ML20237E947
| ML20237E947 | |
| Person / Time | |
|---|---|
| Site: | FitzPatrick  |
| Issue date: | 08/08/1998 |
| From: | Rodriguez F, Zarenba A POWER AUTHORITY OF THE STATE OF NEW YORK (NEW YORK |
| To: | |
| Shared Package | |
| ML20237E946 | List: |
| References | |
| NUDOCS 9809010316 | |
| Download: ML20237E947 (31) | |
Text
e l
NEW YORK POWER AUTHORITY JAMES A.
FITZPATRICK NUCLEAR POWER PLANT REPORT CORE OPERATING LIMITS REPORT REVISION 6 REVIEWED BY:
PLANT OPERATIONS REVIEW COMMITTEE k8[18 MEETING NO. 98- 0 6 DATE APPROVED BY:
ame/sce ud&
DATE 8[8 8 REACTOR ANAVIST
/ISOR 0
k'A APPROVED BY:
had hv d ;t DATE
$ 8 98 Ap.e.n g A SITE EXECUTIVE 6FFICER
/[
l Rev. No. 6 Page 1 of 31 9809010316 980827 PDR ADOCK 05000333 P
" CORE OPERATING LIMITS REPORT CYCLE 13
- 1.,0 PURPOSE This report provides the cycle-specific operating limits for Cycle 13 of the James A. FitzPatrick Nuclear Power Plant.
The foliawing limits are addressed:
Operating Limit Minimum Critical Power Ratio (MCPR)
Flow Dependent MCPR Limits Maximum Average Planar Linear Heat Generation Rate (MAPLHGR)
Linear Heat Generation Rate (LHGR)
Flow-Biased Average Power Range Monitor (APRM) and Rod Block Monitor (RBM) Settings Stability Option ID Exclusion Region 2.0 APPLICABILITY The plant shaIl be operated within the limits specified in this report.
If any of these limits are violated, the corrective actions specified in the Technical Specifications shall be taken.
3.0 REFERENCES
3.1 JAFNPP Administrative Procedure 12.05, Control of Core Operating Limits Report.
3.2 JAFNPP License Appendix A, Operating Technical Specifications.
3.3 FitzPatrick Cy'cle 13 Core Reload Safety Evaluation, JAF-SE-96-052.
3.4 JAFNPP SAFER /GESTR-LOCA Loss of Coolant Analysis, NEDE-31317P Rev.2, April 1993.
l I
3.5 GE Report, Supplemental Reload Licensing Report for James A.
FitzPatrick Reload 12 Cycle 13, J11-02914SRL Rev.0, August 1996.
3.6 GE Report, Lattice Dependent MAPLHGR Report for James A.
FitzPatrick Reload 12 Cycle 13, J11-02914 MAP Rev.0, August
)
1996.
3.7 Cycle 13 Core Reload, M1-95-077.
3.8 RAP-7.3.17 Rev.5, Core Monitoring Software and Databsae Changes.
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Rev. No.dyl##@
Page 2 of 31 l Ylff l
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CORE OPERATING LIMITS REPORT CYCLE 13 3.9 PLANT OPERATION UP TO 100% POWER WITH ONE S'iEAM LINE ISOLATED, JA F-S E-9 6- 0 3 5.
3.10 FitzPatrick Cycle 12 Core Reload Safety Evaluation, JAF-SE-94-127.
3.11 General Electric Standard Application for Reload Fuel, NEDE-24011-P-A-13.
3.12 GE Letter, J. Post to G.Rorke, Reactor Stability Information to Support FitzPatrick Restart, August 7,1998.
4.0 DEFINITIONS 4.1 Minimum critical power ratio (MCPR) - Minimum value of the ratio of that power in a fuel assembly which is calculated to cause some point in that fuel assembly to experience boiling transition to the actual assembly operating power as calculated by application of the GEXL correlation (Reference NEDE-10958).
4.2 Fraction of Limiting Power Density - The ratio of the linear heat generation rate (LHGR) existing at a given location to j
the design LHGR.
The design LHGR is given in Table 8.2.
l 4.3 Maximum Fraction of Limiting Power Density - The Maximum Fraction of Limiting Power Density (MFLPD) is the highest value existing in the core of the Fraction of Limiting Power Density (FLPD).
