callaway plant, unit 1, revision ol-23 to final safety
TRANSCRIPT
GUIDE THIMBLE
0
FUEL ASSEMBLY WITH ROD CONTROL CLUSTER
0 0 0
0 0 0
@ 0 e
0 0
_JL.oso TYP IFM GRIDS
CONTROL CLUSTER ELEMENT
FUEL ROD (264 PER FUEL ASSEMBLY) OD = .360 CLAD THICKNESS = .0225 CLAD MATERIAL = ZIRC-4/ZIRLO
0
11.973 FUEL ASSEMBLY AND RCCA PITCH
8.455 TYP
INSTRUMENTATION TUBE
FUEL ASSEMBLY WITHOUT ROD CLUSTER CONTROL
A. GUIDE THIMBLE DIMENSIONS AT TOP NOZZLE .ADAPTOR PLATE
CALLAWAY PLANT
DI~ENSIONS ARE IN INCHES (NOMINAL) FIGURE 4.2-1
FUEL ASSEMBLY CROSS SECTION 17 X 17 VANTAGE 5N+
REV. OL-9 5/97
SHEET 1
C()fjTROL !304 SST)
..xu.Jl.. tl auaeot
8.386 TYP (UPDATED IFM)
8.372 TYP (IFM)
-11--1-+- .0~3 ( INCONEL) .053 (Z.IRC)
.0105 l>l~IDE STil.v>~ ("'coNE\) .o•So '"""oE STRAPS !ZIRC)
SEE VIEW A
0 0 0
.048 (INCC~aP
.035(ZIRC)
0 0
0 0
0 0
00
0000000 00000
ooo 00
0 00 0
0 0
0 0
00· .474 ID- .442
8.466 TYP
FUEL&CONTROL ROO CROSS SEC'!'ION MA TDIAL· ZIRC-4 OR ZIRLO
CALLAWAY PLANT
FIGURE 4.2-1
FUEL ASSEMBLY CROSS SECTION 17 X 17 VANTAGE 5N+
REV. OL-9 5/97
SHEET2
7.162 TYP ll£F
0.!!7S , 'TYP ll£F
.578 • RET
BOTTOM VIEW (TYP)
I 159.975
, .. ~ 1- lr---1· ---152.25---
1-.4~5 A.l'oi1-J)
122.67 LJ, L . .t U50 L L L (GRIDS 2-7)
133.8.3 113.28 92.73 72.16 51.63 31.0!! 6.00 ~
17X17 VANTAGE 5 FUEL ASSEMBLY
!------------------- 15~.975 -----------------~
17X17 VANTAGE 5 UPDATE FUEL ASSEMBLY
(a) Gopm!uced&am 1.10incbcstoO.o46Sin<:bco.
DIMENSlONS AAE IN INCHES (NOMINAl..)
!51.27 30.72
CALLAWAY PLANT
REV. OL-7 5/94
FUEL ASSEMBLY OUTLINE
17x17 VANTAGE 5 FIGURE 4.2-2
(. 621) ~ TYP
(3. 475)
cs.404l sa
(7. 162) TYP • -~1
• 875 DIA TYP \
·---~-- (0 . 580)
(159.975)
(152.490) FUEL ROD LENGTH
" "" m ...... 1
( 6. 750)
TYI
L~ ~ 875 O!A TYP ------ J
~ (5. 835)
CALLAWAY PLANT
17Xl7 VANTAGE+ FUEL ASSEMBLY
(ZIRLO) FIGURE 4. 2-28
. ~ - ~--~(2. 383)
REV OL-11 5/00
f---------- ( L.,2.8 F,EL LENC~TH) ---------4~---4--
CALLAWAY PLANT
FIGURE 4.2-2C
17X17 PERFORMANCE+ FUEL ASSEMBLY
REV. 14 5/12
152.285
FUEL ROD LENGTH
7.525
PLENUM
144.00
- FUEL STACK LENGTH
SEAL WELD
ZR-4 TOP END PWO (-J...l----1/
GIRTH WELD
• 3 6 0 NOMINAL (.368 MAX)
SPRING STAINLESS STEEL
U0 2 PELLET
PELLET -CLAD GAP
nr~:-'-jp, ___ ZIRCALOY CLAD
.0225 NOMINAL WALL THICKNESS (.0207 MINIMUM WALL)
1'------'t---- GIRTH WELD
~="" • >--1---- BOTIOM END PLUG ILLUSTRATES
-'-------------- ~:~ INTERNAL GRIP CONNECTION
17x17 VANTAGE 5 UPDATE FUEL ROD ASSEMBLY
SPECIFIC DIMENSIONS DEPEND ON DESIGN VARIABLE SUCH AS PREPRESSURIZATION, POWER HISTORY, AND DISCHARGE BURN UP (SEE ALSO FIGURES 4.2-38 AND 4.2-3C)
OIIAEHSIONS AAE IN INCHES (N01.41NAL)
CALLAWAY PLANT
REV. OL-13 05/03
FUEL ROD SCHEMATIC
FIGURE 4.2-3
. 3685 MAX WELD DIA.
TOP END PLUG
VARIABLE PITCH STAINLESS STEEL SPRING
ZIRLO TUGE (. 350) OD (. 0207) MIN WALL
URANIUM DIOXIDE PELLETS
ZR-4 BOTTOM END PLUG
. 3685 MAX WELD DIA.
1~----(7.730) -------1--------- ( 144. 00) FUEL--------' COLUMN LENGTH
~-------------------(152.490)------------------1
REV OL-13 05/03
CALLAWAY PLANT
17Xl7 VANTAGE+ FUEL ROD
ZIRLO™ FIGURE 4. 2-3A
GRID STRAP
" EXPANSION DIAMETER
ZIRCALOY OR ZIRLO SLEEVE
ZIRCALOY OR ZIRLO THI~1BLE
FUEL ROD
EXPANSION LOBE
IFM AND MID GRID EXPANSION JOINT DESIGN
REV. OL-9 5/97
CALLAWAY PLANT
PLAN VIEW
FIGURE 4.2-4
GUIDE THIMBLE TUBE -----n
IFM GRID ---1
EXPANSION LOBE --~
GUIDE THIMBLE TUBE-----+,
MID GRID
MID GRID SLEEVE ---+N
EXPANSION LOBE ---«t
DIMENSIONS ARE IN INCHES (NOMINAL)
WELD
WELD
MIXING VANE
.475
MIXING VANE
t
2 .. 250
!
