-Ks (T-T")-f (41)]'"3 where: 4To Indicated 4T at rated power Average temperature,'F hdicated T>>g at RATED THERMAL POWER less than or equal to 576'F.1.08 K5 0.02/'F for increasing average temperature and 0 for decreasing average temperature 0.00197 for T greater than T;K6=0 for T less than or equal to T v>S (I+s>S)The haction generate by the rate lag conuoller for Tavg dy'c comp nsanon+3 Time constant utilized in the rate lag controller for Ta<<, T3-" 10 secs, S=Laplace transform operator f2 (4I)=0.0 Note 3: The channel's maximum trip point shall not exceed its computed trip point by more than 3.75 percent 4T span.Note 4: The channel's maximum trip point shall not exceed its computed trip point by more than 2.59 percent 4T span.COOK NUCLEAR PLANT-UNIT 2 Page 2-9 AMENDMENT Sl, 434, t f d 3/4 LIMITING CONDITIONS FOR OPERATION AND SURVEILLANCE REQUIREMENTS 3/4.2 POWER DISTRIBUTION LIMITS DNB AND Tav OPERATING PARAMETERS LIMITING CONDITION FOR OPERATION 3.2.5 The following DNB related parameters shall be maintained within the following operational indicated limits: 1.Reactor Coolant System T>>g Less than or equal to 583.3'F 2.Pressurizer Pressure 3.Reactor Coolant System Total Flow Rate Greater than or equal to 2200 psig (for nominal pressure of 2235 psig)/Greater than or equal to 2050 psig (for nominal pressure of 2085 psig)/Greater than or equal to 366,400 gpm APPLICABILITY:

Indicated average of at least three OPERABLE instrument loops.Limit not applicable during either a THERMAL POWER ramp in excess of 5%of RATED THERMAL POWER per minute or a THERMAL POWER step in excess of 10%of RTP Indicated value COOK NUCLEAR PLANT-UNIT 2 Page 3/4 2-15 AMENDMENT A, 434, 3/4 LIMlTING CONDITIONS FOR OPERATION AND SURVEILLANCE REQUIREMENTS 3/4.3 INSTRUMENTATION TABLE 3.34 ENGINEERED SAFETY FEATURE ACTUATION SYSTEM INSTRUMENTATION TRIP SETPOINTS FUNCTIONAL UNIT l.SAFETY INJECTION, TURBINE TRIP, FEEDWATER ISOLATION, AND MOTOR DRIVEN AUXILIARY FEEDWATER PUMPS TRIP SETPOINTS ALLOWABLE VALUES a.Manual Initiation b.Automatic Actuation Logic Not Applicable Sec Functional Unit 9 Not Applicable c.Containment Pressure-High Less than or equal to 1.1 psig Less than or equal to 1.2 psig d.Pressurizer Pressure-Low Greater than or equal to 1815 psig Greater than or equal to 1805 psig e.Differential Pressure Between Steam Lines-High f.Stcam Line Pressure-Low Less than or equal to 100 psi Greater than or equal to 500 psig steam linc pressure Less than or equal to to 112 psi Greater than or equal to 480 psig steam line prcssure COOK NUCLEAR PLANT-UNIT 2 Page 3/4 3-23 AMENDMENT 4;44,&, 434,~,

3/4 LIMING CONDITIONS FOR OPERATION AND SURVEILLANCE REQUDKMENTS 3/4,4 REACTOR COOLANT SYSTEM SAFETY VALVES-OPERATING LIMITING CONDITION FOR OPERATION 3.4.3 All pressurizer code safety valves shall be OPERABLE with a lift setting of 2485 PSIG+3%.~>>APPLICABILITY:

MODES I, 2 and 3.ACTION: With one pressurizer code safety valve inoperable, either restore the inoperable valve to OPERABLE status within 15 minutes or be in HOT SHUTDOWN within 12 hours.SURVEILLANCE RE UIREMENTS 4.4.3 No additional Surveillance Requirements other than those required by Specification 4.0.5.The pressurizer code safety valve shall be reset to the nominal value J1%whenever found outside the J1%tolerance.

The lift setting pressure shall correspond to ambient conditions of the valve at nominal operating temperature and pressure.COOK NUCLEAR PLANT-UNIT 2 Page 3/4 4-5

3/4 LIMITING CONDITIONS FOR OPERATION AND SURVEILLANCE REQUIIKMENTS 3/4.4 REACTOR COOLANT SYSTEM LIMITING CONDITIONS FOR OPERATION Continued SURVEILLANCE RE UIREMENTS 4.4.6.2.1 Reactor Coolant System leakages shall be demonstrated to be within each of the above limits by: Monitoring the containment atmosphere particulate radioactivity monitor at least once per 12 hours.b.Monitoring the containment sump inventory and discharge at least once per 12 hours.C.Determining the seal line resistance at least once per 31 days when the average pressurizer pressure is within 20 psi of its nominal full pressure value.The seal line resistance measured during the surveillance must be greater than or equal to 2.27 E-1 ft/gpm'.The seal line resistance, R<<, is determined from the following expression:

2.31(P,p-P<<)st qs where: Pcia,=charging pump header pressure, psig P<<=2112 psig (Iow pressure operation)

=2262 psig (high pressure operation) 2.31=conversion factor (12 in/ft)t/(62.3 Ib/fthm)Q=the total seal injection flow, gpm The provisions of Specification 4.0.4 are not applicable for entry into MODES 3 and 4.d.Performance of a Reactor Coolant System water inventory balance at least once per 72 hours during steady state operation, and e.Monitoring the reactor head flange leakoff system at least once per 24 hours.4.4.6.2.2 Each reactor coolant system pressure isolation valve specified in Table 3.4-0 shall be demonstrated OPERABLE pursuant to Specification 4.0.5.COOK NUCLEAR PLANT-UNIT 2 Page 3/4 4-16 AMENDMENT 446, 474, tI li 3/4 LIMITING CONDITIONS FOR OPERATION AND SURVEILLANCE REQUIRElVQMIS 3/4.4 REACTOR COOLANT SYSTEM 2600 2400 2200 2000 (9 1800 1600 g 1400 1200 0 1000 o 0 o~800 REACTOR COOLANT SYSTEM HEATUP LIMITATIONS APPLICABLE FOR FIRST 14.5 EFFECTIVE FULL POWER YEARS (MARGINS OF 60 PSIG AND 10'F ARE INCLUDED FOR POSSIBLE INSTRUMENT ERROR)LEAK lEST uMrr MATERIAL PROPERTY BASIS INTERMEDIATE PLATE, 2 C&.15%i&.57%INITNL RTIIor'F 14.5 EFPY RTII0T(1/4T) 178'F (3/47)150'F UNACCEPTABLE I OPERATION PRESSURE-TEMPERATURE UMIT FOR HEATUP RATES UP TO 60'/HR ACCEPTABLE OPERATION 50 100 150 200 250 300 350 400 450 AVERAGE REACTOR COOLANT SYSTEM TEMPERATURE (deg.F)Figure 3.4-2 Reactor Coolant System Pressure-Temperature Limits for 60'F/hr Rate, Criticality Limit and Hydrostatic Test Limit COOK NUCLEAR PLANT-UNIT 2 Page 3/4 4-25 AMENDMENT 4Q, 42$, XV',  

3/4 LIMITING CONDITIONS FOR OPERATION AND SURVEILLANCE REQUIREMENTS 3/4.4 REACTOR COOLANT SYSTEM 2400 2200 2000 REACTOR COOLANT SYSTEM COOLDOWN UMITATIONS APPLICABLE FOR FIRST 14,5 EFFECTIVE FULL POW YEARS (MARGINS OF 60 PSIG AND 10'F ARE INCLUDED FOR POSSIBLE INSTRUMENTATION ERROR.)UNACCEPTABLE OPERATION C9 1800 0 1600 ttj 1400 g 1200 1000 O 800 o o~600 400 200 COOLDOWN RATE'F/HR I ACCEPTABLE OPERATION I PRESSURE-TEMPERATURE LIMITS I I MATERIAL PROPERTY BASIS INTERMEDIATE PLATE, C5556-2 Cu-.15%, Ni.57%INITIAL RTNDT 58 F 14.5 EFPY RT NDT(1/4I)178'F (3/4T)-150.F I I 50 100 150 200 250 300 350 400 450 AVERAGE REACTOR COOLANT SYSTEM TEMPERATURE (deg.F)Figurc 3.4-3 Reactor Coolant System, Pressure-Temperature, Limits for Various Cooldown RatesCOOK NUCLEAR PLANT-UNIT 2 Page 3/4 4-26 AMENDMENT 6Q,~, 474,  

3/4 LIMI'IONG CONDITIONS FOR OPERATION AND SURVEILLANCE REQUIREMENTS 3/4.5 EMERGENCY CORE COOLING SYSTEMS (ECCS)ECCS SUBSYSTEMS

-T3 B 330'F LIMITING CONDITION FOR OPERATION 3.5.2 Two independent ECCS subsystems shall be OPERABLE with each subsystem comprised of: a.One OPERABLE centrifugal charging pump, b.One OPERABLE safety injection pump, One OPERABLE residual heat removal heat exchanger, One OPERABLE residual heat removal pump, An OPERABLE flow path capable of taking suction from the refueling water storage tank on a safety injection signal and transferring suction to the containment sump during the recirculation phase of operation.

MODES 1, 2, and 3.ACTION: With one ECCS subsystem inoperable, restore the inoperable subsystem to OPERABLE status within 72 hours or be in HOT SHUTDOWN within the next 12 hours.In the event the ECCS is actuated and injects water into the Reactor Coolant System, a Special Report shall be prepared and submitted to the Commission pursuant to Specification 6.9.2 within 90 days describing the circumstances of the actuation and the total accumulated actuation.

cycles to date.COOK NUCLEAR PLANT-UNIT 2 Page 3/4 5-3 AMENDMENT 447,  

3/4 LIMITING CONDITIONS FOR OPERATION AND SURVEILLANCE REQUIREMENTS 3/4.7 PLANT SKI'EBLIS TABLE 3.7-1 MAXIMUM ALLOWABLE POWER RANGE NEUTRON FLUX HIGH SETPOINT WITH INOPERABLE STEAM LINE SAFETY VALVES DURING 4 LOOP OPERATION Maximum Number of Inoperable Safety Valves on Any Operating Steam Generator Maximum Allowable Power Range Neuttcn Flux High Setpoint (Percent of RATED THERMAL POWER)58.1 41.2 24.5 COOK NUCLEAR PLANT-UNIT 2 Page 3/4 7-2

',I II BASES 2.0 SAFEIY LIMITS AND LIMITING SAH'Y SYSTEM SKI'INGS 2.1 SAFETY LIMITS 2:1.1 REACTOR CORE The restrictions of this safety limit prevent overheating of the fuel and possible cladding perforation which would result in the release of fission products to the reactor coolant.Overheating of the fuel cladding is prevented by restricting fuel operation to within the nucleate boiling regime where the heat transfer coefficient is large and the, cladding surface temperature is slightly above the coolant saturation temperature.

