ML19345G464
| ML19345G464 | |
| Person / Time | |
|---|---|
| Site: | Maine Yankee |
| Issue date: | 03/30/1981 |
| From: | Solan G Maine Yankee |
| To: | |
| Shared Package | |
| ML19345G463 | List: |
| References | |
| NUDOCS 8104070295 | |
| Download: ML19345G464 (31) | |
Text
. _. _
m t
Maine Yankee Vessel Fluence Calculation Physics Data for Cycles 1,1 A, 2, 3 and 4 C. M.
Solan
SUMMARY
Maine Yankee operating data and calculated results for Cycles 1, lA, 2, 3 and 4 are provided for vessel fluence calculation input. The data presented comprises cycle operating conditions, vessel internals dimensions, capsule location, peripheral assembly descriptions and pinwise burnups by cycle.
OPERATING CONDITIONS The operating conditions by cycle are given in Table 1.
The cycle lengths in M'a'D/MTU are based on calorimetric data and are considered accurate to within 2%.
The loadings in KCU permit calculation of the the total MWH of opera tion by chtle. The opera ting power levels lis ted are in percent rela tive to rated power and best represent average operating conditions. The operating primary sys tem temperature for core inlet and core average correspond to the average operating power levels and are consistent with the daily plant status report data.
Notice the reduced primary sys tem pressure in Cycles 1 throagh 3 to mitigate the eff ects of' actual and. potential fuel failure.
VESSEL INTERNALS DIMENSIONS -
The. location, thicknesses and materials of the core shroud, support barrel, thermal shield and vessel are seen in Figure 1.
The core shroud is adjacent to the active core.. The dimensions in the active core relative to the shroud are given in Figure 2.
Included are the assembly dimensions and pitch.
-810407O N
1 CAPSUUE LOCATION The location of Capsule 263 is described in Figure 3.
The 263 engle of orientation is relative to one core inlet nozzle (0 ).
The core shroud is orientec perpendicular to a 260 an gle. Thus, the capsule location is 3 from a perpendicular to the core shr oud. As-built distances from the core center to the center-line of the vessel wall assembly tube are included in the figure.
PERIPHERAL ASSEMSLY DESCRIPTIONS The peripheral assemblies considered for vessel fluence calculations are identified on the full core map, Figure 4.
The assembly types and assembly loadings (KGU) in residence by cycle for these locations are given in The measured assembly exposures accumula ted in Figure 6, along with Figure 5.
the assembly loaoings, provide a measured cumulative MWH for each assembly
- The measured location by cycle for contribution to the vessel fluence.
assembly exposures are from the INCA incore detector system calculation.
The physical placement of shim pins within the assembly, for the specific assembly types in Figure 5, are shown in Figure 7.
The loadir.g differences among assembly. types include fuel pin design differences and the different
~
number of shim pins per assembly. The shim pin pellet material is B C in 4
A1 0
- 23 PINWISE BURNUPS BY CYCLE' Cycle depletion on a pin-by-pin mesh basis has been performed by Yankee Calculated pinwise burnups by cycle are given for Cycles 2, 3 since Cycle 2.
and 4 for the peripheral assemblies.and those Cycle 2 assemblies residing in peripheral locations in Cycles 3 and 4.
The assembly data is given for the first quadrant locations specified in Figure 4, which are symmetric partners of the assemblies requested. Appropria te rota tion of ;he pinwise data. is thus required.
- 6 i
A guide to the pinwise data is contained in Figure 1-1.
The calculated assembly average data does not match the measured assembly average exposures.
4 This results from differences in power distribution and the total cycle exposure to end-of-cycle between measured and calculated. Normaliza tion factors are thus defined, in Table 2, to apply to each pin burnup for each e
ass embly. 'Ihese factors are also given on each pinwise burnup figure.
No comparable data exists for Cycles 1 and 1A.
Due to the fact that both Cycles.1 and 2 were fresh cores and exhibited similar assembly power sharing, the Cycle' 2 pinvise relative data is sufficiently accurate. Table 3 contains normalization factors to apply to the Cycle 2 pinwise data so as to match the combined Cycles 1 and 1A exposures on an assembly basis!
1 l..
i L
l' i
Table 1 Maine Yankee Cycles I, I A, 2, 3, 4 l
Cyc1e Opera ting Conditions l
Operating Ra ted Operating Primary Primary System
. Cycle Cycle Power' Power System Temperatures Exposure Loa ding Level Level Pressure Inlet Average Cycle
.(MWD /MTU)
(KCU)
(MWt)
(%)
(psia)
( F)
("F)
I' 0-2800 81540 2440 50 2000 525 537 2800-10367 81540 2440 75 1800 525 542 l
1A
'500 83110 2440 80 1800 522 54 2 2
17395.
80885 2440 100 2100-532 556 3
11075-83065 2440 100 2100 538 562 4
104 %
81843 2630 97 2250 547 572 w
9 t
~
l Table 2 l
Maine Yankee Cycles 2, 3, 4 l
Normaliza tion Factors for Pinwise Burnup Data
- Cycle 2 Cycle 3 Cycle 4 Asc eably - Loca t ion Measured Cal c ula ted Measured Cal c ula t ed Measured Calcuated Quadr an t Core MWD /MTU MWD /MTU Factor MWD /MTU MWD /MTU Factor MWD /MTU MWD /MTU Factor 1-H-1 10837 10630~
1.020 7527 7102 1.060 7192 7027 1.024 2
K-1 13567 13489 1.006 9723 9445 1.029 9491 9375 1.012 3
E 10189 10225 0.997 8184 7718 1.060 7363 7132 1.032 4
F-2 13666 13657 1.001 10263 10032 1.023 9671 9304 1.039
~
5 c-2 16767 16524 1.015 11167 10864 1.028 10999 10888 1.010 6.-
J-2 19418 19023 1.021 29548 28808 1.026 30200 28980 1.042 7
K-2 17948 17604 1.020 13294 13179 1.009 13415 13245 1.013 6
D-3 11729 11807 0.993-9094 4004 1.010 8603 8489 1.013 18' C-4 **
19198 19037 1.009 27 J - 5 **
- 20350 19529 1.042-Normalization factor by assembly to match INCA-measured assembly exposure. Acc oun t s for differences in power distributions and the total cycle exposure to end-of-cycle between calculated and measured.
Cycle 2 assembly moved to quadrant location 6 in cycle 3.
Cycle 2 ' assembl y moved to quadrant ':,ce. t i on 6 in Cycic 4 (not in-core in Cyc le 3).
C**
~.. _. _
h i
4 4
6.
i l
Table 3 Maine Yankee Cycles 1 and 1A Normalization Factor For Pinwise Burnup Data
- Cycles 1 & 1A Cycle 2 Normalization Assembly Locations Measured Cal cul a ted Factor for 3
Quadrant Core MWD /MTU MWD /MTU Cycles 1 & 1A 1
H-1 8494 10630 0.799 2
K-1 10407 13489 0.772 3
E-2 8092 10225 0.791 4
F-2 11530 13657 0.84; 5
G-2 14884 16524 0.901 6
J-2 16525 19023 0.869 7
K 14338 17604 0.814 D-3' 9291 11807 0.787 4
't Normalization f actor by assembly to match INCA-measured assembly exposures for Cycles l' and 1A based on the Cycle 2 calculated pinvise exposure data in Figures 2-1 through 2-8.
I e
b f
Figure 1 Maine Yankee Core Shroud Barrel and Thermal Shield Positions Dimensions in inches Distances from co::e center y
' ~
8%
' /j'
/
min.' mum
- y!
/
N.
l
~
J 4 -...
//
5/16 p/
'r s'N 78-3/8 '/
/
~
/
~
4--8-5/84
/
/
//
~~... w
' /,
u N
43+
/,
e
%g 74
/
f j
--> 1 4-4-2-5/8 M 6 4-5/8,)
minimum N
/
4 1-3/44!-
activa
\\
/
/
core 1 N ^,>
i f
/
Core Core Thermal Reactor Shrouk Support Shield Vessel Barrel 316 SS 304 SS 304 SS A-533B Class 1 Steel l
l l
- Reactor vessel as-built IR 86.93 in (average of 24 measurements at 6 angles a:.d 4 elevations in vessel) l
,m..,
A Figure 2 Maine Yankee Active Core Dimensions Fuel rod pitch 0.580 in Fuel rod OD 0.440 in W
0.060 (
in h I
! I I
i 1
l t 1ll i I I i I
i i
i
!! l I I I I i L
I
.I I
I I
I i
i g
e b
i
, i i
I I i i
l i'
i i i
1 I
I i I
i I t gr M I
8.180
__p_p 14 spaces at 0.580 y
in 0.200 in (rod surf aces) or 8.120 in I
1 o
i c
I 1
I i
1 r g
6
'l I
i g
l I
s y
0.134 in (0.204 in from rod surface to shroud) h
////g
//
/
C0RE SHROUD
0 OUTLET 180 Figure 3 N0ZZLE
(-
-*7 Maine Yankee
)
t Core Shroud and Capsule 263 Orientation Relative to Core Vessel yy g INLET N0ZZLE e
N0ZZLE CORE 9
,1
[
\\__
^ SHROUD
\\
p
\\
e g
i
\\
Perpendicular
)
to Core Shroud 0
H 260 1j
- ~ _ _ _ - -
-2 6 3 i
E
~~~
~
2700
~
l' Angular Locati a of h
Capsule 263 i
/
Capsule 263 -
t Distance from core center to
)
center -line of the vessel i
\\
g f
wall assembly tube (as-built) g I-
/ OUTLET
\\
PUTLET N0ZZLE Top of tube 85-29/64 in l
j 40ZZLE b
)
Bottom of tube 85-3/8 in j
i
{
'l-.
i l
- _ _s INLET 4
0" N07.ZLE
l Figure 4 Maine Yankee Core locations and Quadrant Assembly Designations for Puwise Bumup Data Provided 21 20 19 18 17 16 15 13 11 9
7 6
5 h
3 2
1 I
l 1
I i
l I
I I
I l
1 i
i g
l lh 1 12t 10 8
I i
g i
j l
l l
l i
1 2
--h-l-'--
_ _ i- -
1 l
I I
-f-------I I
l 3
4 5
6 7
' -I I
- i 8
j I
16
-.J _ _ _ I 27 "
-j_ _ _ I
__I
__C I
XX
-?
