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bocht Number 50 346 License Number NPF-3 Serial Number 2560 Attachment 1 Page1                                                  '
APPLIGA8ItITi SURVEILLANCE REQUIREMENTS 4.0.1    Surveillance Requirements shall be applicable during the OPERATIONAL MODES or other conditions specified for individual Limiting Conditions for Operation unless otherwise 's;tated in an individual Surveillance Requirement.
4.0.2 Each Surveillance Requirement shall be performed within the specified time interval with a maximum allowable extension not to exceed 25 percent of the specified surveillance interval.
4.0.3 . Failure to perform a Surveillance Requirement within the allowed surveillance interval, defined by Specification 4.0.2, shall constitute noncompliance with the OPERADILIlY requirements for a Limiting Condition for Operation.
The time limits of the ACTION requirements are applicable at the time it is identified that a Surveillance Requirement has not been performed.        -
The ACTION requirements may be delayed for up to 24 hours to permit the completion of the surveillance when the allowable (equipment inoperability) outage time limits of. the ACTION requirements are less than 24 hours.
Surveillance requirements do not have to be performed on' inoperable equipment.
4.0.4 Entry into an OPERATIONA( MODE or other specified applicability condition shall not be made 'unless the Sufveillance Requirement (s) associated with the Limiting Condition for Operation have been performed within the stated surveillance interval or as otherwise specified.
4.0.5 Surveillance Requirements for inservice inspection and testing of ASME Code Class 1, 2 and 3 components shall be applicable as follows:
: a.      Inservice inspection of ASME Code Class 1, 2 and 3 components and inservice testing of ASME Code Class 1, 2 and 3 pumps and valves shall be performed in accordance with Section XI of the ASME Boiler and Pressure Vessel Code and applicable Addenda as required by 10 CFR 50, Section 50.55a.
      -b.      Surveillance intervals specified in Section XI of the ASME Boiler and            l
;              Pressure Vessel Code and applicable Addenda for the inservice inspection and testing activities required by the ASME Boiler and Pressure Vessel Code and applicable Addenda shall be applicable as follows in these Technical Specifications:
4 0 AVIS-BESSE, UNIT 1                                    Amendment No. 77,140,145,197 3/4 0-2 Nft              N    PM 46 y
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      ~                                                                            ~
Docket Number 50-346
  ,,      . License Number NPF-3 Serial Number 2560 Attachment i Page 2 APPLICABILITY BASES 4.0.I to insure the Limiting Conditions for Operation are met and will during the OPERATIONAL MODES or other conditions for which the Limiting Condi-tions for Operation are applicable.
Provisions for additional surveillance activities to be performed without regard to the applicable OPERATIONAL MODES or other conditiens are provided in the individual Surveillance Requirements.
4.0.2 The provisions of this specification provide allowable tolerances for performing lance interval. surveillance activities beyond those specified in the nominal surveil-ity because of scheduling and performance considerations.These        The phrase "at least" tolerance associated with a surveillance frequency does not negate this allowable tolerance value and permits the performance of more frequent surveillance activities.
The allowable tolerance for performing surveillance activities is suffi-ciently restrictive to ensure that the reliability associated with the surveil-lance activity nominal            is notinterval.
specified      significantly degraded beyond that obtained from the It is not intended that the allowable tolerance be used as a convenience to repeatedly schedule the performance of surveillances at the allowable tolerance limit.
The allowable tolerance for performing surveillance activities also provides flexibility to accommodate the length of a fuel cycle for surveillances      that are specified to be performed at least once each REFUELING INTERVAL.
in an OPERATIONAL MODE co'nsistent with safe plant operation.It is 4.0.3 This specification establishes the failure to perform a Surveillance Requirement within the allowed surveillance interval, defined by the provisions of Specification 4.0.2, as a condition that constitutes a failure to meet the OPERABILITY requirements for a Limiting Condition for Operation. Under the provisions of this specification, systems and components are assumed to be OPERABLE
      .within            when Surveillance the specified                  Requirements have been satisfactorily performed time interval.      However, nothing in this provision is to be construed as implying that systems or components are OPERABLE when they are found or known to be inoperable although still meeting the Surveillance Requirements.
This specification also clarifies that the ACTION requirements are applicable when Surveillance Requirements have not been completed within the allowed sitrveillance interval and that the time limits of the ACTION requirements apply from the point.in time it is identified that a surveillance has not been performed and not at the time that the allowed surveillance inter-l davis-BESSE. UtHT I                                B 3/4 0-2            Amendment tio. -NO7-NS, 213 r                                +-          --    m        e
 
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LQ: Bet Number 50-346
                                                                                                                        '        ~
    ,,    .. License Number NPF-3 Serici Number 2560 Attachment 1 Q
Page 3 3/4.2 POWER DISTRIBUTION LIMITS AXIAL POWER IMBALANCE LIMITING CONDITION FOR OPERATION 3.2.1 AXIAL POWER IMBALANCE shall be maintained within the acceptable AXIAL POWER IMBALANCE operating limits provided in the CORE OPERATING-LIMITS REPORT.
APPLICABILITY: MODE 1 above 40% of RATED THERMAL POWER.*
ACTION:
With AXIAL POWER -IMBALANCE exceeding the limits- specified above, either:
: a. Restore the AXIAL POWER IMBALANCE to with the limits provided in the CORE OPERATING LIMITS REPORT within 15 minutes, or j
;                          b. Within one hour reduce power until imbalance limits provided in the CORE OPERATING LIMITS REPORT are met or to 40% of RATED THERMAL POWER or less.
:l SURVEILLANCE REQUIREMENTS 4.2.1 The AXIAL POWER IMBALANCE shall be determined to be within the limits
:                    provided in the CORE OPERATING LIMITS REPORT at least once every 12 hours when above 40% of RATED THERMAL POWER except when the AXIAL POWER IMBALANCE                                        ,
alarm is inoperable, then calculate the AXIAL POWER IMBALANCE at least once                                      l per hour.
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                    *See Special Test Exception 3.10.1.
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DAVIS-BESSE, UNIT 1                3/4 2-1                            Amendment No. 33,A2,45,67,69, (Next page is 3/4 2-5)                                  89.123,144
 