CALLAWAY PLANT
REV. OL-5 6/91
GRID TO THIMBLE ATIACHMENT JOINTS
FIGURE 4.2-5
LOCK TUBE
UNASSEMBLED
SECTION E-E
(TYPICAL)
I
I I
I I
I D I
' I
--+--
ASSEMBLED
REV. OL-5 6/91
CALLAWAY PLANT
THIMBLE/INSERT /TOP GRID SLEEVE BULGE JOINT GEOMETRY
FIGURE 4.2-6
CR04
RCC ASSEMLY INSERTED
DRIVE ROO ASSEMLY
Fll.L LfHG TH ACC ASSEMLY
WIDE TUBE ASSEMB..Y
FUEL ASSEMB.. Y
CALLAWAY PLANT
FIGURE 4.2-8
ROD CLUSTER
Rev. OL-0 6/86
CONTROL AND DRIVE ROD ASSEMBLY WITH INTERFACING COMPONENTS
160.949
I_ 1.845 MAX
SPIDER BODY
-
150.574
80% SILVER 15% INDIUM 5% CADMIUM
CALLAWAY PLANT
RCCA OUTLINE FULL -LENGTH
FIGURE 4. 2 - 9 .J
TOP END PLUG
TYPE 304 STAINLESS STEEL TUBE WITH CHROME PLATING Ag-ln-Cd
BOTTOM END PLUG
.381 DIA NOM
~--------- 142.00 -----------J
ABSORBER MATERIAL
151.885
REV. QL.,...5 6/91
CALLAWAY PLANT
ABSORBER ROD
FIGURE 4.2-10
l[] (() l[]
014-A-20766-163
I f-
"(0 LL.z ww a:_j
Oz ·o
N(f) "<!-,__. -o
Q_
(f) (0 z ...... a: Q_ (f)
(f) (f) Q(f) a:<x: Q_j (]](0
~~ or:n -otl.l NC) as: "<!-~ N<I:J "<!- ....... ·0
0
I
CALLAWAY PLANT
FIGURE 4.2-11 BURNABLE ABSORBER
ASSEMBLY 17X17
REV. OL-7 5/94
014-A-20766-164
0 lJl r0
N lJl
X <
lll:L ffi· 10< ..... 00
~ C) :) _j D..
0 z w
<
L I~
_j ~ ::;: 0 f-f--0 !Il w
~ ......
u .... _j .... UJUJ OUJ 0::< O_j !I] C)
~I
C) :) _j D..
0
~ I D.. 0 f--
~r--.
C) z w _j
z 0 Ul .... 0 D..
u... w a: 0 0
N ~
_j
lll· I'll.. mw
·0:: 0
I f-(9 z w _j
w !Il :) f--
u... w a: m 0
0 lJl
Ul Ul < _j C)
w f-< u .... _j .... Ul 0 a: 0 !Il
_j w w f-Ul
Ul Ul w _j z .... < f-Ul
<1: I
<1:
z 0
1-u w (f)
CALLAWAY PLANT
FIGURE 4.2-12 BURNABLE ABSORBER ROD
CROSS SECTION 17X17
Rev. OL-1 6/87
150.0 TYPICAL
ANNULAR PLENUM
* 134.0 TYPICAL
ABSORBER LENGTH
r A
Note: See Figure 4.2-15A for new spring design.
* 132.0 inches in Current feed assemblies
014-A-20766-165
FLOW PATH
l 11...---UPPER END
PLUG
+ A
FLOW PATH
ZIRCALOY TUBES
A lz03-B4C ANNULAR PELLETS
SECTION A-A
CALLAWAY PLANT
ZIRCALOY
REV OL-13 05/03
FIGURE 4.2-12a BURNABLE ABSORBER ROD
CROSS-SECTION (ALUMINUM OXIDE BORON CARBIDE ABSORBER)
1 ~ ~ ~ ~ \®--a I I 1-.-:La: ow zu lf14:
0.. NUl t<)
:;i; 1---I I •;:::J I I :;:i;H
0~ zo I LOt>.! f-•H (!)
r-IH z ~ w u '--- ..J
I I I z I 0 I (f)
...... 0 0..
('f) LL... Lf) w . a: r-1 Lf) I I I N r-1 <t
I - I
I I I
I
-L-
I I I
I I
~ ~ I I I~ ~
YYY:
I -==-' e-c= .r::..
~~aa I I I I
I I I I
(f) w I u z ......
I I I z ......
I w a: 4:
(Jl z 0 H (Jl
I I I z w
I :L ...... 0
..J
..J <{
.. I I I w
f-0
I z
I I I
I
~ I I I
/L) I I
~~yy (f) (!) z ..... a: 0.. (Jl
,......__
"" ~
(f) (f) w ..J Z..J ...... w 4:W f-f(f)(J)
:L :::) H
z a: 0 LL...
w ..JZ aJO <{(f) z,..... a:o :)D.. (I)
REV. OL-7 5/94
NOTE: See Figure 4.2-lSA CALLAVVAYPLANT for new spring design~------------~-------------------------1
014-A-20766-166
FIGURE4.2-13 PRIMARY SOURCE ASSEMBLY
17X17
NOTE: See Figure 4.2-15A for new spring design
014-A-20766-167
tL W::J u ..... O::_J ::J_j 0>-(flO:
0 w . >-aJ roo: (!)<(>-
oz zo OL u-WI-UlZ
l<(
(f) w I u z
z .... w 0::: <(
(f) !() z 0
0 !() (f) - z w
L .... 0
__) _j <(
-w 1-0 z
0 N
W I
...Jcn >a:l;:~ 1-L...J ;::
~a_ ~ ::J 0
CALLAWAY PLANT
FIGURE 4.2-14 SECONDARY SOURCE ASSEMBLY
17X17
REV. OL-7 5/94
"Y" Corner Orientation
I. (0.426 Dia)
DOUSLE ENCAPSULATED SE::CONDAAY SD~CE ROD
I
THIMBLE PLUG
Spring lnconel 718
I~
11-: -----"'- 88.00 Antimony-Beryllium
l:l
1-----6.345 ---t
1-----------151.553-----------1
CALLAWAY PLANT
REV OL-11 5/00
FIGURE 4.2-14A ENCAPSULATED SECONDARY
SOURCE ASSEMBLY 17X17
0.432 (STD ONLY) 0 . 4 2 4 (OLD DESIGN) 0.426 (NEW DESIGN)
NOTE: See Figure 4.2-15A for new spring design
014-A-20766-168
7. 94 (OLD DESIGN) 6.345(NEW DESIGN)
CALLAWAY PLANT
FIGURE 4.2-15 THIMBLE PLUG ASSEMBLY
REV. OL-9 5/97
I I I
I I I : I !
I I
I' I I
i. I :.. w
Previous
17 X 17
Pinned & Welded Nuts
I I
i I
I I
I ! I I
! I u . !