4.4 Rated Recirculation Flow - that drive flow which produces a j
6 core flow of 77.0 x 10 lb/hr.
5.0 RESPONSIBILITIES 5.1 See AP-12.05 (Reference 3.1).
5.2 It is the responsibility of the Shift Manager to assure that the reactor is operated within the limits described herein.
5.3 It is the responsibility of the Reactor Analyst Supervisor to assure that the limits described herein are properly installed in the 3D-Monicore databank used for thermal limit surveillance (Reference 3.8) 6.0 SPECIAL INSTRUCTIONS / REQUIREMENTS Not applicable.
l Rev. No. 6 Page 3 of 31
t CORE OPERATING LIMITS REPOR'r CYCLE 13 7,0 PROCEDURE 7.1 Operating Limit MCPR During power operation, The Operating Limit MCPR shall be equal to or greater than the limits given below.
7.1.1 Technical Specification
Reference:
3.1.B 7.1.2 The Operating Limit MCPR shall be determined based on the following requirement:
7.1.2.1 The average scram time to notch position 38 shall be:
TAVE 5 I B 7.1.2.2 The average scram time to notch position 38 is determined as follows:
N E N,s, AMr" i=1 I
EN, i=1 where:
n=
number of surveillance tests performed to date in the cycle, N, =
number of active rods measured in the surveillance i, and ri =
aver' age scram time to notch position 38 of'all rods measured in surveillance test i.
I i
l GP Rev. No'. &'pryJL Page 4 of 31 I
tYr/97
F-t i
1 CORE OPERATING LIMITS REPORT
+
CYCLE 13 I
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7.1.2.3 The adjusted analysis mean scram time is calculated as follows:
1 N*
2 T, (soc) = p + 1.65 e
=
E N,
,1=1 where:
y-mean of the distribution for the average scram insertion time to the pickup of notch position 38 = 0.706 sec.
o=
standard deviation of the distribution for average scram insertion time to the pickup of notch position 38 = 0.016 sec.
Ni =
the total number of active rods measured in Technical Specification 4.3.C.1.
The number of rods to be scram tested and the test intervals are given in Technical Specification 4.3.C.
7.1.3 When requirement of 7.1.2.1 is met, the Operating Limit MCPR shall not be less than that specified in Table 8.1, or Table 8.1.A if operating above 75% of rated thermal power with three steam lines in service.
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l Rev. No. ;y)P2P;f Page 5 of 31 YltY97
t CORE OPERATING LIMITS REPORT CYCLE 13 7.1.4 When the requirement 7.1.2.1 is not met (i.e. 7 a<r Avs) then the Operating Limit MCPR values (as a function of 7) are given in Figures 8.1.1 and 8.1.2, or Figure 8.1.A.1 and 8.1.A.2 if operating above 75% of rated thermal power with three steam lines in service.
where 7 = ( tryg -78)/(74 7,)
and the average scram time to notch position 38 7 vg
=
4 as defined in 7.1.2.2.
the adjusted analysis mean scram time as 7
defined in 7.1.2.3 the scram time to notch position 38 as 7
=
A defined in Technical Specification 3.3.C.1.
Note:
Should the operating limit MCPR obtained from these figures be less than the operating limit MCPR found in 7.l.3 then 7.1.3 shall apply.
4 i
7.1.5 During single-loop operation, the Operating Limit l
MCPR shall be increased by 0.01.
7.1.6 During reactor power operation with core flow less t
than 100 percent of rated, the Operating Limit MCPR shall be multiplied by the appropriate Kg specified in Figure 8.2.
7.2 Maximum Average Planar Linear Heat Generation Rate (MAPLHGR)
I 7.2.1 Technical Specification
Reference:
3.5.H 7.2 2 During power operation, the APLHGR for each fuel type as a function of axial location and average planar exposure shall be within limits based on applicable APLHGR limit values which have been approved for the respective fuel and lattice types.
l 7.2.3 When hand calculations are required, the APLHGR for each type of fuel as a function of average planar exposure shall not exceed the limiting value for the most limiting lattice shown in Figures 8.3.a through g.
