ML20199A253
| ML20199A253 | |
| Person / Time | |
|---|---|
| Site: | Summer  |
| Issue date: | 11/04/1997 |
| From: | SOUTH CAROLINA ELECTRIC & GAS CO. |
| To: | |
| Shared Package | |
| ML20199A240 | List: |
| References | |
| NUDOCS 9711170116 | |
| Download: ML20199A253 (32) | |
Text
. .
d SOUTH CAROLINA ELECTRIC & GAS COMPANY VIRGIL C. SUMMER NUCLEAR STATION CORE OPERATING IIMITS REPORT FOR CYCLE 11 ,
VALID FOR 0 TIIROUGH 7,000 MWD /MTU CORE AVERAGE BURNUP I
REVISION 0 NOVEMBER 3,1997 l
! 9711170116 971104 !
LIST OF EFFECTIVE PAGES EAfd REVISION 8 0 O
un 0 iv 0 0
' 0 3 0 4 0 5 0 6 0 7 0 8 0 9 0 10 0 11 0 12 0 13 0 14 0 15 0 16 0 17 0 18 0 19 0 20 9 2I O 22 0 23 0 24 0 25 0 26 0 t
9
Table of Contents !
- Section Title - Page 1.0 Core Operating Limits Report - . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . I ;
+
- 2.0 Opera tin g Li m i t s . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2 2.1 Moderator Temperature Coemcient (Specification 3.1.1.3) . . . . . . . . . . 2 2.2 - Shutd6w n Rod Insertion Limits (Specification 3.1.3.5) . . . . . . . . . . . . . 2 2.3 Control Rod Insertion Limits (Specification 3.1.3.6) . . . . . . . . . . . . . . . 2 2.4 Axial Flux Difference (Specification 3.2.1) . . . . . . . . . . . . . . . . . . . . . . 2*
2.5 Heat Flux Hot Channel Factor . Fo(Z) (Specification 3.2.2) . . . . . . . . . 6 2.6 RCS Flow Rate and Nuclear Enthalpy Rise Hot Channel . . . . . . . . . . . 6 Factor . F% (Soccification 3.2.3) i Revision 0
List of Tables Table Title Page ,
1- RA OC W(Z) at 150 51WD/h!TU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9 i.
V. C. Summer Cycle 11 2 RAOC W(Z) at 4,000 htWD/h1TU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11 Y. C. Summer Cycle 11-3 RA OC W(Z) at 10,000 h1WDAITU . . . . . . . . . . . . . . . . . . . . . , . . . . . . . . . 13 V. C. Summer . Cycle 11' 4 RAOC W(Z) at 18,000 51 WDSITU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15 V. C. Summer Cycle 11 5 Baseload W(Z) at 150 blWDAITU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17 V. C. Summer Cycle 11 6 Baseload W(Z) at 1,100 h1WDSITU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19 Y. C. Summer . Cycle 11 7 Baseload W(Z) at 4,000 SIWDAITI! .... ......................... 21 V. C. Summer Cycle 11 8 Baseload W(Z) at 10,000 htWDAITU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23 V. C. Summer Cycle 11
-9 Baseload W(Z) at 18,000 h!WDSITU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25 V. C. Summer Cycle 11 e
il Revision 0
. i t
(
List of Figures Figure Title Page 1 Moderator Temperature Coemcient vs. Power Level . . . . . . . . . . . . . . . . . . . 3 V. C. Summer . Cycle 11 2 Rod Group lasertion Limits vs. Thermal Power for Three Loop Operation . . . 4 Y. C. Summer Cycle 11 .
3 Axial Flux Difference Limits as a Function of Rated Thermal Power . . . . . . . . 5 V. C. Summer . Cycle 11
-4 K(Z) . Normalized F9 (Z) as a Punction of Core Height . . . . . . . . . . . . . . . . . . 7 Y. C. Summer Cycle 11 5 RA OC W(Z) at 150 hlWDSITU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8 V. C. Summer Cycle 11 6 R AOC W(Z) at 4,000 hlWDSITU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10 V. C. Summer . Cycle 11 7 RA OC W(Z) at 10,000 h t WDSITU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12 V. C. Summer Cycle 11 8 RAOC W(Z) at 18,000 SIWDSITU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14 V. C. Summer Cycle 11 9 Baseload W(Z) at 150 h!WDSITU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16 V. C. Summer Cycle 11 10 Baseload W(Z) at 1,100 M WD/hlTU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18 V. C. Summer . Cycle 11 4
iii - Revision 0
f List of Figures Figure Title Page 11 i Baseload W(Z) at 4,000 MWD /MTU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20 V. C. Summer - Cycle 11 12 Baseload W(Z) at 10,000 MWD /MTU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22 V. C. Summer . Cycle 11 13 . Baseload W(Z) at 18,000 MWD /MTU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24 V. C. Summer . Cycle 11 ,
14 RCS Total Flow Rate vs. Three Loop Operation . . . . . . . . . . . . . . . . . . . . . . 26 Y. d. Summer . Cycle 11 iv Revision 0
-m -- =--_
4
.,; b V. C. SuMMEa CYCLE 11 NOVEMBER 1997 sesso 1.0 Core Operating Limits Report __
- This Core Operating Limits Report (COLR) for V. C. Summer Station Cycle 11 has been prepared in -
- accordance with' the requirements of Technical Specification 6.9.1,11.