LELWfR'uEoer 80-346
    ,,    License Wmber NPF-3 SeritiNwnber 2560 Attachment 1 Page4 1
          . POWER DISTRIBUTION LIMITS l
QUADRANT POWER TILT j            LIMITING CONDITION FOR OPERATION i
L I
l            3.2.4 THE QUADRANT POWER TILT shall not exceed the Steady State Limit for        i
            . QUADRANT POWER TILT provided in'the CORE OPERATING LIMITS REPORT.              l l
APPLICABILITY: MODE I above 15% of RATED THERMAL POWER.*
ACTION:
l
  .                a. With the QUADRANT POWER TILT determined to exceed the Steady        f State Limit but less than or equal to the Transient Limit provided in the CORE OPERATING LIMITS REPORT:
L
: 1. Within 2 hours:
a)    Either reduce the QUADRANT POWER TILT to within its Steady State Limit, or b)    Reduce THERMAL POWER so as not to exceed THERMAL POWER, including power level cutoff, allowable for the reactor coolant pump combination less at least 2% for each 1% of QUADRANT POWER TILT in excess of the Steady State Limit and within 4 hours, reduce the High Flux Trip Setpoint
:                                    and the Flux-a Flux-Flow Trip Setpoint at least 2% for
                                  + each 1% of QUADRANT POWER TILT in excess of the Steady State Limit.
: 2. Verify that the QUADRANT POWER TILT is within its Steady State Limit within 24 hours after exceeding the Steady State Limit or reduce THERMAL POWER to less than 60% of THERMAL POWER allowable for the reactor coolant pump combination within the next 2 hours and reduce the High Flux Trip Setpcint to < 65.5%
                                                                                          ~
of THERMAL POWER allowable for the reactor coolant pump combination within the next 4 hours.
: 3. Identify and correct the cause of the out of limit condition prior to in' creasing THERMAL POWER; subsequent POWER OPERATION above 60% of THERMAL POWER allowable for the reactor coolant pump combinaticn may proceed provided that the QUADRANT POWER TILT is verified within its Steady State Limit at least once per hour for 12 hours or until verified acceptable'at 95% or l                            greater RATED THERMAL POWER.
l' i
l' l          *See Special Test Exception 3.10.1.
i DAVIS-BESSE, UNIT 1                      3/4 2-9          Anendment No. ,J23,144
 
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License Number NPF-3 Serit! Number 2560 Attachment 1 l
Page5 l
POWER DISTRIBUTION LIMITS LIMITING CONDITION FOR OPERATION (Continued)
ACTION:    (Continued) l
: b. With the QUADRANT POWER TILT detemined to exceed the Transient Limit but less than the Maximum Limit provided in the CORE OPERATING LIMITS          l REPORT, due to misalignment of either a safety, regulating or axial power shaping rod:
1.
Reduce THERMAL POWER at least 2% for each 1% of indicated QUADRANT POWER TILT in excess of the Steady State Limit within 30 minutes,          i
: 2. Verify that the QUADRANT POWER TILT is within its Transient Limit within 2 hours after exceeding the Transient Limit or reduce THERMAL POWER
                                          '.o less than 60% of THERMAL POWER allowable for the reactor coolan pump combination within the next 2 hours and reduce the Hic. Flux Trip Setpoint to < 65.5% of THERMAL POWER allowable for the reactor coolant pump combination within the next 4 hours.
: 3. Identify and correct the cause of the out of limit condition prior to increasing THERMAL POWER; subsequent POWER OPERATION above 60%
of THERMAL POWER allowable for the reactor coolant pump combina4 tion may proceed provided that the QUADRANT POWER TILT is verified within its Steady State Limit at least once per hour for 12 hour-or until verified acceptable at 95% or greater RATED THERMAL P0k
: c. With tiiq QUADRANT POWER TILT detemined to exceed the Transient Limit but less than the Maximum Limit provided in the CORE OPERATING LIMITS REPORT, due to causes other than the misalignment of either a safety, regulating or axial power shaping rod:
: 1. Reduce THERMAL POWER to less than 60% of THERMAL POWER allowable for the reactor coolant pump combination within 2 hours and reduce the High Flux Trip Setpoint to < 65.5% of THERMAL POWER allowable for the reactor coolant pump combination within the next 4 hours.
: 2. Identify and correct the cause of the out of limit condition prior to increasing THERMAL POWER; subsequent POWER OPERATION above 60%
of THERMAL POWER allowable for the reactor coolant pump combina-tion may proceed provided that the QUADRANT POWER TILT is verified within its Steady State Limit at least once per hour for 12 hours or until verified at 95% or greater RATED THERMAL POWER.
DAVIS-BESSE, UNIT 1                        3/4 2-10          Amendment No. JU,JM.I44
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                                                                      ^
        ^~ Docktt Number 502346        ?
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  ,. .'-  ' License Number NPF-3                                                              l l
Sedal Numter 2560 Attachment 1 Page 6 POWER DISTRIBUTION LIMITS                                                      !
LIMITING CONDITION FOR OPERATION (Continued)
ACTION:    (Continued)                                                        l
: d. With the QUADRANT POWER TILT determined to exceed the Maximum Limit provided in the CORE OPERATING LIMITS REPORT, reduce THERMAL POWER to < 15% of RATED THERMAL POWER within 2 hours.              ,
1 SURVEILLANCE REQUIREMENTS 4.2.4 The QUADRANT POWER TILT shall be determined to be < the Steady State Limits provided in the CORE OPERATING LIMITS REPORT at least once every 7 days during operation above 15% of RATED THERMAL POWER except when the QUADRANT POWER TILT alarm is inoperable, then the QUADRANT POWER TILT shall be calculated at least once per 12 hours.
1 DAVIS-BESSE, UNIT 1                  3/4 2-11          Amendment No. J23.144 (Next page is 3/4 2-13)
 
_.      _ _ . .                  _ -. ~ . _ - . - _ _ . _ _ ._.._. _ - .. _ _ _ _. _ __ _ . _ ._ _ _ _ .. _ _ _ ._
Docket Number 50-346
                                                                            - Lictnse Number NPF-3
                    ,!  INSTRUMENTATION                                                Nun r 560                                                    ;
Attachment 7 INCORE DETECTORS
                                                                                    *I
                                      ,-                                                                                                            I LIMITING CONDITION FOR OPERATION
          .        3.3.3.2 As a' minimum, the incore detectors shall be OPERABLE as speci-fled below.
L                              a. . For AXIAL POWER IMBALANCE measurements:.
: 1.        Nine detectors sha-11 be arranged such that there are three l-detectors in each of three strings and there are three detectors lying in the same axial plane with one plane at the core mid-plane and one plane in each axial core half.
: 2.        The axial planes in each core half shall be symetrical o
t      >
about the core mid-plane.
: 3.          The detector strings shall not have radial. symetry, i
: b.      For QUADRANT POWER TILT measurements with the Minimum Incore Dectector System:                                                                              ~
1.
!                                                Two sets of 4. detectors shall lie in each core half.
Each set of detectors shall lie in the same axial plane.
The two sets in the same core half may lie in the same axial plane..
: 2.        Detectors ih the same plane 'shall have quarter core
;                                              radial syninetry,
: c.      For QUADRANT' POWER TILT measurements, at least 75% of the Symmetric Incore Detectors in each core quadrant shall be ORERABLE.
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: d.      For F          and F measurements with the Inc6re Detector System at lebt 75% hf all incore detectors in each core quadrant shall be OPERABLE.
APPLICABILITY: When the incore' detection system is used for measurement of:
: a.      The AXIAL POWER IMBALANCE.
: b.      The QUADRANT POWER TILT.
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: c.      F 3g.
: d.      F.q ACTION:
!              W ith less than the specified minimum incore detector arrangement OPERABLE, L              d o  not use incore detectors for thi above applicable measurement. The
[              p rovisions of Specifications 3.0.3 and 3.0.4 are not applicable.
DAVIS-BESSE, UNIT 1                                            3/4 3-35 Amendment No. 70
                                                                                                                                              , , + -
g..-a    g-- + . -          m      g -yw  4                        y-,-      -p            p ,
 