7.2.4 During single loop operation, the APLHGR for each fuel type shall not exceed the values given in 7.2.2 or 7.2.3 above multiplied by 0.84.
Rev. No. Jr*,,g y Page 6 of 31 418'/9/
t CORE OPERATING LIMITS REPORT CYCLE 13 7.3 Linear Heat Generation Rate (LHGR) l 7.3.1 Technical Specification
Reference:
3.5.I.
7.3.2 The LHGR of any rod in any fuel assembly at any axial location shall not exceed the maximum allowable LHGR specified in Table 8.2.
7.4 APRM Trip Settings 7.4.1 APRM Flow Referenced Flux Scram Trip Setting (Run Mode) 7.4.1.1 Technical Specification
References:
2.1.A.1.c, Table 3.1-1, 3.1.A 7.4.1.2 When the Mode switch is in the RUN position, the APRM flow referenced flux scram trip setting shall be Ss0.66W + 54% for two loop operation; Ss0.66W + 54% - 0.66 AW for single loop operation; where:
l S
setting in percent of rated thermal
=
power; recirculation flow in percent of rated; W
=
AW difference between two loop and
=
single-loop effective drive flow at the same core flow..
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l c.
Rev. No. Finn <f Page 7 of 31 t/r/fr
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l CORE OPERATING LIMITS REPORT CYCLE 13 7.4.1.3 In the event of operation with a maximum-fraction of limiting power density (MFLPD) greater than the fraction of rated power (FRP), the setting shall be modified as follows:
Ss(0.66W + 54 %) (FRP/MFLPD) for two loop operation; Ss (0. 66W + 54 % - 0.66 AW) (FRP/MFLPD) for single-loop operation; where:
FRP fraction of rated thermal power;
=
MFLPD =
Maximum fraction of limiting power density, see Definition 4.3.
The ratio of FRP to MFLPD shall be set equal to 1.0 unless the actual operating value is
.less than the design value of 1.0, in which case the actual operating value will be used.
7.4.2 APRM Flow Biased Rod Block Setting 7.4.2.1 Technical Specification
References:
2.1.A.1.d, Table 3.2-3, 3.2.C 7.4.2.2 The APRM rod block trip setting shall be:
Ss0.66W + 42% for two loop operation; Ss0.66W + 42% - 0.66 AW for single loop operation:;
where:
S = rod block setting in percent of rated thermal power; l
W recirculation flow in percent of rated;
=
AW =
difference between two loop and single loop effective drive flow at the same core flow.
Rev.. No. sF'A9&dh Page 8 of 31 t/r/tr
't 4
CORE OPERATING LIMITS REPORT CYCLE 13 7.4.2.3 In the event of operation with a maximum fraction of limiting power density (MFLPD) greater than the fraction of rated power (FRP), the setting shall be modified as follows:
Ss(0.66W + 42%) (FRP/MFLPD) for two loop operation; Ss(0.66W + 42% - 0.66AW) (FRP/MFLPD) for single loop operation; where:
FRP fraction of rated thermal power;
=
MFLPD =
maximum fraction of limiting power density, see Definition 4.3.
7.5 RBM Flow Biased Rod Block Setting 7.5.1 Technical Specification
Reference:
3.2.C 7.5.2 The RBM flow biased rod block trip setting shall be:
Ss0.66W + K for two loop operation; Ss0.66W + K - 0.66AW for single loop operation; where:
S = rod block setting in percent of initial; W
loop flow in percent of rated K = intercept values of 39%, 40%, 41%, 42%, 43%,
and 44% can be used with the appropriate MCPR Operating Limit from Table 8.1(note that for Cycle 13 the RBM intercept value does not effect the MCPR Operating Limit for K values s 44%);
AW = difference between two loop and single loop effective drive flow at the same core flow.
7.6 Stability Option ID Exclusion Region 7.6.1 Technical Specification Reference 3.5.J 7.6.2 The reactor shall not be intentionally operated within the exclusion region given in Figure 8.4.
I C.