__h P
__F 1
1
_.___.____e' 1
l assaablies near f
capsule location I
l
- Cycle 2 asse:ily unved to quadrant location quadrant locations of 6 in Cycle 3 4
synretric assembly
- Cycle 2 assmbly moved to quadrant locaticn data provided 6 in Cycle 4 (not in-core in Cycle 3)
3 8
C-0 394.8 C-0 394.8 F-0 388.7 H-0 398.7 I-0 388.7 Assembly C-0 394.8 Type C-0 394.8 and F-0 388.7 E
Loading H-0 388.7 (KGU)
I-0 388.7 Cycle 1 C-12 367.9 Cycle 1A C-12 367.9 Cycle 2 F-0 388.7 F
Cycle 3 H-0 388.7 Cycle 4 I-0 388.7 C-16 358.9 C-16 358.9 F-12 362.2 c
G-0 388.7 I-0 388.7 C-0 394.8 C-0 394.8 F-0 388.7 H
Mai e a kee 388.7
. Cycles 1, lA,'2, 3, 4 Assembly Types and C-12 367.9 Loading at Peripheral C-12 367.9 Locations F-12 362.2-J E-16 353.4 E-16 353.4 C-12 367.9 C-12 367.9 F-0 388.7 K
H-0 388.7 i
I-0 388.7 B-16 358.9 B-16 358.9 E-16 353.4 L
G-41 379.9 I-4 379.9 1,
3 l
l 6522 2769 l
11729 l
P 9094 4
8603 5712 Assembly 2380 Exposures 10189 E
(MW9/MTil) 8134 7363 Cycle 1 7976 Cycle 1A 3554 Cycle 2 13666
-- r Cycle 3 10263 Cycle 4 9671 10359 4525 16767 c
11167 10999 Figure 6 6051 2443 H
Maine Yankee 10837 Cycles 1, lA, 2, 3, 4 7527 11556 7192 INCA Measured Exposures 4969 Accumulated at Peripheral 19418 a
Assembly Locations 10350 9851 7296 3111 13567 K
9723 9652 949I 4686 17948 L
13294 13415 l
Figure 7 Maine Yankee Cycles 1,1A,2,3,4 Assembly Types i
D D
1 1
O O
l l
1 Types A-0,C-0,RF-0,D-0,F-0 Types RF-4,G-41,G-42,1-4 G-0,H-0 l
I i i I
O O
U O
D D
l l
a_
D t
0 D
D 1
Oi O
O O
i i
I O
O g
O l
'e Type F-8 Types C-12,F-12 l
1 u
I I
I I
i iih D
D 0
D D
- D D
D D
D
.O D
D D
D D
i l
D --- I O O
D D
D D
O' D
D 0
D D.
D D
OF I
II c
L.
Types B-16,C-16 Type E-16 (shims or water rods)
U shim locations
f Figure 1-l' Maine Yankee -
Pinwise Burnup Data
' List of Figures Ass embly-Loca tions.
Quadran t -
Core Cycle 2 Cycle'3 Cycle 4 1
_ H-1 2-1 3-1 4-1 2
K-1 2-2 3-2 4-2 3
E-2 2-3 33 4-3 4
F-!
2-4 3-4 4-4 5
0-2 2-5 3-5 4-5 6
J-2 2-6
~3-6 4-6
-7 K-2
.2-7 3-7 4-7 8
D-3 2-8 3-8 4-8 18 G-4*
2-9 27
. J - 5 ** -
2-10
. Cycle 2 assembly moved to.' quadrant l location.6 in' Cycle 3
'** Cycle,2 assembly moved to quadrant loca tion 6 in Cycle 4 (not in-core in
. Cycle 3)
(
..p-u_
P00R ORllNAL
~
1
- V CYCLE 2 EOC AT 17400 MWL/MT MYIICrJ,mPk5n174>
ep03/21.14.12,;1,p A;.E 30. 44 BEFORE SKFFLE SCALEL POINTWI5E ASSEM2D CCKEGATICh EDIT WEA f1ATIM AGFtlEI4 ASSEM M ASSYO!
KILLIIC MWO!MTV K MEFIC 1D 800 SCALE FACT 06 = 10++ 5 FtAPE 1
97 98 99 100 101 102 102 104 10*
106 107 102 109 110 111 6
e
.0311.0370.0422.0457.0475.0491.0512.0539.0572.0c t ?.0653.0c71.06tL.0e7C
.0364.0484.0578.0623.0c14.0111.0620.06t!.0700.0783.0E75.05 95.0857.0cc
.0451.0593.0000.00(0.0745.0711.0725.0761.0823.094?.0000.00%.102:..Ne.
.0503.0654.0000.0000.062e.07 M.0620.0855.0918.1042.0000.0000 1122.1053 10 10
.0530.0665.0761.0645.0958.0884.0034.0974.1005.10o7.1152.1175.113e. !!!!
.057c.0e82.07tB.0S?0.0906.1003.111E.115e.1125.!!!0.1121.114i.1155. !!e4
.0621.0725.0?07.00P.0931.1143.0600.00(O.1267.1185.!!!i.11%.129.122' Figure 2-1
.0o74.0787.0675.095c. 10*.0.1212.0000.0000.133;.12d0.1254.12e7.12i5. 3K
.0738.0871.00.1054.1116.1209.1324.1367.1335.1334.1367.1357.1395.13+
Normalization 13 15 Factor = 1.020 6
.0612.0695.1157.1231.1221.1223.1272.1316.1362.1454.1571.1547.153t.14%
.0997.1136.0000.M.1353.12if.1296.1341.1424.153.0000.0CO).160*.15%
.0941.12C2.009:.00(0.1414.133c.1341.13?5.1473.It54.0000.0000.1751.1644
.0984.119e.136e.14?4.140:..!?i2.1297.1435.15F.1624.175).177:.1 V.le":
.1061.1214.132e.1347.1425.144).14:2.1501.15*:.1:21.1674. leSt.1673.let!
20 2n 97 98 99 100 101 102 103 104 105 10c 107 10E 109 110 !!;
I
- Y CYCLE 2 EOC AT 17400 M.D/MT Mr!!Cr5.MG.5M174r 61/03/21,14.13.21.F A:{ OX '5 BEFORE SNUFFLE SEALED POINTW!!E ASSE"RY CONCENTRA!!)4 EDIT (AREA RAT 101 AFFLIEIu AMEMEO A55YO2 KtCt!DE P 0/MTU NUME !C ID EO)
SCA.E FAC10F = 10n 5 FtA'.E 1
til 112 113 114 115 11e 117 118 119 120 121 12; 123 124 12' 6
e.
.06?).0705.0736.0742.0726.0710.0704.070).0723.074).0776.0779.07e1.074
.0644.0%6.0051.0957.0921.0560.0ES!.0957.0955.0950.1025.1034.0'e5.0912
.097).1057.0000.0000.1102.10)1.0972.0977.1019.1135.0000.0000.1157.1060
.1073.1154.0000.0000.1207.1110.1093.1044.113.1243.00C0.0(9). 2257.115' 10 10
.1131.1195.1274.12 M.1236.1210.1223.1229.122i.12t?.1334.1333.1267.1217 Figure 2-2
.!!83.1212.1242.1263.1283.1343.1437.1443.1365.1312.1305.1247.1251.1268
.1246.1265.1283.1310.1365.1506.0000.0000.1522.1392.1350.13 4.1331.1?29
.1320.134'.1360.1387.1439.1577.0000.0000.1542.1464.1424.1410.1435.1400 Normalization
.1409.1445.1491.1500.1505.1561. ItA,.16,51.1575.1532.1524.1327.1505.1485 Factor = 1.006 15-15
.1513.1595.1695.1705.1623.1570.1565.1573.1582.1644.1737.1739.1650.155?