Docket Number 50-346 License Number NPF-3 Serial Number 2560 Attachment 1
                    , Page 8 , *
                '' INSTRUMENTATION 1
i.
SURVEILLANCE REQUIREMENTS 4.3.3.2 The incore detector system shall be demonstrated OPERABLE:
a.
By performance of a CHANNEL CHECK within 7 days prior to its use  forTILT. measurement of the AXIAL POWER IMBALANCE or the QUADRANTl POWER b.
At least once per 18 months by performance of a CHANNEL CALIBRATION which does not include the neutron detectors.                                                                i l
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r DA'VIS-BESSE, UNIT 1 3/4 3-36
 
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                                          ~
Docket Number 50-346
,, ,.        License Number NPF-3 Serial Number 2560 Attachment 1 Page 9 3/4. 2 POWER DISTRIBUTION LIMITS BASES The specifications of this section provide assurance of fuel integrity during Condition by:            I (normal operation) and II (incidents of moderate frequency) events (a) maintaining the minimum DNBR in the core > the minimum allowable ONB ratio during nomal operation and during short terii transients, (b) maintaining the peak linear power density 1 18.4 kW/f t during nomal operation, and (c) maintaining the peak power density less than the limits given in the bases to specification 2.1 during short term transients. In addition, the above criteria must be met in order to meet the assumptions used for the loss-of-coolant accidents.
The power imbalance envelope and the insertion limit curves defined in the CORE OPERATING LIMITS REPORT are based on LOCA analyses which have defined the maximum linear heat rate such that the maximum clad temperature will not exceed the Final Acceptance Criteria of 2200 F following a LOCA. Operation outside of the power imbalance envelope alone does not constitute a situation that would cause the Final Acceptance Criteria to be exceeded should a LOCA occur.
The power imbalance envelope represents the boundary of operation limited by the Final Acceptance Criteria only if the control rods are at the insertion limits, as defined in the CORE OPERATING LIMITS REPORT and if the steady-state limit QUADRANT POWER TILT' exists.        Additional conservatism is introduced by application of:
: a.      Nuclear uncertainty factors.
: b.      Thermal calibration uncertainty,
: c.      Fuel densification effects.
: d.      Hot rod manufacturing tolerance factors.
: e.      Potential fuel rod bow effects.
The ACTION statements which permit limited variations from the basic require-ments are accompanied by additional restrictions which ensures that the original criteria are met.
The definitions of the design limit nuclear power peaking factors as used in these specifications are as follows:
F q    Nuclear heat flux hot channel factor, is defined as the maximum local fuel rod linear power density divided by the average fuel rod linear power density, assuming nominal fuel pellet and rod dimensions.
DAVIS-BESSE, UNIT 1                  B 3/4 2-1          Amendment No JJ,33, AE,J//,149
 
    .. .. . Docket Number 50-346 -
License Number NPF.3 Scrill Number 2560 Attachment 1 Page 10 POWER DISTRIBUTION LIMITS BASES F",,    Nuclear Enthalpy Rise Het Channel Factor, is defined as the ratio of the integral of itnear power along the rod on which minimum DNBR occurs to the average rod power.
It has been determined by extensive analysis of possible operating power shapes that the design limits on nuclear power peaking and on minimum DN8R at full power are met by compliance with the protective and operating ' limits in the CORE OPERATING LIMITS REPORT.
Power peaking'is not a directly observable quantity and therefore limits have been established on the bases of the AXIAL POWER IMBALANCE produced by the power peaking. It has been determined that the hve hot channel factor limits will be met provided the following conditions are maintained.
: 1. Control rods in a single group move together with no individual rod insertion differing by more than 6.5% (indicated position) from the group average height.
: 2. Regulating rod groups are sequenced with overlapping groups as required in Specification 3.1.3.6.
: 3. The regulating rod insertion limits of Specification 3.1.3.6 are maintained.
: 4. AXIAL POWER IMBALANCE limits are maintained. The AXIAL POWER IM8ALANCE is a measure of the difference in power between the top and bottom halves of the core. Calculations of core average axial peaking factors for many plants and measurements from operating plants under a variety of operating conditions have been correlated with AXIAL POWER IMBALANCE. The correlation shows that the design power shape is not exceeded if the AXIAL POWER IMBALANCE is maintained between the limits specified in Specification 3.2.1.
I The design limit power peaking factors are the most restrictive calculated at full power for the range from all control rods. fully withdrawn to minimum allowable control rod insertion and are the core DNBR design basis.
Therefore, for operation at a fraction of RATED THERMAL POWER, the design limits are met. When using.incore detectors to make power distribution maps to determine F, and F",,:
: a. The measurement of total peaking factor F,"'**, shall be increased by 1.4 percent to account for manufacturing tolerances and further increased by 7.5 percent to account for measurement error.
DAVIS-BESSE, UNIT 1                          B 3/4 2-2                Amendment No.JJ,gJ,189 ad as
 
8
    .. .- License Number NPF-3 SerialNumber 2560 Attachment i Pagei1
              , ROWER DISTRIBUTION LIMITS                                                                                      .
BASES
: b. The measurement of enthalpy rise hot channel factor, F"H' shall be increasedby5percenttoaccountformeasurementerrof.
For Condition II ev ets, the core is protected from exceeding the values given in the bases to specification 2.1 locally, and from going below the minimum allowable DNB ratio by automatic protection on power, AXIAL POWER IMBALANCE pressure and temperature. Only conditions 1 through 3, above, are mandatory since the AXIAL POWER IMBALANCE is an explicit input to the reactor protection system.
The QUADRANT POWER TILT 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 QUADRANT POWER TILT limit at which corrective action is required provides DNB and linear heat generation rate protection with x-y plane power tilts. In the event the tilt is not corrected, the margin for uncertainty on Fo is reinstated by reducing the power by 2 percent for each percent of tilt in excess of the limit.
3/4.2.5 DNB PARAMETERS The limits on the DNB related parameters assure that each of the parameters are maintained within the normal steady state envelope of operation assumed in the transient and accident analyses. The limits are consistent with the FSAR initial assumptions and have been analytically demonstrated adequate to main-                                                            ,
tain a minimum DNBR greater than the minimum allowable DNB ratio throughout each analyzed transient.
The 12 hour periodic surveillance of these parameters through instrument read-out is sufficient to ensure that the parameters are restored within their limits following load changes and other expected transient operation. The 18 month periodic measurement of the RCS total flow rate using delta P instrumenta-tion is adequate to detect flow degradation and ensure correlation of the flow indication channels with measured flow such that the indicated percent flow will "mvide sufficient verification of flow rate on a 12 hour basis.
DAVIS-BESSE, UNIT 1                B 3/4 2-3                                            Amendment No. 3,3,A5.149
 