DNB is not a directly measurable parameter during operation and therefore THERMAL POWER and reactor coolant temperature and pressure have been related to DNB through the WRB-2 correlation and W-3 correlation for conditions outside the range of WRB-2.The DNB correlations have been developed to predict the DNB flux and the location of DNB for axially uniform and nonuniform heat flux distributions.

The local DNB heat flux ratio (DNBR)is defined as the ratio of the heat flux that would cause DNB at a particular core location to the local heat flux, and is indicative of the margin to DNB.The DNB design basis is as follows: there must be at least a 95 percent probability that the minimum DNBR of the limiting tod during Condition I and II events is greater than or equal to the DNBR limit of the DNB correlation being used (the WRB-2 correlation for Vantage-5 fuel, and the W-3 conelation for conditions which fall outside the range of applicability of the WRB-2).The correlation DNBR limits are established based on the entire applicable experimental data set such that there is a 95 percent probability with 95 percent confidence that DNB will not occur when the minimum DNBR is at the DNBR limit (1.17 for WRB-2 and 1.3 for the W-3).In meeting the DNB design basis, uncertainties in plant operating parameters, nuclear and thermal parameters, and fuel fabrication parameters are statistically combined with the DNBR correlation statistics such that there is at least a 95 percent probability with a 95 percent confidence level that the minimum DNBR for the limiting rod is greater than or equal to a calculated design limit DNBR.The uncertainties in the above plant parameters are used to determine the plant DNBR uncertainty.

This DNBR uncertainty, combined with the DNBR correlation statistics, establishes a design DNBR value which must be met in plant safety analyses using values of input parameters without uncertainties.

For Cook Nuclear Plant Unit 2, the design DNBR values are 1.23 and 1.22 for Vantage-5 fuel typical and thimble cells, respectively.

In addition, margin has been maintained by performing safety analyses to a safety analysis limit DNBR.The margin between the design and safety analysis limit DNBR is used to offset known DNBR penalties (i.e., transition core penalties, rod bow, etc,)and provide DNBR margin for operating and design flexibility.

The curves of Figure 2.1-1 show the loci of points of THERMAL POWER, Reactor Coolant System pressure, and average temperature below which the calculated DNBR is no less than the design DNBR limit value or the average enthalpy at the vessel exit is less than the enthalpy of saturated liquid.COOK NUCLEAR PLANT-UNIT 2 Page B 2-1 AMENDMENT 84, 434, BASES 2.0 SAFEIY LIMITS AND LIIUKI1NG SAIK'IY SYSTEM SETHNGS 2.2.1 REACTOR TRIP SYSTEM INSTRUMENTATION SETPOINTS (Continued)

Ove wer Delta T The Overpower Delta T reactor trip provides assurance of fuel integrity, e.g., no melting, under all possible overpower conditions, limits the required range for Overtemperature Delta T protection, and provides a backup to the High Neutron Flux trip.The setpoint includes corrections for changes in density and heat capacity of water with temperature, and dynamic compensation for piping delays from the core to the loop temperature detectors.

The overpower delta T reactor trip provides protection or back-up protection for at-power steam line break events.Credit was taken for operation of this trip in the steam line break mass/energy releases outside containment analysis.In addition, its functional capability at the specified trip setting is required by this specification to enhance the overall reliability of the Reactor Protection System.Pressurizer Pressure The Pressurizer High and Low Pressure trips are provided to limit the pressure range in which reactor operation is permitted.

The High Pressure trip is backed up by the pressurizer code safety valves for RCS overpressure protection, and is therefore set lower than the set pressure for these valves (2485 psig).The High Pressure trip provides protection for a Loss of External Load event.The Low Pressure trip provides protection by tripping the reactor in the event of a loss of reactor coolant pressure.Pressurizer Water Level The Pressurizer High Water Level trip ensures protection against Reactor Coolant System overpressurization by limiting the water level to a volume sufficient to retain a steam bubble and prevent water relief through the pressurizer safety valves.The pressurizer high water level trip precludes water relief for the uncontrolled control rod assembly bank withdrawal at-power event.COOK NUCLEAR PLANT-UNIT 2 Page B 2-5 AMENDMENT 82, 434, 442, 3/4 BASES 3/4.2 POKER DIS'GUBUTION LIMITS 3/4.2.2 and 3/4.2.3 HEAT FLUX HOT CHANNEL FACTOR AND NUCLEAR ENTHALPY RISE HOT CHANNEL FACTOR Continued When RCS flow rate and PAH are measured, no additional allowances are necessary prior to comparison with the limits of Specification 3.2.3.Measurement errors of 2.1%for RCS flow total flow rate and 4%for F>H have been allowed for in determination of the design DNBR value and in the determination of the LOCA/ECCS limit.Margin between the safety analysis DNBRs and the design limit DNBRs is maintained.(Safety analyses DNBRs: 1.69 and 1.61 for the Vantage 5 typical and thimble cells, respectively.

A fraction of this margin is utilized to accommodate applicable transition core penalties and the appropriate fuel rod bow DNBR penalty for the Vantage 5 fuel (equal to 1.3%per%CAP-8691, Rev.1).The remainder of the margin between design and safety analysis DNBR limits can be used for plant design flexibility.

COOK NUCLEAR PLANT-UNIT 2 Page B 3/4 24a AMENDMENT 434,  

3/4 BASES 3/4.2 POWER DISTRIBUTION LIMITS 3/4.2.4 UADRANT POWER TILT RATIO The quadrant power tilt ratio limit assures that the radial power distribution satisfies the design values used in the power capability analysis.Radial power distribution measurements are made during startup testing and periodically during power operation.

The limit of 1.02 at which corrective action is required provides DNB and linear heat generation rate protection with x-y plane power tilts.The two hour time allowance for operation with a tilt condition greater than 1.02 but less than 1.09 is provided to allow identification and correction of a dropped or misaligned rod.In the event such action does not correct the tilt, the margin for uncertainty on F~is reinstated by reducing the power by 3 percent from RATED THERMAL POWER for each percent of tilt in excess of 1.0.3/4.2.5 DNB PARAMETERS The limits on the DNB-related parameters ensure that each of the parameters are maintained within the normal steady-state envelope of operation assumed in the transient and accident analyses.The Tav<less than or equal to 583.3'F and pressurizer pressure greater than or equal to 2200 psig (for nominal pressurizer operating pressure of 2235 psig)or greater than or equal to 2050 psig (for nominal pressurizer operating pressure of 2085 psig)are consistent with the UFSAR assumptions and have been analytically demonstrated adequate to maintain the core at or above the design DNBR thoughout each analyzed transient with allowance for measurement uncertainty.

Pressurizer pressure is limited to either of two nominal operating pressures of 2235 psig or 2085 psig, with the corresponding indicated limits set forth in the specifications.

The limits are consistent with the UFSAR assumptions and have been analytically demonstrated to be adequate to maintain the core at or above the applicable design limit DNBR value for the current fuel type throughout each analyzed transient.

The 12 hour periodic surveillance of these parameters through instrument readout is sufficient to ensure that the parameters are restored within their limits following load changes and other expected transient operation.

The 12-hour surveillance of the RCS flow measurement is adequate to detect flow degradation.

The CHANNEL CALIBRATION performed after refueling ensures the accuracy of the shiftly flow measurement.

The total flow is measured after each refueling based on a secondary side calorimetric and measurements of primary loop temperatures.

COOK NUCLEAR PLANT-UNIT 2 Page B 3/4 2-5 AMENDMENT S2, 434, 0 f 0 3/4 BASES 3/4.4 REACTOR COOLANT SYSTEM 3/4.4.9 PRESSURE/TEMPERATURE LIMITS All components in the Reactor Coolant System are designed to withstand the effects of cyclic loads due to system temperature and pressure changes.These cyclic loads are introduced by normal load transients, reactor trips, and startup and shutdown operations.

The various categories of load cycles used for design purposes are provided in Section 4.1.4 of the FSAR.During startup and shutdown, the rates of temperature and pressure changes are limited so that the maximum specified heatup and cooldown rates are consistent with the design assumptions and satisfy the stress limits for cyclic operation.

An ID or OD one-quarter thickness surface flaw is postulated at the location in the vessel which is found to be the limiting case.There are several factors which influence the postulated location.The thermal induced bending stress during heatup is compressive on the inner surface while tensile on the outer surface of the vessel wall.During cooldown the bending stress profile is reversed.In addition, the material toughness is dependent upon irradiation and temperature and therefore, the fluence profile through the reactor vessel wall, the rate of heatup and also the rate of cooldown influence the postulated flaw location.The heatup limit curve, Figure 3.4.2, is a composite curve which was prepared by determining the most conservative case, with either the inside or outside wall controlling, for any heatup rate up to 60'F per hour.The cooldown limit curves of Figure 3.4-3 are composite curves which were prepared based upon the same type analysis with the exception that the controlling location is always the inside wall where the cooldown thermal gradients tend to produce tensile stresses while producing compressive stresses at the outside wall.The heatup and cooldown curves were prepared based on the most limiting value of the predicted adjusted reference temperature at the end of 14.5 EFPY.The reactor vessel materials have been tested to determine their initial RTND T.The results of these tests are shown in Table B 3/4.4-1.Reactor operation and resultant fast neutron (E)1 MeV)irradiation will cause an increase in the RTNDT.Therefore, an adjusted reference temperature must be predicted in accordance with Regulatory Guide 1.99, Revision 2.This prediction is based on the fluence and a chemistry factor determined from one of two Positions presented in the Regulatory Guide.Position (1)determines the chemistry factor from the copper and nickel content of the material.Position (2)utilizes surveillance data sets which relate the shift in reference temperature of surveillance specimens to the fluence.The selection of Position (1)or (2)is made based on the availability of credible surveillance data, and the results achieved in applying the two Positions.

COOK NUCLEAR PLANT-UNIT 2 Page 8 3/4 46 AMENDMENT 6Q, 4', 474,  

3/4 BASES 3/4.4 REACTOR COOLANT SYSTEM 3/4.4 9 PRESSURE/TEMPERATURE LIMITS Continued The actual shift in the reference temperature of surveillance specimens and neutron fluence is established periodically by removing and evaluating reactor vessel material irradiation surveillance specimens and dosimetry installed near the inside wall of the reactor vessel in the core area.The heatup and cooldown limit curves of Figures 3.4-2 and 3.4-3 include predicted adjustments for this shift in RT>>r at the end of 14.5 EFPY, as well as adjustments for possible errors in the pressure and temperature sensing instruments.

1.The intermediate shellplate, C5556-2, is the limiting material as determined by position I of Regulatory Guide 1.99, Revision 2, with a Cu and Ni content of 0.15%and 0.57%, respectively.