Rev. No.JfAvaqf Page 9 of 31 rir/Pr l
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CORE OPERATING LIMITS REPORT CYCLE 13 I
8.0 FIGURES AND TABLES Table 8.1 MCPR Operating Limit for Incremental Cycle Core Average Exposure Table 8.1.A MCPR Operating Limit for Incremental Cycle Core Average Exposure for Operation above 75%
of Rated Thermal Power with Three Steam Lines in Service Table 8.2 Maximum LHGR Figure 8.1.1 MCPR Operating Limit Versus 7 for Gell Figure 8.1.2 MCPR Operating Limit Versus 7 for GE12 Figure 8.1.A.1 MCPR Operating Limit Versus 7 for Operation above 75% of Rated Thermal Power with Three Steam Lines in Service for Gell Figure 8.1.A.2 MCPR Operating Limit Versus 7 for Operation above 75% of Rated Thermal Power with Three
' Steam Lines in Service for GE12 Figure 8.2 K Factor g
Figure 8.3.a MAPLHGR Versus Planar Average Exposure:
GE10-P8HXB322-11GZ-70M-150-T Figure 8.3.b MAPLHGR Versus Planar Average Exposure:
GE10-P8HXB324-12GZ-70M-150T Figure 8.3.c MAPLHGR Versus Planar Average Exposure:
GE11-P9 HUB 356-15GZ-100M-146T and ATRIUM-10A Figure 8.3.d' MAPLHGR.Versus Planar Average Exposure:
GE11-P9 HUB 359-16GZ1-100M-146-T Figure 8.3.e MAPLHGR Versus Planar Average Exposure:
GE11-P9 HUB 380-12GZ5-100M-146-T Figure 8.3.f MAPLHGR Versus Planar Average Exposure GE12-P10DSB417-15GZ-100T-150-T
)
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Figure 8.3.g MAPLHGR Versus Planar Average Exposure:
GE12-P10DSB412-17GZ-100T-150-T Figure 8.4 Stability Option ID Exclusion Region i
Figure 8.5.a CYCLE 13 LOADING PATTERN, UPPER LEFT QUADRANT, BUNDLE DESIGN Figure 8.5.b CYCLE 13 LOADING PATTERN, UPPER RIGHT QUADRANT, BUNDLE DESIGN l
G Rev. No. dr AYp.g Page 10 of 31 f/dTAf L
4 CORE OPERATING LIMITS REPORT CYCLE 13 Figure 8.5.c CYCLE 13 LOADING PATTERN, LOWER RIGHT QUADRANT, BUNDLE DESIGN Figure 8.5.d CYCLE 13 LOADING PATTERN, LOWER LEFT QUADRANT, BUNDLE DESIGN 9.0 EXHIBITS Not Applicable, l
l (o
Rev. No. B"A Page 11 of 31 f/f/
t CORE OPERATING LIMITS REPORT CYCLE 13 TABLE 8.1 MCPR Operating Limit for Incremental Cycle Core Average Exposure Cycle 13 Gell GE12 Exposure and Range GE10 BOC 1.32 1.34 to 8.5 GWD/ST
>8.5 GWD/ST 1.32 1.39 to 10.7 GWD/ST
>10.7 GWD/ST 1.33 1.40 to EOC.
Technical Specification
Reference:
3.1.B For single loop operation, these limits shall be increased by 0.01.
See Reference 3.3 for MCPR requirement for ATRIUM-10A assemblies, required margin is provided by non-limiting core location.
Note:
When entering a new Exposure Range, check the current value of 7 to assure adjustment per Section 7.1.4 (o
Rev. No.,6'en Page 12 of 31 FM
I b
CORE OPERATING LIMITS REPORT CYCLE 13 TABLE 8.1.A i
MCPR Operating Limit for Incremental Cycle Core Average Exposure i
for Operation above 75% of Rated Thermal Power with Three Steam Lines in Service Cycle 13 Gell GE12 Exposure and Range GE10 BOC 1.32 1.36 to 8.5 GWD/ST
>8.5 GWD/ST 1.32 1.41 l
to 10.7 GWD/ST
>10.7 GWD/ST 1.35 1.42 l
l to EOC Technical Specification
Reference:
3.1.B l
For single loop operation, these limits shall be increased by O.01.