.1610.1756.0000.0000.1764.1620.1577.1580.1629.1782.0000.0000.18(6.1674 i ~
.1663.1909.0000.0000.1810.1658.1606.1606.1664.1823.0000.0000.1850.1717 i
.1673.1759.1861.1664.1766.1680.1645.1645.1682.1772.1878.1882.1791.1718
.1680.1717.1762.1776.1750.1714.1692.1689.1709.1749.1781.1775.1743.1721 20 20 111 112. 113 114 115 116 117 118 119 120 121 122 123 124 125
P00R ORIGE 1
=Mi CYCLE 2 EOC AT 17400 Itc/Mi Mr110M5.Mvh.5e174L E1/03/21.14.1. 2..%3E (9.4:
BEFORE 94FFLE SCALED POINTWISE ASSEPEY CCNCENTRATION EDIT (Af<EA MT105 # FLIED)
A55EPRY ASSYO3 NUCL1DEftC/MTV NUPIR1C ID 600 SCALE FACTOR = 10* 5 PLANE 1
62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 20 20
.0209.0349.0401.0436.0454.0471.0192.0519.0553.05S3.0634.0e53.0c54.0e5
.0361.0460.0552.0507.0590.05 %.0607.06?).06E7.07e4.0853.0877.084;.0514
.0425.0565.0000.M.0716.0685.o700.0736.0799.0923.0000.0'X6.10@.044!
,0474.0623.0(<v,.0000.0794.0770.0792.0831.0801.1014.0009.000.110:'. It?:
.0508.06?2.0747.0810.0824.0852.0902.0042.0974.1937.1123.1147.1112.10?!
25 25
.0".42.0e47.0733.0804.0870.0ite.107?.!!20.1 W<.1077.1100.111;.112".1:41
.0'e?.0e88.0770.0643.0942.1100.0000.0000.122e.114?.1144.115R.117<.12d
.0633.0745.0833.0914.1007.116e.($X.0000.1294.1219.1216.1230.12".0.12e:
Figure 2-3
.0692.0825.0930.1007.1069.1161.1275.1318.1292.1284.1323.1344.1347.1352
.0762.0943.1102.1176.1169.1178.122?.1267.1313.1403.1513.1546.1455.1442 30 30 Normalization
.0834.1077.0000.0000.1204.1231.1243.1288.13e6.154'.MdX'.M.le40.15?;
Factor = 0.997
.0886.1141.00v0.0000.1351.1278.12i?.1327.1413.1* L1.Mu.'XV.le61.15Si
.0039.1139.1301.1363.1333.1315.13^.+
1371.1440.155. le54.1713.1641:.1535
.1011.1162.1271.1329.1345.1355.137E.1415.14tS.1515. le04.le30.1619.1612 34 34 62 6?
64 65 44 67 e4 oi 70 71 72 73 74 75 7e
=m CYCLE 2 E00 AT 17400 n=3/Mi Mr11GM3,Mvh.!P.174t 81/03/21.14.13.21.FW1 0%47 IF Cfi S M FLE SCALE 0 POINTWISE A55EriY CCer:ENTMilch EDIT (AKIA MT105 APLIED' As5EM;tY A51104 NUCLill M.0/NTO hL?ID.1D 800 SC4.E FAW.4: = iou 5 FLAi 7e 77 7E 79 80 81 82 Si 84 85 ft 67 8?
i; 95 20 20
.0674.0703.0735.0745.0734.0725.072e. 074).07e4.0802.0842.0359.03 % vi5'
.0834.0M.0979.0991.0931.0%5.0875.0890.0929.1009.1104.1123.10e9.1033
.09tt.1080.0@.0000.1112..017.0996.1011.1065.1108.0000.0000.1262.1176
.1060.!!75.0000.0iX/.'.12".1125.1111.1127.1174.1302.0000.0000.13".1272
.1115.1162.1267.1287
'.41.1223.1244.1259.1270.1322.1404.1417.1361.1326 25 25
.1164.1197.1231.12'4.1285.1357.1456.1471.1402.1361.1345.1370.1367.13t 6
.1222.1245.1269.1302.1363.1512.0000.0000.1555.1435.1403.1400.1410.1 0 2 Figure 2-4
.129.131e. 124?.1372.1431.1578.0000.0000.1620.1501.1472.14t;.1476.1417
.1374.1413.1453.1477.1493.155e.1645.1663.1597.1563.157e.1581.1571.1565
.1471.1555.1658.1673.1600.1556.1565.1579.1598.1671.1776.178).1712.1655 Normalization 30 Factor = 1.001
.1561.1707.0000.0000.1730.1597.1565.1578.1639.1803.0000.0000.1864.1746
.1608.1754.0000.0000.1767.1625.1535.1596.1666.1838.0000.0000.1906.1792
.1616.1701.1802.1008.1713.1696.1612.1625.1673.1777.1900.1021.1847.1798
.1628.1664.1706.1711.1679.le50.1643.1655.1685.1733.1796.18!7.1806.1815 34 34 76 77 78 79 80 81 82 83 84 85 86 87 88 M
90 7 +
P00R ORIG NA.
1
=m CYCLE 2 EOC Al 17400 ND/M7 m11Cei.Mih.i";74 E1/0. 21. 14.:..:. LIE t-::i BEF0EE SHtfFLE SCAcEP FtlNTW15E A55Erh t C W EN E !!ON ED11 6 K110i AL M ES A55 EPA t AS$YO5 N/2Ll[6 ND/Mie M E;1C ID EOS f &.E FA;T0; = 10++ 5 ftAT 1
90 91 92 93 94 95 96 97 96 99 10C 10; 102 102 104 v.
,.c.
.0878.0916.0959.(fri2.(r s?.10M.106e.1174.1255.1304.14%.1524.1583.15F e
.1053.0000.1231.12e4.1215.1185.1216.1~9.136e.153. let.2717.000; le3:
.1197.1324.0000.0000.1405.00/6.1323.1390.0000.16et.0000.We.1Evi.17W
.1295.1428.0000.0009.15%.1412.1419. !a 3.1545.1722.0M.0We.1?3.1739 e
.1347.1427.1527.1554.1505.14L7.152-:.157;.le?5.16F.160e.1e4:.1777.17?;
25 N
.139.1430.0w0.1503.153:.1625.17 5.1775.1713.1:.S.171:. ta'=c..I N.!?2' 4
.144:.14e9.1457.153.1602.1774.Os.9X*:. tin.172r.1711.1U.1%.1F.
Figure 2-5
.150t.1537.1565.15iv.Ites.1827.0E.000).1F4.17'1.1755.1hi.147.1765
.1544.le?J.00C6.169i.1712.1714.1592.t'll.1944.1513.1642.0'd.154:.1220 1677.17e,8.1878.1891.1814.1773.1757.156t.!E20.1900.2025.2044.1959.ti'*2 Normalization 30
- +1 Factor = 1.015
.17t7.1922.0000.0W.1951.102;.1757.180!.157.204..(MO.0000.200.:9:e
.1823.1950.00(9.Wh.1004.irie.1314.153;.N@.007e.05.00 3.214. Yr ;
.164).0005.2040.2035.1943. tie;.1542.!!!?.1912.2v15.217.21e'.te.2( i
..'8c;.1923.19eo.15e4.1935.19(2.;E LI.1964.1440.1997.20!!.2077.205:.: 17 34 M
90 02 93 94 05 Ot 97
'i 60 16 10:
102 M 104 1
.et CYCLE 2 EOC AT 17400 ND/Pi m110FJ,mFi3M174e 61/02/21. 14.II.21.F13E 00C#
BEF0FE 5N.iFFLE SCAuEL FtD,TW15E A5iEMid (Cte:ENTMTICt. EDIT WEs ;tT!31 A*F.IEW ASSE*J.Y A55t0e Nf:LIDE N2miu Nu-51C ID 500 SCA.E FACTM = 10
- 5 FU.'.:
1 104 105 '10e 107 105 105 11C 111 112 113 114 115 11c.
117 11:
20 20
.1589.1651.1706.1728.1714.1693.165,. It'4.1733.1733. '?20. it;e.1795.17e 3
.1677.0X0.1895.1909.1824.1756.1730.1743.1793. tin.10'e.2M.0MC.163e
.174.1911.0000.0000.1952.XCO.1773.1725.0'XO.2(ci.0000.0000.2032.!EF
.1771.193t.0000.&X6.1979.1847.1311.1821.1977.2f00.0iX'O.ON6.2M2.1F7
.1761.16:3.1979.1992.1912.1860.1E79.16$7.164.1954.2053.0055.190. 187:
25 25
.1750.1806.00(0.1874.1882.1953.2059.2066.1973.1916.1024.4X6.1864.1647
.1757.1794.1826.1851.1905.2072.0000.0000.2 6.1932.1841.1879.1660.1843
.1766.1823.1654.1876.1927.2001.0000.0000.2104.1945.1909.1E57.187e.1552 Figure 2-6
.1837.1890.0000.1942.1947.2011.2112.2115.2022.1956.1975.0000.1933.1844
.1906.2002.2113.2117.2023.1967.1969.1972.1977.2t.2i.2139.?!41.2035.1950 30 30 Normalization
.1977.2133.0000.0000.2136.1988.1939.1942.1996.2149.0000.0000.2159.20!!