The Technical Specifications affected by this report are listed below:
3.1.1.3 MODERATOR TEMPERATURE COEFFICIENT 3.1.3.5 SHUTDOWN ROD INSERTION LIMITS 3.1.3.6 CONTROL ROD INSERTION LIMITS i
3.2.1 AXIAL FLUX DIFFERENCE 2 3.2.2 HEAT FLUX HOT CHANNEL FACTOR 3.2.3 RCS FLOW RATE and NUCLEAR EhTHALPY RISE HOT CHANNEL-FACTOR
)
4 a-i e
d I-l~
q
- l. Revision 0 L
_ . . _ - . . _ _ . ~ . __ . . - _ . _ _ _ - _ _ . _ - . _ . . _ _ . . _ _ _ ~ - _ _ . _
b iv. C. SUMMER CYCt.E 11" - NOVEMBER 1997 :
- 3 i
2.0 :- Operating Limits 1 i
The cycle specific parameter limits for the.-specifications listed in' Section 1.0 are presented in the subsections which follow.- These limits have been developed using the NRC approved methodologies ,
- specified in Technical Specification 6.9.l.11.
.t
'2,1-' MODERATOR TEMPERATURE COEFFICIENT (Specification 3'Lt.3)i .
4
-i 2.1.1 The Moderator Temperature Coefficient (MTC) limits are:
The BOUARO-MTC shall be less positive than the limits shown in Figure 1.
4 The EOUARO/RTP MTC shall be less negative than 5x10 AkA/'F.
2.1.2 - The MTC Surveillance limit is:
d The 300 ppm /ARO/RTP-MTC should be less negative than or equal to 4.1x10 ALAfF.
> where: BOL stands for Beginning-of-Cycle-Life -
ARO stands for All Rods-Out RTP stands for RATED THERMAL POWER ,
EOL stands for End-of-Cycle-Life 2.2 SHUTDOWN ROD INSERTION LIMITS (Specification 3.1.3.5):
The shutdown rods shall be withdrawn to at least 228 steps.
2.3 CONTROL ROD INSERTION LIMITS (Specification 3.1.3.6):
The Control Bank Insertian Limits are specified by Figure 2.
l 2.4. ' AXIAL FLUX DIFFERENCE (Specification 3.2.1):
[ 2.4.I' : The Axial Flux Difference (AFD) Limits for RAOC operation for Cycle 1I are shown in --
- p. -Figure 3.
' 2A.2 The Axial Flux Difference (AFD) target band during base load operations for Cycle 11 is:
Bole SOL (0 22,4S0 MWD /MTU): :e 5% about a measured target value.
' 2.4.3 ~ The minimum allowable power level for base load operation, APL* is 85% of RATED TIIERMAL POWER.
2 Revision 0 l-i-
1,c
- V. C. SUMMER CYCLE 11. NOVEMBER 1997--
- sceau Figure 1
' Moduator Temperature Coemcient vs. Power Level V. C. Summer Cycle 11 ,
i 1
10 0.9
- k. $ll.*lNIl [
0.8 4
0 . *)
^
C 0
, y 0.6 +
s y
!g - im.,,m.
ODeratten i b 0.5
- O 0.4 O.3 O.2 0.1
-0.0 0 20 40 60 80 100
. Percent of Rated Themal Power 3 Revision 0
.-e, , -
+ , + . , - > - , -- , . , , , ,- . - - , = .
. 4
, V C. SUMMER CYCLE 11_- NOVEMBER 1997 '
SCE&G
- Figure 2 _
Rod Group Insertion Limits vs. Thermal Power for Three Loop Operation
' V. C. Summer . Cycle 11 i
B 230 i i ! ! i /t 4 i
! i
. i 6 i Vi I 6 220 , ; i f i .>4 . si , , ,
i i V! I i i 210 , , f, , , ,
i i / I i i i 200 I /
i / 'l t 194 W) 190 f f . _ r ,f 9 f controt ; i wc i f 180 f , 'fi f + 6 f i 170 f , , , , f; e f i i i / i o '160 j , ! , i ,
f i i -, i , /
O 150 f , .
"y ; , 100 Step-i ' !
O 140 , j overlap
[
lf( '
l 0, 130 --
y / i i i i t i i / t t u /I i i I i i i i / , i f n 120 3 ,, , , , ; i f , , ,
f 110 i i/ !'
W ' ' ' ' ' * " * * ,I '
Q 100 r fl I i it
/ } l i i CK 90 i
i f f" , ,
r
, i I I i
i 80 ; f, , j ,
l .7 e i i i i ^I 70 , ,
f ; ; i j i i / i i i i 60 , , , , f ; , , ,
i i i f i
- i i 50 f, , , i f i , . i fi ,
i t i e i , i . i 30 f , , , , , , ,
O
/i e ! ! 4
! t i
/ I i I {
6 I I e
! /, i ! ! ! ! I i i ! !
