ML20209E143
| ML20209E143 | |
| Person / Time | |
|---|---|
| Site: | LaSalle  |
| Issue date: | 05/31/1999 |
| From: | COMMONWEALTH EDISON CO. |
| To: | |
| Shared Package | |
| ML20209E127 | List: |
| References | |
| COLR-990531, NUDOCS 9907140161 | |
| Download: ML20209E143 (28) | |
Text
_.
Administrative Technical Requirements - Appendix A Section 1 LaSalle Unit 1 Cycle 8 Core Operating Limits Report May 1999
$ *$0$$d $8o$$73 P
pm
Administrativa Tcchnical R::quirem::nts - Appandix A L1C8 Core Operating Limits Report issuance Of Changes Summary Affected Affected Summary of Changes Date Section Pages All All Original issue (Cycle 8) 3/96 All All Format Changes 7/98 Addition of Reload Transient Analysis Results section Changes to Thermal Limits to allow for changed RR FCV minimum position setpoint, changed APRM flux scram analytical value, operation at less than rated pressure and deletion of automatic flow control limits.
Change to EOOS combinations allowing for operation with one TCV stuck closed in various combinations.
All All Changed Table 2.1 (removed column for MCP3p >or= 30%
5/99 power) and Figures 1.2-1 and Figure 2.2-3 (revised thermal limits) due to moving Pbypass setpoint from 30% power to 25% power. As a result of the Pbypass change, the MCPR, and K, multiplier for EOOS were removed. The previous Figure 2.2-4 (EOOS MCPR and K limits) was deleted.
p Added the 0.40 MAPFACp multiplier to Figure 1.2-3.
Changed Page 1-1 and 5-1 to reflect same presentation of EOOS/EOD limits as L2C8 (added TBVOOS and FHOOS combination and changed SLO to idle loop startup).
Added the restriction to operation in TCV stuck closed of FCL<108% and MCFL >or= 120%. (References 18 and 19)
Added 25% Power resutts from Reference 10 to the cycle specific reload transien1 analysis results in Attachment 3.
LaSalle Unit 1 Cycle 8 i
May 1999
p Administrativa Tcchnical R:quiram::nts - Appsndix A L1C8 Core Operating Limits Report
/
Table of Contents R ef eroncoa.....................................................
. iii 1
Average Planar Linear Heat Generation Rate (3/4.2.1).........................................1-1 1.1 Tech Spec
Reference:
... 1-1 1.2 D e s c riptio n............................................................................... 1 - 1 2
Minimum Critical Power Ratio (3/4.2.3)....
........................ 2-1 2.1 Tech Spec Referenee................................................................ 2-1 2.2 Description....................................................
... 2-1 3
Linear Heat Generation Rate (3/4.2.4)......................
. 3-1 3.1 Tech Spec R efe rence........................................................ 3-1 3.2 Desc ription.................................
.31 4
Controf Rod Withdrawal Block instrumentation (3/4.3.6)........
........................41 4.1 Tech Spec Reference..
.. 4-1 4.2 De sc ription.......................................
........ 4-1 5
Allowed Modes of Operation (B 3/4.2.3)............................................... 5-1 l
LaSalle Unit 1 Cycle 8 ii May 1999
Administrativa Tcchnical R:quircm:nts - App ndix A L1C8 Core Operating Limits Report References 1.
Commonwealth Edison Company Docket No. 50-373, LaSalle County Station, Unit 1 Facility Operating Lica..se, License No.
2.
Letter from D. M. Crutchfield to All Power Reactor Licensees and Applicants, Generic Letter 88-16; Concerning the Removal of Cycle-Specific Parameter Limits from Tech Specs, dated October 4,1988.
3.
Supolemental Reload License Submittal for LaSalle County Station Unit 1 Reload 7 Cvele 8. Rev.1, May 1998.
4.
Neutronics Licensino Report for LaSalle Unit 1 Reload 7. Cvele 8. BND:95-163, NDIT 960014, Rev.1, March 11,1996.
5 LaSalle County Station, Units 1 and 2, SA_FER/GESTR LOCA Loss-of-Coolant-Accident Analvsis. NEDC,32258P, October 1993 (latest approved revision).
6.
General Electric Standard Aoolication for Reactor Fuel (GESTAR), NEDE-24011-P-A (latest approved version).
7<
Extended Ooeratina Domain and Eauioment Out-of-Service for LaSalle County Station Units 1 and 2. NEDE-31455 (latest approved version).
8.
Eauipment Out-of-Service in the increased Core Flow Domain for LaSalle County Station Units 1 and 2. GE-NE-187-62-1191 (latest approved version).
9.
Evaluation of a Postulated Slow Turbine Control Valve Closure Event for LaSalle County Station. Units 1 and 2. GE-NE-187-13-0792, Revision 2, July 1998.
10.
ARTS Imorovement Proaram Analysis for LaSalle Units 1 and 2. NEDC-31531P, December 1993 and Supplement 1. June 1998.
11.
~ Letter from Hoa Hoang (GE) to Dave Henry (Comed), "LaSalle Recirculation Pump Trip Out-of Service with Feedwater Temperature Reduction," February 7,1995.
12.
Analysis of EFPC Coastdown With Load Followina for LaSalle 1 and 2. GENE-637-016-0693, June,1993.
13.
GE document, DRF AOO-05525, " Safety Evaluation for Feedwater Temperature Variation at LaSalle County Station Units 1 and 2", February 8,1993.
14.
Letter from R. W. Tsal (Comed, Nuclear Fuel Services) to D. A. Henry (Comed, LaSalle Station), "LaSalle Units 1 and 2 Operating Limits with Multiple Equipment Out-of Service (EOOS)*, April 6,1995.
15.
Lattice-Dependent MAPLHGR Report for LaSalle County Station Unit 1 Reload 6 Cvele 7. 23A7231 AA, Rev. O, December 1993. (Reloaded exposed fuel only) 16.
Lattice-Deoendent MAPLHGR Report for LeSalle County Station Unit 1 Heload 7 Cvele 8. 24A5180AA, Rev. O, December 1995. (New fuel only) 17.