Factor = 1.021
.2016.2167.0000.0000.2150.0000.1937.1940.0000.2161.0000.0 % 0.2188.2040
.2014.0000.2182.2165 '.2054.1967.1926.1928.1972.2063.2177.2196.00($.2031
.2003.2025.2045.2027.1979.1937.1916.ii'8.1942.15s7.2033.2053.2040.2020 34 34 104 105 106 1(7 108 109
!!^
111 112 113 114 115 116 117 118
P00R ORIGINAB 1
=m CYCLE 2 EOC AT 17400 ND/MT MYIIGMi MiFr.59174L el/va... s.
.2..:;;.E e a BEFORE SH EFLE SCALED POINTWISE ASSEMSD CtN:ENTRATICA EDIT (MEA FCIf.r5 MFLIED ASSEMBLY AS5YO7 NUCtIDE ND/MTU NUME;10 10 800 5% E Fu.TC5 = 19++
5 FLAtE 1
118 119 120 121 122 123 124 125 20 20
.1609.1625.1654.1664.1634.1605.15 7
.1666.0000.1802.1799.00(9.1640.!!21
.1722.1827.000 ).0000. If06.1663.1647
.1737.1844.0000.0000.lE29.1713.1654
.1713.0000.1845.1847.000.::.173).1751 25 25
.16 8.1713.17?t.1747.1753.181'.1005 0
.1701.1708.1715.1733.1782.1924.00(,
Figure 2-7
.1716.1724.1731.1744.1797.1932.(ii.(
.1744.1762.1786.1795.1800.1860.1051
.1791.0000.1929.1930.0000.1811.1821 Normalization 30 30 Factor = 1.020
.1847.!'6'.0000.00(0.1043.1810.17ie
)
.18e*.1084.0(60.0000.lo"i.1927.1764
.185i.0000.200o.24 %.0(60.1828.18M
.18o9.19(O.1935.1932.1991.185'.1941 34 34 118 119 120 121 122 123 12a 125 1
=Mi CYCLE 2 EOC AT 17400 ND/MT MylIGMi.r., Pig '74t 81/03/21. 14.li..:. R}E (4 *:
BEFORE SkfFLE SCALED P01NTw15E ASSEMRY CtMENTFATION EDIT (MS FATIO5 AxJEb A55Eth? A55y0?
NUCLlif NW.is it.GM ID EM R E FA;10E = 10+e 5 F.h 1
45 49 50 51 52 53 54 t.5 56
- 7 53 5;
e6 el e2 34 54
.035e,.0428.0494.0543.0573.0603.0641.0e86.0742.08J3.0874.0919.0953.1023 35 35
.0420.0547.0660.0719.0720.0727.07e2.0315.0891.100*.1136.1191.117e.1127
.0497.0661.0000.0000,085s.0830.0860.0017.1010.!!st.0v00.0009.1355.1307
.0547.0722.0000.0000.0937.0918.095*.1014.1102.1268.0000.0M.1431.137c.
.0580.0725.0860.0939.0961.1001.1068.1127.1179.1271.1390.1435.14J9.1402
.0612.0735.0836.0922.1004.!!20.1255.1313.1201.1293.1334.1369.1394.1422
- CO 40 Figure 2-8
.0652.0772.0869.09e2.1074.1258.00($.0000.1427.1353.1358.1355.1420.1455
.0701.0629.0930.1025.1136.1310.0u00.0000.1436.1411.1416.1442.1473.1%4
.0760.0909.1027.1117.1192.1302.1434.14S9.14t7.1471.1515.1545.iS57.1570 Normalization
.0631.1029.1205.1290.1289.1307.1364.1419.1475.15S0.1710.1746.1690.1653 Factor = 0.993
.0902.1166.0000.0000.1414.1353.1373.1428.1523.1714.0000.0(in.1835.1732 45 45
.0952.1227.0000.0000.1464.1392.1404.1457.1557.1754.0000.0000.1874.1767
.0991.1216.1395.1468.1442.1422.1444.14?3.1573.1702.1843.1978.1813.1763
.1064.1233.1352.1418.1440.1455.1484.1529.1591.1670.1745.177e..1767.1763 48 ~
48 48 49 5s 51 52 53 54 55 56 57 58 59 60 61 62
P00R ORIGINAL 1
Wly CYCLE 2 EOC AT 17400 miD/MT MYI!GR5 mF7.5n174t.
81/03/21, 14.li.;;.cM E 9 M:1 MFORE SHLFFLE STALED POINTWISE ASSEMEO CONCENTRATICh EDil (AREA RATIOS AFft1ELi ASSEMBLY ASSY18 ItlCL1DE miD/MTU IG.IPERIC ID 800 SCALE FACTOR = 10++
5 FtANE 1
90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 48 48
.1999.1913.1943.1940.1901.1860.1857.1860.1880.1914.1965.1976.1952.1541
.1915.0000.2031.2024.0000.1854.1830.1834.1865.0000.2048.2063.0000.1957 to 50
.1947.2033.0000.0000.1997.1965.15C4.1828.1575.2014.0M.0000.2068.1%7
.1945.2027.0000.0000.1995.1972.184:.1641.12E1.2^::.(@).9M.2C9.191; 1907.0000.2000.1996.0000.187'.15-;;.184.1553.vh).20:e.2c25.ex0.lc42
.18W.1859.1869.1874.1880.1044.2(&.204;.1952.18i1.1M;.1952.3 F. lo(E
.1864.1836.1829.1843.133.2040.W.
9XC.X4:.1001. tie :. tis..se;.189 Figure 2-9 e
53
.1865.1841.18i4.1847.1897.2043.0000.WO.2059.1006.18C.1151.16e.15%
.1890.1873.1882.1887.1892.1955.2048.20%.19e !.1603.1M2.19.>1.187e. 191e Normaliz.ation
.1930.0000.2022.2018.0000.1897.1907.1900.1904.0000.2031.2041.0000.10!!
Factor = 1.009
.1976.2058.00Ca.0000.2023.1&i?.1863.1865.1003.2034.0000.0000.2010.20M
.1987.2073.00n.0000.2033.1897.1854.185e.1901.2043.00v0.0000.26 4.20;"
60 60
.1964.0000.2078.2069.0000.1893.18ee.15:5.190'.0 W.2022.2005.00K.195e
.1956.1969.1997.1991.1950.1915.189).1501.1920.1052.2001.2012.1 % 7.19'?
e2 62 90 91 92 93 94 95 9:
n 0:
c:
- A 10; le, 1P li ;
4 4.__
P00R ORIGil#po;,;j,14, 1
1
=m CYCLE 2 EOC AT 17409 MWD /Mi My!!GM5,MYFthM174t e
3,g;,g g v.
c IEF0EE SHfFLE SCALED POINTWISE ASSEMKi C0CENTMTION EL1T tAFIt. MT105 ALF;IED A55EMiu A55V27 NUCl.!DE MWL/MTu NUMERIC ID 800 SC LE FACTOR = 10++
5 FtA*E 1
104 105 106 107 108 109 110 111 112 113 114 115 11e 117 115 62 e;
.1990.1993.2(C1.2015.1972.195e.1919.191'.1953.1576.202'.
202i.2:XC.1991
.1994.0000.2104.20%.E.1919.1900.1951.102;.00v0.2104.211e.Mf.29g
.2022.2110.0000.00M.20cc.192?.18?2.1883.1950.2070.00'X'.0((6.2115.2-)32 63 65
.2017.2100.0000.0000.2061.1932.189e.195.1935.20e5.0000.0v00.2108.2026
.1975.0000.2067.2062.00(9.1937.1045.1046.194).00%.20ei.2074.0X9.1994
.1939.1922.1930.1034.1538.FfX. 2"i2.F%.2MC.1941.1'53.19?e 192;.154'
.1923.!E44.14?5.1805.1947.2053. Art;.(6X.65.150.1C0;.1?00.1%.151 8 " 2-
.1924.1f4.1187.16*i'. li4I.2V*4.00&c.b?N.3f'*.
1951.140,:.1192.1N2.192, 70 7
Normalization
.1544.1'27.193.19M.1943.2004.200t.20'7.200:.1945.1942.1940.1923.195, Factor = 1 S 2
.1993.000v.207o.2070.0000.1944.1952.1052.194:,.00(6.2074.20e1.0000. los
.202?.2111.0000.0000.2072.1942.1905.190!.1944.2075.ixW'.exQ.2117.2e?-
.2037.2124.009;.0v00.2079.19Ce.1804.1r44. ly42.2ei2.tM.0vr;.21h 2945
.20!!.0000.2126.2115.00X'.1034.1'04.1995.193>.,09D.2119. 2139.tx6.20:'
75
?!
.2001.2013.2040.2034.1991.1953.1035.19.h.1%4.10-3.2037.M5.201E.2tge 76 7:
104 10' 101 107 105 104 110 111 1;.
111 114 115
- lt 117 Ili u.