O V '* * ' ' f ' ' * * ' '
O.0 0.2 0.4 0.6 0.8 1.0 Fraction of Rated Thermal Power J
4 Revision 0
4 JV. C. SL'MMER CYCLE I1 .. NOVEMBER 1997.- '
"3 SCE&O -
1 Figure 3 ._ _
Axial Flux Difference Limits as a Function of Rated Thermal Power V. C. Summer - Cycle 11 120 .
110 l l
l(-8,100il l(+B,100)i AOO l Unacceptable l l \ itJnacceptable W t
, 7
)
e i * '
" t
) / \I L a
O' i / \- 1 E / lAcceptablel
\ i j
.< 7C --
,/
7 I / \ I g y I /- \ i
/ \ I
!- o
/ i ) l
,{ l(-22,50)l l l(+20,50)l l
5 40 l
i 30 I
i 20 l
10l 0
-40 -30 -20 0 10 20 '30 40 Axial Flux Differenes (% AI) 5 Revision 0
h
. :I
_o 1
! V, C. SUMMER CYC1.E 11-- -NOVEMBER 1997; 2.5 ~ HEAT FLUX HOT CHANNEL FACTOR - FJZ) (Specification 3.2.2):- __ ;
m_
~
- F4Z) s' ppm ~P-
- K(Z). -forPF0.5 i
F4Z) s *K(Zf for Ps 0.5 where; P = g,N'[,Ijp'p'g i
1 2.5.1 Fo* = 2.45 2.5.2 K(Z) is provided in Figure 4 ,
2.5.3 . Elevation dependent W(Z) values for RAOC operation at 150, 4,000,10,000, and 18,000 MWD 81TU are shown in Figures 5 through 8, respectively. This information is .
sufficient to determine W(Z) versus core height in the range of 0 MWDS1TU to EOL~
burnup through the use of three. point interpolation. -
'- 2.5.4 Elevation dependent W(Z)n. values for base load operation between 85 and 100% of rated t thermal power with the item 2.4.2 specified target band about a measured target value at ,
150,1,100,4,000,10,000, and 18.000 MWDS1TU are shown in Figures 9 through 13, respectively. This information is sufficient to determine W(Z).c versus core height for bumups in the range of 0 MWD /MTU to EOL burnup through the' use of three point interpolation.-
2.6 RCS FLOW RATE and NUCLEAR ENTHALPY RISE HOT CHANNEL FACTOR - F"w (Specification 3.2.3):
N Thermal Pyr FAH where: P , Rated Thermal Power R.
F,7.(1 + PFay . (1-P)) .
-2.6.1 .F ,"" = 1.56, 2.6.2 PF, = 0.3 2.6.3. The Acceptable Operation Region from the combination of Reactor Coolant System total flow and R is provided in Figure 14.'
-6 Revision 0
- - - - . -- , n,., e ,- e w , e
-4
~ V. C. ShMMER CYC1.E I1 :
NOVEMBER 1997 -
l_ SCEso Figure 4 .
i K(r) . Normalized F n(Z) as a Function of Core Height Y. C. Summer - Cycle 11 -
f t '
4 -
1.2 1,1 Jo.0, 1.01. 16 . 0, 1.01
~
~ m 0.9 !12. 0, O.925l' 2
~
o 0.8 4
3
.o.?
o 0.6
=
i
- 0.5
, 0.4 0.3 i
0.2
- i
< 0.1 0.0 0 -1 .2 '3 .4 5 6 7- B 9 10 11 -12 Core Height (Feet) 0
. 7 Revision 0 i
y w -, y - , , -,r-- . -r .- - r a m . ---
. -- - . -. . . - . . . . . . . - - . . . ~ . . . ~ - . - . . ~ - . ~. . - _ . . ~ . . . . . . . ~
T
'; - % C. SUMMER CYCLE 11 - NOVEMBER 1997 ' '
sceae-S
- Figure 5 -
RAOC W(Z) at 150 MWD /MTU
% C. Summer Cycle 11 T
4 i 1.50 ,
1,45
.1.40 W
1,35 -
a b
- 1.30 a i
a a ,
1 H '
~.
s 1.25 a
a.
a 1.20
'a,
'&aa g' 4 A,i 1.15 S'aaa .a a-
'saaa ',
1.10 i-1.05 1.00 0 1 -2 3 4 5 6 7 8 9 10 11 12 Core Height (Feet) i.