On-Site Review 98-331, "UFSAR Changes to Sections 7.7.5.2.2 and 15.2.1.1: Abnormal Modes of EHC/ Turbine Operation".
18, NFM Review of OE9387 - Assmptions made in Analysis of Slow Flow Runout Transients, NFM:BSA:99-010, R.W. Tsal to J.
Meister, February 8,1999.
19.
NFS Transient Analysis Evaluation for LaSalle 3 TCV Operation, NFS:BSA:98-022, R.W. Tsal to G.A. Poletto, February 18, 1998.
20.
GE document, Updated Transient Analysis: Abnormal Start up of an Idle Reciruculation Loop for LaSalle County Nuclear Station, Units 1 and 2, B33-00296-03P, March 1998.
Lasalle Unit 1 Cycle 8 lii May 1999
1 7
4 AdminiStrctiva Technical RequiremantS - Appsndix A L1C8 Core Operating Limits Report 1
~ Average Planar Linear Heat Generation Rate (APLHGR) (3/4.2.1) 1.1 Tech Spec
Reference:
)
1.2
==
Description:==
The MAPLHGR Limit is determined from Table 1,1, and is either MAPLHGRp or MAPLHGRr, whichever is lower at any given power, flow condition. No thermal limit monitoring is required below 25% power.
However, if official monitoring is desired, the lattice type MAPLHGR limits as determined from Table 1.2 and 1.1 may be used, and multiplied by the appropriate MAPFACp values in Figures 1.21 or 1.2-2 or the i
MAPFACf values in Figure 1.2-3, which ever is more limiting.
{
1 TABLE 1,1 l
Inoperable Equipment
- MAPLHOR, MAPLHGRr For All Power Levels All Flow Ranges b
No EOOS Fuel-Type MAPLHGR Umit determined per Table Fuel-Type MAPLHGR Limit determined per Table 1.2, l
1.2, multiplied by MAPFAC, from Figure 1.2-1 multiplied by MAPFAC, from Figure 1.2 3 Or.3 SRV OOS / TCV Stuck Fuel-Type MAPLHGR Umit determined per Table Fuel-Type MAPLHGR Umit determined per Table 1.2,
)
Closed 1.2, multiplied by MAPFACp from Figure 1.21 multiplied by MAPFACr from Figure 1.2-3 Feedwater Heater (s) OOS '/ One Fuel-Type MAPLHGR Umit determined per Table Fuel-Type MAPLHGR Umit determined per Table 1.2, SRV OOS / TCV Stuck Closed 1.2, multiplied by MAPFAC, from Figure 1.2-1 multiplied by MAPFACr from Figure 1.2-3 l
Turbine Bypass OOS / One SRV Fuel-Type MAPLHGR Limit determined per Table Fuel-Type MAPLHGR Umit determined per Table 1.2, OOS 1.2, multiplied by MAPFAC, from Figure 1.21 multiplied by MAPFACr from Figure 1.2 3 i
Fuel Type MAPLHGR Umit determined per Table Fuel-Type MAPLHGR Limit determined per Table 1.2, TCV Stuck Closed / Feedwater 1.2, multiplied by MAPFAC, from Figure 1.2-1 multiplied by MAPFAC, from Figure 1.2-3 Heater (s) OOS' Turbine Bypass OOS / Feedwater Fuel-Type MAPLHGR Limit determined per Table FueLType MAPLHGR Umit determined per Table 1.2, Heater (s) OOS' / One SRV OOS 1.2, multiphed by MAPFAC, from Figure 1.21 multiplied by MAPFAC, from Figure 1.2-3 EOC-RPT OOS / TCV(s) Slow Fuel-Type MAPLHGR Umit determined per Table Fuel-Type MAPLHGR Limit determined per Table 1.2,
1.2, multiplied by MAPFAC, from Figure 1.2-2 multiplied by MAPFAC, from Figure 1.2-3 Feedwater Hester(s) OOS' idle Loop Startup / One SRV OOS Fuel-Type MAPLHGR Umit determined per Table Fuel-Type MAPLHGR Umit determined per Table 1.2,
/ TCV Stuck Closed 1.2, multiplied by MAPFAC, from Figure 1.2-1 multiplied by 0.4. which is MAPFACr for idle Loop Startup Single RR Loop / One SRV OOS /
Fuel-Type MAPLHGR Limit determined per Table Fuel Type MAPLHGR Limit determined per Table 1.2 TCV Stuck Closed 1.2, multiplied by MAPFAC, from Figure 1.21 multiplied by MAPFAC, from Figure 1.2-3 1.
Up to 100 F reduction (to 320 F) in feedwater temperature allowed at full power with Feedwater Heaters Out-of-Service (reduction varies at off-rated power levels). Up to 13 F reduction in feedwater temperature from nominal allowed at all power levels without feedwater heaters considered Out-of Service.
l LaSalle Unit 1 Cycle 8 11 May 1999 1!'
l i
L
i Administrativa TcChnical Rcquirements - App 2ndix A L1C8 Core Operating Limits Report TABLE 1.2 Table for Fuel-Type Fuel Type Cycle First Number of MAPLHGR Limits inserted Bundles 1.2-1 GE98-P8CWB303-9GZ-100M-150-T 5
108 1.2-2 GE9B-P80WB313-9GZ-100M-150-CECO 6
128 1.2-3 GE9B-P8CWB314-9GZ-100M-150-CECO 6
72 1.2-4 GE9B-P8CWB32211GZ-100M-150-CECO 7
104 1.2-5 GE98-P8CWB320-9GZ-100M-150-CECO 7
104 1.2-6 GE98-P8CWB343-12GZ-80M-150-CECO 8
104 1.2-7 GE98-P8CWB342-10GZ-80M-150-CECO 8
144 l
LaSalle Unit 1 Cycle 8 1-2 May 1999 I
I Administrativa TcchniCal R:quircm:nts - App:ndix A L1C8 Core Operating Limits Report Maximum Average Planar Linear Heat Generation Rate (MAPLHGR) vs.