P003 BRIGIM 1
Wif CYCLE 3 E00 Ai 11000 ND/MT syC3PIC.srytSM11r 51r03C1.14.;i.34.pA3E fx44 BEFORE $HLFFLE 5.ALED POINTWISE ASS:MB.T CONCEN1R4i10N EDIT (AFEA RAT 105 A R IED:
ASSE E r A55Y01 NUCLIDE MWDtITU MJMEE!C 10 000 SCALE FA:TOF - 10++ 5 FtANE 1
97 98 99 100 101 102 103 104 105 10e 107 108 105 110 111 e
e
.0211.0249.0282.0304.0318.0?i9.0344.0362.0?e5.0412.044.>.045?.0454.645e
.0259.0923.03E5.0415.0404.0407.0420.0441.0474.M27.05?7.0@4.095.Me:
.0303.0396.0000.000".0405.0473.04?:.0506.0540.0e35.000).00.*:.0eM.0:!!
.033?.0437.0000.0000.0".43.0529.0'4?.05e9.0o10.0(97 +.0000.0759.0714 10 10
.03e.3.0444.0520.0'e2.0".47.0582.0e13.0640.06e4.07:1.0772.0790.07 e 5.07D
.63is.0456.0512.0557.0'47.0654.0725.0754.073c:.0736.0754.07e9.07'?.0727
.0414.04?:. 0533. M8i.0$45.0743 R
R.02. 0764.0783.0754.05!d.0E '
F
,- 1
.045e.0525.0!64.0e34.0e02.0791 R
R.0979.0831.0611.0643.025B.u n
.04);.05E$.0653.0702.0738.0794. & E.0847.0E79.0880.0904.0915.0923.093 15 15 Normalization
.0550.0e44.0777.0824.0812.0812.0839. h ?.0P 7.0i s.1042.10e1.1019.04;!
Factor = 1.060
.0eX.07e7.0000.0w0.0906.0854.0857.0%4.0934.1059.0000.0(60.11/e.16:
.0e4.081t.0#.0'XO.0?5?.0691.0W.051e.0973.100..0000.%C'.
11t2.1:;4.-
.0e75.0817.0930.05:2.044t.0025.0+?3.0' ti.1005.10:2.11c.).11 '.112. 10;;
.0740.0841.0414.0057.0670.0575.0352.1025.1063.1111.!!45.1151.1134.11:'
20 h
97 95 99 100 101 102 103 104 105 10e 107 101 10;
!!0 111
-1
=Mt CYCLE 3 E00 AT 11000 !$Di?i raC3 TIC.Mr3H.EP.11L 61/03/21. 14.25. M.F ME @.4!
BEFORE SHLFFLE SMED POINTWISE AliEEt CW:ENTRAi!0N EDIT (AREA f ATI0i A%1ED' Ai!E G Y Alit 02 NJCL1DE ND/MTV Mf'iRIC 1D ir fRE FA:TO' = 19,+ 5 FA:
1 111 112 113 114 115 116 117 112 119 120 121 12.
123 124 12!
6 e
.04e4.0435.0505.0511.0502.04?3.0401.0496.0% :.0527.0546.0"C.0538.052i
.M75.0618.0672.0673.0c.35.06(>1.0592.05s?.(d19.0e47.(i?24.072;.0e.E ?.0t a:
.0666.0743.0000.0000.0761.0e92.0675.0682.0713.07?S.000v.0'X4.0819.0751
.0731.M05.0000.0000.0521.07e6.075e.0763.07;1.0674.0v0c.00($.0? I.062:
10 10
.07e*.0?!5.0973.088e.0852.0837.0950.0858.08:1.0202.0944.094e (t+L.08.>t
.0803.M24.0645.0866.0834.0934.1003.1012.0955.0924.0922.0919.0010.0N4 Figure 3-2
.0843.0858.0574.M97.v;40.1047.00C0.0000.1073.0+S2.(r955.0443.0941.045?
.0891.06C7.0924.0547.09ES.1097.0(G.0000. !!25.1034.10D.1003.1003.10M
.0447.0973.1003.1021.1034.1001.1151.1161.1111.1084.10?!.10h'.107'.10e7 Normalization 15 15 Factor = 1.029
.1013.1073.1152.1165.1113.1033.1091.1102.1116.1170.1247.1252.1167.1142
.1076.1184.0000.0000.1213.!!!7.1046.1107.1152.1276.0000.00 %.1300.1213
.1109.1219.0000.0000.1247.1146.1120.1131.11El.1311.00(C.0000.1347.12*4
.111e.1184.1271.1295.1223.1172.1156.1165.1200.1277.1367.1375.130t.1257
.1133.1177.1230.12*4.1247.1233.1218.1217.1237.1274.1306.130e.22??.12e6 20 20 111 112 113 114 115 116 117 !!B 119 120 121 122 123 124 125
P00R OR BINAL 1
=ff CYCLE 3 EOC AT 1100v ND/MT m CVDO,mi h 5M11t flici 2:. :4.;:
3.,, ;;. g BEFORE SHUFFLE SCALED POINTW15E A55EMKt C0 KEN'4T10N EDIT TARE-FA7105 A%1E*o A55EMK t ASSYO3 hUCL10E M /MTV KMEElC ID 800 SCA E FACF.E = 10++
5 FtANE 1 62 63 64 65 e4 67 69 69 70 71 72 73 74 75 7e.
20 20
.0220.0263.0302.0?23.0342.0354.0370.0300.04:4.0444.0473.04F.04?7.04F
.0273.0345.0413.044e.0441.0440.0454.0477.0512.05:5.0634.0c"2.0o24.0ei5
.0221.0423.0000.00m.0535.05:1.0522.054.095.0ei?.0E.MM.0750.Ge2
.0359.0467.0000.00(9.0%3.0573.0589.0c!3.0c c3.0755.E9.0000.0929.0711
.0385.0475.0560.0006.0614.0631.066t.0Ft.0723.0773.(183:.03'5.0625.08:4 25 25
.04:1.043:.0551.0601.0e47.0710.0786.0E01.0804.0802.0821.053:.0542.08i2 Figure 3-3
.0443.0520.0'e).0e3t.0700.0*(3 R
R.000e.0856.0855.06ee.0?i. 0??7
.04?2.0 e4.0425.0i57.0752.09e!
R R.04 1.00:;.0010.052. 63:.9ct
.0527.0e2e.0703.0730.0903.08o7.0950.055..09e4.0567.0cci.1005.101C.1014 Normalization
.05?:.071o.0837.0892.0654.0565.0920.0653.0985.10's.114'.1:o'.:11?.10i?
Factor = 1.060 30 30
.0e37.0501.0000.00(9.0ii<.0'3".0542.6c5.103e.!W.Ei;.00.0.123.1:50
.0e74.0873.0000.Cr.%.1034 '.M7e.057.10:0.197a.!212.0W.0e.12?2 !2
.07:e.0375.1003.1054.10 M.102:.1022.1CE.1:01.1:?e.:2F.!Fe.!:P.12.:
.076:.040i.09h.1037.1050.1057.1075.!!Ce.11F.!!c~.;23;.1257.1:w.!'ai 34 54 62 63 64 65 to 67 65 66 70 71 72 73 74 7'
7e 1
=m CrCLE 3 EOC AT 11000 M/r.T MvC5 % rv3P 5n11p 61/03/21. 14.26.3'.'A3E O.T BEFCFG S.:JFLE SCA;.EI POINTWISE ASSEMKY CNEh! RAT!>. chii tAREA Mi105 RIEI)
A5fErh v A55*04 K(t.!LE r.J:P.iu
. N'.rERE 10 E0e 50.LE FF T0F = 10++ 5 FJu 1
7e 77 78 79 60 81 62 81 54 ES 6e 67 si 6:
'O 20.
1
.05w.0520.0*K.054).0543.0532.0532.0540.0556.0582.0e10.0e22.062e.0e 2e.
.0618.0ec5.072. 0729.0es?.0648.0e.39.064i.0e75.0731.0800.0814.077o.0757
.0718.07??.E6.0000.0817.0744.0727.073o.0773.0669.0000.0000.0918.05o4
.07H.0870.0000.00M.0903.0823.0511.0520.0852.044o. E 9.0000.0?ie.0935
.0030.0277.0957.044;.0il2.08 2.0902.0917.0922.0 W.1020.1029.099.0-72 25 25
.W7.0Er35.0910.0927.0544.0995.1M7.1075.1020.0955.0988.0691.0991.10H
.0412.09:4.0933.055).1001.1112.0CK6.0 %0.1155.104).3014.1012.1021.10 F Figure 3-4
.0%5.0677.0ivl.1012.1052.1161.0060.0000.!!B2.1057.10c2.105'.10e7.1084
.1027.1050.1076.1090.10ii.1141.1210.1216.!!64.3130.!!3).!!??.112C.1137
.1101.1159.1235.1242.1179. !!41.1143.1143.1158.1204.12h.12c3. 3233.1202 Normalization 30 3v Factor = 1.023
.1172.1279.0000.0000.1282.1172.1142.1147.1167.1309.0000.0000.1345.1262
.1213.1319.0000.0000.1314.1197.1160.!!64.1209.1336.0000.One tr.1255
.1228.1268.1364.1363.1291.1214.11 6.1102.1222.1256.1385.1395.3329.1283
.12e1.1292. 3321.1319.1284.1253.1237.1236.12*.8.1294.1331.1338.1317.1303 34 34 76 77 78 79 60 81
&2 83 64 05 66 67 f*
B; 90
P90R DNINAL 1
sm CYCLE 3 E0C A 11000thD/'O MfC3PDO myt5N11t 81 G21. 14. 21. I'.L 0E w 4 :
I BEFO'.E $HUFFLE SCALED POINTWISE ASSEMPLY CMENTW10h EDIT WEA NIOS AFF.!EW ASSEMh.Y AS5YO5 MXLICf IVJ/Miu 10MERIC 10 800 SCA E FACT 05 = 10n 5 PLAf4E 1 90 91 92 93 94 95 96 97 99 100 101 102 103 104 20 20 8
.0599.0627.0656.0668.0665.0671.0705.0773.0840.0002.0452.@74.0W.0s4
.0726.0783.0851.08o5.0826.0802.0816.0853.000'.0093.1053.1107.1072.let?