E i! 8 ' Revision 0 e
w a - a-U e , - - - . 4 wty4-. a .e y, y 9gy_en- $ -y p y *er v- yy yp-r w-ev . -- r ww-- 7W
i
-I se V.' C. SOMMER CYCLE 11 NOVEMBER 1997
-scaso (
i
- Table 1 l q RAOC W(Z) at 150 MWD /MTU. l V, C. Summer . Cycle 11-- -
Core Heigh.L(.fG W(Z) Core Heicht (ft) W(Z) f 0.00 - 1.0000 '6.08 1.1493 0.16' l.0000 6.24- - 1.1561 0.32 1.0000- 6.40 1.1611 5 0.48 1.0000 6.56 - l1.16501 Of>4 !.0000 6.72 1.1684 0.80 1.0000 ' 6.88 - 1.I713 l 0.96 -
1.0000 7.04 - 1.1734-1.12 1.0000 ' 7.20 11745 1.28 1.0000 7.36 1.1748 1.44- 1.0000 7.52- 1.1741 1.60 - 1.0000 7.68 1.1725 1,76 1.3490 7.84 1.1698
- 1.92 - 1.3305 8.00 1.1662 2.08' 1.3114 8.16 1,1618 !
2.24 1.2922- 8.32 1.1563 2.40 1.2725 8.48 1.1491 2.56 -1.2522 8.64 1.1403 2.72 1.2324 8.80 1.1322 2.58 1.2150 8.96 1.1273 3.N - 1.2014 9.12 1.1253 3.20 1.1919 9.25 1.1253 3.36 1.1869 9.44 1.1271 3.52 1.1837 9.60 1.1310-3.68 1.1796 9.76 1.1370 3.84 1.1748 9.92 1.1437- -
4.00 1.1710 - l'0.0S 1.1500 4.16. 1.1687 10.24 1.1553 4.32 -1.1670' 10.40 -1.0000
-4.48 1.1651 10.56 1.0000-i- 4.64 1.1628' 10.72- 1.0000 4.80 - 1.I602 10.88- 1.0000 4.96 11571 1!.04 1.0000 5.12 1.1537 i1.20 1.0000 5.28 1.1497 11.36 1.0000 5.44 1.1456 - 11.52 1.000) :(
5.60- 1,i416 11.6S 1.0000 5.76- 1.1411: :11.84 1.0000 5.92- 1;1427 12.00 1.0000
.r 9 Revision 0
. . ~ . . _ . = _ . . , _ _ - _ . _ _ . _ _ _
. Vi C. SUMMER CYCLE 11 - NOVEMBER 1997 :
ectae -
i Figure 6- ,
- RAOC W(Z) at 4,000 MWD /MTU-V. C. Summer Cycle 11 i
.1.30 l
' )
1.25 .
e a
5
^
1.20 -
a a 4 4
&&'e g - !
h g&
f1.15 :
4 6 a a a
b a
Aa&&a,,gg j4 6&A 1.05 1,00 J 0- 1 2 3 4 5- 6 7 8 9 10 11 12 Core Height (Feet) l 10 Revision 0
- s.
r.
1 V. C. SUMMER CYC1.E 11- . NOVEMBER 1997 .7;
-.- g Table 2 RAOC W(Z) at 4,000 MWD /MTU
-V.' C. Summer Cycle 11' Core Hdcht (ft) ' W(Z1 Core Height (ft) W(Z) !
- 0.00 --1.0000 ' 6.08 1.1105-
- O.I6 1.0000 6.24 -1.1195
- 0.32 1.0000-' 6.40. 1.1273 -l 0.48 1.0000'- 6.56 1.13/3 i 0.64 -1.0000 6.72 1.1407 0.80 1.0000 - 6.88 1.1467 '
0.96 . 1.0000 7.04- 1.1519
.. I 2 1.0000 7.20 1.1563 '
1.28 1.0000 7.36 1.1599 l.44 'l.0000 7.52 1.1627 1.60- 1.0000 7.68 1.1645 1.76 1.1891 7.84 1.1653 1.92 1.1751 8.00 1.1653 2.08 1.1619 8.16 1.1645 2.24 - 1.1501 8.32 1.1626 '
2.40 1.1388 8.48 1.1589 2.56 1.1272 8.64 1.1538 2.72 1.1157 8.80 1.1537 2.88.- 1.1056 8.96 1.1607 3.04 1.0977 9.12 1.1747-3 20 1.0929 9.28 1.1889 3.36 1.0925 9.44 1.2012 3.52 1.0920 -9.60 1.2129
- 3.68 1.0916 9.76 1.2248 V 1.0909 9.92 1.2367 4.00 1.0904 10.08 1.2483 4.I6 1.0902 10.24' 1.2592 4.32 1.0900 10.40 1.0000 4.48- 1.0892 10.56 1.0000 4/; 1.0884 10.72 1.0000 4.S0 1.0S86 10.88 1.0000 4.96 1.0897 11.04 1.0000 5.12 1.0909 11.20- 1.0000 5.26 1.0920 11.36 1.0000 5.44 1.0929- 11.52 1.0000
'5.60 1.0937- 11.6S ' l.0000 5.76- 1.0959 11.84 1.0000 5.92 1.1018 12.00 1.0000 s
11 Revision 0
. - .. . . . . - . . . .. . -. . . . . . . . - . . . - . _ . . - . . - ~ . .
w_
d I
_. V. C. SUMMER CYCLE 11 - - NOVEMBER 1997.