New
Hold down Assembly Updates - 17 x 17
REV. OL-5 6/91
CALLAWAY PLANT
MODIFIED SPRING DESIGN
FIGURE 4.2-15A
goo
014-A-20766-169
R P N M L K J G F E 0 C B A
FIRST CORE
D REGION
~ REGION 2
~ REGION 3
CALLAWAY PLANT
FIGURE 4.3-1
2
3
4
5
--6
--7
--8 270°
--9
--10
--II
12
13
14-
15
Rev. Ol-1 6/87
FUEL LOADING ARRANGEMENT
9
8
::> 7 ~ -en ::.:::
(I) 6 UJ I:L 0 1-0
5 (I)
~---0::: UJ ;' :X: / (.!:)
~ :X: / Pu239 u...
/ 0
z:: 3 0
I 1-u ::>
I 0 0 2 0::: I:L
I
0
BURN UP
0
-~
-8 ~· -en ::.:::
-12 (I) UJ I:L 0 --- 1-0
-16 (I)
....J UJ ::>
-20 u... u... 0
z:: 0
-2~ -1-I:L ~ ::> (I)
z:: -28 0
u
-32
-36 ~0
CALLAWAY PLANT
FIGURE 4.3-2
Rev. Ol-0 6/86
PRODUCTION AND CONSUMPTION OF HIGHER ISOTOPES
2000 r-----------------------------------------------~
1600 l.._
................ ........
1200
800
400
NOTE: HOT, FULL POWER, RODS OUT
'-, JWITHOUT BURNABLE " ABSORBERS
........ ........
........ ........
........ ........
' ' ' ' ' ' 0 ~----~----~----~----~----~----~----~~--~~~
0
014-A-20766-170
4000 8000 12,000 16,000
CORE AVERAGE BURNUP (MWO/MTU)
CALLAWAY PLANT
FIGURE 4.3.3A
Rev. OL-1 6/87
BORON CONCENTRATION VERSUS FIRST CYCLE BU RNUP WITH AND WITHOUT
BURNABLE ABSORBER RODS
!XI !XI
!XI D !XI !XI
!XI D !XI !XI
DIXI !XI D D !XI
!XI D DIXI
014-A-20766-171
!XI !XI !XI !XI !XI D !XI !XI
!XI D r;R1 !XI D !XI D !XI
!XI !XI D !XI !XI D !XI D !XI !XI D !XI D !XI
!XI !XI !XI !XI !XI D !XI !XI
20 BA'S CORE CENTER
16 BA'S
D IXID !XI !XI [g1 IXID !XI D !XI !XI D !XI D D
!XI D !XI !XI D D !XI D !XI !XI D D D D
D IXID Do D Do
12 BA'S CORE CENTER
9 BA'S
!XI !XI
!XI D
!XI D
D D Do
t !XI !XI !XI
!XI D !XI
D !XI
D D D D oo
10 BA'S
CALLAWAY PLANT
FIGURE 4.3·4A
Rev. Ol·1 6/B7
BURNABLE ABSORBER ROD ARRANGEMENT WITHIN AN ASSEMBLY
180° R P N M L K J H G F E D C B A
I I I I I I I 10 10 10
9 12 20 19 12 9 IS
9 20 16 16 16 20 9
20 20 4S 16 16 20 20
12 20 16 16 16 20 12 --10 16 16 20 20 16 16 10 --
20 16 20 20 20 16 20 --10 16 16 20 20 16 16 10 --
20 16 20 20 20 16 20 --10 16 16 20 20 16 16 10 --
12 20 16 16 16 20 12 --
20 20 16 16 4S 20 20
9 20 16 16 16 20 9
9 12 20 19 12 9 IS
10 10 10
NUMBER INDICATES NUMBER OF BURNABLE ABSORBER RODS
IS INDICATES PRIMARY SOURCE ROD
4S INDICATES FOUR SECONDARY SOURCE RODS
2
3
4
5
6
7
8 270°
9
10
I I
12
13
14
15
REV OL-13 05/03
014-A-20766-172
CALLAWAY PLANT
FIGURE 4.3-5 A TYPICAL BURNABLE ABSORBER LOADING
PATTERN (CYCLE 1)
ct_l H G F E D C B A ct_ I
- I . 06 f--f- - --- -f--f- -f--f- -f--f- -f--f-
8~~ I I
9 I .00
I I 0 I. 12
I
I I
I I I. 15 I
I I
12 I .21 I
I I
13 I. 12 I
I I
14 I .03
I I
15 0. 72
0 14-A-20766-173
GDDDDDD GBDDDDD BBBDDDD BBBBDD BGGEJBD B 10.99110.991 EJ B BBEJ
CALCULATED F~H = I . 35
KEY: VALUE REPRESENTS ASSEMBLY RELATIVE POWER
CALLAWAY PLANT
FIGURE 4.3-6A
REVOL-13 05/03
TYPICAL NORMALIZED POWER DENSITY DISTRIBUTION NEAR BEGINNING-OF-LIFE,
UNRODDED CORE, HOT FULL POWER, NO XENON (CYCLE 1)
ct_ I H G F E 0 c B A ct_ I
- 1.09--8 I
--- -1--r-
I I
9 1.02
I I
I 0 I. 15 I
I I I I. 16
I 12 I .22
I I
13 I. 12
l 14 I .02
I I
15 0. 71
014-A-20766-174
BDDDDDD GBDDDDD BBBDDDD BBGDDD BGGBBD BBEJEJB EJE]EJ
CALCULATED F~H = I . 34
KEY: VALUE REPRESENTS ASSEMBLY RELATIVE POWER
CALLAWAY PLANT
FIGURE 4.3-7 A
REV OL-13 05/03
TYPICAL NORMALIZED POWER DENSITY DISTRIBUTION NEAR BEGINNING-OF-LIFE, UNRODDED CORE, HOT
FULL POWER, EQUILIBRIUM XENON (CYCLE 1)
ct_ I H G F E 0 c B A ct_ I
- l.oo---8 I
-r---1- -r---1- -1-- --I I
9 1.00 I
I I
10 I. 15 I
I I
J J I. 18 I
I I
I 2 I .25 I
I I
I 3 I. 13 I
I 14 0.95
I
I 15 0.69
014-A-20766-175
GDDDDDD GGDDDDD GBBDDDD BGGGDD BBBBBD BGGEJB BBB
CALCULATED F~H I .33
KEY: VALUE REPRESENTS ASSEMBLY RELATIVE POWER
CALLAWAY PLANT
FIGURE 4.3-8 A
REV OL-13 05/03
TYPICAL NORMALIZED POWER DENSITY DISTRIBUTION NEAR BEGINNING-OF-LIFE, GROUP D AT 28 PERCENT INSERTED, HOT FULL POWER, EQUILIBRIUM XENON
(CYCLE 1)
~I H G F E 0 c B A
~ I
- 1.15-1- -f--r- -f--r- -- -- --8 I
I I
9 I. 18 I
I I
I 0 I. 15 I
I I
I I I .21 I