See Reference 3.3 for MCPR requirement for ATRIUM-10A assemblies, required margin is provided by non-limiting core location.
l Note:
When entering a new Exposure Range, check the current I
value of 7 to assure adjustment per Section 7.1.4 G
Rev. No. F%MdL Page 13 of 31 1
r/r/tr l.
a 6
CORE OPERATING LIMITS REPORT CYCLE 13 L
l TABLE 8.2 l
Maximum LHGR Fuel Type Fuel Bundle Design Maximum LHGR (kw/ft)
GE10-P8HXB322 GE10, also known 14.4 11GZ-70M-150-T as GE8x8NB-3 GE10-P8HXB324 GE10, also known 14.4 12GZ-70M-150-T as GE8x8NB-3 Gell-P9 HUB 356 Gell 14.4 15GZ-100M-146-T GE11-P9 HUB 359 Gell 14.4 16GZ1-100M-146-T GE11-P9 HUB 380 Gell 14.4 12GZ5-100M-146-T GE12-P10DSB417 GE12 11.8 15GZ-100T-150-T GE12-P10DSB412 GE12 11.8 17GZ-100T-150-T Technical Specification
Reference:
3.5.I Design features of'the fuel assemblies in the Cycle 13 core are provided in Reference 3.7 LHGR for ATRIUM-10A assemblies is controlled by the MAPLHGR limit given in Figure 8.3.c see Reference 3.10 Rev. No. Jr Md Page 14 of 31 th&r
L CORE OPERATING LIMITS REPORT CYCLE 13 FIGURE 8.1.1 MCPR Operating Limit Versus 7 (TAU) for Gell and GE10 1.52 1.52 1.5 1.5 1.48 1.48 1.46 1.46 1.44 1,44 1.42 1.42 (
1.4 1.4 g
1.38 1.38 'j 1.36 1.36 '
1.04 1.34.
1,32 1.32 h
i 1.3 1.3 1.28 1.28
)
1.26 1.26 1.24 1.24
)
1.22 1.22 1.2 1.2 0
1 Tau e BOCto8.5 GVOfST + 8.5 b10.7 GVDST dr 10.7 GVDfSTtoEDC Technical Specification
Reference:
3.1.B For single loop operation, these limits shall be increased by 0.01.
Note:
Should the operating limit MCPR obtained from this figure be less than the operating limit MCPR found in 7.1.3 for the applicable RBM trip level setting then 7.1.3 shall apply.
G Rev. No. Jr 28P#d Page 15 of 31 vint/
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s CORE OPERATING LIMITS REPORT CYCLE 13 FIGURE 8.1.2 MCPR Operating Limit Versus 7 (TAU) for GE12 1.52 1.52 1.5 1.5 1.48 1.48 1.46 1.46 1.44 9,44 1 42 1.42 E u
1.4 1.4 3
1.38 1.38 1E d
1.36 1.36 j,34 3 1.34 1.32 1.32 8.
1.3 1.3 o
1.28 1.28 1.26 1.26 1.24 1.24 1.22 1.22 1.2 1.2 0
j Tau e 80Cto8.5 GVDST + 8.5 to10.7 GVDST 610.7 GVDSTtoEOC Technical Specification
Reference:
3.1.B For single loop operation, these limits shall be increased by 0.01.
Note:
Should the operating limit MCPR obtained from this figure be less than the operating limit MCPR found in 7.1.3 for the applicable RBM trip level setting then 7.1.3 shall apply.
G Rev.No.Xp, page 16 of 31
CORE OPERATING LIMITS REPORT CYCLE 13 l
FIGURE 8.1.A.1 MCPR Operating Limit Versus 7 (TAU)
For Operation above 75% of Rated Thermal Power with Three Steam Lines in Service For Gell and GE10 1.52 1.52 1.5 1.5 1.48 1.48 1.46 1.46 1.44 1.44 g
1.42 1.42 6 1.4 1.4 2
1.38 j
1.38 '
1.36 1.36 1.34 1.34.
1.32 1.32 h
1.3 1.3 1.28 1.28 l
1.26 1.26 1.24 1.24 1.22 1.22 1.2 1.2 0
1 Tau s 10.7 GVCPSTtoEOC.e.8.5 to10.7 GVDST 610.7 GVDSTtoEOC i
l l
Technical Specification
Reference:
3.1.B For single loop operation, these limits shall be increased by i
0.01.