- Sceae Figure 7- 4
~ RAOC W(Z) at 10,000 MWD /MTU-V. C Summer . Cycle 11 '
f T
I 1.30 1- i ;
^
1.25 ,
..d I a6 , A, A
0 g6 4 & 4 1.20 -
a a
A H. A
- 1.15 3 a ,
e a a a a 6 1.10 ,
, a' ,
A &
'aa '
g ga
1.05 1.00 1 .2 3 4 5 6 7 8 9 10 11 12 Core Height"(Feet) 12 Revision 0
, _ , _ - - ,n .. . . 1 - - . . . . _ . . . . , _ _
4 4
L V/ C. SUMMER CYCLE I1 ' NOVEMBER 1997 8c540.
Table 3 '
RAOC W(Z) at 10,000 MWD /MTU V. C. Summer ~. Cycle 11
- Core Height (ft) - W(7) - Core Heicht (ft) W(Z) 0.00 1.0000 - 6.08 1.1413 0.16 1.0000 ' 6.24 1.1535 0.32 1.0000 6.40 1.1644 0.48 1.0000 6.56 1.1745 =
0.64 1.0000- 6.72 1.1838 0.80 1.0000 6.88 1.1923 0.96' -1.0000 7.M 1.1998 1.12- 1.0000 7.20 1,2063 1.28 - 1.0000 7.36 1.2117 1.44 1.0000 - 7.52 1.2159 1.60 1.0000 -7.68 1.2189 1.76 1.1709 7.84 1.2206 1.92 1.1579 8.00 1.2210-2.0* 1.1447- 8.16 1.2205 2.24 1.1315 8.32 1.2185 ,
2.40 1.1185 8.48 1.2142 2.56 1.1056 : 8.64 1.2074 2.72 1.0930 8.80 1.2024 2.88 1.0812 8.96 1.2031 3.04 1.0713 9.12 1.2071 i, 3.20 1.0656 9.28 1.2098 3.36 1.0667 9.44 1.2110 3.52- 1.0678- 9.60 1.2148 3.68 1. % 97 9.76 1.2234 3.84 1.0713 9.92 1.2341 4.00 1.0725 10.08 1.2438 4.16 1.0738 10.24 1.2516 4.32 -1.0753 10.40 1.0000 4.48- 1.0775 10.56 1.0000 4.64 1.08N 10.72 1.0000 4.80 1.0841 10.88 1.0000 4.96 1.0880 -11.04 1.0000 5.12 1.0909 11.20 1.0000 5.28 1.0929 11.36 1.0000 5.44 1.0969 11.52 1.0000
-5.60 1.1056 11.68 1.0000-5.76 1.1172 - = 11.84 1.0000 5.92 1.1297' 12.00 1.0000 13 Revision 0
. - -. . - . . . . . . . - . . . . . _ . . . . - ~ , .- . - . - - - - . - . - , ----
V. C. SUMMER CYCLE 11 - - NOVEMBER 1997 Sce&O l I
Figure 8 RAOC W(Z) at 18,000 MWD /MTU ,
V. C. Summer . Cycle 11 -)
i, i
i 1.30 G
1.25 s
& L4 e' a'a .
& o
^ -6' * ~
1.20 .
a ,
4 & &
g & l gg' a &
N '
d 1.15 .
8 & &
1.10 . ,'
s a
1.05 4
1 00 1 2 3 4 5 6 7 -8 9 10 11 12 Core-Height (Feet) 4 e
d 14 Revision 0 4
y-, -
, . c e- - - - , - . . s - - , . . . , . , , ,- --
i
.s-Vi C. SUMMER C.CLE 11 - NOVEMBER 1997
- sesaa Table 4 RAOC W(Z) at 18,000 MWD /MTU =
V. C. Summer Cycle 11 Core Height (ft) N(Z) Core Heicht (ft) - - W(2) 0,00- 1.0000-- 6.08 1.1932 O 16 1.0000 6.24 1.2022 0.32 1.0000 6.40 1.2092
-0.48 -1.0000- 6.56 1.2148 =
- 0.64 1.0000 6.72 1.2193-0.80 J 1.0000 6.88 -1,2227 - !
0,96- 1.0000 7.04 1.2248 1.12 1.0000 7.20 1.2255 1.28 1.0000 7.36 1.2249 1.44 1.0000 7.52 1.2228' l.60 1.0000 7.68 1.2196 .
1.76 1.1749. 7.84 1.2151 1.92- 1.1639 8.00 1.209:
2.08 1.1527 8.16 1 JOU, 2.24 1.1416 8.32 1.191(-
2.40 'l.1308 8.48 1.1837 2.56 1.1205 8.64- 1.1805 2.72 1.I101 8.80 1.1789 2.88 1.0985 8.96 1.1767
'3.04 1.0873' 9.12 1.1747
- 3.20 1.0822 9.28 1.1754 3.36 1.0S92 9.44 1.1793 -p 3.52 1.0961 9.60 1.I846 3.68 1.1038 9.76 1.1902 3.84 1.I102 9.92 1.1954 4.00 ' -1.1156 = 10.08 1.1995 4.16 . 1.1209 10.24 1.2034 l.