                ' Docket Number 50-346 Lic:ns) Number NPF-3 i        -
Serial Number 2560 Attachment I l                  Page 12                  .
l                  3 /4.3 INSTRUMENTATION BASES l                                                                                                          -
3 /4.3.3 MONITORING INSTRUMENTATIQf(
3/4.3.3.1 RADIATION HONITORING INSTRUNENTATION The OPERABILITY of the radiation monitoring channels ensures that 1) the l                radiation levels are continually measured in the areas served by the individuallevel radiation                  channels  and 2) the trip setpoint    alarm or automatic action is initiated when the is exceeded.
3/4.3.3.2 INCORE DETECTORS The OPERABILITY of the incore detectors ensures that the measurements obtained from u'se of this system accurately represent the spatial neutron flux distribution of the reactor core. See Sases Figures 3-1 and 3-2 for examples of acceptabic minimum incore detector arrangements.
3 /4.3.3.3 SEISMIC INSTRUMENTATION l
Deleted 1
J/4.3.3.4 NETEOROLOGICAL INSTRUMENTATION l            Deleted l
3 /4.3.3. 5 REH0TE SHUTDOWN INSTRUMENTATION Tha OPERABILITY of the remote shutdown instrumentation ensures that sufficient capability is available to permit shutdown and maintenance of l
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i l
l DAVIS-BESSE, UNIT 1 B 3/4 3-2                            Amendment No. 201 1                                                                                                                          -
 
Docket Number 50-346
      .. License Number NPF-3 Serial Number 2560                                                                  3/4.5(l1)      4 Attachment 2                              MAY 181988                                                ;
Pagei HEM 0'RbDUMFOR: Ted Quay. Senior Project Manager Projdct Directorate 111-1 Division of Reactor Projects - III        IV and Special Projects, NRR THRU:
Richard L. Emch, Section Chief Technical Specifications Branch Division of Operational Events Assessment, NRR FROM:
Robert J. Giardina, Reactor Engineer Review & Assessment Section Technical Specifications Branch Division of Operational Events Assessment, NRR l
 
==SUBJECT:==
FERMI-2 TECHNICAL SPECIFICATION INTERPRETATIONS
 
==REFERENCE:==
 
Memorandum for G. Holahan, from C. Morelius dated August 12, 1987 l'              In response to your August 26, 1987 request for assistance to clarify several Technical Specification questions submitted by Region !!!,
Enclosures 1, 2 and 3 provide OTSB's response to Issues 2 (Situational Surveillances), 3 (Startup Definition), and 6 (Technical Specification                          i Parameter Accuracy) respectively.
i N  _
                                                              . Giardina, Reactor Engineer Rober Review and Assessment Section Technical Specifications Branch Division of Operational Events Assessment, NRR
          ~
 
==Enclosures:==
As staced CONTACT: Robert J. Giardina 492-1188 Distribution 0155 r/f              00EA r/f Oceket Files          CERossi
.                EJButcher            RLEmch RJGiardina            CHBerlinger W0Lanning            GRKlingler JLieberman            OTSB Members
                'JTaylor
* l                  ILRB FM-OTSB:00EA:NRR          OTSB:00E RJGiardina:pmc        RLEmch 05/1/28              0548/88
                                                                                                ~
f
 
Dock:t Number 50-346 License Number NPF-3 SerialNumber 2560
        ~ Attachment 2
        - Page 2 * ~    .'
OTSB PART 9900: TECHNICAL GUIDANCE STANDARD TECilHICAt. SPECIFICATIONS STS SECTION 4.0.2 A.        PURPOSE To provide guidance regarding the conditions under which the specified time interval for Surveillance Requirements may be extended.
B.        BACKGROUND During inspection activities performed in 1987 at the Fermi-2 site, the Resident Inspectors encountered a number of issues associated with Technical Specifications (TS) interpretations. One of the issues involved TS 4.0.2 which allows a 25% extension to the interval for performance of a Surveil-lance Requirement (SR). Certain surveillance activities in the Fermi-2 Tech-(        nical . Specifications and all other Standard Technical Specifications              (STS)
Two examples  of are based upon particu,lar plant conditions or situations.
this type of " situational" surveillance are SR 4.4.1.4 which states "The temperature offferentials and flow rate shall be determined to be within the
            ~11mits within 15 minutes prior to startup..."' and SR 4.8.1.1.1.c.2            Thewhich Region states "By verifying within 30 days of obtaining the sample ....".
requested that NRR provide assistance in determining whether TS 4.0.2 applies to situational surveillances.
C.      DISCUSSION TS 4.0.2 establishes the conditions under which the specified time interval for SRs may be extended. According to the BASES, the intent of STS 4.0.2 is to provide operational flexibility by permitting an extension of up to 25%
of the nonnal surveillance interval to facilitate surveillance scheduling and consideratiors of plant operating conditions that may not be suitable for transient conditions or other on-going conducting the surveillance; e.g.,            The second part of TS 4.0.2 states surveillance or maintenance activity.
              ~ that the total of three consecutive intervals may not exceed 3.25 times the specified interval. This part is intended to limit the use of the 25% exten-sion to ensure that it is not used excessively.
Clearly TS 4.0.2 was intended for application to regular surveillance inter-vals, intervals characterize'd by the wording "At least once            per" a specified A situational sur-time interval (i.e.,15 minutes. I week, 31 days, etc.).
veillance requirement is characterized by the wording "within" a specified Issue Date:  xx/xx/88
 
                                      . -s . . _ _ _ _ ___ ._ ._.-__. _ _.._ _. _ ._.-._            _ _ _ . _ .__
Docket Number 50-346 License Number NPF-3                                                                                  ,
Serial Number 2560 Attachment 2 Page 3 time interval and is followed by a certain condition or situation (i.e.,
prior to startup, af ter control rod movement, af ter taking a sample, etc.).
~
The wording of the situatfional surveillance requirement allows the specified surveillance to be performed at any time during the specified time interval.
Therefore, the operational flexibility is already built into the situational surveillance which is not a regular surveillance interval, and TS 4.0.2 does not apply.
In some cases, a situational surveillance can become a regular interval sur-veillance temporarily because of circumstances. For example, during a period when the containment personnel airlock is being used everyday, the situational surveillance "within 72 hour af ter airlock use" becomes a regular surveillance interval of "cnce per 72 hours."              Under such conditions the flexibility of TS 4.0.2 can be applied.
l D.        CONCLUSION TS 4.0.2 is not applicable to situational surveillance requirements.                                  ,
E.        REFERENCE
      .        1. Memorandum for G. Holahan from C. Morelius dated August 12, 1987 on Request for Technical Assistance - Technical Specification Inter-pretations.
!(                                          ,
END Ae a}}

Latest revision as of 17:21, 17 December 2020

Proposed Tech Specs 4.0.2 Re Applicability of 25% Surveillance Interval Extension Allowance
ML20155E497
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Site: Davis Besse Cleveland Electric icon.png
Issue date: 10/28/1998
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Download: ML20155E497 (15)


Text

~ ~

bocht Number 50 346 License Number NPF-3 Serial Number 2560 Attachment 1 Page1 '

APPLIGA8ItITi SURVEILLANCE REQUIREMENTS 4.0.1 Surveillance Requirements shall be applicable during the OPERATIONAL MODES or other conditions specified for individual Limiting Conditions for Operation unless otherwise 's;tated in an individual Surveillance Requirement.