I I
Note:
Should the operating limit MCPR obtained from this figure be less than the operating limit MCPR found in j
7.1.3 for the applicable RBM trip level setting then j
7.1.3 shall apply.
Rev. N o. # N.p Page 17 of 31 J'Idf f l
4
e CORE OPERATING LIMITS REPORT CYCLE 13 l
FIGURE 8.1.A.2 MCPR Operating Limit Versus 7 (TAU)
For Operation above 75% of Rated Thermal Power with Three Steam Lines in Service For GE12 1.52 1.52 1.5 1.5 1.48 1.48 1.46 1.46 1.44 1,44 1,42 1.42 g 1.4 1.4 g
1.38 1,38 -
1.36 1.36 1.34 1.34 1.32 1,32 h
1.3 1.3 1.28 1.28 1.26 1.26 1.24 1.24 1.22 1.22 1.2 1.2 0
1 Tau e BOCto8.5 GMDST e 8.5 to10.7 GWDST *10.7 GVDSTtoBOC Technical Specification
Reference:
3.1.B For single loop operation, these limits shall be increased by 0.01.
Note:
Should the operating limit MCPR obtained from this figure be less than the operating limit MCPR found in 7.1.3 for the applicable RBM trip level setting then 7.1.3 shall apply.
(o Rev. No. # M//4 Page 18 of 31 t'/r/tf
o CORE OPERATING LIMITS REPORT CYCLE 13 l
FIGURE 8.2 Kr Factor 1.4 i
iJ Kr u
umane newcomm i.)
ionsnanswcomm
.S"L...".
167.85 11 M #
=
isr m se
=
so
=
a se se iso ESRE ROW 198 I
I J
Technical Specification
Reference:
3.1.B f
6 Rev. No. #9N//4 Page 19 of 31 Y{YIf)
l CORE OPERATING LIMITS REPORT
~.
CYCLE 13 FIGURE 8.3.a MAPLHGR Versus Planar Average Exposure:
GE10-P8HXB322-11GZ-70M-150-T 14.ss 13.80 12.11 11 18 10.81 3.11 1,11 1.en 8.st 3.51 4.88 3.tl 2.st l
1,81 t
8.18 8
18 28 Jg og 5g gg pieser averes. ti....r e toson i This curve represents the limiting exposure dependent MAPLHGR values per Reference 3.11.
Technical Specification
Reference:
3.5.H
Reference:
NEDC-31317P For single loop operating these MPLHGR values shall be multiplied by 0.84.
I l
l (o 7fd No. g*/r/ry Rev.
page 20 of 31
/
~
CORE OPERATING LIMITS REPORT
=
CYCLE 13 FIGURE 8.3.b MAPLHGR Versus Planar Average Exposure:
GE10-P8HXc324-12GZ-70M-150T 14.00
- 11. 1 12.00 tt.88 10.01 3.30 1.00 1.00 I.00 3.11 4.80
~
1.00 2.81 -
f.Il -
' 1 11 fl 18 40 Il Pleser Averess EssessrelGt0lt)
This curve represents the limiting exposure dependent MAPLHGR values per Reference 3.11.
Technical Specification
Reference:
3.5.H
Reference:
For single loop operating these MAPLHGR values shall be multiplied by 0.84.
Rev. No. g Page 21 of 31
CORE OPERATING LIMITS REPORT CYCLE 13 i
FIGURE 8.3.c MAPLHGR Versus Planar Average Exposure:
GE11-P9 HUB 356-15GZ-100M-146-T and ATRIUM-10A*
12.80 11.18 18.81 -
3.00 1.88 7.00 4.00 5.08 4.11 1.00 2.80 1.00 1.18 O
18 28 11 48 58 il Pleser Aversie EssessrelGeolti l
'The ATRIUM-10A bundles will be monitored as a GE11-P9 HUB 356-15GZ-100M-146-T bundle.
Operation to the limiting MAPLHGR for the Gell bundle assures this bundle will remain within LHGR limits, see Reference 3.10.
This curve represents the limiting exposure dependent MAPLHGR values per Reference 3.11.
For single loop operating these MAPLHGR values shall be multiplied by 0.84.