.0627.0920.0000.0000.0 % 0.0993.0888.0015.0972.1092. @.0000.1167.1122
.0894.0987.0000.0000.1026.095).0953.0??3.1020.1131.M.0000.1193.1145
.0924.0984.1050.1065.1028.1011.1023.1041.1057.1107.117e.1165.1147.113i 25 25
.0956.F33.10M.1026.1041.1085.1151.116?.1121.1100.1103.1111.1109. !!21
.0000.1007.1022.1043.1030.1177 F
R.120e.112t.1104.110!.110".1118 Figure 3-5
.1031.1045.1042.1081.!!!6.1211 R
R.1234.1152.1120.!!24.1127.1140
.1080.1107.1132.1145.1150.1185.!'46.1252.1203.1170.1185.1135.1177.11Ee
.1140.11 %.1270.1276.1216.1178.1178.1184.1193.1241.1312.1317.1264.1247 Normalization 30 30 Factor = 1.028
.1195.1258.Wh.0000.1299.1196.!!t?.1171.120;.1322.00%.0(+'s.13e4.12c4
.1218.1321. MOO.0000.1313.1203.1165.1172.121".1334.0@.0000.1380.1315
.121e.1273.1341.1337.1257.!!55.1172.!!75.12%.127?.13t5.137*.1327.!36
.1224.1243.12o6.12'4.1221.1189.1175.1178.1201.124).1253.1M/.12%.12%
34 34 90 91 92 93 94 95 9e 97 98 99 10(
101 10; 103 104 1
=% CYC4.E 3 EOC AT 11000 twNM; mCJLO.MGA5N11t 81/03/21. 14.26.34. P d M BEFORE SHLFFLE S M.EL POINT =1EE A5iEr?.Y COTENTM110N ED11 WEA FAT 135 AEIED, A53fnhui A55f0e NOCLlDE FWWMlU N#:31C IL 8A i M E W.l'i = 1 A+ 5 FM 1
104 105 10e 107 lei 105 110 !!!
112 113 Ils 115 lle.
117 116 20 20
.2475.2722.2762.2777.2747.2701.2675.26 0.2744.281E.2874.2@0.2872.284:-
0
.2745.0000.2982.2984.0000.2783.2731.2745.2827.0000.3083.3108.0000.2911
.2801.2996.0000.0000.2982.2512.2745.2756.2854.3052.0000.0u00.3138.2458
.2817.3008.0000.0000.2996.2835.2778.2741.2875.30c1.0000 A 000.3140.26:3
.2792.Wh.3001.3004.0000.2860.2548.2860.2895.0000.308e.3104.0000.2027 25 25
.2751.2821.2838.2851.2867.2925.3018.3028.2956.2919.2024.2931.2932.2873
.2731.2775.2778.2809.2862.3025.0000.0000.3051.2907.28t4.28o0.2874.2841 Figure 3.2751.2796.2798.2819.2e7).3040.0000.0000.3065.2421.2877.2872.20So.2851
.2810.2883.2899.2909.2920.2973. 2 1.3060.2997.2960.20 4.2 % i.2967.2903 0
.2651.0000.3102.3100.00'h.2941.2921.2929.2% 3. W A.3152.3167.0000.2977 Normalization 30 30 Factor = 1.026
.2954.3149.0000.0000.3119.2948.2881.2ft9.2970.3155.0000.0000.3221.3034
.2976.3175.0000.0000.3139.2957.2879.2885.2977.3172.0000.0000.3243.3050
.2960.0000.3192.3184.0000.2959.2894.2900.2977.0000.3225.3244.00v0.3030
.2933.2975.3007.3002.2958.2W3.2860.2865.2913.29?5.3M8.3053.3031.3001 34 34 104 105 106 107 108 109 !!0 til 112 113 114 115 116 117 118
-wvr g-g
-m-4-
- - +
,m ww-w
9 P00R OR GINAL 1-wir CYCLE 3 EK AT 11(is fw2/r'T MyC3HO.Mr35 5M11+
EliO3,;. 14,;.,3,p
_,. (
t IEF0PE SHUFFLE St#tE0 P0thTii!5E ASSES.Y CtXEATGT10N EDIT tifEA FL1105 eftIE!1 ASSE!@.y A55YO7 MXt1LE WJ!"TV N. PEE 1C 1D M
SCkE F A".TCf = 10* 5 F1JAE 1
118 119 120 121 122 123 124 125 20 20
.1202.1215.1246.12'.i.12P.1214.1201
.1267.1304.137e.1351.130'.1247.1222
.1312.1394.0000.00C6.1397.12B3.124!.
.1322.1404.0000.0(Of.1425.1314.1272
.1299.1332.1407.142'.0X4.1334.1317 25 25
.1263.127v.1256.1321.1337.1 M.1422 Figure 3-7
.1244.1247.12th.1264.!?2e.1427 E
.1253.1255.12o8.12*2.1332.1434 F
.1290.12'5.131'.1344.135d.! We.1441 Nor=alization
.1344.137o.144i.14+i.00)>.13ec.134t Factor = 1.009 30 2C
.1MO.14:7.0000.9W;.147c.135E.1314
.1404.1490.(OM.GXe.1464.1342.1202
.170.1422.14H.1483.13?).1?26.1244
.1390.1?ie.1417.1412.1374.132i.1M
$4 54 118 11' 120 121 122 123 124 125 1
WlY CYCLE 3 EE Ai 11000 !sDmT MiC35% nG G11t 61/ 4/21. 14.2:.34. % E O P!.
BE:0P.E SHRLE SrA.ED F01NTW15E ASSE"lLY COV.ENTMil?. EDIT WEL FAT 105 #FLIEb AIEEP5a A5505 NXLIIE r%'M.iu N rE;1C 10 EX fME FA:19 : 10n 5 SME 1
4?
49 50 51 52 53 54 5e 57 5~
5^
60 ei e2 34 34
.0272.0326.0376.0413.0437.04e0.043).0525.05e7.0613.0ee.0705.0734.0%5 35 35
.0326.0414.040'.tfA3.0'45.0552.0560.0621.0e72.0767.0ie'.(713.000'.0025 0
.0377.04n.0000.0(r/>.064?.0629.0653.06'?.07ei.0501.th>.(OM.1045.1029
.0415.M4!.00Xi.00(9.0709.0695.0724.0770.083?.0%S.WA.0000.1104.1075
.0440.(fA9.0650.0710.0727.0756.0M.0ESS.08%.09e9.1063.1102.10E.c.1005
.0464.0556.0632.0697.075).0843.M53.04?S.0982.0%4.1013.104?.1074.1110 Figure 3-8 40 C3
.04'5.0554.0656.0727.0911.0954.0 W.0000.1087.1029.1025.10t0.10'3.1135
.0532.0627.0702.0774.0658.1000.0000.0000.1131.1073.1078.1101.113.:.117:
Normalization
.0576.0686.0775.0843.M00.0+85.1083.1132.1114.1117.1152.117).1193.1219 Factor = 1.010
.062S.0776.0910.0975.0974.095$.1031.1074.1117.1199.1304.1335.1265.1261
.0682.0061.0000.0000.1070.1022.1038.1080.1153.1304.0000.00 M.140E.1341 45 45
.0719.0927.0000.0000.1110.10'.a.1062.1103.1179.1335.0000.00(0.1438.1368
.0751.0921.1059.1115.1094.107).1095.1133.1193.1??4.1407.1437.1388.13e6
.0616.0943.1035.1066.1103.1114.1137.1171.1218.1279.123'.1366.1345.137o 4?
O O-49 50 51
'52 53 54 55 56 57 58 59 60 61 62 L1
I wft CYCLE 4 EOC AT 10500 M C'ffi MYC4%MY4RP3105e RELEil%
Ftc;, 0@4:
BEFEE 94FFLE SCALED POINTWISE ASSES.Y (DNCINTRATION ELli ( AFit. FAT 105 #f tlED)
ASSEMILY AS5701 NUCL1DE N0/MTU 14.MEEIC ID 800 SCALE FW. TOR = 10* 5 PLANE 1 97 99 100 101 102 103 104 105 106 107 108 109 110 til 6
6
.0209.0246.0281.0304.0316.0327.0342.036C.0382.0410.0437.0450.0451.0453
.0256.0320.03e2.0411.040c.0404.0417.0439.0471.0523.0554.0e01.0575.0555
.0300.0392.0000.0000.0491.0469.0478.0'43.0545.0631.0000.0000.0690.0c47
.0335.0433.0000.0000. M44.0525.0530.056'.0606.0692.0000.0000.075?.0710 10 10
.0359.0440.051e.M57.0*43.0578.0e09.063e.06e0.070e.0767.07s". 0760.074?