4.0.2 Each Surveillance Requirement shall be performed within the specified time interval with a maximum allowable extension not to exceed 25 percent of the specified surveillance interval.

4.0.3 . Failure to perform a Surveillance Requirement within the allowed surveillance interval, defined by Specification 4.0.2, shall constitute noncompliance with the OPERADILIlY requirements for a Limiting Condition for Operation.

The time limits of the ACTION requirements are applicable at the time it is identified that a Surveillance Requirement has not been performed. -

The ACTION requirements may be delayed for up to 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> to permit the completion of the surveillance when the allowable (equipment inoperability) outage time limits of. the ACTION requirements are less than 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br />.

Surveillance requirements do not have to be performed on' inoperable equipment.

4.0.4 Entry into an OPERATIONA( MODE or other specified applicability condition shall not be made 'unless the Sufveillance Requirement (s) associated with the Limiting Condition for Operation have been performed within the stated surveillance interval or as otherwise specified.

4.0.5 Surveillance Requirements for inservice inspection and testing of ASME Code Class 1, 2 and 3 components shall be applicable as follows:

a. Inservice inspection of ASME Code Class 1, 2 and 3 components and inservice testing of ASME Code Class 1, 2 and 3 pumps and valves shall be performed in accordance with Section XI of the ASME Boiler and Pressure Vessel Code and applicable Addenda as required by 10 CFR 50, Section 50.55a.

-b. Surveillance intervals specified in Section XI of the ASME Boiler and l

Pressure Vessel Code and applicable Addenda for the inservice inspection and testing activities required by the ASME Boiler and Pressure Vessel Code and applicable Addenda shall be applicable as follows in these Technical Specifications

4 0 AVIS-BESSE, UNIT 1 Amendment No. 77,140,145,197 3/4 0-2 Nft N PM 46 y

l.

P

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Docket Number 50-346

,, . License Number NPF-3 Serial Number 2560 Attachment i Page 2 APPLICABILITY BASES 4.0.I to insure the Limiting Conditions for Operation are met and will during the OPERATIONAL MODES or other conditions for which the Limiting Condi-tions for Operation are applicable.

Provisions for additional surveillance activities to be performed without regard to the applicable OPERATIONAL MODES or other conditiens are provided in the individual Surveillance Requirements.

4.0.2 The provisions of this specification provide allowable tolerances for performing lance interval. surveillance activities beyond those specified in the nominal surveil-ity because of scheduling and performance considerations.These The phrase "at least" tolerance associated with a surveillance frequency does not negate this allowable tolerance value and permits the performance of more frequent surveillance activities.

The allowable tolerance for performing surveillance activities is suffi-ciently restrictive to ensure that the reliability associated with the surveil-lance activity nominal is notinterval.

specified significantly degraded beyond that obtained from the It is not intended that the allowable tolerance be used as a convenience to repeatedly schedule the performance of surveillances at the allowable tolerance limit.

The allowable tolerance for performing surveillance activities also provides flexibility to accommodate the length of a fuel cycle for surveillances that are specified to be performed at least once each REFUELING INTERVAL.

in an OPERATIONAL MODE co'nsistent with safe plant operation.It is 4.0.3 This specification establishes the failure to perform a Surveillance Requirement within the allowed surveillance interval, defined by the provisions of Specification 4.0.2, as a condition that constitutes a failure to meet the OPERABILITY requirements for a Limiting Condition for Operation. Under the provisions of this specification, systems and components are assumed to be OPERABLE

.within when Surveillance the specified Requirements have been satisfactorily performed time interval. However, nothing in this provision is to be construed as implying that systems or components are OPERABLE when they are found or known to be inoperable although still meeting the Surveillance Requirements.

This specification also clarifies that the ACTION requirements are applicable when Surveillance Requirements have not been completed within the allowed sitrveillance interval and that the time limits of the ACTION requirements apply from the point.in time it is identified that a surveillance has not been performed and not at the time that the allowed surveillance inter-l davis-BESSE. UtHT I B 3/4 0-2 Amendment tio. -NO7-NS, 213 r +- -- m e

y

~

LQ: Bet Number 50-346

' ~

,, .. License Number NPF-3 Serici Number 2560 Attachment 1 Q

Page 3 3/4.2 POWER DISTRIBUTION LIMITS AXIAL POWER IMBALANCE LIMITING CONDITION FOR OPERATION 3.2.1 AXIAL POWER IMBALANCE shall be maintained within the acceptable AXIAL POWER IMBALANCE operating limits provided in the CORE OPERATING-LIMITS REPORT.

APPLICABILITY: MODE 1 above 40% of RATED THERMAL POWER.*

ACTION:

With AXIAL POWER -IMBALANCE exceeding the limits- specified above, either:

a. Restore the AXIAL POWER IMBALANCE to with the limits provided in the CORE OPERATING LIMITS REPORT within 15 minutes, or j
b. Within one hour reduce power until imbalance limits provided in the CORE OPERATING LIMITS REPORT are met or to 40% of RATED THERMAL POWER or less.
l SURVEILLANCE REQUIREMENTS 4.2.1 The AXIAL POWER IMBALANCE shall be determined to be within the limits
provided in the CORE OPERATING LIMITS REPORT at least once every 12 hours1.388889e-4 days <br />0.00333 hours <br />1.984127e-5 weeks <br />4.566e-6 months <br /> when above 40% of RATED THERMAL POWER except when the AXIAL POWER IMBALANCE ,

alarm is inoperable, then calculate the AXIAL POWER IMBALANCE at least once l per hour.

l 4 -

l 1

i

  • See Special Test Exception 3.10.1.

4 j

DAVIS-BESSE, UNIT 1 3/4 2-1 Amendment No. 33,A2,45,67,69, (Next page is 3/4 2-5) 89.123,144

LELWfR'uEoer 80-346

,, License Wmber NPF-3 SeritiNwnber 2560 Attachment 1 Page4 1

. POWER DISTRIBUTION LIMITS l

QUADRANT POWER TILT j LIMITING CONDITION FOR OPERATION i

L I

l 3.2.4 THE QUADRANT POWER TILT shall not exceed the Steady State Limit for i

. QUADRANT POWER TILT provided in'the CORE OPERATING LIMITS REPORT. l l

APPLICABILITY: MODE I above 15% of RATED THERMAL POWER.*

ACTION:

l

. a. With the QUADRANT POWER TILT determined to exceed the Steady f State Limit but less than or equal to the Transient Limit provided in the CORE OPERATING LIMITS REPORT:

L

1. Within 2 hour2.314815e-5 days <br />5.555556e-4 hours <br />3.306878e-6 weeks <br />7.61e-7 months <br />s:

a) Either reduce the QUADRANT POWER TILT to within its Steady State Limit, or b) Reduce THERMAL POWER so as not to exceed THERMAL POWER, including power level cutoff, allowable for the reactor coolant pump combination less at least 2% for each 1% of QUADRANT POWER TILT in excess of the Steady State Limit and within 4 hours4.62963e-5 days <br />0.00111 hours <br />6.613757e-6 weeks <br />1.522e-6 months <br />, reduce the High Flux Trip Setpoint

and the Flux-a Flux-Flow Trip Setpoint at least 2% for

+ each 1% of QUADRANT POWER TILT in excess of the Steady State Limit.