4.32 1.1270 : 10.40 1.0000 4.48- 1.1345 10.56 .0000 4.64 1,1424 - 10.72 1.0000 4.80 1.1495 10.88 1.0000 4.96 1.1554 11.04 1.0000 5.I2 1.1603 11.20 1.0000 5.28 1,1643 11.36 - 1.0000 5.44 1.1679 11.52 .-1.0000 5.60 1.1715 11.68 1.0000 5.76 1.1762 11.84 1.0000 5.92 - 1.1837 12.00 1.0000
~
15 Revision 0 i
l=
i -i
' V! C. SUMMER CYCLE l }
. NOVEMBER 1997 /
Figure 9 :
- Baseload W(Z) at 150 MWD /MTU- -
V. C. Summer . Cycle 11 :
1.30 1.25 1.20 U 1 4 1.15 1 8 .
1 'L O ' % ,,
OA 0 j 44,,4,
A & ,, '
&a*
,,6 O
e g& A g ..g. "
1.05 -j 1,00 l .l
- 0. 1 2 3 .4- 5 6 7 8 9 10 11 12 Core. Height (Feet) 1
~16- - Revision 0 -
i 4
~ __
1.
=
V. C. St.'MMER CYCI.E 11 ! 1 NOVEMBER 1997 SCsao 4
' Table 5 ;
Basaload W(Z)'at 150 MWD $1TU '
- V, C. Summer Cycle 11 Core Height (fi): W(Z)- - Core Heicht (ft) . W(Z) -
0.00 1.0000~ 6.08 1.0660 0.16- 1.0000 6.24 1.0637 0.32 -1.0000- 6.40 1.0613 0.48 1.0000 6.56 1.0586 0.64 -1.0000- 6.72 1.0556 ;
').80 1.0000 6.88 1.0526 C 96 - 1.0000 7.04- 1.0499-1.' 2 1.0000 7.20 1.0481 1.28' l.0000 7.36 1.0480-1.41 z 1.0000 7.52 1.0498 1.60 1.0000 7.68 1.0524 1.76 1.lN2 7.84- 1.0546 1.92 1.1033 8.00 1.0564 2.08- 1.1022 8.16 - 1.0582 2.14 1.1010 8.32 1.0600 2.40 -1.0997: - 8.48 = 1.0618 2.56 1.0982 8.64 1.0635 2.72 1.0%5 8.80 1.0652 2.88 1.0947 8.96 1.0667 3.N 1.0928 9.12 1.0683 3.20 1.0907 9.28 1.0697 3.36 1.0884- 9.44 1.0711 3.52 1.0863 9.60 1.0724 3.68 1.0848 9.76 1.0737
. -3.84 1.0838 9.92 1.0749 4.00 1.0831 10.08 1.0760 4.I6 1.0824 10.24 1.0770-4.32 - 1.0816 -10.40 1.0000
'4.48 1.0808 10.56 1.0000 4.64 1.0798. 10.72- 1.0000 4.80 1.0788- 10.88 1.0000 1.0000 4.96 1.0776 11.04
- 5. I 2 - .1.07 64 11.20- 1.0000-5.28 1.0750 11.36 1.0000 5,44- -1.0735 11.52 ~ 1.0000 5.60 .1.0718 11.68 1.0000 5.76 1.0701- 11.84 1.0000
'5.92- 1.0681 12.00 1.0000 17 Revision 0 m ,- . - n,, e , , m .r-,7
4 V. C. SUMMER CNCL.E 11 NOVEMBER 1997 i SCE40
.i:
Figure 10 '
~
. Baseload W(Z) at 1,100 M%MITU '
. V. C. Summer . Cycle 11 _
T f . '
t 1.30 6
1.25 1.20 E
- 1.15 3
4 44 ,,
1.10 :.'""*a ag 6
,0 g& &.