Average Planar Exposure for Fuel Type GE9B-P8CWB303-9GZ-100M-150-T Reference 15 Table 1.2-1 Bundle Type 10 Exposure (MWD /ST)
Lattice Specific MAPLHGR (kw/ft)
P8CWLO71 P8CWL327 P8CWL338 P8CWL327 P8CWLO71 NOG 9G5.0 4G5.0/5G4.0 4GS.0/5G4.0 9GE O
12.74 11.98 11.35 12.01 12.74 200 12.67 12.05 11.39 12.08 12.67 1000 12.48 12.17 11.48 12.22 12.48 2000 12.42 12.37 11.67 12.43 12.42 3000 12.41 12.56 11.90 12.61 12.41 4000 12.44 12.69 12.16 12.78 12.44 5000 12.46 12.81 12.38 12.91 12.46 6000 12.49 12.92 12.56 13.03 12.49 7000 12.51 13.04 12.75 13.15 12.51 8000 12.54 13.16 12.94 13.27 12.54 9000 12.55 13.29 13.13 13.37 12.55 10000 12.57 13.41 13.29 13.47 12.57 12500 12.41 13.49 13.33 13.51 12.41 15000 12.04 13.18 13.05 13.20 12.04 20000 11.27 12.54 12.46 12.55 11.27 25000 10.49 11.84 11.87 11.84 10.49 35000 8.95 10.35 10.54 10.36 8.95 45000 6.15 9.02 9.14 9.02 6.15 46850 5.21 5.21 51460 5.90 51790 5.82 51850 5.81 Lattice Type 28 21 22 23 24 Lanice No.
733 884 885 886 887 LaSalle Unit 1 Cycle 8 1-3 May 1999
y l
Administrctiva Technical R::quircm:nts - Appandix A L1C8 Core Operating Limits Report Maximum Average Planar Linear Heat Generation Rate (MAPLHGR) vs.
Average Planar Exposure for Fuel Type GE9B-P8CWB313-9GZ-100M-150-CECO Reference 15 Table 1.2-2 Bundle Type 11 Exposure (MWD /ST)
Lattice Specific MAPLHGR (kw/ft)
~
P8CWLO71 P8CWL339 P8CWL350 P8CWL350 P8CWL339 P8CWLO71 NOG 7G4.0 2G4.0/5G3.0 4G4.0/5G3.0 2G4.0/5G3.0 9GE O
12.74 12.34 11.79 11.32 12.35 12.74 200 12.67 12.39 11.84 11.40 12.40 12.67 1000 12.48 12.49 11.96 11.55 12.52 12.48 2000 12.42 12.63 12.12 11.73 12.68 12.42 3000 12.41 12.74 12.28 11.92 12.83 12.41 4000 12.44 12.85 12.40 12.11 12.96 12.44 5000 12.46 12.97 12.49 12.27 13.10 12.46 6000 12.49 13.10 12.58 12.39 13.19 12.49 7000 12.51 13.22 12.67 12.52 13.29 12.51 8000 12.54 13.34 12.76 12.65 13.37 12.54 9000 12.55 13.38 12.84 12.78 13.45 12.55 10000 12.57 13.38 12.91 12.89 13.41 12.57 12500 12.41 13.36 12.85 12.85 13.36 12.41 15000 12.04 13.01 12.56 12.56 13.01 12.04 20000 11.27 12.34 11.98 11.97 12.33 11.27
_25000 10.49 11.69 11.38 11.37 11.69 10.49 35000 8.95 10.46 10.12 10.11 10.46 8.95 45000 6.15 9.12 8.53 8.50 9.13 6.15 46850 5.21 5.21 50360 5.84 50390 5.85 51860 5.84 51880 5.84 Lattice Type 29 30 31 32 33 34 Lattice No.
733 1577 1578 1579 1580 1581 I
l LaSalle Unit 1 Cycle 8 14 May 1999
]
i-j l
Administrctiva Technical R:quircm:nts - App ndix A L
L1C8 Core Operating Limits Report f
. Maximum Average Planar Linear Heat Generation Rate (MAPLHGR) vs.
Average Planar Exposure for Fuel Type GE9B-P8CWB314-9GZ-100M-150-CECO Referome 15 Table 1.2-3 Bundle Type 12 Exposure (MWD /ST)
Lattice Specific MAPLHGR (kw/ft)
P8CWLO71 l P8CWL339P8CWL350 P8CWL350 P8CWLO71 NOG 7G4.0 7G4.0 9G4.0 9GE O
12.74 12.34 11.77 11.50 12.74 200 12.67 12.39 11.83 11.55 12.67 1000 12.48 12.49 11.94 11.66 12.48 2000 12.42 12.63 12.08 11.80 12.42 3000 12.41 12.74 12.22 11.93 12.41 4000 12.44 12.85 12.37 12.07 12.44 5000 12.46 12.97 12.47 12.20 12.46 6000 12.49 13.10 12.56 12.34 12.49 7000 12.51 13.22 12.65 12.49 12.51 8000 12.54 13.34 12.74 12.64 12.54 9000 12.55 13.38 12.83 12.79 12.55 10000 12.57 13.38 12.90 12.90 12.57 12500 12.41 13.36 12.84 12.84 12.41 15000 12.04 13.01 12.55 12.55 12.04 20000 11.27 12.34 11.97 11.97 11.27 25000 10.49 11.69 11.38 11.38 10.49 35000 8.95 10.46 10.12 10.11 8.95 45000 6.15 9.12 8.51 8.46 6.15 46850 5.21 5.21 50260 5.85 50370 5.84 51860 5.84 Lattice Type '
35 36 37 38 39 Lattice No.
733 1577 1582 1583 1584 LaSalle Unit 1 Cycle 8 1 May 1999
T Administrativa Tcchnical Rcquircm::nts - Appandix A j
L1C8 Core Operating Limits Report Maximum Average Planar Linear Heat Generation Rate (MAPLHGR) vs.