2. Verify that the QUADRANT POWER TILT is within its Steady State Limit within 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> after exceeding the Steady State Limit or reduce THERMAL POWER to less than 60% of THERMAL POWER allowable for the reactor coolant pump combination within the next 2 hours2.314815e-5 days <br />5.555556e-4 hours <br />3.306878e-6 weeks <br />7.61e-7 months <br /> and reduce the High Flux Trip Setpcint to < 65.5%

~

of THERMAL POWER allowable for the reactor coolant pump combination within the next 4 hours4.62963e-5 days <br />0.00111 hours <br />6.613757e-6 weeks <br />1.522e-6 months <br />.

3. Identify and correct the cause of the out of limit condition prior to in' creasing THERMAL POWER; subsequent POWER OPERATION above 60% of THERMAL POWER allowable for the reactor coolant pump combinaticn may proceed provided that the QUADRANT POWER TILT is verified within its Steady State Limit at least once per hour for 12 hours1.388889e-4 days <br />0.00333 hours <br />1.984127e-5 weeks <br />4.566e-6 months <br /> or until verified acceptable'at 95% or l greater RATED THERMAL POWER.

l' i

l' l *See Special Test Exception 3.10.1.

i DAVIS-BESSE, UNIT 1 3/4 2-9 Anendment No. ,J23,144

QXATM(T5%M

^ -

License Number NPF-3 Serit! Number 2560 Attachment 1 l

Page5 l

POWER DISTRIBUTION LIMITS LIMITING CONDITION FOR OPERATION (Continued)

ACTION: (Continued) l

b. With the QUADRANT POWER TILT detemined to exceed the Transient Limit but less than the Maximum Limit provided in the CORE OPERATING LIMITS l REPORT, due to misalignment of either a safety, regulating or axial power shaping rod:

1.

Reduce THERMAL POWER at least 2% for each 1% of indicated QUADRANT POWER TILT in excess of the Steady State Limit within 30 minutes, i

2. Verify that the QUADRANT POWER TILT is within its Transient Limit within 2 hours2.314815e-5 days <br />5.555556e-4 hours <br />3.306878e-6 weeks <br />7.61e-7 months <br /> after exceeding the Transient Limit or reduce THERMAL POWER

'.o less than 60% of THERMAL POWER allowable for the reactor coolan pump combination within the next 2 hours2.314815e-5 days <br />5.555556e-4 hours <br />3.306878e-6 weeks <br />7.61e-7 months <br /> and reduce the Hic. Flux Trip Setpoint to < 65.5% of THERMAL POWER allowable for the reactor coolant pump combination within the next 4 hours4.62963e-5 days <br />0.00111 hours <br />6.613757e-6 weeks <br />1.522e-6 months <br />.

3. Identify and correct the cause of the out of limit condition prior to increasing THERMAL POWER; subsequent POWER OPERATION above 60%

of THERMAL POWER allowable for the reactor coolant pump combina4 tion may proceed provided that the QUADRANT POWER TILT is verified within its Steady State Limit at least once per hour for 12 hour-or until verified acceptable at 95% or greater RATED THERMAL P0k

c. With tiiq QUADRANT POWER TILT detemined to exceed the Transient Limit but less than the Maximum Limit provided in the CORE OPERATING LIMITS REPORT, due to causes other than the misalignment of either a safety, regulating or axial power shaping rod:
1. Reduce THERMAL POWER to less than 60% of THERMAL POWER allowable for the reactor coolant pump combination within 2 hours2.314815e-5 days <br />5.555556e-4 hours <br />3.306878e-6 weeks <br />7.61e-7 months <br /> and reduce the High Flux Trip Setpoint to < 65.5% of THERMAL POWER allowable for the reactor coolant pump combination within the next 4 hours4.62963e-5 days <br />0.00111 hours <br />6.613757e-6 weeks <br />1.522e-6 months <br />.
2. Identify and correct the cause of the out of limit condition prior to increasing THERMAL POWER; subsequent POWER OPERATION above 60%

of THERMAL POWER allowable for the reactor coolant pump combina-tion may proceed provided that the QUADRANT POWER TILT is verified within its Steady State Limit at least once per hour for 12 hours1.388889e-4 days <br />0.00333 hours <br />1.984127e-5 weeks <br />4.566e-6 months <br /> or until verified at 95% or greater RATED THERMAL POWER.

DAVIS-BESSE, UNIT 1 3/4 2-10 Amendment No. JU,JM.I44

.e

^

^~ Docktt Number 502346  ?

~

,. .'- ' License Number NPF-3 l l

Sedal Numter 2560 Attachment 1 Page 6 POWER DISTRIBUTION LIMITS  !

LIMITING CONDITION FOR OPERATION (Continued)

ACTION: (Continued) l

d. With the QUADRANT POWER TILT determined to exceed the Maximum Limit provided in the CORE OPERATING LIMITS REPORT, reduce THERMAL POWER to < 15% of RATED THERMAL POWER within 2 hours2.314815e-5 days <br />5.555556e-4 hours <br />3.306878e-6 weeks <br />7.61e-7 months <br />. ,

1 SURVEILLANCE REQUIREMENTS 4.2.4 The QUADRANT POWER TILT shall be determined to be < the Steady State Limits provided in the CORE OPERATING LIMITS REPORT at least once every 7 days during operation above 15% of RATED THERMAL POWER except when the QUADRANT POWER TILT alarm is inoperable, then the QUADRANT POWER TILT shall be calculated at least once per 12 hours1.388889e-4 days <br />0.00333 hours <br />1.984127e-5 weeks <br />4.566e-6 months <br />.

1 DAVIS-BESSE, UNIT 1 3/4 2-11 Amendment No. J23.144 (Next page is 3/4 2-13)

_. _ _ . . _ -. ~ . _ - . - _ _ . _ _ ._.._. _ - .. _ _ _ _. _ __ _ . _ ._ _ _ _ .. _ _ _ ._

Docket Number 50-346

- Lictnse Number NPF-3

,! INSTRUMENTATION Nun r 560  ;

Attachment 7 INCORE DETECTORS

  • I

,- I LIMITING CONDITION FOR OPERATION

. 3.3.3.2 As a' minimum, the incore detectors shall be OPERABLE as speci-fled below.

L a. . For AXIAL POWER IMBALANCE measurements:.

1. Nine detectors sha-11 be arranged such that there are three l-detectors in each of three strings and there are three detectors lying in the same axial plane with one plane at the core mid-plane and one plane in each axial core half.
2. The axial planes in each core half shall be symetrical o

t >

about the core mid-plane.

3. The detector strings shall not have radial. symetry, i
b. For QUADRANT POWER TILT measurements with the Minimum Incore Dectector System: ~

1.

! Two sets of 4. detectors shall lie in each core half.

Each set of detectors shall lie in the same axial plane.

The two sets in the same core half may lie in the same axial plane..

2. Detectors ih the same plane 'shall have quarter core
radial syninetry,
c. For QUADRANT' POWER TILT measurements, at least 75% of the Symmetric Incore Detectors in each core quadrant shall be ORERABLE.