~ ' &
44
%a,&e O'4 ',a hag &
1.05
.. l'.00 0 1- -2 -3 4 5- 6 7 8 9 10 11 1 Core Height (Feet)
]8 Revisic.n 0 p 8' y * 'J ^ - cm -
V. C. S8/MMrk CYCLE 11 NovtMatn 1997 SCEso Table 6 Ilauload W(Z) at 1,100 blWDAITU V. C. Summer . C3cle 11 l
Core lleicht (f t) W/7) Core lleicht (ft) W(7) 0.00 1.00C0 6 OS 1.0788 0.16 1.00C0 6.24 1.0765 0.32 1.00C0 6.40 1,0741 0.48 1.(XXX) 6.56 1.0713 0.64 1.(XKO 6.72 1.0681 0.80 1.(KKO 6.88 1.0650 0.96 1.0(XO 7.04 1.0629 1.12 1.00(0 7.20 1.0619 1.28 1.(XXO 7.36 10621 1.44 1.(XKO 7.52 1.s640 1.60 1.0000 7.68 1.0665 1.76 1.1l'O 7.84 1.0686 1.92 1.11*/1 8.00 1.0705 2 OS 1.1160 8.16 1.0723 2.24 1.I149 8.32 1.0742 2.43 1.I135 8.48 1.0760 2.56 1.I120 8.64 1.0777 2.*2 1.I1(M 8.80 1.0794 2.88 1.1086 8.96 1.0810 3.04 I.1067 9.I 2 1.0825 3.20 1,i046 9.28 1.0840 336 1.1023 9.44 1.0854 3.52 1.1002 9.60 1.0868 3.68 1.0985 9.76 1.0380 3.84 10973 9.92 1.0893 4'T I0964 10.0S 1.0904
- 4. I 6 I.0956 10.24 1.0915 4.32 1.0948 10.40 1.(XK)0 4.48 1.0939 10.56 1.0(XX) 4 44 1.0930 10.72 1.0000 4.80 1.i)919 10.88 1.0000 4.96 1.0907 11.04 1.0000 5.12 1.0S94 11.20 1.0000 5.28 1.0S80 11.36 1.000D 5.44 1.0865 11.52 1.0006 5 60 1.0848 11.68 1.0000 5.73 1.0S30 11.84 1.00M 5.i 2 1.0S10 1100 1.00C0 19 Revisien 0
V. C. St'MMLR CYCLE 11 NOVEMBER 1997 ECEAG l'igure 11 Itastload W(Z) at 4,000 MWD /MTU Y. C. Summer . Cycle 11 1.30 1.25 2.20 - - -
2
-- 1.15
'.. 10 As. ,A e
g'A
'e& J gd g gae^
b A Ag&
A "A 4 g&A 1.05 4 4' 1.00 0 1 ; 3 4 5 6 7 8 9 10 11 12 Core Height (Feet) a 20 Reusion 0
V. C. SL'MMER CYCLE 11 NOVEMBER 1997 SCE&G Table 7 Itaseload W(Z) at 4,000 51WD/hlTU Y. C. Summer . C3 cle 1I Core Heicht (ft) W(7) Core licirbt (f0 W(Z) 0.00 1.0000 6.0S 1.0654 0.16 1.CXX0 6.24 1.0632 0.32 1.0(X)0 6.40 1.0608 0,48 1.0(XX) 6.56 1.0579 0.64 1.0(XX) 6.72 1.0543 0.80 1.0000 6.88 1.0511 0.96 IfXX0 7.04 1.0511 1.12 1.0000 7.20 1.0522 1.28 1,(XX)0 7.36 1.0536 1.44 1.(XX0 7.52 1.0557 1.60 1.(KXX) 7.68 1.0577 1.76 1.1055 7.84 1.0596 1.92 1.1048 8.00 1.0616 2.08 1.1040 8.16 1.0634 2.24 1.1029 8.32 1.0652 2.40 1.1017 8.48 1.0670 2.56 1.1004 8.64 1.0687 2.72 1.0988 8.80 1.0703 2.88 1.0971 8.96 1.0719 3.04 1.0953 9.12 1.0735 3.20 1.0934 9.28 1.0750 3.36 1.0913 9.44 1.07M 3.52 1.0S91 9.60 1.0778 3 68 1.0870 9.76 1.0791 3.84 1.0851 9.92 1.0S(4 4.00 1.0837 10.08 1.0816
- 4. I 6 1.0S27 10.24 1.0828 4.32 1.0S19 10.40 1.0000 4.48 1.0810 10.56 1.0000 4.64 1.0799 10 72 1.0000 4.80 10788 10.88 1 (XX0 4.96 1.0776 11.04 1.(K00 5.12 1.0763 11.20 1.0000 5.28 1.0748 11.36 1.0000 5.44 1.0733 11.52 1.00(X) 5.60 1.0716 11.6S I.0000 5.76 1.0697 11.84 1.0000 5.92 1.0676 12.00 1.00(X) 2} Reviuen 0 0
V. C. SL'AthtER CYCLE 11 NovthtBER 1997 SCE40 l'igure 12 Itastload W(Z) at 10,000 MWD /MTU V. C. Summer . Cycle 11 1.30 1.21 1 20 Ii
- 1.15 lc
- a "a
g*
1.10 .,
'a,
'"'6 6 , ,,,$aa a3
a'
a.,,**" ,,a 1.05 1,00 0 1 2 3 4 5 6 7 E 9 10 11 12 Core lieight (Feet) 22 Revision 0