2.The fluence values contained in Table 6-14 of Westinghouse WCAP-13515 report,"Analysis of Capsule U From the Indiana Michigan Power Company D.C.Cook Unit 2 Reactor Vessel Radiation Surveillance Program", dated February 1993.The RT>>r shift of the reactor vessel material has been established by removing and evaluating the reactor material surveillance capsules in accordance with the removal schedule in Table 4.4-5.Per this schedule, Capsule U is the last capsule to be removed until Capsule S is to be removed after 32 EFPY (EOL).Capsules V, W, and Z will remain in the reactor vessel and will be removed to address industry reactor vessel embrittlement concerns, if required.The pressure-temperature limit lines shown on Figure 3.4-2 for reactor criticality and for inservice leak and hydrostatic testing have been provided to assure compliance with the minimum temperature requirements of Appendix G to 10 CFR 50.The number of reactor vessel irradiation surveillance specimens and the frequencies for removing and testing these specimens are provided in Table 4.4-5 to assure compliance with the requirements of Appendix H to 10 CFR Part 50.The limitations imposed on pressurizer heatup and cooldown and spray water temperature differential are provided to assure tliat the pressurizer is operated within the design criteria assumed for the fatigue analysis performed in accordance with the ASME Code requirements.

The OPERABILITY of two PORVs, or of one PORV and the RHR safety valve ensures that the RCS will be protected from pressure transients which could exceed the limits of Appendix G to 10 CFR Part 50 when one or more of the RCS cold legs are less than or equal to 152'F.Either PORV or RHR safety valve has adequate relieving capability to protect the RCS from overpressurization when the transient is limited to either (1)the start of an idle RCP with the secondary water temperature of the stem generator less than or equal to 50'F above the RCS cold leg temperatures of (2)the start of a charging pump and its injection into a water solid RCS.Therefore, any one of the three blocked open PORVs constitutes an acceptable RCS vent to preclude APPLICABILITY of Specification 3.4.9.3.3/4.4.10 STRU TURAL INTEGRITYThe inspection and testing programs for ASME Code Class 1, 2 and 3 components ensure that the structural integrity of these components will be maintained at an acceptable level throughout the life of the plant.To the extent applicable, the inspection program for these components is in compliance with Section XI of the ASME Boiler and Pressure Vessel Code.COOK NUCLEAR PLANT-UNIT 2 Page B 3/4 4-10 AMENDMENT BQ, 423, 4A, 474 iJ, ,L 3/4 BASES 3/4,5 EMERGENCY CORE COOLING SYSTEMS-3/4.5.1 ACCUMULATORS Continued allowed completion times are reasonable, based on operating experience, to reach the required plant conditions from full power conditions in an orderly manner and without challenging plant systems.If more than one accumulator is inoperable, the plant is in a condition outside the accident analyses;therefore, LCO 3.0.3 must be entered immediately.

3/4.5.2 311d 3/4.5.3 ECCS SUBSYSTEMS The OPERABILITY of two independent ECCS subsystems ensures that sufficient emergency core cooling capability will be available in the event of a LOCA assuming the loss of one subsystem through any single failure consideration.

Either subsystem operating in conjunction with the accumulators is capable of supplying sufficient core cooling to limit the peak cladding temperatures within acceptable limits for all postulated break sizes ranging from the double ended break of the largest RCS cold leg pipe downward.In addition, each ECCS subsystem provides long term core cooling capability in the recirculation mode during the accident recovery period.COOK NUCLEAR PLANT-UNIT 2 Page B 3/4 5-la AMENDMENT BQ, 447, 440, 1 II 3/4 BASES 3/4.6 CONTAINMENT SYSTEMS 3/4.6.1.4 INTERNAL PRESSURE The limitations on containment internal pressure ensure that 1)the containment structure is prevented from exceeding its design negative pressure differential with respect to the outside atmosphere of 8 psig and 2)the containment peak pressure does not exceed the design pressure of 12 psig during LOCA conditions.

The maximum peak pressure resulting from a LOCA event is calculated to be less than the design limit of 12 psig, which includes 0.3 psig for initial positive containment pressure.3/4.6.1.5 AIR TEMPERATURE The limitations on containment average air temperature ensure that I)the containment air mass is limited to an initial mass sufficiently low to prevent exceeding the design pressure during LOCA conditions and 2)the ambient air temperature does not exceed that temperature allowable for the continuous duty rating specified for equipment and instrumentation located within containment.

The containment pressure transient is sensitive to the initially contained air mass during a LOCA.The contained air mass increases with decreasing temperature.

The lower temperature limit of 60'F will limit the peak pressure to less than the containment design pressure of 12 psig.The upper temperature limit influences the peak accident temperature slightly during a LOCA;however, this limit is based primarily upon equipment protection and anticipated operating conditions.

Both the upper and lower temperature limits are consistent with the parameters used in the accident analyses.3/4.6.1.6 CONTAINMENT VESSEL STRUCTURAL INTEGRITY This limitation ensures that the structural integrity of the containment will be maintained comparable to the original design standards for the life of the facility.Structural integrity is required to ensure that (1)the steel liner remains leak tight and (2)the concrete surrounding the steel liner remains capable of providing external missile protection for the steel liner and radiation shielding in the event of a LOCA.A visual inspection in conjunction with Type A leakage tests is sufficient to demonstrate this capability.

COOK NUCLEAR PLANT-UNIT 2 Page B 3/4 6-2 i I 0 3/4 BASES 3/4.7 PLANT SYSTEMS 3/4.7.1.3 CONDENSATE STORAGE TANK I The OPERABILITY of the condensate storage tank with the minimum water volume ensures that sufficient water is available to maintain the RCS at HOT STANDBY conditions for 9 hours with steam discharge to the atmosphere concurrent with total loss of off-site power.The useable water volume limit reflects the volume of water above the centerline of the discharge pipe.An allowance for water not useable because of tank discharge line location or other physical characteristics is not required.3/4.7.1.4 ACTIVITY The limitations on secondary system specific activity ensure that the resultant off-site radiation dose will be limited to a small fraction of 10 CFR Part 100 limits in the event of a steam line rupture.This dose also includes the effects of a coincident 1.0 gpm primary to secondary tube leak in the steam generator of the affected steam line.These values are consistent with the assumptions used in the accident analyses.3/4.7.1.5 STEAM GENERATOR STOP VALVES The OPERABILITY of the steam generator stop valves ensures that no more than one steam generator will blowdown in the event of a steam line rupture.This restriction is required to I)minimize the positive reactivity effects of the Reactor Coolant System cooldown associated with the blowdown, and 2)limit the pressure rise within containment in the event the steam line rupture occurs within containment.

The OPERABILITY of the steam generator stop valves within the closure times of the surveillance requirements are consistent with the assumptions used in the.accident analyses.With one steam generator sto p valve inoperable in MODE I, action must be taken to restore OPERABLE status withm 8 hours.Some repairs to the valves can be made with the unit hot.The 8 hour completion time is reasonable, considering the low probability of an accident occurring during this time period that would require a closure of the steam generator stop valves.If the steam generator stop valve cannot be restored to OPERABLE status within 8 hours, the unit must be placed in a MODE in which the LCO does not apply.To achieve this status, the unit must be placed in MODE 2 within 6 hours and the MODES 2 and 3 action statement entered.The completion times are reasonable, based on operating experience, to reach MODE 2 and to close the steam generator stop valves in an orderly manner and without challenging unit systems.COOK NUCLEAR PLANT-UNIT 2 Page B 3/4 7-3 AMENDMENT W, 470, I

ATTACHMENT 3 TO AEP:NRC:1223 EXISTI'NG TECHNICAL SPECIFICATION PAGES MARKED TO REFLECT PROPOSED CHANGES  

The OPERABILITY of the steam generator stop valises within the closure times of the surveillance requirements aze consistent w5.th the assumptions used in the accident analyses.With one steam generator stop valve inoperable in MODE I., action must be Caken to restore OPERABLE status within 8 hours.Some repairs to the valves can be made with the unit hot.The 8 houx completion.time is reasonable, considering the low probability of an accident occurring during this time.period that would require a closure of'he steam generator stop valves.If the steam generator scop valve cannot be restoxed to OPERABLE status within 8 hours, the unit must be placed in a MODE in which the LCO does not apply.To achieve this status, the unit must be placed in MODE 2 within 6 hours and the MODES 2 and 3 acCion statement entered.The completion times are reasonable, based on operaCing experience, Co reach MODE 2 and to close the steam generator stop valves in an orderly manner and without challenging unit systems.Since the steam generator stop valves are required to be OPERABLE in MODES 2 and 3, the inoperable valves may either be restored to OPERABLE status or closed.When closed, the valves are already in the posiCion required by the assumptions in che safety analysis.The 8 hour completion time is consiscenC COOK NUCLEAR PLANT-UNIT 1 B 3/4 7-3 AMENDMENT NO.W, 185, IANT SYSTEMS~AS~K 4 ST GENERATOR STOP VALVES co tinued.with the MODE 1 action statement requirement.

For inoperable steam generator stop valves that cannot be restored to OPERABLE status within the specified completion time, but are closed, the inoperable valves must be verified on a periodic basis to be closed.This is necessary to ensure that the assumptions in the safety analysis remain valid.The 7 day completion time is reasonable, based on engineering Judgement, in view of steam generator stop valve status indications available in the control zoom,'and other adlai.stzative controls, to ensure that these valves are in the closed position.Xf in NODES 2 or 3 the steam generator stop valves cannot be restored to OPERABLE status or aze not closed within the associated completion time, the unit must be placed in a MODE in which the LCO does not apply.To achieve this status, the unit-must be placed at least in MODE 3 within 6 hours, and in NODE 4 within 12 hours.The allowed completion times aze reasonable, based on operating experience, to reach the required'nit conditions from MODE 2 conditions in an orderly manner and without challenging unit systems.COOK NUCLEAR PLANT-UNXT 1 B 3/4 7-3a AMENDMENT NO.185,  

CURRENT PAGES MARKED-UP TO REFLECT PROPOSED CHANGES TO THE COOK NUCLEAR PLANT UNIT NO.2 TECHNICAL SPECIFICATIONS C~lvlTTCMS OEFlhH TERS 1.i The OEFTHEQ TERS of this sect<on ayaear<n cayftall~type ancl are ayylfc-aole througnoict these Technical Soedflcat<ons.