N

d. For F and F measurements with the Inc6re Detector System at lebt 75% hf all incore detectors in each core quadrant shall be OPERABLE.

APPLICABILITY: When the incore' detection system is used for measurement of:

a. The AXIAL POWER IMBALANCE.
b. The QUADRANT POWER TILT.

N

c. F 3g.
d. F.q ACTION:

! W ith less than the specified minimum incore detector arrangement OPERABLE, L d o not use incore detectors for thi above applicable measurement. The

[ p rovisions of Specifications 3.0.3 and 3.0.4 are not applicable.

DAVIS-BESSE, UNIT 1 3/4 3-35 Amendment No. 70

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g..-a g-- + . - m g -yw 4 y-,- -p p ,

Docket Number 50-346 License Number NPF-3 Serial Number 2560 Attachment 1

, Page 8 , *

INSTRUMENTATION 1

i.

SURVEILLANCE REQUIREMENTS 4.3.3.2 The incore detector system shall be demonstrated OPERABLE:

a.

By performance of a CHANNEL CHECK within 7 days prior to its use forTILT. measurement of the AXIAL POWER IMBALANCE or the QUADRANTl POWER b.

At least once per 18 months by performance of a CHANNEL CALIBRATION which does not include the neutron detectors. i l

l l

l I

r DA'VIS-BESSE, UNIT 1 3/4 3-36

~

~

Docket Number 50-346

,, ,. License Number NPF-3 Serial Number 2560 Attachment 1 Page 9 3/4. 2 POWER DISTRIBUTION LIMITS BASES The specifications of this section provide assurance of fuel integrity during Condition by: I (normal operation) and II (incidents of moderate frequency) events (a) maintaining the minimum DNBR in the core > the minimum allowable ONB ratio during nomal operation and during short terii transients, (b) maintaining the peak linear power density 1 18.4 kW/f t during nomal operation, and (c) maintaining the peak power density less than the limits given in the bases to specification 2.1 during short term transients. In addition, the above criteria must be met in order to meet the assumptions used for the loss-of-coolant accidents.

The power imbalance envelope and the insertion limit curves defined in the CORE OPERATING LIMITS REPORT are based on LOCA analyses which have defined the maximum linear heat rate such that the maximum clad temperature will not exceed the Final Acceptance Criteria of 2200 F following a LOCA. Operation outside of the power imbalance envelope alone does not constitute a situation that would cause the Final Acceptance Criteria to be exceeded should a LOCA occur.

The power imbalance envelope represents the boundary of operation limited by the Final Acceptance Criteria only if the control rods are at the insertion limits, as defined in the CORE OPERATING LIMITS REPORT and if the steady-state limit QUADRANT POWER TILT' exists. Additional conservatism is introduced by application of:

a. Nuclear uncertainty factors.
b. Thermal calibration uncertainty,
c. Fuel densification effects.
d. Hot rod manufacturing tolerance factors.
e. Potential fuel rod bow effects.

The ACTION statements which permit limited variations from the basic require-ments are accompanied by additional restrictions which ensures that the original criteria are met.

The definitions of the design limit nuclear power peaking factors as used in these specifications are as follows:

F q Nuclear heat flux hot channel factor, is defined as the maximum local fuel rod linear power density divided by the average fuel rod linear power density, assuming nominal fuel pellet and rod dimensions.

DAVIS-BESSE, UNIT 1 B 3/4 2-1 Amendment No JJ,33, AE,J//,149

.. .. . Docket Number 50-346 -

License Number NPF.3 Scrill Number 2560 Attachment 1 Page 10 POWER DISTRIBUTION LIMITS BASES F",, Nuclear Enthalpy Rise Het Channel Factor, is defined as the ratio of the integral of itnear power along the rod on which minimum DNBR occurs to the average rod power.

It has been determined by extensive analysis of possible operating power shapes that the design limits on nuclear power peaking and on minimum DN8R at full power are met by compliance with the protective and operating ' limits in the CORE OPERATING LIMITS REPORT.

Power peaking'is not a directly observable quantity and therefore limits have been established on the bases of the AXIAL POWER IMBALANCE produced by the power peaking. It has been determined that the hve hot channel factor limits will be met provided the following conditions are maintained.

1. Control rods in a single group move together with no individual rod insertion differing by more than 6.5% (indicated position) from the group average height.
2. Regulating rod groups are sequenced with overlapping groups as required in Specification 3.1.3.6.
3. The regulating rod insertion limits of Specification 3.1.3.6 are maintained.
4. AXIAL POWER IMBALANCE limits are maintained. The AXIAL POWER IM8ALANCE is a measure of the difference in power between the top and bottom halves of the core. Calculations of core average axial peaking factors for many plants and measurements from operating plants under a variety of operating conditions have been correlated with AXIAL POWER IMBALANCE. The correlation shows that the design power shape is not exceeded if the AXIAL POWER IMBALANCE is maintained between the limits specified in Specification 3.2.1.

I The design limit power peaking factors are the most restrictive calculated at full power for the range from all control rods. fully withdrawn to minimum allowable control rod insertion and are the core DNBR design basis.

Therefore, for operation at a fraction of RATED THERMAL POWER, the design limits are met. When using.incore detectors to make power distribution maps to determine F, and F",,:

a. The measurement of total peaking factor F,"'**, shall be increased by 1.4 percent to account for manufacturing tolerances and further increased by 7.5 percent to account for measurement error.

DAVIS-BESSE, UNIT 1 B 3/4 2-2 Amendment No.JJ,gJ,189 ad as

8

.. .- License Number NPF-3 SerialNumber 2560 Attachment i Pagei1

, ROWER DISTRIBUTION LIMITS .

BASES

b. The measurement of enthalpy rise hot channel factor, F"H' shall be increasedby5percenttoaccountformeasurementerrof.

For Condition II ev ets, the core is protected from exceeding the values given in the bases to specification 2.1 locally, and from going below the minimum allowable DNB ratio by automatic protection on power, AXIAL POWER IMBALANCE pressure and temperature. Only conditions 1 through 3, above, are mandatory since the AXIAL POWER IMBALANCE is an explicit input to the reactor protection system.

The QUADRANT POWER TILT 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 QUADRANT POWER TILT limit at which corrective action is required provides DNB and linear heat generation rate protection with x-y plane power tilts. In the event the tilt is not corrected, the margin for uncertainty on Fo is reinstated by reducing the power by 2 percent for each percent of tilt in excess of the limit.

3/4.2.5 DNB PARAMETERS The limits on the DNB related parameters assure that each of the parameters are maintained within the normal steady state envelope of operation assumed in the transient and accident analyses. The limits are consistent with the FSAR initial assumptions and have been analytically demonstrated adequate to main- ,

tain a minimum DNBR greater than the minimum allowable DNB ratio throughout each analyzed transient.