Average Planar Exposure for Fuel Type G E9B-P8CWB322-1 1 GZ-100M-150-C ECO I
Reference 15 Table 1.2-4 Bundle Type 1 Exposure (MWD /ST)
Lattice Specific MAPLHGR (kw/ft)
P8CWLO71 P8CWL345 P8CWL362 P8CWL362 P8CWL345 P8CWLO71 i
NOG SG5.0/4G4.0 9G4.0 2G5.0/9G4.0 9G4.0 11GE O
12.74 12.09 11.65 11.25 12.11 12.74 200 12.67 12.13 11.70 11.32 12.15 12.67 1000 12.48 12.22 11.83 11.46 12.25 12.48 2000 12.42 -
12.35 12.00 11.61 12.39 12.42 3000-12.41 12.48 12.14 11.77 12.54 12.41 4000 12.44 12.62 12.28 11.94 12.70 12.44 i
5000 12.46 12.77 12.43 12.11 12.86 12.46 6000 12.49 12.90 12.58 12.29 13.02 12.49
~
7000 12.51 13.03 12.73 12.46 13.19 12.51 8000 12.54 13.16 12.88 12.64 13.33 12.54 9000 12.55 13.30 13.01 12.82 13.43 12.55 10000 12.57 13.42 13.12 12.98 13.44 12.57 12500 12.41 13.41 13.08 13.04 13.40 12.41 15000 12.04 13.05 12.78 12.77 13.06 12.04 20000 11.27 12.38 12.16 12.16 12.40 11.27 25000
-10.49 11.74 11.51 11.51 11.76 10.49 35000 8.95 10.52 10.22 10.22 10.53 8.95 45000 6.15 9.13 8.75 8.68 9.13 6.15 46850 5.21 5.21 50680 5.86 50830 5.85 51870 5.83 51910 5.83 Lattice Type 40 41 42 43 44 45 Lattice No.
733 1817 1818 1819 1820 1821 LaSalle Unit 1 Cycle 8 1-6 May 1999
7 Administrativa Technical R:quirem:nts - App:ndix A L1C8 Core Operating Limits Report Maximum Average Planar Linear Heat Generation Rate (MAPLHGR) vs.
Average Planar Exposure for Fuel Type GE9B-P8CWB320-9GZ-100M-150-CECO i
Reference 15 Table 1.2-5 Bundle Type 2 Exposure (MWD /ST)
Lattice Specific MAPLHGR (kw/ft)
P8CWLO71 P8CWL346 P8CWL358 P8CWL358 P8CWL346 P8CWLO71 NOG 4G5.0/3G4.0 7G4.0 2G5.0/7G4.0 7G4.0 9GE2 0
12.74 12.05 11.62 11.10 12.09 12.74 200 12.67 12.09 11.64 11.15 12.14 12.67 1000 12.48 12.19 11.73 11.27 12.25 12.48 2000 12.42 12.32 11.86 11.44 12.39 12.42 3000 12.41 12.44 11.99 11.62 12.53 12.41 4000 12.44 12.57 12.13 11.80 12.67 12.44 5000 12.46 12.70 12.27 11.96 12.81 12.46 6000 12.49 12.83 12.42 12.09 12.89 12.49 7000 12.51 12.97 12.54 12.23 12.98 12.51 8000 12.54 13.07 12.62 12.37 13.07 12.54 9000 12.55 13.15 12.70 12.51 13.15 12.55 i
10000 12.57 13.20 12.77 12.66 13.22 12.57 12500 12.41 13.19 12.70 12.67 13.20 12.41 15000 12.04 12.89 12.40 12.40 12.90 12.04 20000 11.27 12.29 11.82 11.82 12.30 11.27 25000 10.49 11.69 11.25 11.25 11.70 10.49 35000 8.95 10.46 10.07 10.07 10.46 8.95 45000 6.15 9.09 8.35 8.26 9.09 6.15 46850 5.21 5.21 49790 5.87 49990 5.86 51490 5.88 I
51500 5.88 -
Lattice Type 46 47 48 49 50 51 Lanice No.
733 1812 1813 1814 1815 1816 l
LaSalle Unit 1 Cycle 8 17 May 1999
l Administrctiva Tcchnical R::quircm:nts - Appandix A j
L1C8 Core Operating Limits Report Maximum Average Planar Linear Heat Generation Rate (MAPLHGR) vs.
Average Planar Exposure for Fuel Type GE9B-P8CWB343-12GZ-80M-150-CECO Reference 16 Table 1.2-6 Bundle Type 4 Exposure (MWD /ST)
Lattice Specific MAPLHGR (kw/ft)
P8CWLO71 P8CWL363 P8CWL390 P8CWL390 P8CWLO71 NOG 10G5.0 10G5.0 12G5.0 12GE O
12.66 11.69 11.37 10.92 12.66 200 12.59 11.71 11.43 10.99 12.59 1000 12.40 11.78 11.55 11.13 12.40 2000 12.34 11.95 11.72 11.33 12.34 3000 12.34 12.16 11.91 11.54 12.34 4000 12.37 12.40 12.11 11.76 12.37 l
5000 12.40 12.67 12.32 12.00 12.40 6000 12.43 12.90 12.53 12.24 12.43 7000 12.46 13.05 12.76 12.49 12.46 8000 12.48 13.21 12.98 12.75 12.48 9000 12.50 13.37 13.13 13.01 12.50 10000 12.51 13.54 13.30 13.22 12.51 12500 12.35 13.75 13.60 13.57 12.35 15000 11.98 13.48 13.23 13.21 11.98 20000 11.20 12.71 12.40 12.37 11.20 j
25000 10.42 11.92 11.60 11.57 10.42 35000 8.87 10.36 10.09 10.06 8.87 45000 6.00 8.95 8.66 8.64 6.00 46610 5.19 5.19 51270 5.65 51300 5.63 52260 5.70 Lattice Type 1
2 3
4 5
Lau'ce No.