tag ta 4 C&#xc3;9L 40 ES?T 8 0 fA Vlt (Je Vg 4C (F?et T g F l tt ps O.615.9.S.a.02 4.9.2 cQOO O.O.SS 6.t 0 6 59.5 5.5 QO.QO 6.K 0 2 61<0 0 6'2 0.7 2$..9 45 0.6 60.6 37 340: S6 f~0 0.0 39..62 2.0.2 65 40 C<0 FSS 54 lA 0-144 44 Stk 1 0 A 5 0-, 57 e-.so.0 ffguiI 2.1 1 Ffer l4ta 91,600 gpafloop (Furl Vaa'Aia, 5~)P~t Tave~Q~o Cfracl L2'fadL.44k Qmrl D75 0.00 613.1 1.10 5ea.a I.le Sn.a 1.2 2000 0.00 632.2 1.12 597.5 I.14 596.0 1.2 Tavg~d SZSA 589.4 2100 0.00 639.2 1.08 605.5 1.10 6N.8 1.2 593.5 2250 2400 0.00 639.0 0.96 631.9 I.l , 616.7 605;F 0.00 Q9.4 1.02&19.5 1.10 610.9 1.2 599.7~~cg Lal CS CI 4SI 5 am~i+V75 tQA~~M,"to FRACfJN Of llIEWQL NIKR (95OOWt;=La)

Figure 2.1-1 Reactor Con Safety t.fata Fen Loops 3a Operatfoa

~TUL 2.T.TRI?fYSTDf TN~iQfQfTATI0N WI?S~~0NAJ-UNIT WIT SETPOI&#xc3;Z AIICOASI?VAL~l~Nanuel Reaocor TrSy Nec Applicable 2.fever Range, Neutron Lov Secyoknc~Laaa than Flux~r equal to 25'f RATED Q)ER)aU.NaX Rtgh Secpotnt~Loaa than er equal co 10%%oC RATED CREEDAL BRED 5~lover Range~Neutron Lkaa than er equal co 51 ef Flux, Mt'oatctvo RATED%QRNAL?CNXk vtch a Race tive eonacant greater than~r equal to 2 aeeoaCa 4.?over Range, Neutron Laaa than er equaL to 5l ef flux.&Sh Negative RATED THER)fAL NE'ER vtth a kate tioe conacant ggeatar than~r equaL to 2 aeeoeuta Nec~Lteabl<<Lov Seeyetnt~L<<<<a than or equaL to 2Ct<<C RAIiD TERNAL?m EX Qgh 5<<gotnc~L<<aa~4 or equaL to LL0I ef RATED'DER))AL 20QEX Laaa than er<<quaL co 5.$i of RATED QKlXAL 8&#xc3;EX viA a cthe cenacant g.<<at<<r chan er<<qual ta 2 a<<coats Laaa than er<<quaL to 5.5i~C RAtED THECAL?CQXL vtW 4 test coclacaot+eater than er<<quaL ca 2 aecoack 5o Encawedtate Range~Naut=on flux C.Source Range, Neucr~flux~~7~Overten)eeracuro DeLca T Leaa than er equaL to 25%~f RATED 5)mQL NQXX Laaa chan er equaL to LO oounta p4r a4cooL See Nota l Laaa than er<<qual to 20i oC RATED T))ERAL ROE'a)a than er<<quaL to L.l x 10 ceonca per<<<<cod See Nota 3 C.Ovegover Delta 7 See Nota 2 See Noca 4%.Preaau=Qar

&eaaure Lov L0.freaaurtrer tzeaauca ee QQ LL.?teaaurtaar Voter Lovel>>Qgh L2.Loaa of flov Crutar than er equaL to L$50 yatg Laoa chan er equaL to 2545 yatg Leaa chan er equal to N%~f tna~nc apaa Creator than er<<qual to Nt ef 4aatgn flov per Creacer than er equaL to U40 patg Loaa than er<<qoaL co 25S5 yakg Leaa than or'qual co Sls~C tna~nc tp<<n Creacer than<<r equaL to 4%.ll ef CeatpL.'L<<v y<<c'~Death flov ta~)'(~~c.~-.+

<,~-""'

@here: hT 0 P'+~S Tlo T2 hT<hT'K-K f(1+mls)/(1+g2S)](T-T')+(P-P')-fl(hI)

J IndLcated hT at RhTED 5KQQL PSKR~hverage temperature, F 0~Inttcatid T at RhTED THHQQLL tSKR less than or equal t,o~l.3'F surfer Pressure.psfg~p$$$gfxldicRcId RCS DoEf041 opozs'cog pL'55llzEf+95~g or QoP$'@sic The function pnerate4 by the lead-lag controller for T dynanic coctpensa&on 4V j~Tive constants utilized h the lead-lai controller, for T;rl~secs, v2 4 secs.Laplace trans fo rater COOK HUCLZhR TLhBT QHIT 2 2 7 mxmazr so.82~34 II f!,

c 2.2-l Continued REhCTOR TRIP 5YSTBf INSTRUMBKlTICN TRIP~c,;TNT'ORTATION Cantiaaad) 4 Loops fn Oped'scion Xl~ke09 I.l7 a~am o.oQ.47+~+41@54 0.04 t1 t and f>(4I)ia a function of the indicated difference becveen toy snd bottoa detectors of the yavet-range nucleat ion chsnbez's; Kth gains to be selected based on aeaeued inst@ment response dutiag y4nc scatty tests esca cham: (i)foz'-qb becveen~yezcent and+6 pezcant, f>(hI)W (vheze q and q ate percent RhTZD QKQQL NVKR in the top and bottoa halves of the coze respectively, and q+q is total OKRA B%ER in yet'cent of RhTED BANAL POUER).(ii)fox'ach percent that the magnitude of{q-q)exceeds yetcanc, che 4T eely setyoint shaQ be autocatically t'echoed peccant of its vatue at RAZED TH&LAL ESKER.ok (iii)For each percent that the axed.ate of (g g)exceeds+5 percent, the ht crLy setyoint sha11 be axcoeatically itdnced Q LrO pattens oi its valQ4 at RhTZD 5KRQL PSKR c4?COOK HUCLEhR P?hHT VHZT g 2-4 AKHDt62fT 80.82~<'3~

TABLE 2.2-1 Continued REACTOR TRIP SYSTBt INSTRUMENTATION TRIP SETPOINTS NOTATIONS Continued Overpo<<r AT<hT (K4-K5(t3S/(1+r3S)]T-K6(T-T"]-j

(<I)]%here: K4 K5 K6 Indicated hT at rated pover Average temperature, F 0 C Indicated T at RATED THERMAL POVER less than or avg equal to 576.0 F 1.08 0 0.02/F for increasing average temperature and 0 for decreasing average temperature

-0.0019?for T greater than T', K6 0 for T less than or equal to T" AS/(1+z S)The function generated by the 3 T dynamic compensation avg T3 Time constant utilized in the T y r3~10 sees'vg.S=Laplace transform operator f2(g)-0 0 rate lag controller for rate lag controller for Note 3: Note 4: The channel's maximum trip point shall not point by more than (Qt percent Q'pan.3.'lS The channel's maximum trip point shall not point by more than QP percent Q span.BS'].exceed its computed trip I exceed its computed trip COOK NUCLEAR PLANT-UNIT 2 2-9 AMamMENT NO.82, 134 i

POSE OI 5 aRI5UTION LINITS DN5 hND Tav OPERATINC PARAMZEERS LL9ITINC CONDITION FOR OPERATION 3.2.5 The folloving D?8 related parameters shall be maintain<<vichin che follovtng operational indicaced limits'.a.DN Zo sz~k 1.Reactor Coolanc System T 2.Pressurizer Pressure 3.Reaccor Coolant Syscem Total Flov Rate Less chan or equal co 57$.7 W 0 Creacer than or equal co 2200 paid+/~Creacer or aqua to, gp~b.T avg 1.Reactor Coolant System T gg/~APPLICA5ILITY:

MODE 1 Creater chan or equal to 543,9 F>>hCTION:><ch any of the above parameters exceeding ics limit, rescore the parameter to vithin ics limit vithin 2 hours or reduce THZ@gZ, pyrZR.co less than 5g of RATED THERMAL PCQER vichin the next 4 hours.SURVEILvVNCE RE RBfQiTS 4.2.5.1 Each of the above parameters shall'be verified to be vithin their.limits ac lease once per 12 hours.4.2.5.2 Th>>indicators used co determine RCS tocal flov shall be subjected co a CHANNEL CALXBRATIOH ac, least once per 1$months.4.2.5.3 The RCS tocal'lov rata shall be determined by a pover balance around the steam generacors ac lease once per 1$months.4.2.5.4 The provisions of Spec&cation 4.0.4 shall not apply to primary flov surve illancas.Indicacad average of at least three OPERA$LE instrument loops.Limit noc applicable during.either a QKBHhL PQMER tamp in excess of 5%of RATED TKDtMAL PCKk pet'inute or a THEWhL POMEiL seep in excess of 10'f RTP~Indicated value COOK NUCLEAR PLANT UNIT 2 3/4 2-U muamEHT HO.S7..f 34 I

INSERT 3I4 2-<5 1.Reactor Coolant System T 2.Pressurizer Pressure Less than or equal to 583.3'F Greater than or equal to 2200 psig (for nominal pressure of 2235 psig)t Greater than or equal to 2050 psig(for nominal pressure of 2085 psig)I

TABLE 3.3-4 ENGViEKLED SAFETY FEATURE hCTUATXOH STUD(XHSTRUHEHThTIOH TRXP~OXHTS hLLOVhBLE VALUES l.SAFETT XHJECTXOH, TURBXHE TRIP, FEEDVhTER ISOLATION, hHD HOTOR DRIVEH hGZXLZART FEEDVhTER PUMPS a.Eanual Initiation aaammaeaumma See'Functional Unit 9 amaaw~a~~~~

b.hucoaacic Actuation Logic c.Containmenc Pressure--

High d.Pressuriser Pressure-Lov e.Differential Pressure Becveen Steant Lines Hf.gh Hot Applicable Less than oc'qual to l.l psig Creater than or equal to~psig IE i8 Less than or equal to 100 psi Hoc hpplicable Less than or equal to l.2 psig Creater than or equal to~psig gras Less chan or e~to ll2 pai f.Stean Line Prassure-Lov Crea r than or equal Crea r chan or equal-to psig steam line to psig stean line ressure~assure COOK NUCLEAR~>>IXT 2 3/4 3 23 f34, is7 TABLE 3.3-4 Continued EHCZHZZEED SAFErr FEATmz hCTUATZOH STD(EHSTRmmTATZOH TRIP SETPOiHTS STIr~i LZHE ZSOLATZOH a.manual-----------

See Puaccianal Quit 9----b.Automatic Actuation Logic Hoc Applicable Hoc Appli,cab].e c.Containment Pressure--

High-High d.Steam Flov tn Tvo Steam Lines--High Coincident vith Tang--Lov-Lov e.Steam Line Pressure--Lov 5.TQREIBE TRIP AHD PKKDVATEL ISOLATXOS Lass than, or equal co 2.9 psig Less than or aqua!.to a function defined as follovs: A Delta-p corresponding to 1.6 x 10,lbs/hr steam flov becveen 0%and 20%load and chen a Delta p increasing