The 12 hour1.388889e-4 days <br />0.00333 hours <br />1.984127e-5 weeks <br />4.566e-6 months <br /> periodic surveillance of these parameters through instrument read-out is sufficient to ensure that the parameters are restored within their limits following load changes and other expected transient operation. The 18 month periodic measurement of the RCS total flow rate using delta P instrumenta-tion is adequate to detect flow degradation and ensure correlation of the flow indication channels with measured flow such that the indicated percent flow will "mvide sufficient verification of flow rate on a 12 hour1.388889e-4 days <br />0.00333 hours <br />1.984127e-5 weeks <br />4.566e-6 months <br /> basis.

DAVIS-BESSE, UNIT 1 B 3/4 2-3 Amendment No. 3,3,A5.149

' Docket Number 50-346 Lic:ns) Number NPF-3 i -

Serial Number 2560 Attachment I l Page 12 .

l 3 /4.3 INSTRUMENTATION BASES l -

3 /4.3.3 MONITORING INSTRUMENTATIQf(

3/4.3.3.1 RADIATION HONITORING INSTRUNENTATION The OPERABILITY of the radiation monitoring channels ensures that 1) the l radiation levels are continually measured in the areas served by the individuallevel radiation channels and 2) the trip setpoint alarm or automatic action is initiated when the is exceeded.

3/4.3.3.2 INCORE DETECTORS The OPERABILITY of the incore detectors ensures that the measurements obtained from u'se of this system accurately represent the spatial neutron flux distribution of the reactor core. See Sases Figures 3-1 and 3-2 for examples of acceptabic minimum incore detector arrangements.

3 /4.3.3.3 SEISMIC INSTRUMENTATION l

Deleted 1

J/4.3.3.4 NETEOROLOGICAL INSTRUMENTATION l Deleted l

3 /4.3.3. 5 REH0TE SHUTDOWN INSTRUMENTATION Tha OPERABILITY of the remote shutdown instrumentation ensures that sufficient capability is available to permit shutdown and maintenance of l

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l DAVIS-BESSE, UNIT 1 B 3/4 3-2 Amendment No. 201 1 -

Docket Number 50-346

.. License Number NPF-3 Serial Number 2560 3/4.5(l1) 4 Attachment 2 MAY 181988  ;

Pagei HEM 0'RbDUMFOR: Ted Quay. Senior Project Manager Projdct Directorate 111-1 Division of Reactor Projects - III IV and Special Projects, NRR THRU:

Richard L. Emch, Section Chief Technical Specifications Branch Division of Operational Events Assessment, NRR FROM:

Robert J. Giardina, Reactor Engineer Review & Assessment Section Technical Specifications Branch Division of Operational Events Assessment, NRR l

SUBJECT:

FERMI-2 TECHNICAL SPECIFICATION INTERPRETATIONS

REFERENCE:

Memorandum for G. Holahan, from C. Morelius dated August 12, 1987 l' In response to your August 26, 1987 request for assistance to clarify several Technical Specification questions submitted by Region !!!,

Enclosures 1, 2 and 3 provide OTSB's response to Issues 2 (Situational Surveillances), 3 (Startup Definition), and 6 (Technical Specification i Parameter Accuracy) respectively.

i N _

. Giardina, Reactor Engineer Rober Review and Assessment Section Technical Specifications Branch Division of Operational Events Assessment, NRR

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Enclosures:

As staced CONTACT: Robert J. Giardina 492-1188 Distribution 0155 r/f 00EA r/f Oceket Files CERossi

. EJButcher RLEmch RJGiardina CHBerlinger W0Lanning GRKlingler JLieberman OTSB Members

'JTaylor

  • l ILRB FM-OTSB:00EA:NRR OTSB:00E RJGiardina:pmc RLEmch 05/1/28 0548/88

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Dock:t Number 50-346 License Number NPF-3 SerialNumber 2560

~ Attachment 2

- Page 2 * ~ .'

OTSB PART 9900: TECHNICAL GUIDANCE STANDARD TECilHICAt. SPECIFICATIONS STS SECTION 4.0.2 A. PURPOSE To provide guidance regarding the conditions under which the specified time interval for Surveillance Requirements may be extended.

B. BACKGROUND During inspection activities performed in 1987 at the Fermi-2 site, the Resident Inspectors encountered a number of issues associated with Technical Specifications (TS) interpretations. One of the issues involved TS 4.0.2 which allows a 25% extension to the interval for performance of a Surveil-lance Requirement (SR). Certain surveillance activities in the Fermi-2 Tech-( nical . Specifications and all other Standard Technical Specifications (STS)

Two examples of are based upon particu,lar plant conditions or situations.

this type of " situational" surveillance are SR 4.4.1.4 which states "The temperature offferentials and flow rate shall be determined to be within the

~11mits within 15 minutes prior to startup..."' and SR 4.8.1.1.1.c.2 Thewhich Region states "By verifying within 30 days of obtaining the sample ....".

requested that NRR provide assistance in determining whether TS 4.0.2 applies to situational surveillances.

C. DISCUSSION TS 4.0.2 establishes the conditions under which the specified time interval for SRs may be extended. According to the BASES, the intent of STS 4.0.2 is to provide operational flexibility by permitting an extension of up to 25%

of the nonnal surveillance interval to facilitate surveillance scheduling and consideratiors of plant operating conditions that may not be suitable for transient conditions or other on-going conducting the surveillance; e.g., The second part of TS 4.0.2 states surveillance or maintenance activity.

~ that the total of three consecutive intervals may not exceed 3.25 times the specified interval. This part is intended to limit the use of the 25% exten-sion to ensure that it is not used excessively.

Clearly TS 4.0.2 was intended for application to regular surveillance inter-vals, intervals characterize'd by the wording "At least once per" a specified A situational sur-time interval (i.e.,15 minutes. I week, 31 days, etc.).

veillance requirement is characterized by the wording "within" a specified Issue Date: xx/xx/88

. -s . . _ _ _ _ ___ ._ ._.-__. _ _.._ _. _ ._.-._ _ _ _ . _ .__

Docket Number 50-346 License Number NPF-3 ,

Serial Number 2560 Attachment 2 Page 3 time interval and is followed by a certain condition or situation (i.e.,

prior to startup, af ter control rod movement, af ter taking a sample, etc.).

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The wording of the situatfional surveillance requirement allows the specified surveillance to be performed at any time during the specified time interval.

Therefore, the operational flexibility is already built into the situational surveillance which is not a regular surveillance interval, and TS 4.0.2 does not apply.

In some cases, a situational surveillance can become a regular interval sur-veillance temporarily because of circumstances. For example, during a period when the containment personnel airlock is being used everyday, the situational surveillance "within 72 hour8.333333e-4 days <br />0.02 hours <br />1.190476e-4 weeks <br />2.7396e-5 months <br /> af ter airlock use" becomes a regular surveillance interval of "cnce per 72 hours8.333333e-4 days <br />0.02 hours <br />1.190476e-4 weeks <br />2.7396e-5 months <br />." Under such conditions the flexibility of TS 4.0.2 can be applied.

l D. CONCLUSION TS 4.0.2 is not applicable to situational surveillance requirements. ,

E. REFERENCE

. 1. Memorandum for G. Holahan from C. Morelius dated August 12, 1987 on Request for Technical Assistance - Technical Specification Inter-pretations.

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