.0364.0452.0507.05';.0'42.0edi.0715.074i.0732.073S.074;.07e3.0771.0752 Figure 4-1
.0415.04&1.0531.0*43.0e40.0737 F
E.0528.0772.0777.0755.0004.0i22
.0451.0522.0576.0629.064e.0724 E
h.0871.0824.052*. 023e.08'1. W 2
.0493.0579.0646.0695.0731.0757. & O.088;.0872.0872.089e.0012.0915.0923 Normalization 15 Factor = 1.024 15
.0543.0662.0769.0ile. 0004.08)4.0821.0853.0i9.0951.1032.1052.1010.Ms:
.0594.0758.0009.0000.0eL5.%44.0645.0875.0529.104).0000.0000.111e.1047
.0631.0804.0000.0000.0937.0B80.0674.0906.0962.1 W.0000.0000.1150.107+
.0661.0601.0913.0955.0930.0909.0?!B.0946.0993.1065.1156.1171.1120.10*i
.0715.0815.0887.0925.0943.0440.09ec.1006.1052.10'e.1131.1137.1116.1101 20 20 97 96 Sr:
100 101 102 102 104 10' 10:
10' 10i 10:
110 111 1
=Mf CfCLE 4 EOC AT 10500 N 2mi MiC4%Pv4RFi!05 FIDEilk 61/Mr24. Oi.2e.e?.N.:4 OM5 BEFORE SdfFLE SCa.ED H)lhTwliE A5iE"ia CONCENTEATION EDIT iMEA FAT 105 intlEE F L.:
1 Alii".i Y Aiit02 k.G.IDE th2.
- eiG lb H+
IGA FC.T> = 10++ 5 A
112 112 114 115 lle-117 115 120 di 122 12: 124 1:^-
c e.
.04e4.0452.0'0?. 05%.05:6.6431.041).04:4.60e.0525.M44.Mai.Mit.M2
.0571.6615.0-29.0:75.0t ?2.MU.0573.096.0-1?.0-:4.0722.072e.et:..0:r
.0x2.07T.WX.%00.0757.0e8.0:72.0:75.071C.0795.0F>:.0 W.'.011:.074i
.Ch.080'.N7..0000.0?2".0?c4.0752.0V.0'57.0570.W6.M9:.0i:. 0ia 10 10
.07o4.0?10.Dico.0M2.ei43.0033.094t.0554.0957.0c5.0041.M49 %.056
.0798.0015.0?43.0tti.0??4.0024.06i4.1007.0 %4.0020.0419.00!o.0c07.0'v1 Figure 4-2
.0933.0352.b?.091.094.1042.0X6.WXi.16d.0077.06".1.0944.0c44.054:
.OliA.0h6.0917.0441.0983.10?0.0000.00h.1116.1020.10v5.0W9.M'i.060
.094).09e4.Mh.1014.1027.1074.1144.1155.1105.1079.1024.1X5.1072.10e2 Normalization 15 15 Factor = 1.012
.1005.10o5.1143.1157.11 6.1075.1064.1055.1105.1163.1240.1245.1151.113:
.1066.1174.0000.0000.1203.1108.1069.1100.1144.12e4. M 0.0000.1301.1205
.1098.1207.00 W.0000.1236.1136.1110.1121.1170.1300.0000. W e.131e.1240
.1104.1172.1258.1273.1211.1160.1144.1150.1185.1260.134).135?.125'.124.-
.1119.1164.1216.124).1233.1217.1200.1193.1205.1244.1275.127e.1253.123:
20 20 111 112 113 114 115 116 117 118 115 120 121 122 123 124 125
P00R ORIGINM 1
=MY CYC1.I 4 EOC AT 10500 K!D/MT MYC4PDQ,MY4RP5105k REESIGN 81/03/24. 00.29.03 F AGE 0004t BEFME SHLFFLE SCALED POINTWISE ASSEMBLY CONCENTRATION EDIT (AREA RAT 105 APftIEDr ASSEMit.Y ASSYO3 14JCL1DE PWD/MTU NUMERIC ID 800 SCALE FACT @ = 10u 5 PLANE 1
62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 20 20
.0205.0245.0281.0305.0318.0329.0344.0362.0385.0412.0439.0453.0453.0455
.0254.0321.0 25.0415.0411.0400.0422.0444.0477.0529.0590.0607.0581.0563
.0299.0394.0000.0000.0498.0476.048e.0513.0553.0626.0000.0000.0696.0653
.0334.0435.0000.0000.0552.0533.0548.0574.0616.0703.0000.0000.0763.0717
.0358.0442.M21.0564.0571.0587.0619.0e47.0t72.0718.0779.0797.0770.0756 25 25
.0382.0454.0512.05eo.0602.0661.0733.0763.0747.0744.0762.0776.0782.0791
.0412.04S3.05?0.0".01.0651.0751 R
R.0842.0794.0793.0803.0e!'.0SM
.0443.052". 0584.0638.069E.0801 R
R.0802.0844.0843.0853.0666.M7' Figure 4-3
.0490.05?2.0653.070e,.0746.0805.0882.0912.000*.089". 0919.0932.0933.093t
.0540.06e.0778.0829.0821.0824.0853.0882.0914.0978.1061.1078.1032.1001 30 30 Normalization
.M92.0763.0000.0000.0914.0865.0871.0901.0oS7.1080.0000.0006.1142.1067 Factor = 1.032
.0629.0810.0000.0000.0956.0901.0902.0930.0984.1116.0000.0000.1179.1101
.0641.0808.0926.0971.0947.0928.0936.0962.1008.1087.1178.1196.1145.1111
.0720.0828.0904.0942.0953.09".8.0972.0095.1020.1075.1120.1136.1125.1125 34 34 62 67 et e5 6t 67 69 6;
70 71 73 74 75 76 1
=(h CYCLE 4 E00 AT 10500 NDmi MfC4rN er49510"-
REDEi!0:.
61/0N24. F.29.03.FAGE OK BEFORE SHfFLE SCA.ED F01NTwlSE A55EMio COMaiEAT10N EDIT (AFEA RATIO 5 MfLIED)
AiSEaL Ali4 4 NXLIDE N:WTe NTE;i; I:
6' SCALE FACT 0F = 10++
5 FtME 1
7e.
77 7
7; 80 8:
82 83 84 55 it Ei 85 fi c2 20 20
.04 9.04i5.09i:. 0'12.0"i05.0401.04?). M 09.0525.0551.0579.0502.05A1.05:4
.05':.0 0.0 7 4.0651.0i?.0e0c.066).0tD.0ne. 0:02.075).0774.0735.071:
.0e:5.9744. w ;.M.0762.0t%.6611.0c'1.072i.0522.M93.00C *.0571.M15
.071..".:1.M.;. 06:-.033'.0iG.075;.07e?.0iu.0P3.00C0.05). basi.0Bii
.0U1.03:e.01'I.0iH.0hs.0335.0541'.0L.0i:5.0M0.09:3.0473.F34.0'11 25 25
.08 6.0824.084t.0862.0575.0027.099e. 1005.0055.0926.0930.0034.0933.0939
.0645.085e.0869.0890.0930.1034.4X9.0000.10e1.0573.0751.0950.0953.0M Figure 4-4
.0902.0004.0917.0936.0974.1078.0000.0000.110;.1014.0993.0091.0997.1(07
.0943.0965.0903.10:7.1014.105e.1122.1120.1076.1051.105A.10e1.1054.1053
.1015.3049.1138.1145.1087.1051.10 4.1061.1071.1120.1154.1202.!!45.1105 Normalization X-33 Factor = 1.039
.1078.1177.0000.0000.1179.1077.1049.1055.1094.1209.0000.00C0.1246.11to
.1113.1213.0000.0000.1205.1095.1060.1065.1103.1230.(000.0000.1269.1182
.1124.1181.1251.1249.1171.1105.1073.1082.!!!4.1185.1275.125e.1225.11E2
.1151.1186.1212.120i.1175.113?.1108 1109.1135.1184.1224.1235.1220.1205 34 34 76 77 78 79 80 81 82 83 84 8!
6:.
E7 88 89 90
P00R ORIGlWAt WY CYCLE 4 EOC AT 10500 lWD/MT MYC4PL4MY4RPS105A EDE51CN 81/03/24. 09.29.03.PA0E (%4i EFORE SHtFFLE SCALED POINTWISE ASSEMBLY CtNCENTRATION EDIT (AREA RAT 105 APftlE!"