6 Rev. No. /.f*r*4.-
Page 22 of 31
//2177
"o CORE OPERATING LIMITS REPORT CYCLE 13 FIGURE 8.3.d MAPLHGR Versus Planar Average Exposure:
GE11-P9 HUB 359-16GZ1-100M-146-T 12.80 11.00 f
18.tl 1.18 4.81 1.00 6.00 3.10 4.81 3.81 2.10 1.81 i
i i
i e
g,gg 0
18 ft 38 48 51 18 Pissar Averste Estessre IGeol3T)
This curve represents the limiting exposure dependent MAPLHGR
. values per Reference 3.11.
Technical Specification
Reference:
3.5.H
Reference:
23A7114 Rev 1 For single loop operating these MAPLHGR values shall be multiplied by 0.84.
l Rev. No. g
- Page 23 of 31 l
e CORE OPERATING LIMITS REPORT CYCLE 13 FIGURE 8.3.e MAPLHGR Versus Planar Average Exposure:
GE11-P9 HUB 380-12GZ5-100M-146-T 14 13 12 11 10 I
7 I
5 4
3 1
I
' I I
s'n I
d I
in 18 31 31 Pleser Averste EsseserelGW0ltl This curve represents the limiting exposure dependent MAPLHGR values per Reference 3.11.
Technical Specification
Reference:
3.5.H
Reference:
24A5167 Rev 0 J
For single loop operating these MAPLHGR values shall be I
multiplied by 0.84.
{
l i
e G=
Rev. No. 88F#4 Page 24 of 31 th1W l
t
o CORE OPERATING LIMITS REPORT C'ICLE 13 FIGURE 8.3.f MAPLHGR Versus Planar Average Exposure:
GE12-P10DSB417-15GZ-100T-150-T 11 10 3.. e,...
g,*
s
,' N 'N 7
6 5
4 3
2 1
0 O
10 20 30 40 50 60 Ranar Average &posure (GVDt)
This curve represents the limiting exposure dependent MAPLHGR values per Reference 3.11.
l Technical Specification
Reference:
3.5.H l
Reference:
NEDC-31317P For single loop operating these MAPLHGR values shall be j
multiplied by 0.84.
l l
6 Rev. No. /*iffff Page 25 of 31
- 4 r
CORE OPERATING LIMITS REPORT CYCLE 13 FIGURE 8.3.g MAPLHGR Versus Planar Average Exposure:
GE12-P10DSB412-17GZ-100T-150-T 11 10
, / r ""\\.' N.,s,'
e s,N 7
N 6
s '** %,,
5 4
3 2'
1 0
O 10 20 30
- 0 50 60 Fhnar AuerageEsposwo (GVDR)
This curve represents the limiting exposure dependent MAPLHGR values per Reference 3.11.
Technical Specification
Reference:
3.5.H
Reference:
NEDC-31317P For single loop operatifig these MAPLHGR values shall be multiplied by 0.84.
(o Rev. No. # prof Page 26 of 31 rMir
6 s
CORE OPERATING LIMITS REPORT CYCLE 13
=
Figure 8.4 Stability Option ID Exclusion Region ioo....
s 0
l APRM HIGH FLUX
...... {...
.. j..... SCRAM
..{.
oo.
t so.
io EXCLUSION
.. REGION.:
i a no APRM ROD :
BLOCK 4 so 4
.......l C3 J
l s
2 l
40
}.
...,w.
l 20% PUMP NATURAL l
SPEED -2 LP l
a, 30 <
-,' - - - - - CIRCULATION
- - - 1 I
.--.-l..
......f.