I I
12 I. 13 I
I I
13 I. 14 I
I
BDDDDDD BBDDDDD BGBDDDD BBBGDD GBGEJBD
14 0.97 G 10.94110.961 EJ B I
I 5 0. 70 I 0. 731 I 0. 651 I 0. 541
~ CALCULATED F~H = I . 29
014-A-20766-176
KEY: VALUE REPRESENTS ASSEMBLY RELATIVE POWER
CALLAWAY PLANT
FIGURE 4.3-9A
REV OL-13 05/03
TYPICAL NORMALIZED POWER DENSITY DISTRIBUTION NEAR MIDDLE-OF-LIFE, UNRODDED CORE, HOT FULL
POWER, EQUILIBRIUM XENON (CYCLE 1)
ct_ I H G F E D c B A ct_ I
-1.05--8 I
-1--~ -1--t- -1--~ -~~ --- ---
I I
9 I. II
I I
I 0 I .05
I I
I I I. 12
I I
12 I .06
I I
13 I. 13
l 14 I .01
_l
l I
15 0.80
014-A-20766-177
BDDDDDD BBDDDDD BBGDDDD BGBBDD BBBGBD BEJGBB EJBB
CALCULATED F~H = I . 25
KEY: VALUE REPRESENTS ASSEMBLY RELATIVE POWER
CALLAWAY PLANT
FIGURE 4.3-10A
REV OL-13 05/03
TYPICAL NORMALIZED POWER DENSITY DISTRIBUTION NEAR END-OF-LIFE, UNRODDED CORE, HOT FULL
POWER, EQUILIBRIUM XENON (CYCLE 1)
ct_ I H G F E 0 c B A ct_ I
- 0.92f--~
8 I
-f--f- f--f- --- --- ---I I
9 I .08 I
I I
I 0 I .06 I
I I
I I I. 15 I
I I
12 I .09 I
I I
13 I. 17 I
I I
14 I .04 I
I I
15 0.82
0 14-A-20766-178
BDDDDDD BGDDDDD GBBDDDD BGBBDD BBBBEJD BBBBEJ EJBEJ
CALCULATED F~H = I . 25
KEY: VALUE REPRESENTS ASSEMBLY RELATIVE POWER
CALLAWAY PLANT
FIGURE 4.3-11 A
REV OL-13 05/03
TYPICAL NORMALIZED POWER DENSITY DISTRIBUTION NEAR END-OF-LIFE, GROUP D 28 PERCENT INSERTED,
HOT FULL POWER, EQUILIBRIUM XENON (CYCLE 1)
--- --------
r---
I. 02
1.02 I. 03
1.02 1.05 1.08
1.02 1.06 I. 12 ~ 1.03 I. 08 I. 14- I. 17 I. 16
1.03 I. 10 ~ I. 17 I. 18 X 1.03 1.08 I. 14- I. 14- I. 16 I. 18 I. 17
1.03 1.08 I. 14- 1. 14- 1. 16 I. 19 I. 17
1.03 I. 10 X I. 16 I. 18 X I. 19
1.03 1.09 I. 14- I. 14- I. 16 I. 19 I. 17
1.03 1.09 I. 15 I. 15 I. 16 I. 19 I. 17
I. 04- I. I I ~ I. 18 I. 18 X I. 19
I. 04- I. 09 I. 15 I. 18 I. 17 I. 19 I. 17
1.04- I. 08 I. 14- X I. 18 I. 18 I. 16
1.04- 1.06 I. 10 I. 14- I. 16 ~ I. 16
1.04- I. 05 1.07 1.08 I. 10 I. 12 1. 10
I. 04- I. 04- 1.04- I • 04- I. 05 I. 05 I. 05
I. 17
I. 20 >< I. 17 I. 20
I. 17 I. 20
I. 19 X I. 17 I. 19
I. 16 I. 18
I. 16 ~ I. 10 I. 12
I. 05 I. 05
I. 18
I. 18 I. 18
I. 20 I. 20 X I. 17 I. 17 I. 20 I. 18
I. 16 I. 16 I. 19 I. 19 ~ I. 16 I. 16 X I. 17 I. 15 I. I I
I. I 0 I. I I I. 12 I • I I I. 09 I. 08 1.07
I. 05 I. 05 I. 06 I. 06 1.06 1.06 I. 06
CALLAWAY PLANT
FIGURE 4.3-12
6274--6
1.06j
Rev. OL-0 6/86
RODWISE POWER DISTRIBUTION IN A TYPICAL ASSEMBLY NEAR BEGINNING
OF-LIFE, HOT FULL POWER, EQUILIBRIUM XENON; UNRODDED CORE
-0.98
0.98 0.99
0.98 1.00 1.03
0.99 1.02 I. 07 X 1.00 1.03 1.09 I. II 1.09
1.0 I 1.06 C>< I. II I. II
1.00 1.0~ 1.08 1.07 1.08
1.00 1.0~ 1.08 1.07 I. 08
1.0 I 1.06 C>< 1.09 I. 10
1.00 1.0~ 1.08 1.07 1.08
1.00 1.0~ 1.08 1.07 I. 08
1.0 I 1.06 C>< I. II I. II
1.00 1.03 1.09 I. II 1.09
0.99 1.02 1.07 C>< I. II 0.98 1.00 1.03 1.07 1.09
0.98 0.99 1.00 1.02 1.03
0.98 0.98 0.98 0.99 1.00
C>< I. 10 I. 08
1.10 1.08 1.08
X I. 10 I. 10 ~ I. 10 I. 08 1.08 I. 10
I. 10 I. 08 1.08 I. 10
X I. 10 I. 10 C>< I. II I. 08 1.08 I. I 0
I. II I. 07 I .07 I. 09
C>< I. 08 I. 08 C>< I. 06 1.0~ I. 0~ I. 06
I. 0 I 1.00 I. 00 I. 0 I
1.08
1.08
I. 10
I. 08
1.07
1.08
I. Ol+
I. 00
I. 08
I. 10 >< 1.08 I. II I. 09
I. 07 I. II I. II C>< 1.08 C>< 1.09 1.07 1.03
1.0~ 1.06 1.03 1.02 1.00 0.98
I. 00 I. 0 I 1.00 0.99 0.98 0.98
CALLAWAY PLANT
FIGURE 4.3-13
627~-7
0. 981
Rev. OL-0 6/86
RODWISE POWER DISTRIBUTION IN A TYPICAL ASSEMBLY NEAR END-OFLIFE, HOT FULL POWER, EQUILIBRIUM
XENON;UNRODDEDCORE
0::: w 3:: 0 a...
a w N
_j
<(
::::E 0::: 0 z:
13,557-17
2.Qr--------------------------------------------------,
I. 5
1.0
0.5
0.0 0 0.1
p =
D =
AO =
0.2
r = I .c ,,
= ) . I C'
AO = -8. t I
P = NORMALIZED POWER
D = FRACTIONAL INSERTION OF BANK D
AO = AXIAL OFFSET (PERCENT)
0.3 0.4 0.5 0.6 0.7
p = 0. 5
D = 0. I
;,() = 5.91
0.8 0.9 1.0
FRACTION OF ACTIVE CORE HEIGHT FROM BOTTOM
CALLAWAY PLANT
FIGURE 4.3-14
REV OL-13 05/03
TYPICAL AXIAL POWER SHAPES OCCURRING AT BEGINNING-OF-LIFE
(CYCLE 1)
0:::: LJ..I 3:: 0 0..