732 2083 2084 2085 2086 l
l l
Lasalle Unit 1 cycle 8 1-8 May 1999
L Administrctiv3 Tcchnical R:quircm:nts - App:ndix A l
L1C8 Core Operating Limits Report Maximum Average Planar Linear Heat Generation Rate (MAPLHGR) vs.
i Average Planar Exposure for Fuel Type GE98-P8CWB342-10GZ-80M-150-CECO Reference 16 Table 1.2-7 4
Bundle Type 5 Exposure (MWD /ST)
Lattice Specific MAPLHGR (kw/ft)
P8CWLO71 P8CWL363 P8CWL388 P8CWL388 P8CWL363 P8CWLO71 NOG 8G5.0 8G4.0 2G5.0/8G4.0 8G4.0 10GE O
12.66 12.04 12.25 11.72 12.09 12.66 200 12.59 12.08 12.28 11.77 12.12 12.59 1000 12.40 12.16 12.35 11.87 12.22 12.40 2000 12.34 12.28 12.45 12.00 12.37 12.34 3000 12.34 12.42 12.55 12.13 12.53 12.34 4000 12.37 12.57 12.65 12.27 12.70 12.37 5000 12.40 12.73 12.76 12.41 12.88 12.40 6000 12.43 12.89 12.87 12.56 13.07 12.43 7000 12.46 13.06 12.98 12.72 13.27 12.46 8000 12.48 13.24 13.10 12.88 13.47 12.48 9000 12.50 13.42 13.21 13.05 13.65 12.50 10000 12.51 13.61 13.31 13.21 13.76 12.51 12500 12.35 13.79 13.35 13.31 13.82 12.35 15000 11.98 13.50 13.06 13.05 13.51 11.98 20000 11.20 12.79 12.47 12.45 12.79 11.20 25000 10.42 11.95 11.67 11.63 11.95 10.42 35000 8.87 10.37 10.08 10.04 10.37 8.87 45000 6.00 8.96 8.66 8.63 8.96 6.00 46610 5.19 5.19 51070 5.69 51180 5.65 52160 5.72 5.72 Lattice Type 6
7 8
9 10 11 Lanice No.
732 2087 2088 2089 2090 2091 l
l LaSalle Unit 1 Cycle 8 1-9 May 1999
00 1
99 is>lys 9
f n
1
- o5nm 5
K iu qf oa 9
y di2 t
r a
ea c
r uois M
r s
)
e 0
J qE dgr l-0 l
e enu Ret ir s r
1 0
h la oo P
e 9
gt t l
(
,oic w
l n
pn 4
0 o
irdaoV 2
0 P
l e oer mS 2
l t r t iix 1
T 5
a nsEl oe aW 0
=
m 5
0 p
r MDeicC 8
Bi 0
C e
T f
ss f
h A T
+
it i yO e.
1 P
e mga 0
F h
nMet d iLi r
e
= A o
r rh o
hl P
w lat et it b p M C 08 s
a
=
C
. d miw dw n n
r A P e
s r o o e de o
F a
A s
eM P t
d P
eT P
h iv r
0 R
>Tl %omP x
e r
5 A
0 r
5 a5r 2oic2poR 2
M id lp i
1 5
rNi f
d r
r
=
7 r
f r n
o
.en o
o f
o F
OfoPpa F F
P i
t e
l p
u
.!l!
l!
pt M
)
r d
s 0 e Ao R
j 7
t p
a e
G R
sR H
tn L
l
(
s et P
5 r 6 e A
mi w
m M
o ei
)
P rL t 0 n1 iug ece a
06 m qn dn
[
r 0
e ei nr e
1 t
e Ra ef h
e 1
r pR T
la e e(
e 5 r cp D
5 o iO C
r n
e h e w
cr eo o
0 TC P
5 1
e8 iC 2
v t
1 a1 5
rL e
4 t
r s
u in g
iF i
m 04 dA 5
3 8
le 03 c
y C
1 5
it 2
n 5 9 5 8 5 7 5 6 5 5 5 4 5 3 2 5 1
5 0 U
9 0 8 0 7 0 6 0 5 0 4 0 3 0 0
1 0 0 le 0
0 0
0 0
0 0
0 0
la g4$<
Ng52aS:%Eg 8
ho0 S
a L
0 0
1 9
9 9
1 l
ya
=
M l
lar ic o i
0 f
9 fO%P i 5 f
d; 2 >
r o%
ef 5 riu o2
)
r q
. o e r-f 0
w R
d 0
e 0
r e
sa w
8 1
/
iE'@i : 0 n
-P o
P iue l
(
i h 8
i a
u t, 4
%0 m
MeE 0
r d
0 0 e
r
+
h l
itsi e 1
s 0
- U T
eB e
mDy A
1 P
r U
a r
=
0 "
o s
0 C
0 x
e
- iM
=,
2w ia 7
1 r C d
g%
oA
= #
e i
i n
u l
P d
p a
h iu0 0
< F r
t o
a n
i Ti1
%P R
t A
n 5
e 5
lu 2 oo<
2M P
p NMP r
pt M
r r
=
o o
o r
F F
F P
Ao R
d
)
p 0 e G
6 t
e H
a sR R
L )e t
s n
P r et Au
(
r mim Ms e
o w
ei t
l rL nC9 0 o
)
ug e
e 5 P i
qn d wn il l
c a
ei noe m
r 1
t el e r
1 Ra psf h
e e
1 e )R r
la e D (s (
T cp e
iO rV 0 r n
eC 4 oC h e wT cr o(
eo P
TC 2-e8 v
2 iC 0
1 3
ta1 e
rL r
t u
s g
in iF i
m d
02 A
0 1
8 lec y
C 1
itn O
U 5 9 5 8 5 7 5 6 5 5 4
3 5 2 5 1
5 0 e
9 0 8 0 7 O 6 0 5 0 0 2 0 1
0 0 l
l O
0 0
0 0
0 0
0 a
Sa
$<$<1'g [o 3 ccIN I v{3$
L o
50 1
999 1
0 y
0 a
M 1
I
)
1 6
5 8
9 04 0
I 1 0 4
I
+
0 R )0 E
=
H1 I
0 0
T/
F I
9
)
T
(
IEW CA f
C o (x FP 5
A m4 w
A 8
A F
u8 o
M P
m7 l
i6 F
x i
A n
p I
i0 e
u d
M M{
r t
o n
eR C
a 80 r
e r
hO t
p e
T d
S e
p i
pt l
t r
=
a o
p Ao i
r R
o p
t C
L 5
e u
A le 7
l F
sR M
=
id
)
P t
d s
R 1
A T
n ro e
l M
W F
a et t
G mi 0
l 0 R
)
m H
2 l
7 L
d i
rL n
(
P a
i w
ug A
0 qn M
e 5 F o
1 2
l ei t c
6 1
Ra t
n n
e e
r r
1 r
la e e
e o
f R
d C
d e
cp n
e
(
iO e
0 n
6 p
h e e
cr eo D-TC w
5 e8 o
5 l
viC F
ta1 3
rL 0
2 ts 5
1 in e
i r
m u
d g
5 i
A F
4 04
/
lc 8
e 53 y
C 1
itn 0
U 3
le 9
8 7
7 5
4 3
la 0
0 O
O 0
0 0
Sa 2 n. j E 0 '
S.:.$ NE8$k L
p i
Administrctiva Technic ^l Requircm:nts - Appendix A L1C8 Core Operating Limits Report 2
Minimum Critical Power Ratio (3/4.2.3) 2.1 Tech Soec
Reference:
2.2 Qgscriotion
1 The Governing MCPR Operating Limit is determined from Table 2.1, and is either MCPRp or MCPRr, whichever is greater at any given power, flow condition. These limits are not applicable for Automatic RR Flow Control.