'inearly to a Delta-p corresponding to 4.5 x 10 I.bs/hr ac fuLL load.T greater thea or eQI.to 541 7 Crea er than oz equal to psig steam line pressure.Less chan or equa].to 3.0 psig Less than or equal to a function defined as follovs: A Delta-p corresponding co 1.75 x 10 lbs/hr sceam flov becveea 0%aad 20%I.oad and thea a Delta-p increasing linearly co a Delca-p corresponding co to 4.55 x 10 lbs/h ec full load.T greata>>chan br equal to 539 P Crea r chan oz equal t sig sceam line pressure a.Steam Ceaeracor Vacer Level--Egh-Egh Less than or equal co 67%of aarrov range instrument span each steam generator Less than or equal co 68\of narrov range instrument span each steam generator COOK HUCLFJLR PLEX'HZX 2 3/4 3-25 AHRHDHEHT Ho-82, f88, f3{1, I 37

3.4.2 A alaiaua of one preaaurizer coda aafety valve ahall be OPERhlLZ vf.th a lift setting of 2415 PS's/rKGK ULth ao ao preaaurirer code aafecy valve OPG4ULLE: Zanediataly suspend all operation!

invoking poaitive reactivity changes~aad place an OPERhSLE RHR loop into operation M the ahutdova cooling aode.b.Tauaediataly reader all Safety Infection puapa aad all bat one chary~poap iaoperabLe by reaoviag the appLicable aotor circuit breakarx fcoo, the eleccricaL pover circuit vithin oae boar.4.4.2 No additional Surveillance Reqnkreaeata other thea phoae required by Spec'cacion 4;0.5.~%he U.fc aecciag preset'halL correapond to ambient coaditiona of tba vaLve ac noaixaL operachg teaperacure aad preaanre.~For pnrpoiea of thea apecification, addition of eater free the~doea aoc conscience a dilution activity pcmridad che boroa coooeacracion La the MST ia~eater than or equal co tha aiaiama required by specificacioa 3.L.2.8.b.2 (WOE 4)or 3.1 2.l.b.2 (~K 5).~5am~s~+V~~me SO.SZ, 3/4 4+4 Insert 4-4 for 0 footnote on tech spec page 3/4 4-4 and 3/4 4-5 The pressurizer code safety valve shall be reset to the nominaL value 41%vhenever found outside the i1%tolerance.

REACT"R CMlANT mar VALVeS-OmmT1~LINlTLM CON)ETTAN FOR OPGQTION 3.4.3 All pressurfzer code sat valves shall be OPUS@fifth a lff't Iai:In't'485 PSN APPLKABtLITY:

NOCHES 1.i and i%ON: Mfa one presmrfzer code saf'e.y valve fnoperable, efther restore the fnooerable valve to OP64LM suNs rfthfn 15 Nfnucos or be fn%T QQTQSN~i&fn 1Z hours.SUR"KILU'R NENCfTS<.<.3 Nc addftfonal Survefilance RCqufteeel&

other than Mse~ufrtd by 8".ccff'fcatfon 4.0.5.'BT'valve ac, anal ogera fhg C4$gcrare and pressuree 9.C.COOX-LifftT Z~Inc 5

'n PQ00 2400 3200 g4 2000~~~ti!ill.l Ii']iy,S flEACTOA COOLAHT SYSTEH IIE LIHITATIOHS APPLICAQLE FOA FIRST EFFECTIVE FLLL POIIEA YEAAs IttAAoltts oF ao Palo Ate IooF AAE lttcLUAEA FOA POSSISLE IttSTAUHEllfhf rdtl EAAOA.)!t ij:tti!0 Ii It f000 t~LEAK MST LIHll-" lt 1600 i400 1800 1000 800 Jid IklACCEP f ABLE OPEAAl IOH ttt~~I PAE4 SNIE-TEHV AATLNE LIHll FOA ILATN'ATES UP la daof/IN---CA 1l ICAL11 Y LIHIT ACCEPTASLE OPEAATlott 600 400 200 ij lt i}.)i'i)t;}:'j I I'TEAIAL PAOPEAlY SA414 IHTEAttEOIATE PLATE, Cdddd-tt cu-.ra x.Ht-.av 4 IHIrrAL Al-aaof EfPY AT~<(I/ATI l74of 3/1TI tdoof 06 0 400 460 100 160 200 260 300 60 0 AVEAAOE AEACTOA COOLAHT SYSTEH MHPEAAlUAE FIOUAE$.4"S AEACTOA COOLAttl SYSTEH,PAESSUAE TEHPEAATINE,LIHITS FOA dO P/ttA AATE, CAlllCAL11Y LIHll'IN IIYOAOSTATIC MST LIHll

C3'n 9600 2400 2200 IO 2000/0 lfEACTOA COOLANt SYSTEH C tfN LlHTTATlONS APPLlCASLE FOA FlAST EFFECTIVE FN.L POMEA TEAAS Q4AAGTHS OF ffd PSlQ AIQ 10 F AAE INCLINED FOA POSSISLE INST~NTAT IOfl EAAOA.l~~j~~~f~I~j o o$I~f';!))'s ff')'i)i'000 iaao i400 1200 I~~~~PAESStNE-TEHPEAATLNE LIHl TS$~~j g~l,)~I WACCEPTAOLE

!OPEAA'TIOH l I o I i.:iif!.: g 0 ACCEPTABLE OPEAAT10ff i000 SOO~~600 400 200 60 COOL%50I AATE f/fn 100 HATKATAL PAOPEATY OASIS THTHaaDTATK PLATE, Caadd-a Cu~.Id X, NI.d7 X INITIAL AT-an4r RPPY AT~T Il/4TI l744F IS/ST)IaO4r f~~400 460 l I'160 200;260 300 360 AYEAAOE AEACTOA COOLANT STSTEH TEHPEAATf&#xc3;lE I F)f TON%3.4"3 AEAGTOA COOLAIIT STSTEH.PAESSfNE-TEIL'EAATN!E, LlHl18 FOA YAAINIS COOLOOMfl llATES I

+6 I ME5 l.2.cad 3.hSZZQK: a.lith oae ECCL cubcyscca iaopercb4, raceoea the iaopeesb4 cubcyseea to OPERhSLK aeacus vithin 72 hours or be in MZ STEROL&#xc3;<<ithin the next L2 hours.'<itis a ately ta]~aau-cue aaaea, naPa.cartSss-

~.cLa val<<e eo open poci or sochaoe tha-cora po<<er lave laca~E~eo<<iehin oem'hoar.5~4~4, doe+.nac apply.b.Zn eha event tha KCCS ia aceuatad cnd in)acta<<aecr into tha Reactor Coo4ne Syseaa, a Special Iapore chalI.ba prepared cad cubccLeaid eo the Coeaisaion pursuant eo gpecificatioa 4.9.2.<<ithfn.K days daacribing ehe circmaecncaa ot tha actuation cad the total acuaaalaead acacacion cyc4a co data COOK NUCLEAR PLANT UNIT I 5/4 5 5 ZmramtT NO.t67 3/4 LIMZ71NG CONDITIONS FOR OPERATION AND SURVIHLLANCE REQUGEKENTS 3/4.7 PLANT SYSTEMS TABLE 3.7-1 MAXIMUM ALLOWABLE POWER RANGE NEUTRON FLUX HIGH SETPOINT WITH INOPERABLE STEAM LINE SAFETY VALVES DURING 4 LOOP OPERATION Maximum Number of Inoperable Safety Valves on Any g Steam Generator Maxinuun Allowable Power Range Neutron Flux High Setpoint (Petcent of RATED THERMAL POWER)COOK NUCLEAR PLANT-UNlT 2 Page 3/4 7-2 PLANT SYSTEMS CONOKNSATK STORAGE TANK LIMITING CONOITION FOR'PKRATION gcen4lu 3.7.1.3 The condensate storage tank (CST)shall be OPKRASLE-with a minimum conta>ne volume of 175,000 gallons of water.APPLICASILITY:

MOOES 1, 2 and 3.ACTION: Mith the condensate storage tank inoperable, within 4 hours either: a.Restore>e CST to OPKRASLE status or be fn HOT SHUTOOMN within the next 12 hours, or b.Oemonstrate the OPERASILITY of the Essentfal Service Mater System as a backup supply to the auxiliary feedwater nutnps and restore the condensate storage tank to OPERASLE status within 7 days or be fn HOT SHUTOOMN within the next 12 hours.SURVEILLANCE RK UIRKMKNTS uses bit 4.7.1.3.1 The condensate storage tank sha11 be emonstrated OPERASLE at 1east once per 12 hours by verffyfng the contain water volume fs within its lfmits wnen the tank.fs the suppIy source or the auxiliary feedwater pumps~4.7.1.3.2 The Essential Service Mater System shall be demonstrated OPKRASLE at, least once per 12 hours by verifyfng that the Essentfal Servfce Mater System fs fn operatfan whenever the Essential Service Mater Systea fs the supply source for the auxiliary feedwater pumps.O.C.COOK-UNIT 2 3/4 7-7 2.She: ro jericeiona of chic lafte Lime yt~nc~theat'f cha r~L yo ai~4 yor oration&tch voul4 reaule in eho roZIaso og fia i by ream'cew4 fuel oyoraeion eo vSthpn eha escleata boU,Q ri i+ne boat c=anafar co~ar coefficient ta Lac'go aa4@ho claLCtng aurfaco eNxporaeurl alightly chere eha coolant saturation eaayoraeura.

yoraeion abm tho uyyor beauhry of the nucleate.boSUng re!~coulg reaule in cxcoaaSve cladding eaeyoraeuraa bocauaa o f eha oaaat of day~~froa nuclaaea botany (RQ)an4 eho raauleant chary reduction Sn boat e-anagoge coefficient.