0 I..L.I N
_J <(
:::E 0:::: 0 z:
13,557-18
2.0 .---------------------------------------------------~
p :::: 0. 5
D ::: 0. 55
AO = -26.03 p 0. 5
I. 5 o 0.21 AO ::: 8. 20
1.0
P NORMALIZED POWER D FRACTIONAL INSERTION OF BANK D
AO AXIAL OFFSET (PERCENT)
0.5
0.0 ~--~----~----~----~--~----~----._--~----~--~ 0.0 0.1 0.2 0.3 0.~ 0.5 0.6 0.7 0.8 0.9 I. 0
FRACTION OF ACTIVE CORE HEIGHT FROM BOTTOM
CALLAWAY PLANT
FIGURE 4.3-15
REV OL-13 05/03
TYPICAL AXIAL POWER SHAPES OCCURRING AT MIDDLE-OF-LIFE
(CYCLE 1)
0:: LLJ
~ Cl..
0
13.557-19
2.0 ~------------------------------------------------------~
I .5
p = 0. 5
D = 0.62
A0=-25.7
0.5
0.61
6.59
~ 1.0 ...J <t :::::E: 0::: 0 z:
0.5
P = NORMALIZED POWER
D = FRACTIONAL INSERTION OF BANK D
AO = AXIAL OFFSET (PERCENT)
0.0 ~----~--~~--~----~----~----~----~----~----~--~ 0 0. I 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 I. 0
FRACTION OF ACTIVE CORE HEIGHT FROM BOTTOM
CALLAWAY PLANT
FIGURE 4.3-16
REV OL-13 05/03
TYPICAL AXIAL POWER SHAPES
OCCURRING AT END-OF-LIFE (CYCLE 1)
I. 5
I .0
0::: w ~ 0 0....
w > f-<l: _J
w 0:::
_J
<l:
>< <l: 0.5
0.0
CORE BOTTOM
CORE AVfRAGE
ADJACENI TO D BANK
REMOVED FROM D BANK
PERIPHEqAL LOW POWER ASSEMBLY
CORE HEIGHT CORE TOP
CALLAWAY PLANT
Rev. OL-0 6/86
FIGURE 4.3-17 COMPARISON OF A TYPICAL ASSEMBLY
AXIAL POWER DISTRIBUTION WITH CORE AVERAGE AXIAL DISTRIBUTION
BANK D SLIGHTLY INSERTED
~ w s: 0 0..
>< N" 0 u.
>< < ::!!
2.6 .--------------------,-----------------------------------------,
2.4
2.2
2
1.8
1.6
1.4
1.2 ~
0.0
Fq Ht. (ft) 2.50 0.0 2.50 6.0 2.31 12.0
2.0 4.0 6.0
CORE HEIGHT (FT)
8.0 10.0 12.0
CALLAWAY PLANT
FIGURE 4.3-21
HAXIMUM FoX POWER VERSUS AXIAL HEIGHT DURING NORMAL
OPERATION REV. 14 10/09
0::: w 3
20.0
l5. 0
2i: 10.0 0::: ex: w z ....... _J
:..! ex: w 0...
5.0
0.0 -50.0
0 c.Pcfj ~ CD o --ooo o
0
-25.0 0.0
8555-74-
25.0 50.0
FLUX DIFFERENCE (~I)
CALLAWAY PLANT
FIGURE 4.3-22
Rev. OL-0 6/86
PEAK LINEAR POWER DURING CONTROL ROD MALFUNCTION
OVERPOWER TRANSIENTS
........ 1-1..1... -~ .........
0:: LIJ 3 0 c.. 0:: <( LIJ z: -....J
:.::: <( LIJ c..
20.0
15.0
10.0
5.0
0.0 -50.0 -25.0
8555-75
0.0 25.0 50.0
FLUX DIFFERENCE (61)
CALLAWAY PLANT
FIGURE 4.3-23
Rev. OL-0 6/86
PEAK LINEAR POWER DURING BORATION/DILUTION OVERPOWER
TRANSIENTS
0.759 0.792
4.3''
0~ 774 I. 255 0.800 I. 249
3.4% -0. 5;:{
I. 229 I. 225 -0, 3'c
I. 109 I. 077 I. 107 1.092
-0.2/c· I. 4'1,
I. 202 I. 223 I. 170 I. 256 -2.7fc 2. 7'/;
0.523 1. 217 I. 221 o. 548 I. 203 I. 233
4.6% I. I% t.or,
'· 229 I. 189 -3. 3~
I. 217 I. 224 0. 6'
I. 217 I. 211 -0.5;:
I. 229 I. 218 -0.9'1
I. 229 I. 220 -0.7%
-F z
~H :
FN Q
I. 217 I. 210 -0.6;~
~ CALCULATED ...___ MEASURED ~DIFFERENCE
PEAKING FACTORS 1.5
1.357
2.07
REVOL-13 05/03
CALLAWAY PLANT
FIGURE 4.3-24
COMPARISON BETWEEN TYPICAL CALCULATED AND MEASURED RELATIVE FUEL ASSEMBLY
POWER DISTRIBUTION
a:: UJ 3: 0
1.4-
1.2
1.0
::. 0.8 > I-< ....J UJ a:: ....J < >< <
0.6
0.4-
0.2
0 BOTTOM
10 20 30 4-0 50
CORE AVERAGE FROM INCORE MAP
AO = 2% ------
60 70
BOL NO XENON POWER AT 70% BANK D 25% INSERTED
80 90 100 PERCENT OF CORE HEIGHT TOP Rev. OL-0
6/86
CALLAWAY PLANT
FIGURE 4.3-25
COMPARISON OF TYPICAL CALCULATED AND MEASURED AXIAL SHAPES
X REACTOR I 0 REACTOR ~ V REACTOR 2 • REACTOR 5
0 FQ
e REACTOR 3
0
0 3.0
• 0
• • \1 2.5
\1 \7;< o• • X
0 \1 0 • • X \1 X X •
•o• • X ~X X • ii. • xx ~ ~
0 X • • 0 0 \1 'V5l_C>. 0
• 0 ~ oo
• •• 8 ~f
• ~~ 0
Olo 0 <c. 9
~ •• 0~ X
1.5 ,e
I ·r ·~ -50 -~5 -~ -35 -30 -25 -20 -15 -10 -5 0 5 10 15 20 25 30
INCO~E AXIAL OFFSET (%) Rev. OL-0 6/86
CALLAWAY PLANT
FIGURE 4.3-26
MEASURED VALUES OF FQ FOR FULL POWER ROD CONFIGURATIONS
u... 0 -::::E <..:> c...