V. C. SL'MMr.R CYCLt 11 NovtMDtk 1997 SCE&O Table 8 Ilaseload W(Z) at 10,000 MWD /MTU V. C. Summer . C 3cle 11 Core lleicht (ft) W(7) Core lleicht (ft) W(7) 0.00 1.0000 6.08 1.0581 0.16 1.000() 6.24 1.0558 0.32 1.0000 6.40 1.0531 0.48 1.0(XX) 6.56 1.0514 0.64 1.0000 6.72 1.0519 0.80 1.0000 6.88 1.0538 0.96 1.0000 7.04 .l.0561 1.12 1.0000 7.20 1.0581 1.28 1.0000 7.36 1.0601 1.44 1.0000 7.52 1.0619 1.60 1.0000 7.68 1.0637 1.76 1.1127 7.84 1.0653 1.92 1.1110 8.00 1.0668 2.08 1.1091 8.16 1.0683 2.24 1.1069 8.32 1.0696 2.40 1.1045 8.48 1.0708 2.56 1.1019 8.64 1.0719 2.72 1.0991 8.80 1.0730 2.88 1.0960 8." ^ 1.0739 3.04 1.0928 9.12 1.0748 3.20 1.0893 9.28 1.0757 3.36 1.0858 9.44 1.0765 3.52 1.0S27 9.60 1.0772 3.68 1.0S05 9.76 1.0778 3.84 1.0789 9.92 1.0785 4 00 1.0775 l'O.08 1.0791 4.16 1.0759 10.24 1.0797 4.32 1.0741 10.40 1.0000 4.48 1.0721 10.56 1.0000 4.64 1.0703 10.72 1.0(XX) 4.80 1.0689 10.88 1.0000 4.96 1.0679 11.04 1.0000 5.12 1.0669 11.20 1.0000 5.28 1.0657 11.36 1.0000 5.44 1.0644 11.52 1.0000 5.60 1.0630 11.68 1.0000 5.76 1.0614 11.84 1.0000 5.92 1.0599 12.00 1.0000 23 Revision 0
V. C. SUMMtn CYCLE 11 NovtMatn 1997 SCE&O Figure 13 Itaseload W(Z) at 18,000 MWD /MTU V. C. Summer Cycle 11 1.30 1.25 i
1,;c - . . . - .
2 1.15
'a
& ga 1.10 ,.
a ,e'4 a
a'e 'M d
'A g gg&&&'
'e4 &anha 1.05 1.00 0 1 2 3 4 5 6 7 8 9 10 11 12 Core Height (Feet) 24 Reusion 0
V. C. SUMMtk CYCLE 11 NOVEMf1ER 1997 sceso Tali!c 9 11aseload W(Z) at 18,000 51WD/hlTU Y. C. Sumrr.er . Cgle 11 Core lleicht (fo W(7) Core fleicht (f0 W(Z) 0.00 1.(K(X) 6.08 1.0588 0.16 1.0000 6.24 1.0597 0.32 1.0000 6 40 1.0619 0.48 1.0000 6 56 1.0644 0.64 1.0000 6.72 1.0665 0.80 1.(KKX) 6.88 1.0683 0.96 1.0000 7.04 1.0698 1.I 2 I.0000 7.20 1.0712 1.28 1.0000 7.36 1.0724 1.44 1.00CX) 7.52 1.0734 1.60 1.(KKX) 7.68 1.0743 1.76 1.13N 7.84 1.0750 1.92 1.1269 8.00 1.0755 2.08 1.1230 8.16 1.0757 2.24 1.I188 8.32 1.0757 2.40 1.I142 8.48 1.0764 2.56 1.1093 8.64 1.0785 2.72 1.1041 8.80 1.0814 2.88 1.0984 8.96 1.0851 3.04 1.0923 9.12 1.0890 3.20 1.0870 9.28 1.0927 3,36 1.0834 9.44 1.0962 3.52 1.0809 9.60 1.0994 3.68 1.0790 9.76 1.1024 3.84 1.0773 9.92 1.1052 4.00 1.0756 10.08 1.1078 4.16 1.0737 10.24 1.1101 4.32 1.0717 10 40 1.0000 4.48 1.0696 10.56 1.0000 4.64 1.0675 10.72 1.0000 4 SO 1.0654 10.88 1.0000 4.96 I.0636 11.04 1.0000 5.I 2 1.0623 11.20 1.0000 5.28 1.0615 11.36 1.0000 5.44 1.0607 l 1.52 1.0000 5 60 1.0595 11.68 1.0000 5.76 I.0584 11.84 1.0000 5 92 1.05S3 12.00 1.0000 25 Reusion 0
~%, , ,
.c V. C. SththtER CYCLE I1 NOVDIBER 1997 Sceae (
rigure 14 RCS Total Flow Rate is. R for Three I,oop Operation :
V. C. Summer . Cycle 11
't hieasuremen! Unces taintles of 2.1% for flow (includes 0.1% for feedsater ienturi fouling) and ,
10% for Intere hiesturement of !% are included in this figure.
i 28.9 ,
28.7 1
ACCEPTABLE UhACCEPTAIC C I OP(RAfl0NRIGION 1 .l l OPERA 110N REQlON J 1
C 28.5 0 . .
I (100, il N1 i 28.3 28.1 27.9 27.7 0.90 0.95 1.00 1.05 1,10 FI a FNAH 11.56[1.0 + 0.3(1.0 P)]
4
.26 Reusen0
. . _ . - . .,.-,..-...~._.,.;...._-. __.. . . . - . - - , _ - _ ~ _ _ - . - - _ _ _ . ...-.-.._-__;-_.__.-