M ia not a 4tracely aeaaurabla yaraaeear 4u'Sag oyoration a~therefore QHXM 2%SR anl reactor coolant eaayoraeuro an4 yreaauzo~b<<<rolatal to QO through the 4'2 corrolaeion anl 1 3 corralation for con4itioc outaida the range ot M-2.Iho NS corre4tioea

The Local NO heat flux ratio (MR)ia dafina4 ag eho ratio of cho hoat flux chat voQL4 cauao OtO ae a yareicular cora Location eo eho Local heat flux, an4 ia indicative of the aargin eo DI3.The DQ doaiga baaia ia aa follows: ehaee mt be at Laaae a S5 yorconc yrobabiliey chit ehe akaSaua DHN, of ehe Lixiciag ro4@ac~Coaction an@II evonta ia gcaaear than or equal ee the DIIR L~t of eha CA correla oa NX 2 correlation for Vaneago 5 fse1, cat ehe 1-3 cor:a eione Aich faLL oueaiko ehe raga of ayylicab of the-.correlation ONt Quite are oatabliahe4 baaol on the ayylicabla ixyorisoncaL data les Hach ehac chemi i$4$5 yercacc yrobahilfty arith$5 yorcant confidence that QQ%11 tet occur vhea the aSniem ECQk ia at the QSt Liait (L.U fot QR$-2 anl L.5 fm eho V-3).In aeoCag eh>>0%daaign baal, uneareaintiae in ylant oyoraeing yaralatars, escloar an4 ther,laL yaraaoeare, anl fuel fabrication yaraaoeara a-e atatiaticaLIy coehinal vith the%OR correlation, aeatiatics each that thoro ia at Laaat a N yorcanc yrohabiliey Web a S5 yoraant confi4aaco L~L that eha~~~for ehe LidiCQ1$rol ik gz04eat chas os~tS a calculatal 4eaiya Liaie CAR.The uacereatneiae io the abele ylant yaraaeeaca aro uao4 e-4ata~La4 ehe jlan!MRR uncareainey.

shia RR uncertaiaey, coabine4 vith~~cerrelaC4lc acaCL4CLcs, catahliahee a laa~OAR~So v5$ch QJst be Ioc in plant aafacy analyses meggy~uea of igygg yarg~geerg

<or~k tueLaae fiaee Caid 2, ehe 4aaiya NSR mbsea or Vanea 5-fhaeL~thhshlo ao eiffel II aktf,eioo, ear yo o Safer.anal~ac ee a aafacf 1Xatt~The aaegin boeraae eh>>4aaiga anl aafaey<<nalyaia Liiie~++M"+~'Ca e4~~e~pa'QQR yonaLeiaa (S.e., ezanaitioe coro yonaltioa.

LIMIT:NO S~Sermon SETTINCS hASES Overlayer Delta T The Overpover Delta T reactor trip provides assurance of fuel Lnteg:Lg, e.g..no aelcing, under all possible overpover conditions.

linits the zequLred range for Overtaarpetasuze Delta I proceccion, and provides a backup to tha High Neutron Flux criy.The secpoint includaa corrections fot changes Ln density and heat capac'Lty af vatez vith temperature an4 47tL1lic caepensatLan far piping delays ftea the core to the loo te erasure detectors., re ace~Qpe (I'~4-u f~.dur candisi fo~ful ove r e cures~safe yais.avezpaver delta T reactor t-p provides procacc on o ace uy prateo for at-paver stean L&e break events.Czedic vas taken for oyetation of chis ttip Ln the staaa LLne break ness/energy releases outside cantaimaent analysis.In addition.Lts functional capability ac the specified trap sassing Ls squired by this specif'cacion ta enhance she overall reliability of the Reactor Prataosian Sys ten.Pressuri er Pressure The Pressurizer High and Lov Pressure stiya ate ytavi4e4 co Linis the yressuze range in vhich reactor operation Ls permitted.

The High Pressure t=ip Ls backed up by che pressurizer code safety valves fot LC5 avezytessuze procection.

and Ls therefore sac lover chan che sec ptessuze fot these valves (24~5 psig).The HLgh Pzaasut~ttiy provides protection fot a Loss of External Load event.The Lev Pteaauze czip provides protsc'an by c:Lpping che reactor'n the evens of a loss of reactot coolant pressure.Pressur'=er Peter Level The Pressurizer High Qatar Level trip ensures protection against~actor Coolant Syatee ovetyreasuzizasion by limiting the vatat laveL co a volune suf Lciens co retain a ac44$bubble an4 prevent vasar relief thtough che pressurizer safety valves.The pteasuzizar high vaser level cr'y pteclu4es vates relief fot the uncontrolled control rod assumably bank vithdzaval at~paver evens CaeC NUCme, tOet-UNIT 2 a 2-5~g)gyre HO.jZ.LJS

&~XX GT a C&#xc3;SASK/: (Canthus)~~fl~raca M4 2 are Seaigget, no gtQg+aaaL aLLovagceg a a aeceaa~prior co coeyartaoc+~

====3.2.3 Neaaureaet====

errora of 2.1%for RCX CIec tocaL flee gaea ancL 44 for g~e beea allow@for La daeazakaactoa ef the deatga lMR ralua 404 ta this wca~ctoa of aha LOC~CCf Ltmtc..becveeo~Safest 454%7etm Qgggk CREE the Skates Ltitc MS'a IaQlcaL044 (Safe'cg 48417$ea CAR@: L-Ct m4 L.CL fot the Vaacage 5 typical and Le calla, reapeccSmL Death Limit 411ca jo eh reapecttveL 4 iTacKoc~sar$$0 co aocooodkca appltcab IC.I Wl t~~~1>>LTf Vantage 5 fueL (equai co L.3%per~ICAL, Ear.1).The reaatader og the aargin beateen 4eaiyl eel aafa~aaaL7ita NRL~ta can be uaa4 for per.death's flexibtlt ty.  

3 4.2 POWER DISTIBUTION LIMITS BASES 3 4.2.4 UADRANT POWER TILT RATIO The quadx'anc paver cflc ratio limit assures that the radial pover distribution sacfsfies che design values used in che povar capability analysis.Radial povex distribution measurements are made during startup testing and periodically during pover operatfon.

The limit of 1.02 at vhfch corrective action is required provides DNB and linear heat generation rate protection vith x-y plane paver tilts.The tvo hour time allovance for operation vith a tilt condition greater than 1.02 but less than 1.09 fs provfded to allov identfffcatfan and correctfon of a dropped or mfsalfgned x'od.In the event such action does not cozrect the tilt, the margin for uncertainty on F fs reinstated by zeducfng the pover by 3 percent fzom RATED THERMAL POWER fear each percenc of tilt fn excess of 1.0.3 4.2.5 DNB PARAMETERS e limits an the DNB-xelated parametezs ensure that each of the paramete are maintained vichfn the normal steady-state envelope opex'ation a ed in che transient and accident analyses.Th.less than or equal to 57.F and pressurizer pxessure greater than equaY.to 2200 0 avg psfg are consfstenc th the UFSAR assumptions and ha een analytically demonstrated adequate maintain the core at or ve the design DNBR thraughout each analyzed t ienc vfth allov e foz'easurement uncertainty.

The T greater an or eq co 543.9 F is conservative to a 0 safety analysis pezfoRned to demon that the plant may operate on a lineaz contz'ol program vhere the a y cal limit of T at 1008 RATED THERMAL POWER may xange fxom 5.4 F to 5 1 F.The 1Y5it of 543.9 F'contains a margin of 1.1 F The core may be o rated vith indicated vessel average tcmperacuze at y value betveen the uppe nd lover limits.Pressurizer pressu is limited co a single nominal s oint, vith the lover limit of che f caced value setpofnt set forth in the sp ficacfons.

The T/S value selected for consistency vith Unit 1 and conta a margin of 6 psi.e limits are consistent vfth the UFSAR assumptions and ve been an tically demonstxaced to be adequate to maintain the coxe at or ve the pplfcable design limit DNBR values for each fuel type,(which are lfste che bases for Sectfan 2.1.1)throughout each analyzed transient.

INSERT A The limits on the DNB-related parameters ensur the parameters are maintained within the normal envelope of operation assumed in the transient analyses.The T, less than or equal to 583.3 F pressure greater than or equal to 2200 psig that each of steady-state and accident d pressurizer for nominal (pressurizer operating pressure of 2235 psig)or 2050 psig (for nominal pressurizer operating pressure of 2085 psig)are consistent with the USFAR assumptions and have been analytically demonstrated adequate to maintain the core at or above the'esign DNBR throughout each analyzed transient with allowance for measurement uncertainty.

Pressurizer pressure is limited to either of two nominal operating pressures of 2235 psig or 2085 psig, with the corresponding indicated limits set forth in the specifications.

REACTOR COOLANT SYSTEM BASES The actual shift in the reference temperature of surveillance specimens and neutron fluence is established periodically by removing and evaluating reactor vessel material irradiation surveillance specimens and dosimetry installed near the inside wall of the reactor vessel in the core area.The heatup and cooldown limit curves of Figures 3.4-d 3.4-3 predicted adjustments for this shift in RT~at the end of FPY, as adjustments f'r possible errors in the pressure and emperature instruments.

The EFPY heatup and cooldown curves were developed based f ollowing: include well as sensing on the 1.The intermediate shellplate, C5556-2, is the limiting material as determined by position 1 of Regulatory Guide 1.99, Revision 2, with a Cu and Ni content of 0.15%and 0.57%, respectively.

2~The fluence values contained in Table 6-14 of Westinghouse WCAP-13515 report,"Analysis of Capsule U From the Indiana Michi,gan Po~er Company D.C.Cook Unit 2 Reactor Vessel Radiation Surveillance Program", dated February 1993.The RT~shift of the reactor vessel material has been established by removing and evaluating the reactor material surveillance capsules in accordance with the removal schedule in Table 4.4-5.Per this schedule, Capsule U is the last capsule to be removed until Capsule S is to be removed after 32 EFPY (EOL).Capsules V, W, and 2 will remain in the reactor vessel and will be removed to address industry reactor vessel embrittlement concerns, if required.The pressure-temperature limit lines shown on Figure 3.4-2 for reactor criticality and for inservice leak and hydrostatic testing have been provided to assure compliance with the minimum temperature requirements of Appendix G to 10 CFR 50.The number of reactor vessel irradiation surveillance specimens and the frequencies for removing and testing these specimens are provided in Table 4.4-5 to assure compliance with the requirements of Appendix H to 10 CFR Part 50.The limitations imposed on pressurizer heatup and cooldown and spray water temperature differential are provided to assure that the pressurizer is operated within the design criteria assumed for the fatigue analysis performed accordance with the ASME Code requirements.

The OPERABILITY of two PORVs, or of one PORV and the RHR safety valve ensures that the Rcs will be protected from pressure transients which could exceed the limits of Appendix G to 10 CFR Part 50 when one or more of the RCS cold legs are less than or equal to 1524F.Either PORV or RHR safety valve has adequate relieving capability to protect the RCS from overpressurization when the transient is limited to either (1)the start of an idle RCP with the secondary water temperature of the stem generator less than or equal to 50'F above the RCS cold leg temperatures of (2)the start of a charging pump and injection into a water solid RCS~Therefore, any one of the three blocked open PORVs constitutes an acceptable RCS vent to preclude APPLICABILITY of Specification 3.4.9.3.3 4.4.10 STRUCTURAL INTEGRITY The inspection and testing programs for ASME Code Class 1, 2 and 3 components ensure that the structural integrity of these components will be maintained at an acceptable level throughout the life of the plant.To the extent applicable, the inspection program for these components is in compliance with Section XZ of the ASME Boiler and Pressure Vessel Code.COOK NUCLEAR PLANT-UNIT 2 B 3/4 4-10 AMENDMENT NO~89,~i 15k i 171

(Conabu~d) allovect ccnnpla&on tinea are caasonabla, bued on operactng experience, to reach che required plant conditions

&m fuLL power coaditioaa in an orderly earner and vichouc chaLLcagiag plane aystaaa.If nor~than one aocuasulator Sa inoperable, the plant is fn a condition outside.tha accident analyau;therefore, LCO 3.0.3 axsc be entered Saaediataly.