TABLE 2.1 MCPRp MCPRr inoperable Equipment With Core Thermal Power > or = 25%
All Flow Ranges (Combination Number - Figures 2.2-1 and 2.2-2) 8 No EOOS (#1)
OLMCPR from Figure 2.21or Figure 2.2-2', multiplied by MCPRr from Figure 2.2-5 K, from Figure 2.2-3 j
8 8
One SRV OOS /TCV Stuck Closed (#2)
OLMCPR from Figure 2.2-ior Figure 2.2-2, multiplied by MCPR, from Figure 2.2-5 K, from Figure 2.2 3 Feedwater Heater (s) OOS '/ One SRV OLMCPR from Figure 2.2-1or Figure 2.2-2. multiplied by MCPRr from Figure 2.2-5 8
K, from Figure 2.2-3 8
8 Turbine Bypass DOS / One SRV OOS OLMCPR from Figure 2.2-tor Figure 2.2-2, multiplied by MCPRr from Figure 2.2-5
(#4)
K, from Figure 2.2 3 3
EOC-RPT OOS / One SRV OOS / TCV OLMCPR from Figure 2.2-ior Figure 2.2-2', multiplied by MCPRr from Figure 2.2-5
]
Stuck Closed / Feedwater Heater (s)
K, from Figure 2.2-3 OOS'(#5)
Turbine Bypass DOS / Feedwater OLMCPR* from Figure 2.2-1or Figure 2.2-2, multiplied by MCPR, from Figure 2.2 5 8
Heater (s) OOS' / One SRV OOS (#4)
Kp from Figure 2.2 3 8
EOC RPT OOS /TCV(s) Slow Closure /
OLMCPR from Figure 2.2-ior Figure 2.2-2', multiplied by MCPR, from Figure 2.2-5 One SRV OOS / Feedwater Heater (s)
K, from Figure 2.24
. OOS'(#6)-
j 8
Idle Loop Startup / One SRV OOS / TCV OLMCPR from Figure 2.2-tor Figure 21/, multiplied by MCPRr = 2.2 Stuck Closed (#7)
K, from Figure 2.2-3 Single RR Loop / One SRV OOS /TCV OLMCPRs from Figure 2.2-1or Figure 2.2-2 multiplied by MCPRr from Figure 2.2-5 8
Stuck Closed (#7)
K, from Figure 2.2-3 1.
Up to 100*F reduction (to 320*F) in feedwater temperature allowed at full power with Feedwater Heaters Out-of-Service (reduction varies at off-rated power levels). Up to 13"F reduction in feedwater temperature from nominal allowed at cl! power levels without feedwater heaters considered Out-of-Service.
2.
If, during Unit Coastdown, power operation exceeding the equilibrium power level is desired, then Figure 2.2-2 shall be used.
3.
OLMCPR is the full power MCPR limit.
LaSalle Unit 1 Cycle 8 2-1 May 1999
J' 9
9
/[
9 1
7 y
4 a
8 M
lr/
'l 0
g :.
I n
i u w
/
7 lo i4
=#
lo l
V Go 7
r s
fe m3, 2
i h
6 A
i f
N
/
C 8, 8
t m
o S2 0
a e O #,
r h
m l
O1 t
EE#
C
/
'l 7
S O
O A
E 0
x 8
i
/
d 0
g :=
n n
u e
w i
\\
o n
=
p pt R
o G
\\
f r
Ao P
e h
m
/
p C
C 6 t
fo 7
e M
S#
s m
iteOo l
l
/
8 r
,/
sR r
7 t
h O5 t
c 0
i n
EE#
e e e
es etmi L
y i
s 7 m
68 4
7
^
86 i@L gd 00 u
i n
r na u
a i
i i
AB T
ug t 3
=
as uu 7
qn re e,
TT 7
2 aa 6
ei ec t
n Ra pe w
6 0
r C
2 Of r
e y s:
r S
la e e
, o 1
O h
R O
a5 cp t #
=
iO 2
l t
E n
G4, e
h e 2
h m3 cr t
7 C #,
4 eo e
o f
r S2 7
r TC u
e O #,
0 h O1 g
lt e8 i
EE#
v F
iC ta1 rL t
is 7
n
~
2 i
7 im v
0 d
=
i A
i u.