'+'+<V
1-'1:> -a. '1:>
~
1-z: UJ
<..:>
u... u... UJ 0 <..:>
UJ 0::: ::::> I<( 0::: UJ a.. ::::E UJ I-
0::: UJ ....I a.. a.. 0 Cl
-I.~
-I. 6
-I. 8
-2.0
-2.2
-2.~
-2.6 500
13,557-20
600 700 800 900 I 000 II 00 1200
EFFECTIVE FUEL TEMPERATURE Teff (°F)
CALLAWAY PLANT
FIGURE 4.3-27
Rev. OL-0 6/86
TYPICAL DOPPLER TEMPERATURE COEFFICIENT AT BOL AND EOL,
CYCLE 1
f-z: LJ..J---- 0::: (..) LJ..J -~ u... 0 u... 0... LJ..J 0 f-(..) z:
LJ..J 0::: (..)
LJ..J 0::: ~LJ..J 0 0... o....-
::::E >- (..) --' 0.... z:-0
0. 0::: ~ LJ..J-_J 0. 0.... 't:> 0.... 0 0
-10
-12
-1~
-16 0
13.557-21
20 ~0 60 80 I 00
POWER LEVEL (PERCENT OF FULL POWER)
CALLAWAY PLANT
FIGURE 4.3-28
Rev. OL-0 6/86
TYPICAL DOPPLER-ONLY POWER COEFFICIENT AT BOL AND EOL,
CYCLE 1
0
:::E (..) 0...
0. -500
. I-(..) UJ u.. UJ 0
0::: UJ 3: 0 0...
>-....I z: 0
0::: -1000 UJ ....I 0... 0... 0 0
-1500 0
13.557-22
20 40 60 80 I 00
POWER LEVEL (PERCENT OF FULL POWER)
CALLAWAY PLANT
FIGURE 4.3-29
Rev. OL-0 6/86
TYPICAL DOPPLER-ONLY POWER DEFECT AT BOL AND EOL, CYCLE 1
20
1..1.. 0 -~ c...> 10 ~
~ 1-'1:> -Q.
"' 0 ~
I-z: 1J.J
c...>
u.. - 10 1..1..
1J.J 0 c...>
1J.J 0::: ::I 1-
-20 <( 0::: 1J.J ~ ~ 1J.J 1-
0::: -30 0
1-<( 0::: 1J.J c 0 ~
-40 0 100
13,557-23
2000 PPM
200 300 400 500 600
MODERATOR TEMPERATURE (OF)
CALLAWAY PLANT
FIGURE 4.3-30
Rev. OL-0 6/86
TYPICAL MODERATOR TEMPERATURE COEFFICIENT AT BOL, CYCLE l,
NO RODS
u... 0 -:::E c.> 0.. -
:::E f-"'0 -a. "'0 ~
f-z: u..J
c.>
u... u... u..J 0 c.>
u..J c:t:: ::::::> f-c:( c:t:: u..J 0.. % u..J f-
c:t:: 0 f-c:( c:t:: u..J 0 0 %
20
10
0
- 10
- 20
-30
-40
-50 0 I 00
13,557-2~
UNRODDED
200 300 400 500 600
MODERATOR TEMPERATUR~ (°F)
CALLAWAY PLANT
FIGURE 4.3-31
Rev. OL-0 6/86
TYPICAL MODERATOR TEMPERATURE COEFFICIENT AT EOL, CYCLE 1
1...1.. 0 -:::E <:..:> Q..
:::E 1-
~ a. -5
't:l
<:..:> -10 1...1.. 1...1.. I..LJ 0 <:..:>
I..LJ
~ -15 1-<( oc I..LJ Q.. :::E I..LJ
1- -20 oc 0 1-<( oc I..LJ 0 0 :::E -25
13,557-25
-30L---------------L---------------~--------------~ 0 500 1000 1500
SOLUBLE BORON CONCENTRATION {PPM)
CALLAWAY PLANT
FIGURE 4.3-32
Rev. OL-0 6/86
TYPICAL MODERATOR TEMPERATURE COEFFICIENT AS A FUNCTION OF BORON CONCENTRATION AT BOL,
CYCLE 1, NO RODS
LJ... 0 -~ u Q...
~ 1-~ -a. ~
1-:z: LJ.J
u LJ... LJ... LJ.J 0 u LJ.J 0::: :::::1 1-<( 0::: LJ.J Q...
~ LJ.J 1-
0::: 0 1-<( 0::: LJ.J 0 0 ~
0
-5
-10
-15
-20
-25
-30
-35
-ItO 0 5000 10000 15000
BURNUP (MWD/MTU)
CALLAWAY PLANT FIGURE 4.3-33
13.557-26
20000
REV OL-13 05/03
TYPICAL HOT FULL POWER TEMPERATURE COEFFICIENT DURING CYCLE 1 FOR THE CRITICAL BORON
CONCENTRATION
-12
-II+
I- 0::: z:: LLJ
~~ (.)c...
I.J...I-- -16 LJ... z:: LLJ LLJ 0 (.) (.) 0:::
LLJ 0::: c... LLJ-3:::::e:: 0 (.) -18 c... c... -_J
<(C... I- l't)
o-I- 0..
l't)
-20
-22
~
I--
1--
I--
I--
0
13,557-27
l,
/EOL
1 I J I 20 ItO 60 80 I 00
POWER LEVEL {PERCE~T OF FULL POWER)
CALLAWAY PLANT
FIGURE 4.3-34
Rev. OL-0 6/86
TYPICAL TOTAL POWER COEFFICIENT AT BOL AND EOL, CYCLE 1
0
-500
~ (..) Q..
-1000 Q.
. I-(..)