~~ad b su es a decrease acceptable Lhxj ts in The OPD4QZLITY of aco independent ECCS aubaystaas ensuru that sufhcient~nergency cot'a coolLag capability vtLL be arailabla in tha crane of a QKA assuming the Loaa of one aubsyctaa tbr~h any aisle failure consideration.

Either aubayssea operaetng in conjunction vith the atamxlacncs ia dapabla of supplying audient cora cooling to Limit the peak claddhrg~ieracuras

&chin acceptable Xfsica for aLL poatulatad break aixaa ragtag froa the double ended break of the Largest PCS cold Leg pipe doenaar4.In addi~, each ECCS I I!doaCag the accLdeac recovery period.4 5EEis~oo c?M$clE 0 1$, tvo lines the Loss cf one saf a@le failure co'tion.The resnl THERMhL Quoit the taspezstnra the erenc a postulated aaall break Q&#xc3;l COOK NQC~~PLhHT UHlT 2 5 5/4 5-4 CT HO.~I69,  

CONTA IHMEHT S YSTEMS BASES 3/4.6.1.4 INTERNAL PRESSURE The limitations on containment internal pressure ensure that 1)the containment structure is prevented from exceeding its design negative pressure differential with respect to the outside atmosphere of 8 psig and 2)the containment peak pressure does not exceed the design pressure of 12 psig during LOCA conditions.

The maximum peak pressure is resvl 6n from a LOCA event~lcolaWd+++as f4~M dcS\qm 4vQK+I psgq 0+i'-lv~itic'Ivies 0.$pstg gee lacuna(.3/4.6.1.5 C.IR TEMPERATURE The'limitations on containment average air temperature ensure that 1)(the containment air mass is limited to an initial mass sufficiently low to prevent exceeding the design pressure during LOCA'conditions and 2)the ambient air temperature does not exceed that temperature allowable for the continuous duty rating.specified for equipment and instrumentation located within containment.

The containment pressure transient is sensitive to the initially contained air mass during a LOCA.The contained.air mass increases with decreasing temperature.

The lower temperature limit of 60'F will limit k P PP~t I tk t d tg pressure of 12 psig.The'upper temperature limit influences the peak accident temperature slightly during a LOCA;however, this limit is based primarily upon equipment protection and anticipated operating conditions.

Both the upper and lower temperature limits are consistent with the para-meters used in the accident analyses.3/4.6.1.6 CONTAIHMEHT STRUCTURAL INTEGRITY This limitation ensures that the structural integrity of the con-tainment w'ill be maintained comparable to the original design standards for the life of the facility.Structural integrity is required to ensure that (1)the steel liner remains leak tight and (2)the concrete surround-ing the steel liner remains capable of providing external missile protec-tion for the steel liner and radiation shielding in the event of a LOCA.A visual inspection in conjunction with Type A leakage tests is sufficient to demonstrate this capability.  

(y qO 4 3 CONDENSATE STO GE TANK~allowance for water not usable because of tank discharge line location or other physical characteristicsis m+cello'i~.u5~.The OPERABILITY of the condensate st age tank with the m nimum water volume ensures that sufficient water is av ilable to maintain the RCS at HOT STANDBY conditions for 9 hours with steam di charge to the atmosphex concurrent with total loss of off-site power.The A 4 CT VITY The limitations on secondary system specific activity ensure that the resultant off-site radiation dose will be limited to a small fraction of 10 CFR Part 100 limits in the event of a steam line rupture.This dose also includes the effects of a coincident 1.0 gpm primary to secondary tube leak in the steam generator of the affected steam line.These values axe consistent with the assumptions used in the accident analyses.4 5 S GENERATOR STOP VALVES The OPERABILITY of the steam generator stop valves ensures that no more than one steam generator will blowdown in the event of a steam line rupture.This restriction is required to 1)minimize the positive reactivity effects of the Reactor Coolant System cooldown associated with the blowdown, and 2)limit the pressure rise within containment in the event the steam line rupture occurs within containment.

The OPERABILITY of the steam generator stop valves within the closure times of the surveillance requirements.are consistent with the assumptions used in the accident analyses.With one steam'enerator stop valve inoperable in MODE 1, action must be taken to restore OPERABLE status within 8 hours.'ome repaizs to the valves can be made with the unit.hot.The 8 hour completion time is reasonable, considering the low pxobability of an accident occuzring during this time period that would require a closure of the steam generator stop valves.If the steam generator stop valve.cannot be restored to OPERABLE status within&hours, the unit must be placed in a MODE in which the LCO does not apply.To achieve this status, the unit must be placed in MODE 2 within 6 hours and the MODES 2 and 3 action statement entered.The completion times are reasonable, based on operating experience, to reach MODE 2 and to close the steam generator stop valves in an orderly manner and without challenging unit systems.COOK NUCLEAR PLANT-UNIT 2 B 3/4 7-3 AMENDMENT NO.m, 170  

DESCRIPTION OF PROPOSED UNIT 2 POWER UPRATE TECHNICAL SPECIFICATIONS I I l Attachment 4 to AEP:NRC:1223 Page 1 Key for Summary Table Page Section Technical Specification Page Technical Specification Group Related Groups Discussed in Attachment 1, Description of Proposed Changes and 10 CFR 50.92 Significant Hazards Consideration Analysis Uprate Group 1, Changes Directly Related to Increased rated thermal power HHSI Group 2, Change to Remove Power Restriction for High Head Safety Injection Cross Ties Closed Operation Margin Group 3, Changes Proposed to Increase Unit 2 Operating Margin Transition Group 4, Changes Related to Transition Core or Transition to Temperature Window/Dual Pressure Technical Specifications Both'roup 5, Changes Proposed for both units.Admin Group 6, Administrative Change Description Remarks A Brief Description of Each Proposed Change Brief Comments with a Cross Reference to the Analyses Note that all changes are~onl for unit 2 unless they are included in the"both" group.The changes in this group are proposed for both unit 1 and unit 2 of Cook Nuclear Plant.  

(i Attachment 4 to AEP:NRC:1223 Page 2 Page 2-2 Section 1.3 Figure 2.1-1 Group.Uprate Margin Description Increase rated thermal power to 3588 MNt.Revise Reactor Core Safety Limits Remarks The support for this proposed change consists of analyses that have been performed over a period of years.Including the new analyses, which are described in Attachment 6, NCAP 14489, and the evaluations described in Attachment 7, Balance of Plant Evaluations and Miscellaneous Safety Evaluations, all the necessary analyses and evaluations have been completed to support an uprate of Unit 2 to a core power of 3588 MNt.The new analyses and summaries of earlier analyses and evaluations performed by Westinghouse Electric Corporation for the nuclear steam supply system (NSSS)are described in NCAP 14489.The impact of recent model changes on.the new analyses is discussed in Attachment 1 under Group 1 changes as well as in Attachment 6.Attachment 7 describes balance of plant evaluations and miscellaneous safety evaluations.

Since the analyses which support the uprated power have been performed over a period of years, Attachment 5 is provided to describe the history of earlier analyses and to identify the submittal of earlier work and the associated SER's.The review status of the analyses supporting the uprated core power is discussed in Attachment 1 under Group 1 changes and in Attachment 5.The Safety Limit Figure currently in the Unit 2 Technical Specifications was designed for a mixed core of Westinghouse and Advanced Nuclear Fuel.The Unit 2 core now consists totally of Westinghouse Vantage 5 fuel.The new thermal design is discussed in Section 3.3.2.1 of Attachment 6 WCAP 14489'he proposed Safety Limit Figure is consistent with a rated thermal power of 3588 MWt and an all Vantage 5 core.

Attachment 4 to AEP:NRC:1223 Page 3 Page 2-5 Section Table 2.2-1 Footnote Group Admin Description Redefine design flow in footnote of Table 2.2-1 to be 1/4 MMF.Remarks Minimum Measured Flow (MMF)is Reactor Coolant System Total Flow Rate of T.S.3.2.5.MMF is used directly in the DNB analyses as discussed in Section 3.3.2.1 of Attachment 6, WCAP 14489.MMF is 1'35 times thermal design flow (TDF).Therefore, the MMF employed in the DNB analysis is 1.035 times TDF.TDF is specified in Section 3.3.3.1 of WCAP 14489.TDF is generally used in no-DNB analyses.See, for example, WCAP 14489 tables 3.1-7 and 3.1-13.A lower (loop)TDF is indicated in Table 3.5-1 because the containment analysis bounds both units and Unit 1 is analyzed for a St flow asymmetry.

Design flow in current technical specification Table 2.2-1 is loop MMF or total MMF/4.2-7 2-7 2-7 Table 2.2-1 Margin Table 2.2-1 Margin Table 2.2-1 Margin The upper limit on T'ncreased to 581.34F to reflect analyses.Both analyzed, nominal RCS pressures, 2235 psig and 2085 psig, are indicated.

Tau 1 reduced from 28 secs to 22 secs.New OTDT and OPDT setpoints have been calculated to support operation at a rated thermal power of 3588 MWt with all Westinghouse Vantage 5 cores which are currently being used in Unit 2.K1 was increased from its current value of 1.09 to 1.17 thereby signi,ficantly increasing load rejection margin.The value 1.17 was selected to allocate some margin to instrumentation, increased allowance for core burnup effects such as changes in hot leg streaming, and an increase in the positive~I break point for the f(~I)penalty.Increased load rejection margin was also obtained by reducing tau 1 from 28 seconds to 22 seconds.The analysis value of K4 was also evaluated to obtain increased margin for burnup effects.The OTDT and OPDT trips are discussed in Section 3.3.2.1 of WCAP 14489.Details, including T', T', and time constants of the analyzed setpoint, are in Table 3.3-4 of WCAP 14489.Due to the analysis performed for transition cores of both Westinghouse and Advanced Nuclear Fuel, low pressure operation was not permitted for operation with mixed cores of Westinghouse and Advanced Nuclear Fuel.The basis for this limitation is discussed in Section"Group 4" of Attachment 1.Unit 2 is currently operated with cores of all Westinghouse Vantage 5 fuel.Therefore, low pressure operation is acceptable.

See remark on increase of T'pper limit on page 2-7.  

Attachment 4 to AEP:NRC:1223 Page 4 Page Section Group Description Remarks 2-8 2-8 2-8 2-8 2-9 Table 2.2-1 Margin Table 2.2-1 Margin Table 2.2-1 Margin Table 2.2-1 Margin Table 2.2-1 Margin Increase Kl from 1.09 to 1.17.Increase K2 from 0.01331 to 0.0268 Increase K3 from 0.00058 to 0.00111 Change f(al)penalty.Maintain the upper limit.on T''at 576oF to reflect analyses.See remark on increase of T'pper limit on page 2-7.See remark on increase of T'pper limit on page 2-7.See remark on increase of T'pper limit on page 2-7.See remark on increase of T'pper limit on page 2-7.This item is not a change.However, due to the fact that 5764F is not the maximum analyzed temperature of the temperature window, it is appropriate to identify the fact that the upper limit on T''is being deliberately maintained at its current value.2-9 Table 2.2-1 Margin Change the allowable values in notes 3 and 4.Cook Nuclear Plant Unit 2 is operated a temperature significantly lower than the maximum analyzed temperature.