-.--.-.-.- -- t- -- -
20 t
j
\\
\\
to o
J - -
L-
- - l- - -
l-- - -
b--'
o 10 20 3o do 50 so PERCENT RATED CORE FLOW Technical Specification Reference 3.5.J Reference GE Letter, Reactor Stability Information to Support FitzPatrick Restart 27 Rev. No. 6 Page.% of 31
_ _ _ ____ ________Yll1E
e
+
CORE OPERATING LIMITS REPORT
\\
CYCLE 13 i
N4 B
B B
B B
s2 from above the core B
B B
B D
B 50 B
B B
B B
D B
B B
48 B
B B
D D
D D
D D
D 46 B
B B
D B
D B
B B
D B
44 B
B D
B D
B B
B D
B B
42 A
D B
D C
D B
D B
D B
40 B
B D
D B
D B
D B
D B
D 38 B
B B
D B
B B
D B
B B
D B
36 B
B D
D B
B D
B B
B D
B B
34 B
B B
D B
D B
D B
D B
D B
32 B
D B
D D
B D
B D
B D
B D
30 B
B B
D B
B B-D B
B B
D B
28 1
3 5
7 9
11' 13 15 17 19 21 23 25 FIGURE 8.5.a CYCLE 13 LOADING PATTERN, UPPER LEFT QUADRANT, BUNDLE DESIGN A = GE8x8NB-3 B = GEli C = ATRIUM - 10A i-D = GE12 6
- .d.
Page 28 of 31 Rev. No.g/r/r/
r J
,9 CORE OPERATING LIMITS REPORT CYCLE 13 B
B B
B B
4 52 from above B
D B
B B
A the core 50 B
B B
D B
B B
B B
48 D
D D
D D
D D
B B
B 46 B
D B
B B
D B
D B
B A
44 B
B D
B B
B D
B D
B B
42 B
D B
D B
D C
D B
D A
40 D
B D
B D
B D
B D
D B
A 38 B
D B
R B
D B
B B
D B
B B
36 B
B D
B B
B D
B B
D D
B B
34 B
D B
D B
D B
D B
D B
B B
32 D
B D
B D
B D
B D
D B
D B
30 B
D B
B B
D B
B B
D B
B A
28 27 29 31 33 35 37 39 41 43 45 47 49 51 FIGURE 8.5.b CYCLE 13 LOADING PATTERN, UPPER RIGHT QUADRANT, BUNDLE DESIGN A = GE8x8NB-3 B = Gell C = ATRIUM - 10A D = GE12 l
l l
l
\\
Cr ww4 Rev. No. g/r/tr Page 29 of 31 r
,7 CORE OPERATING LIMITS REPORT CYCLE 13 6
B D
B B
B D
B B
B D
B B
B 26 D
B D
B D
B D
B D
D B
D B
24 j
l t
B D
B D
B D
B D
B D
B B
B 22
{
B B
D B
B B
D B
B D
D B
B 20
)
B D
B B
B D
B B
B D
B B
B 18 D
B D
B D
B D
B D
D B
B 16 B
D B
D B
D C
D B
D B
14 i
l B
B D
B B
B D
B D
B B
12 B
D B
B B
D B
D B
B B
10 D
D D
D D
D D
B B
A 8
{
I B
B B
D B
B B
B A
6 l
1 B
D
.B B
B B
N4 4
from above B
B B
B B
the core 2
j i
27 29 31 33 35 37 39 41 43 45 47 49 51 1
)
EIGURE 8.5.c l
CYCLE 13 LOADING PATTERN, LOWER RIGHT QUADRANT, BUNDLE DESIGN l
l A = GE8x8NB-3 B = Gell C = ATRIUM - 10A D = GE12 6
avnd-Rev. No. g/r/t/
Page 30 of 31 r
L-
.8
' v' ',
CORE OPERATING LIMITS REPORT CYCLE 13 B
B B
D B
B B
D B
B B
D B
26 B
D B
D D
B D
B D
B D
B D
24 B
B B
D B
D B
D B
D B
D B
22 B
B D
D B
B D
B B
B D
B B
20 B
B B
D B
B B
D B
B B
D B
18 B
B D
D B
D B
D B
D B
D 16 B
D B
D C
D B
D B
D B
14 B
B D
B D
B B
B D
B B
12 B
B B
D B
D B
B B
D B
10 A
B B
D D
D D
D D
D 8
A B
A B
B D
B B
B 6
y4 B
B B
B D
B 4
from above the core B
B B
B B
2 1
3 5
7 11 13 15 17 19 21 23 25 FIGURE 8.5.d CYCLE 13 LOADING PATTERN / LOWER LEFT QUADRANT, BUNDLE DESIGN A = GE8x8NB-3 B = Gell C = ATRIUM - 10A D = GE12 Rev. No. y Page 31 of 31
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