1 m2
=
Ce l
Sb Oa 7
T 0
Oe 7
l Ee s,
0 fo s.
ts h
Ea i
r in 8
ot F N lce 7
y 8
C 6
1 7
6 5
4 0 it 3
3 3
3 n
1 1
1 1
U e
Ca J_O la l
S a
L
f 999 1
I7 7
y 4
a 1
8 M
0 Il 7
LI' f
I.
f 72 a
8 lj
/
f 0
4 b
7-iu
-. "p l'
7 a
n u
A w
C 0
x o
d 8
id S
0 n
s O
t e
a O
p o
y I.
p i
i!
ot gs E
7 n n mio pt C
/
f b b
a r
n n
Ao g
ei a
~
u em3 p
n
/
h 7
or e
i i
t 8
r C o, u
Ii fo sR u
S2 7
C r
tn D
te O #,
0 S
h s
2 iO1
/
l' s7 et R
O EE#
1 O
ee mi P n d es m
E
- r L C
a.
68 u
i g :m 86 M
4, a
n H
[
00 iug 3
m b T
7
"'p
==
o o
t 7
n qn AB 6
i o
ei m E u.
s f
uu 7
3
=
e t
aa Ra L
fe o
i TT 0
h u
a 2
t C 6 r
f l
e g R r
a S#
cp n
teOo r
h i
i O5 iO
/
t EE#
n ar h e cr e
7 eo p
4 TC O
7
/
0 e8 2
g viC 2
t a1 2
rL t
e s
r m
F i
f ls_~jl 7
u L
i 2
n g
7 i
i 0
b d
i a
A i u.
l s#~,
i 1 u2 Ce Sb 7
Oa 1
0 T
! Oe fo s/,t"sl 7
E es 0
t s is re l
b a m 8
r
[
lc ou F N e
~
7 y
8 C
6 1
9 7
5 4 0 4-3 3
3 3
itn 1
~
U 1
1 1
1 ie mS3O la Sa L
999 1
y 5
a r
d 9
o n
M f
a d
eaiely s.
a no
=
ei s s
u d g eE 4ge r
r iu e
= 6, u qh s
e el e
t, o
b Rd uc e y
)
)
r gr adV P
P e
)
nim! S p
w i 8 s
5 i
r iaT r
e o
toDecW i
0 P
ns wf 5
6 i
f C 4
(
1 e
i oio o
(
Mgpt T 7
(
-u 4
6 5
si%hae 3
8
- 7 I
n s
r h
- 1
- 0 0
t to5t t 50 00 0
i 0
T mi2dh 1
n et 4 0 6 0 0
A i
e r
L ood id
< +
< +
0 o
l Mf we 0
r
- e. l leM db Ps P5 P +
0 C
l r
x e
-i t
e i r ea
= 2
= 1
= 0 0
d l.
1 iab l
- . c a pmn i
o1
=1 t
r i
r 1 r 1 e
d i
,r e
o =,
o =,
n p
Pif iP r
< =
o a
=,
R 5
T f
> To p>t r
w5 eP 2Ni
. 2 pR 5x 5K 0%
>K I.
7 i
e t
5 o 2
4 6
P f
l p
u r
r r
r r
=
o o
o o
o pt M
r F
F F
F F
P Ao l
)
p p
d K
e e
sR R
l taR tn P
et C
s
(
mi M
5 r m
6 e ci t 0 w
rL n1 i
o o
e m
P ug d
=
qn l
n=
a ei m
4 t
efe Ra pR r
e 2
r e
h la e D
T cp
-r e
iO e
5 r
n 5 o h e w
C cr o
eo P
TC 3-e8 2
viC 2
ta1 e
rL r
t u
5 s
g 4
i i
n F
im dA 53 8
e lc y
C 1
52 itn 3
8 6
4 2
2 8
6 4
2 U
2 2
2 2
1 1
1 1
le EE EQE3 la Sa L
0 9
0 9
h 1
9 1
y t
a M
r 0
o 9
P f
s >
n5 io2 t
r a o uf d q d
ieEe t
ruea qhl o
e
- t. p 0
Rd a 8
r er gr t
)
e inix P
w sE r e o
oiDe 0
P t
B 0
A t
s 1
l r
a ot y
(
m Mga 7
r x
siM
- 6 e
n 00 h
r id it r
imto0 0 1 T
0 i 0 1
n 0
r e
n e
L o1
< 0 0
o 7
lam <
e i
P P +
0 C
l p
p ml 1
i r ia =
= 0 0
d
=
e pt ecr l
i r 1 1
r t
- hf o o
r t
P TfO<
a
=
Ao o =,
l R
p u
M 2NI 2 2
P m
5 o 5
5 K K
f e
)
r r
r
=
sR p
F F
F P
0 e o
o o
d tn K
N 6
t s
a et R )e R
mi Pr m
u
- r L Cs
(
i r
Mo9 N
e iug w
t Cc l
e qn n
n 5 P 0 o ei ewr 5
e t
Ra dof l
e a
2 g
m r
nl e la e eSR e
r cp p) h iO es T
n D(
h e V
e 0
r cr rC 4 o eo e
T C
TC w(
g o
e8 P
T
\\
viC 4
t a1 rL 2
0 t
2 3
is e
g n
ru i
m g
u' i
d F
\\
A g
02 N
q'
\\
0 1
8 le cy C
1 itn 0
U 1
le 6
5 4
3 2
1 2
9 O
1' 2
l 1-l 1
1 1
1 laS 72[o 52 h2 a
L
50 lI
[ [L.
L
[l[ipe 1
999 II 1
0 0
y 2
0 a
M 1
1
]
r
)r o
W
]
6
-0 4
5 i!
4 7
9
(
1 1I x
+
)
2 0
!I II 3
0 0
1 0
r 9
Il 0
/
i!
0 W
+
(
1 x
[
Il x
95 5
Il
]6 6
8 A
I I
i l
74 0-x g
[
i R
1 r
+
e d
P
!I
)
h n
0 0
C 8
e 0
it e
p M
1 i!