LJ.J LL.. LJ.J 0
a::: u.J ~ 0 Q.. -1500 .....J < 1-0 1-
-2000
-2500 0 20
13.557-28
ItO 60 80 I 00
POWER LEVEL (PERCENT FULL POWER)
CALLAWAY PLANT
FIGURE 4.3-35
REV. OL-7 5/94
TOTAL POWER DEFECT AT BOL AND EOL, CYCLE 1
13,557-29
R p N M L K J H G F E D c B A
I I I I
180° I
I SA B c B SA 2
so SB SB sc 3
SA D SE D SA
sc so 5
B c A c B 6
SB SB 7
c SE A D A SE c - 270°- 8
SB SB 9
B c A c B 10
so sc II
SA D SE D SA 12
sc SB sB So 13
SA B c B SA Itt
15
00
CONTROL NUMBER SHUTDOWN NUMBER BANK OF RODS BANK OF RODS
A It SA 8 B 8 SB 8
sc It
so It
c 8 D 5
TOTAL 25 SE It
TOTAL 28 Rev. OL-0 6/86
CALLAWAY PLANT FIGURE 4.3-36
ROD CLUSTER CONTROL ASSEMBLY PATTERN
160
150
140
130
120
110
,....... 100 Vl w I 90 {) z '-'
z 80 0 E 70 Vl 0 a. 60
50
40
30
20
10
0 0 0.4 0.8 1.2 1.6 2
TI~E OF TRAVEL (SECONDS)
THIMBLE DASHPOT
2.4 2.8 3.2
REV. OL-5 6/91
CALLAWAY PLANT FIGURE 4.3-38
DESIGN TRIP CURVE
1-0 1-
0. -0.
1.0
0.5
0.0 100 50
ROD POSITION (PERCENT INSERTED)
CALLAWAY PLANT
FIGURE 4.3-39
13.557-31
0
Rev. OL·O 6/86
TYPICAL NORMALIZED ROD WORTH VERSUS PERCENT INSERTION, ALL
RODS OUT BUT ONE
5 ~----------------------------------------------------------------------------,
0
........ !it: -5 LLJ (..) or:: LLJ
-==--10 1-LLJ (/)
LL. -15 LL. 0
_J
<C
>< -20 <C
;..25
CURVE I
CURVE I 2
BURN UP (MWD/MTU)
1550 7700
PERIOD (HOURS) 32.lJ. 27.2
STABILITY INDEX {HOURS-I)
-O.OlJ.I -O.OilJ.
-30 ~--~--._--~--~--~--_.--~--~----~--~--~--~--~--_.--~--~--~~~ 0 32 36 4-0
TIME (HOURS)
CALLAWAY PLANT
FIGURE 4.3-40
72
Rev. OL-0 6/86
AXIAL OFFSET VERSUS TIME, PWR CORE WITH A 12 FOOT HEIGHT
AND 121 ASSEMBLIES
~
...--.. :::::1'"
1-z: < a:: 0 < ;::) 0"
N
1-z: < a:: 0 < ;::) 0"
LJ.J (...) z: LJ.J a:: LJ.J LL.. LL..
0
1--I
1-
1-z: < a:: 0 < ;::) 0"
10
8
6
~
2
0
- 2
- ~
- 6
- 8
-10
-12
-I~
-16 0
STABILITY INDEX= -0.076 (HR.-I)
RCC E-ll
N~3 N~l
~ 8 12 16 20 2~ 28 32 36 ~ ~~ ~8 52 56 60 6~
HOURS AFTER WITHDRAWAL OF RCC E-1 I
CALLAWAY PLANT
FIGURE 4.3-41
Rev. OL-0 6/86
X-Y XENON TEST THERMOCOUPLE RESPONSE QUADRANT TILT DIFFERENCE VERSUS TIME
-60.0
-50.0
c.. ~
E' -~o.o (.) 0.
1-:z: UJ
u -30.0 LL. LL. UJ 0 u
ffi -20.0 ....J "-0... 0 0
-10.0
0 0 10
0 CONTROL BANK COMPENSATION
BORON COMP EN SAT I ON
--- EXPERIMENT ---CALCULATION
20 30 40 50 60 PERCENT OF FULL POWER
-2~00
-2200
-2000
-1800 E' (.) 0.
-1600 ::-u UJ
-I ~00 t!:i 0
-1200 ec:: UJ ....J 0... 0...
-1000 0 0
....J
-800 < ec:: <.!) UJ
-600 1-:z:
-~00
-200
0 70 80 90 100 Rev. OL-0
6/86
CALLAWAY PLANT
FIGURE 4.3-42 CALCULATED AND MEASURED DOPPLER DEFECT AND COEFFICIENTS AT BOL,
2-LOOP PLANT, 121 ASSEMBLIES, 12 FOOT CORE
N-
t:: 1 .2 a: J: 1.1 ' ::I 1-~ 1.0 X ::I it 0.9 1-~
~ 0.8 ..J ~ (.) 0.7 E a: (.) 0.6 0 w a:
0.5 ::I (fJ
~ w 0.4 :E (fJ
~ 0.3 :E
Iii"' 0.2 0 ....
' u. ~ 0.1
E: 0
0 0.1
0 14-A-20766-180
0.2 0.3 0.4 0.5 0.6 0.7
95/95*
* 95% OF DATA WILL FALL ABOVE THIS LINE WITH 95% CONFIDENCE.
0.8 0.9 1.0
+ +
1.1 1.2
(q"CHF/106) PREDICTED CRITICAL HEAT FLUX (BTU/HR-FT2)
CALLAWAY PLANT
FIGURE 4.4-2a
Rev. OL-1 6/87
MEASURED VERSUS PREDICTED CRITICAL HEAT FLUX· WRB-1 CORRELATION
1.3
1.10
1.00 -N
t: 0.90 I
a: X ....... ;:)
0.80 ti -~ ;:)
0.70 -' ..... .... cC w
0.60 X
-.1. u -.... 0.50 ..... a: u c
0.40 ""' a: ;:) en cC
0.30 w :E . ~ 0.20 ---+--~~-f----1----+---+---+ ..... • '*951 of data w111--t----t ~ fall above this ~ line with 951 "&... 0.10 confidence.