ASSEMBLY ASSYO5 IWCLIIE MWD /MTU HJPERIC 10 800 SCALE FACTC6 = 10++
5 PLANE 1
90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 20 20
.0609.0636.0666.0679.0676.0684.0724.0792.0863.0928.0981.1005.1011.1036
.0733.0790.0862.0678.0836.0811.0025.06>5.0925.1014.1112.1138.1102.1104
.0833.0928.0000.0000.0971.0894.0895.0923.0984.1115.0000.0000.119c.1157
.0898.0992.0000.0000.1034.0962.0 %.0979.1029.1151.0000.0000.1222.1178
.0928.0981.1052.1068.1028.1011.1028.1046.1064.1115.1196.1210.1167.!!67 25 25
.0952.0973.0999.1019.103*.1084.1158.1173.1127.1105.1115.1121.1122.114! Figure 4-5
.0991.0993.1007.1030.1071.1178 R
R.1214.1128.1106.1105.1114.1134
.1016.3029.1043.1063.1103.1208 Fi R.1238.1150.1126.1125.1134.1157 Normalization
.1063.1064.1109.1123.1131.1172.1241.1250.1198.1173.1182.1184.1181.1202Factor = 1.010
.1118.1173.124;.1257.1195.1158.1162.1170.1182.1235.1314.1323.1270.12c2 30 D
.1170.1274.0000.0000.1279.1172.1145.1152.1195.1320.0000.0000.1370.1?1?
.1190.1295.0000.0000.1293.1179.1145.1152.1201.1332.0000.0000.1389.1321
.1189.1246.1321.1321.1243.1177.1154.!!61.1199.1280.1375.1391.1336.1323
.1212.1240.1266.1265.1234.1196.1176.1183.1214.1272.1318.1333.1323.1320 34 34 90 91 92 93 94 95 9e 97 98 90 1(9 101 102 103 104 1
- Y CYCLE 4 E0C AT 10500 M 4/MT MvC4P00 Mi4Ff5105:
REIE516*.
81/03 O. 0:... G.F;JE N -
BEFORE SHLFFLE SCALED FTJINTWISE ASSEG.Y CONCENTMTICri EDIT RREA FAT 105 MP'.!EW ASSEMPLY ASS N NUCtlLE M O MTV NUMERF. 1D E%
SLA.E FACTOR = 10" 5 FtA*2 1 104 105 10e 107 105 10v 11C 111 112 113 114 115 116 11?
116 20 20
.2729.2781.2924.2831.2799.2749.2721.2732.2784.2357.2411.2925.2904.28 1
.27i4.0000.3034.3734.0000.282e. 2772.2764.2863.0C00.3117.3139.00N.20?1
.2645.3043.0000.m.303.2E52.2782.2794.288C.3054.M.0000.3162.2'74
.2m '.3050.0vX.0000.30?S.2872.2612.2823.2905.3090.0000.0000.31e!.247:
.2825.0(6v.3039.3041.0000.2832.2879.2883.2+23.0000.3110.31'6.E.20: 25 25
.2773.2852.2871.2883.2897.2954.3046.3054.2980.2942.2945.294).2945.2679
,2753.2800.2804.2827.2888.30'4.0000.0000.3073.2927.2882.2874.20$4.284:
Figure 4-6
.2767.2816.2819.2841.2901.3061.0000.0000.",o43.2937.2891.28?4.2893.2851
.2822.2898.2916.2926.2038.?99v.3078.3035.;011.2972.2974.2977.2071.29e>
Normalization
.2803.0000.3114.3113.0000.2953.2934.2940.2974.0000.3159.3172.0000.2G72 30 Factor = 1.042 90
.2956.3155.0000.0000.3127.2956.2EM.2896.2976.3160.0000.0000.3219.303
.2974.3176.0000.0000.3142.2964.2832.2889.2979.3173.0000.0000.3237.3029
.2954.0000.3188.3100.0000.2955.28*1.2896.2973.0000.3220.3237.0000.3016
.2924.2964.2996.2991.2947.2886.2649.2854.2901.2972.3025.3030.3015.2921 34 34 104 105 106 107 108 109 110 111 112 113 114 115 11:
117 !!S L
P003ORIGIg2.
1 WIY CYQ.E 4 EOC AT 10500 M/MT MYC4f00.Mv4RP510'e REliEION 81/03/24. v.
.%3E 005 BEFORE SRFFLE SCALED POIKTWISE ASSEMBLY CONCENTRATION ED!1 (AREA RATIO 5 AffLIED)
ASSEMBLY ASSYO7 ItJCLIDE M /MTV NUERIC ID 800 SCALE FACTif = 10**
5 PLANE 1
118 119. 120 121 122 123 124 125 20 20
.1252.1258.1287.1297.1277.1250.1235
.1311.1341.1414.1415.1334.1266.1241
.1354.1431.0000.0000.1411.128L.1259
.1360.1435.0000.0000.1407.1297.1237
.1330.1352.1417.1409.0000.1300.130t 25 25 Figure 4-7
.1291.1282.1295.1300.1302.1347.14'1
.1260.1257.1259.1273.1310.1424 F
.1276.1263.1264.1278.1314.1429 R
Normalization
.1312.1301.1312.1315.1315.1350.14?2 Factor = 1.013
.1367.1365.1447.1436.0000.1320.132?
30 30
.1413.1483.0000.0000.1441.1325.12';
.1427.1498.0000.0000.1458.1325.125"
.1412.1437.1504.1495.1401.1323.1240
.1405.1419.1439.1431.1391.1342.131' 34 24 Ili
!!9 120 121 122 123 124 12*
1
- .1 CYCLE 4 ECC AT 10'00 MWD /MT MvC45IO.Mv4;?i!0*-
RE;ii.%
61'03/24. (;:.".01.F.4E w t BEF05E SHIFLE SLALED POINTWISE A53E9.) Ot:ENTW10s ELIT WE; F4110i AH !E%
AETENs f A55YO?
NUCLIIC NWD+1)
Pr.G.:. :D in-STA E F.'.:TCA = 10++ E PWd 48 45 50 51 52 53
- 4 te.
Se
- 7
!i
- d e0 el e2 34 34
.0259.0309.0356.0301.0413.0415.04t2.04 '5.0534.0560.0e27.0:Si.0e32.0721 35 25
.0310.0393.0474.0516.0517.0523.054i.0E.0e?.0721.M15.0655.0iG.014
.035; 'J475.00(0.0000.0615.05'?.0t1?.0650.0724.0645.00%.0000.007:.0+
.0?'5.0519.0000.0000.0674.0t!'.oeit.0728.0741.04 ;.E.E.102i.0;i-1
.0419.0522.0619.0676.0641.072v.07ei.0ev5.0847.0013.1(00.103 1011.10e Figure 4-8
.0443.0530.0602.06M.0722.080e.0905.0047.0029.0029.00*4.0653.0m.101c AJ 4
.0473.05*4.0626.0693.0773.0903.0000.(e ;.10X.0472.0"!.0%.1017.104 Normalization
.023.0599.0671.0739.0818.0555.000;.(e.1M3.1014.1cle. 193).1v54.1.ch Factor = 1.013
.0550.065e 0741.0805.0E59.00!v.107.10h.!W.1057.101.llif.1111.!!2.
.0601.0743.0871.0933.0931.(642.(rh. 1021.1060.1126.1212.125c 120;.11E.
.0652.C843.0000.0000.1023.097e.(r4).1027.10'4.123e.00(6.0C00.1317.121.:
45 45
.0688.0008.0000.0000.1061.1005.1011.1041.1118.1264.M.0000.1343.129
.0716.0879.1010.1064.1042.1026.1049.1073.1128.1221.1325.1347.12'I.1251
.0773.0892.0978.1026.1040.1050.10:0.1(6 *.1141.110s.1248.1267.1255.1244 48 41 48 49 50 51 52 53 58 55 to 57 58 59 e ':-
of e2
Maine Yankee Vessel Flucnce Calcu'ation Capusle Holder Location G. M. Solar:
The location of the capsule holder, relative to the vessel wall, is provided in Figure 1.
The dimensions of the capsule holder are given. The centerline of the capsule holder tube is 1.73 to 1.79 inches f rom the vessel wall. There is 0.96 to 1.02 inches between the capsule holder and ;he vessel wall.
The as-buil t distance from the core center to the centerline of the capsule holder tube is given in Figure 2 for Capsule 263. The ceasurements are made at the locations of the top and bottom supports for the capsule holder tube.
O
I
'.1. *. 0
...:.L-4 a; su.e :n.ot:
3..
Loca:1cn..c.stive tc... esse.
at-.
Dimensior.t
- 1. in:. c.
1.73 to 1.79 m
~
r a
L.-
m I
i
(
l]
l
(
l '-
c 1.263
,0.96 te r,
m m
j r
s r
' ~.0-t le N
- c
- :
Distanc.
4 1
c C T. L L; 7 LC : C:s*. t :-
d C
line of vesic" 1:2.11
=
=
, t d e-asse:
3-see Ti;=c e
u l
l I
e u
l 1
u u
l I
i 1.539 I
is
-r I
i i
I i
w s
- 16 A
i i
l I
- 0 l
3','n W'
3/lb
(
l t
t I.
,n,
..Li! E
') i;.r.t t Capsule F.cicer Lo.n.er fer 'apru.e h.
D_sensiens in in::.es 1.,,,., t., c.- -
/,
h 5
3L--
D:.stan:e tc c:re cen:er E5-29 N (as-buil: )
J_
u
=
e sr i
co
=
m 3
4
_ =_
v.
~~
- n SC U
r l
l l
t i
1 a.L.
g--
J 5
SC_
Distance to core center i
^
l 85-3/8 5-15/16 (as-built) f
%f l
I 1'
l
--