/
f r
o pt W
r t
r w
Ao e
i p
m
!I
(
o t
x a
l 5
e p
F i
i e
L 9
r u
e l
7 sR 5
e a2 o
l
)
g t
0 r
r R
6 0
d tn s
P 0
4 h
2 C
l e
t m
M
=
T S
et t
d C
p=
e a
[
Q mi iI 0
=
r
=
0 R o
o 7
t p
a ci 4
p p
oR R
rL t
R R
L
(
0 P
P P
n i
leC 1
w r
7 ug e e C
C W
W IdM
=
o c
qn d n M
M l
5 e
ei n
r T
F r
r r
t e
o o
o 6
6 Ra e
fe lI F
F F
W e
2 r
p R II r
a e e
=
o l
C cp D
iO w
0 n
6 he o
!I cr lF eo TC 5
e8 2
m 55 v
w iC 2
t e
a1 r
rL u
h 0
t s
g 5
i i
n F
i m
d 5
A 4
04 53 8
elc y
C 0
1 3
itn 4
2 U
2 8
1 1
1
~
1 le z,_ j u2 jE8g.!E la Sa L
I Administrctive Technical Requircm::nts - App:ndix A L1C8 Core Operating Limits Report L
1 3
Linear Heat Generation Rate (3/4.2.4) 3.1 Tech Soec
Reference:
3.2
==
Description:==
4 The LHGR Limit is 14.4 kw/ft for fuel types:
1.
GE9B-P8CWB303-9GZ 100M-150-T 2.
GE98-P8CWB313-9GZ 100M-150-CECO 3.
GE9B P8CWB314-9GZ 100M-150-CECO 4.
GE9B-P8CWB32211GZ 100M-150-CECO 5.~
GE98-P8CWB320-9GZ-100M-150-CECO 6.
GE9B-P8CWB34312GZ-80M-150-CECO 7.
GE98-P8CWB34210GZ-80M-150-CECO i
LaSalle Unit 1 Cycle 8 3-1 May 1999 J
p L
Administrctiva Technical Requir m:nts - App;ndix A L1C8 Core Operating Limits Report i
4 Control Rod Withdrawal Block Instrumentation (3/4.3.6) 4.1 Tech Soec
Reference:
Tech Spec Table 3.3.6-2.
4.2
==
Description:==
The Rod Block Monitor Upscale instrumentation Setpoints are determined from the relationships shown below:
ROD BLOCK MONITOR UPSCALE TRIP FUNCTION TRIP SETPOINT ALLOWABLE VALUE Two Recirculation Loop Operation
- 0.66 W + 45%"
0.66 W + 48%"
Single Recirculation Loop Operation
- 0.66 W + 39.7%"
0.66 W + 42.7%"
J l
This setpoint may be higher / lower and will still comply with the RWE Analysis.
Clamped, with an allowable value not to exceed the allowable value for recirculation loop drive flow (W) of 100%.
LaSalle Unit 1 Cycle 8 4-1 May 1999
f b
AdminiStrctive Technical R:quircrn:ntS - App:ndix A L1C8 Core Opercting Limits R: port 5
Allowed Modes of Operation (B 3/4.2.3) 5.
Allowed Modes of Operation (B 3/4.2.3) -
The Allowed Modes of Operation with combinations of Equipment Out-of-Service are as described below:
OPERATING REGION----
L ce Options' Standard ELLLA ICF Coastdown Equipment Out of S i
None Yes Yes Yes Yes Feedwater Heaters' Yes No' Yes Yes Single RR Locpiid!9 Loop Startup Yes Yes N/A Yes Turbine Bypass Valvos Yes Yes Yes Yes i
EOC Recirculation Pump Trip Yes Yes Yes Yes TCV Slow Closure /EOC Recirculation Pump Trip Yes Yes Yes Yes TCV Slow Closure /EOC Recirculation Pump Trip /
Yes No' Yes Yes Feodwater Heaters
- 8 Turbine Bypass Valves / Feedwater Heaters No No Yes*
Yes EOC Recirculation Pump Trip /
Yes' No' Yes' Yes Feedwater Heaters
- TCV Stuck Closed' Yes Yes Yes Yes 1
Each EOOS condition may be combined with one SRV OOS, and a 13 reduction in feedwater temperature (without Feedwater Heaters considered OOS).
2 Up to 100"F Reduction in Feedwater Temperature Allowed with Feedwater Heaters Out-of-Service. Feedwater Heaters OOS may be an actual OOS condition, or an intentionally entered mode of operation to extend the cycle energy.
j 3
If operating with Feedwater Heaters Out-of-Service, operation in ELLLA is supported by current transient analyses, b;t administratively prohibited due to core stability concerns.
4 EOC Recirculation Pump Trip OOS/Feedwater Heaters OOS is allowed during non-coastdown operation using the TCV Slow Closure /EOC Recirculation Pump Trip OOS/Feedwater Heaters OOS operating limits.
5 Only when operating in coastdown, otherwise this combination is not allowed.
I 6
Operation is only allowed when less than 10.5 million Ibm /hr steam flow and when average position of 3 open TCVs is less than 50% open, with FCL <108%, and the MCFL setpoint 2120% TCV Stuck Closed may be in f
combination with any EOOS except TBVOOS or TCV Slow Closure. If in combination with other EOOS(s),
thermal limits may require adjustment for the other EOOS(s) as designated in Sections 1,2, and 3.
LaSalle Unit 1 Cycle 8 5-1 May 1999
Administrativo Technical Requirem:nts - App ndix A Section 2 LaSalle Unit 1 Cycle 8 Roload Transient Analysis Results May 1999 l
i Administrativa Tcchnical Requirem:nts - Appendix A L1C8 Reload Transient Analysis Results Table of Contents 4
Attachment Preparer Document 1
Comed Neutronics Licensing Report 2
General Electric Supplemental Reload Licensing Report 3
General Electric ARTS improvement Program Analysis, Supplement 1 (Excerpts) 4 General Electric TCV Slow Closure Analysis (Excerpts) 5 Comed Additional Reload Transient Analysis Information (Excerpts)
L salle Unit 1 Cycle 8 May 1999
Administrctiva Technical R:quircmants - Appsndix A L1C8 Reload Transient Analysis Results r
i LaSalle Unit 1 Cycle 8 Neutronics Licensing Report I
4 l
l
'(
)
II.salle Unit 1 Cycle 8 May 1999