X zu CT - o.oo~~~ .. ~~~~~~~~~~ .. ~~~~~~~~~~~~ .. ~
0.00 0.10 0.20 0.30 0.40 0.50 0.60 0.70 0.80 0.90
(QCHF/106
,,.'RED, PREPICTED CRITICAL HEAT FLUX (8TU/HR-FT2)
1.00 1.10
REV. 16 10/06
CALLAWAY PLANT
FIGURE 4.4-2b MEASURED VERSUS PREDICTED
CRITICAL HEAT FLUX WRB-2 CORRELATION
Rev. OL-21b
4/16
CALLAWAY PLANT
FIGURE 4.4-3b
MEASURED VERSUS PREDICTED CRITICAL
HEAT FLUX – WLOP CORRELATION
014-A-20766-180
0.12
0.10 i-
0.08 1--
~ 0.06 ~
0.04 t-
0.02 i-
0 I 0 1.0
0
I I 2.0 3.0
I 4.0
G De Re=}L (lo- 5 )
I
5.0
LEGEND:
0 26" SPACING I -PHASE
0 26" SPACING 2-PHASE
0 0 0
I I 6.0 7.0 8.0
CALLAWAY PLANT
FIGURE 4.4-4
Rev. OL-0 6/86
TDC VERSUS REYNOLDS NUMBER FOR 26 INCH GRID SPACING
9 1.029 1.001
l
10
I I
I l.l53
1.000
J 1. Iss I .000
J 12 1.223
I .000 I
J 13
I. 126
I .001 J
I 14 1.025
I
15 0.717 0.999
014-A-20766-181
G F E 0
-1--- --- ---
c
--:-
B A KEY:
-r-- .6.h/.6.h G/G
DDDDDD [;]DDDDD [;][;]DODD ~~~DO ~~~[fBD [[;]~[[;]§
§§ FOR RADIAL POWER DISTRIBUTION NEAR BEGINNING OF LIFE. HOT FULL POWER, EQUILIBRIUM XENON
CALCUAL TEO F~H = l . 34
(CYCLE l ONLY)
CALLAWAY PLANT
Rev. Ol-1 6/87
FIGURE 4.4-5 NORMAliZED RADIAl FLOW AND
ENTHALPY DISTRIBUTION AT 4 FOOT ELEVATION
~I H G F E 0 c B A
~1.096 __
8 0.996 -f--f- -f--f- -f- --- ---
KEY: -- l:.h/b.h
G/G
1 9 1.026
1.002 L
I I. 155
I O 0.991
I I I I. 169
0.990
1 12 1.228
0.985
1 13
I. 129
0.992 L
I 14 1.024
1.900
I o.-715
15 1.022
014-A-20766-182
§DDDDDD §§DDDDD §~§DODD ~[;][;]~DO §[;]~rnmo
~[;]~~~ [ill]~~
FOR RADIAL POWER DISTRIBUTION NEAR BEGINNING OF LIFE. HOT FULL POWER, EQUILIBRIUM XENON
N CALCUAL TED F L'.lH = I . 34
(CYCLE I ONLY)
CALLAWAY PLANT
Rev. OL-1 6/87
FIGURE 4.4-6 NORMALIZED RADIAL FLOW AND
ENTHALPY DISTRIBUTION AT 8 FOOT ELEVATION
ct_J H ct_ I
_I. 0971--1-
B o.T95
I
I. l57 10
o.r91
I I
I I. ;70 0.990
I
I 1.231
12 0.987
I
I I. ;30
13 o.r93
I 14
1.023
I
15 0. 711 1.016
014-A-20766-183
G F E 0
-1-- --r-
c B
-r-r-
A
KEY: -- L'.h/ L'.h
G/G
DDDDDD §DDDDD ~§DODD §§§DO §§E§~D [;][§[U]~ [;][§
FOR RADIAL POWER DISTRIBUTION NEAR BEGINNING OF LIFE. HOT FULL POWER, EQUILIBRIUM XENON
CALCUAL TEO F~H = I . 34
(CYCLE I ONLY)
CALLAWAY PLANT
Rev. OL-1 6/87
FIGURE 4.4-7 NORMALIZED RADIAL FLOW AND
ENTHALPY DISTRIBUTION AT 12 FOOT ELEVATION- CORE EXIT
0.07
() 0
I
~ () "-3: t:. ~
> 1-
LEGEND: PERCENT PERCENT 0 u THEORETICAL THEORETICAL 0.06
\· DENSITY DENSITY
0 GYLLANDER 96.4 0 HOWARD & GULVIN 96.0
0~ • ASAMOTO 95.0 • LUCKS & DEEM··· 96.5
\o 0 GODFREY 93.4 ()DANIEL ET Al. 96.5
0.05 A STORA 92.2 • FEITH 97.9 0 0 A.D. BUSH 94.4 0 VOGT ET AL. 97.0
<>,t • ASAMOTO 91 .. 0 6. NISHIJIMA 95.0
0 \ 'V KRUGER 93.7 '9' WHEELER & 97.0
> 1-(.) :::> 0 2 0 ()
...I
-1 <(
:r (') ~ -<D a:
-1~3 :t> w :r ..... w "'-:; r- :X: (DOl_ H r- 1-~()("') GJ :t> <D 0 0 c
~ ~-::: ::J " nroa. tTl :t> Ill () c - .... ()
""' -< o~=· <D < , :J ,... ;:;: ""' (1)0-< I r-
0.04 g't AINSCHOUGH
o't SEE REFERENCES FOR THERMAL-HYDRAULIC SECTION
0~· 6.
0.03 ~-~· 0 • o' o• • t • 6. ~'~·~ co 0 t
0 •'V'V'V~~-~--o 0.02
6. ... •
rl. (.0 0 1.0 :t> $01-Cf<C z
0 -4 0.01 ~------~------~--------~------~--------~------~--------~----_j
0 400 2800 3200 800 2000 2400 1200 1600 N
en ::a ....... (])
~< TEMPERATURE (T), °C
0 r 6
620
610
600
LL 590 0
w 580 0::: ~ 1-<{
570 0::: w Cl. 2: w 560 1-
550
540
530 0 20
0 14-A-20766-184
TcOLD (556.8)
40 60 80 100
PERCENT POWER
CALLAWAY PLANT
FIGURE 4.4-10
REV. OL-15 5/06
REACTOR COOLANT SYSTEM TEMPERATURE-PERCENT POWER MAP
0 H
f-<( a: rlJ z 0
:L :::.) :L H
z H
:L
I .8 ~------------------------------------------------~
~~-5 BOL I +5 ... , I. 7
, .. 5 FOL I +5 ,...,
I .6 0 0
§';s>~ ~\o I .5
0 d>o ~ o0 o B~o 0
0 0 0
0 I. 4
<co
I .3 I . 55 COSINE tl
I .2 ~--------------~----------------~--------------~ -20 -10 0 10
AXIAL OFFSET (PERCENT)
Rev. OL-1 6/87
CALLAWAY PLANT
FIGURE 4.4-11 100% POWER SHAPES EVALUATED AT
CONDITIONS REPRESENTATIVE OF LOSS OF FLOW, ALL SHAPES EVALUATED
WITH FNAH = 1.55
014-A-20766-185 (CYLE 1 ONLY)
2 3 4-
D
T T
D
T T
D D
T T
T D D D
D T T
D
T T
TO TD
D
13,'i57-32
5 6 7 8 9 10 II 12 13 14- 15
I I I I
I I I 270° I
T T D T D A
D D D B
D T D TO T T T c
D D D D D
D T T D T D T T E
D D D F
D T T D T TD T -- G
D D D TD -oo- H
T D TO TD T TD J
D I) -- K
D T TD TO D T D 1 D -- L
D
TO TO T T D TD
D p
TD TO T D R
T = THERMOCOUPLE (50 LOCATIONS) D = MOVABLE INCORE DETECTOR (58 LOCATIONS)
CALLAWAY PLANT FIGURE 4.4-21
DISTRIBUTION OF INCORE INSTRUMENTA'riON
Rev. OL-0 6/86