Therefore, the OPDT setpoint was analyzed with a low upper limit on T''to convert unused margin to operating margin.The OPDT trip is discussed in Section 3.3.2.1 of WCAP 14489.Details, including T'', of the analyzed setpoint are in Table 3.3-4 of WCAP 14489.The values indicated in the markups of'Attachment 3 and in the proposed technical specifications of Attachment 2 were calculated by our organization using the Westinghouse"stepit" methodology described in WCAP-12741.

This is the same methodology used for the calculation of all existing Reactor Trip and Engineered Safety Feature Actuation Setpoints.

This methodology is consistant with the requirements of ISA Standard S67.04.  

Attachment 4 to AEP:NRC:1223 Page 5 Page 3/4 2-15 Section Section 3.2.5 Group Transit ion Description Increase DNB temperature limit from 578.74F to 583.30F.Remarks Due to the analysis performed for transition cores consisting of both Westinghouse fuel and Advanced Nuclear Fuel, the maximum nominal Tavg was limited to 576 F for operation with mixed cores of Westinghouse and Advanced Nuclear Fuel.Unit 2 is currently operated with cores of all Westinghouse Vantage 5 fuel.Therefore, the full analyzed temperature window analyzed for an all Vantage 5 core is acceptable.

The DNB temperature limit is obtained by adding the controller allowance to the high nominal Tavg used in the analysis and then subtracting the readability allowance.

The high nominal Tavg for a full Vantage 5 core is 581.34F and the controller allowance is 4.1oF.These values are found in Table 3.3-1 and Section 3.3.3.1 of WCAP 14489, respectively.

The readability allowance, calculated by AEPSC, is 2.1 F.The resulting DNB temperature limit is 583.3OF.The high nominal Tavg for a full Vantage 5 core is identified in the Vantage 5 Reload Transition Safety Report for Cook Nuclear Plant Unit 2 (RTSR), reference 11 of Attachment 5.RTSR was submitted via reference 13 of Attachment 13 of Attachment 5.Operation of Unit 2 with Westinghouse fuel was approved in reference 17 of Attachment

: 5.  

Attachment 4 to AEP:NRC:1223 Page 6 Page 3/4 2-15 3/4 2-15 3/4 3-23 Section Section 3.2.5 Section 3.2.5 Table 3.3-4 Group Transit ion Transit ion Transit ion Description DNB pressure limits for both analyzed nominal RCS pressures, 2200 psig and 2050 psig, are indicated.

Remove reference to low temperature limit in order to return the specification to a purely DNB specification.

Reduce safety injection actuation setpoint on low pressurizer pressure to 1815 psig.Remarks Due to the analysis performed for transition cores consisting of both Westinghouse fuel and Advanced Nuclear Fuel, low pressure operation was not permitted for operation with mixed cores of Westinghouse and Advanced Nuclear Fuel.The basis for this limitation is discussed in Section"Group 4" of Attachment 1.Unit 2 is currently operated with cores of all Westinghouse Vantage 5 fuel.Therefore, low pressure operation is acceptable.

The DNB pressure limit is obtained by subtracting the total pressure allowance used in the analysis from the nominal operating pressure used in the analysis and then adding the readability allowance.

The nominal pressures and the total allowance are found in Section 3.3.1 and 3.3.3.1 of WCAP 14489, respectively.

The readability allowance, calculated by AEPSC, is 18.9 psi.The pressure limit currently in the T/Ss for high pressure operation is conservatively higher than the calculated value of 2191 psig.The proposed limit of 2050 psig for low pressure operation is an addition.Zt is conservatively higher than the calculated value of 2041 psig.The proposed value for the low pressure limit is the same as the unit 1 limit.The proposed change converts the DNB speci.fication back to a purely DNB specification.

This proposal is discussed further in Attachment 1.Additional margin to trip for safety injection on low pressurizer pressure was needed as discussed in the description of changes for Group 4 of Attachment 1.The required evaluations to lower the safety analysis value for the setpoint have been performed as discussed in Sections 3.3.4.5 and 3.3.4.6 of WCAP 14489.The nominal Technical Specification setpoint proposed is the same as the corresponding setpoint for Unit 1.Th'e instrument allowances calculated by our organization support this nominal setpoint.  

Attachment 4 to AEP:NRC:1223 Page 7 Page 3/4 3-23 3/4 3-23 Section Table 3.3-4 Table 3.3-4 Group Transit ion Transit ion Description Change allowable value for safety injection actuation setpoint on low pressurizer pressure to 1805 psig.Reduce safety injection actuation setpoint on low steam line pressure to 500 peig.Remarks The value 1805 psig, indicated in the markups of Attachment 3 and in the proposed technical specifications of Attachment 2, is conservative to the value that was calculated by our organization.

Et is consistent with value for unit 1 and is proposed in order to make the Technical Specifications of the two units more similar.At the time of the transition from Advanced Nuclear Fuel to Westinghouse fuel, the reanalysis of mass and energy release (M&E)outside containment for rerating and reduced temperature/reduced pressure operation was not complete.The evaluation of the then applicable analysis assumed an NSSS power of 3425 MWt and a nominal setpoint for low steam line pressure no less than 520 psig.The AEPSC analysis of the impact of the steam line mass and energy release (SM&E)outside containment on the operabilit of equipment in the main steam enclosures, at 3588 MWt core power, was described and submitted in reference 24 of Attachment 5.Reference 24 was our proposal to operate both units with 0 ppm boron concentration in the boron injection tank (BZT).The SHEE was analyzed consistently with the proposed safety injection setpoint on low steam line pressure.The mass and energy release portion of this analysis is discussed in Section 3.3.4.7 of WCAP 14489.The core response steamline and feedwater line breaks submitted with the RTSR support the proposed setpoint.The references for the RTSR, its submittal, and approval are 11, 13, and 17 of Attachment 5.Evaluations of these analyses are discussed in Sections 3.3.4.6 and 3.3.4.7 of WCAP 14489.The revised SM&E release analysis to containment also supports the proposed setpoint.This analysis is discussed in WCAP 14285, reference 29 of Attachment 5.WCAP 14285 was submitted via reference 30 of Attachment 5.Zt is not yet approved.This analysis is summarized, in Section 3.5.4 of WCAP 14489.  

Attachment 4 to AEP:NRC:1223 Page 9 Page Section Group Description Remarks 3/4 4-16 3/4 4-25 3/4 4-26 3/4 5-3 Section 4.4.6.2.1 Figure 3.4-2 F igu re 3.4-3 Section 3.5.2 Transit ion Uprate Uprate HHSZ Pressure criteria for both analyzed nominal RCS pressux'es are indicated.

Reduce the applicability of the heatup curve from 15 to 14.5 EFPY's.Reduce the applicability of the cooldown curve from 15 to 14.5 EFPY's.Remove power reduction currently required for operation with HHSZ cross tie valves closed.Due to the analysis performed for transition cores of both Westinghouse and Advanced Nuclear Fuel, low pressure operation was not permitted for operation with mixed cores of Westinghouse and Advanced Nuclear Fuel.The basis for this limitation is discussed in Section"Group 4" of Attachment l.Unit 2 is currently operated with cores of all Westinghouse Vantage 5 fuel.Therefore, low pressure operation is acceptable.

The applicability of the current heatup and cooldown curves is discussed in Section 3.11.2.1 of Attachment 6, WCAP 14489.See the xemark on the applicability of the heatup and cooldown curves on page 3/4 4-25 When the SBLOCA analysis performed to support the main stea safety valve tolerance relaxation to 3%was carried out, it was found that a power reduction was required to obtain satisfactory results with the high head safety injection (HHSZ)cross ties closed.Since then, improvements have been made to the Westinghouse NOTRUMP SBLOCA model.As indicated in the cover letter to this submittal, the SBLO analysis performed for this submittal was performed using the new model.The results of this analysis show that an acceptable PCT results with the HHSZ cross tie valves closed at a core power of 3588 MWt.The SBLOCA analyses are described in Section 3.1.2.4 of WCAP 14489.3/4 7-2 Table 3.7-1 Uprate Lower the maximum Allowable Power Range Setpoint.These setpoints are calculated in accordance with the prescription in Westinghouse Nuclear Safety Advisory Letter 94-001.Zn this prescription, nominal NSSS power appears in the denominator of the equation for the setpoint.Therefore, the proposed setpoints were lowered accordingly.

Attachment 4 to AEP:NRC:1223 Page 10 Page UNIT 1 3/4 7-7 UNIT 2 3/4 7-7 B 2-1 B 2-5 B3/4 2-4a B 3/4 2-5 B 3/4 4-6 B 3/4 4-10 Section UNIT 1 Sections 3.7.1.3 and 4.7.1.3.1 UNIT 2 Sections 3.7.1.3 and 4.7.1.3.1 Bases Section 2.1.1 Bases Section 2.2.1 Bases.Section 3/4.2.2 and 3/4.2.3 Bases;Section 3/4.2.5 Bases Section 3/4.4.9 Bases Section 3/4.4.9 Group Both Transit ion Margin Transit ion Transit ion Uprate Uprate Description Change contained volume to useable volume.Remove references to Advanced Nuclear Fuel.Remove detail f rom the discussion of the OPDT protection trip.Remove references to Advanced Nuclear Fuel.Remove reference to low temperature limit in order to return the specification to a purely DNB specification.

Reduce the applicability of the heatup and cooldown curves from 15 to 14.5 EFPY's.Reduce the applicability of the heatup and cooldown curves from 15 to 14.5 EFPX's.Remarks The analysis of 3.10.2.5 of WCAP-14489 shows that 174, 500 gallons of water are required to maintain the RCS at hot standby for 9 hours.The Technical Specifications currentl require a minimum contained volume of 175,000 gallons of water.However, due to the fact that the zero of the level instrumentation is located at the centerline of the discharge pipe, above the level for required NPSH, all the indicated volume is useable.Therefore, the proposed Technical Specifications are revised to address useable volume.The Unit 2 core now consists totally of Westinghouse Vantage 5 fuel.The discussion of the proper normalization of T''is being removed.This information is documented in Section 3.3.2.1 of WCAP 14489 and will be controlled administratively.

The Unit 2 core now consists totally of Westinghouse Vantage 5 fuel.See remark on low temperature limit on page 3/4 2-15.See remark on the applicability of the heatup curve on page 3/4 4-25.See remark on the applicability of the heatup curve on page 3/4 4-25.