ML19327C195
| ML19327C195 | |
| Person / Time | |
|---|---|
| Site: | Palo Verde  |
| Issue date: | 10/31/1989 |
| From: | ABB COMBUSTION ENGINEERING NUCLEAR FUEL (FORMERLY |
| To: | |
| Shared Package | |
| ML17305A394 | List: |
| References | |
| CEN-390(V)-NP, NUDOCS 8911210134 | |
| Download: ML19327C195 (27) | |
Text
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i PALO VERDE NUCLEAR GENERATING STATION - UNIT 1
' J.,
END-OF-CYCLE 2 FUEL EXAMINATION REPORT J
CEN-390(V)-NP 1
Oc+ober, 1989 l
A Report to i
Arizona Public Services Company ll:
from i
l:-
l Combustion Engineering, Inc.
i f-Nuclear Power Systems
- t. 'i l l.
Windsor, Connecticut 1'L i
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l 891121 J28 PDR A
g, PDC i
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g 1-LEGAL NOTICE y
TlilS REPORT WAS PREPARED AS AN ACCOUNT OF WORK PERFORMED BY COMBUSTION ENGINEERING, INC.
NEITHER COMBUSTION ENGINEERING NOR ANY PERSON ACTING ON ITS BEHALF:
A.
MAKES ANY WARRANTY OR REPRESENTATION, EXPRESSED OR IMPLIED INCLUDING I
THE WARRANTIES OF FITNESS FOR A PARTICULAR PURPOSE OR MERCHANTABILITY, l
WITH RESPECT TO THE ACCURACY, COMPLETENESS, OR USEFULNESS OF THE l-INFORMATION CONTAINED IN THIS REPORT,-OR THAT THE USE OF ANY INFORMATION, APPARATUS, METHOD, OR PROCESS DISCLOSED IN THIS REPORT l
MAY NOT INFRINGE PRIVATELY OWNED RIGHTS; OR 1
B.
ASSUMES ANY LIABILITIES WITH RESPECT TO THE USE OF, OR FOR DAMAGES RESULTING FROM THE USE OF, ANY INFORMATION, APPARATUS, METHOD OR i
L PROCESS DISCLOSED IN THIS REPORT.
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I' Table of Contents Section
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1.0 INTR 000CTION 11 2.0.
FUEL ASSEMBLY DIMENSIONAL CHANGE EVALUATION 2-1 2.1 Pre-Shutdown Evaluation 2-1
{.
'f
2.2 Dimensional
Change Data 2-2 2.3 Post-Shutdown Evaluation 2-2 c
3.0
SUMMARY
AND CONCLUSIONS 3-1
4.0 REFERENCES
4-1 i
l APPENDIX A Palo' Verde 1 Cycle 2 Fuel Assembly Dimensional Change Data e
i i
8
[( ' -I r
3
':L q
7,.' s-L 1
List of Tables.
IAhlt 11111 Ensut i
l' Palo Verde-1 Fuel Assemblies inspected 1-2
,e at EOC-2 e
f f
,,z
+
List of Figures 1
(
P Fiaure 1111g Eggg 1-Palo ' Verde-1 Shoulder Gap Decrease 2-4 2
Palo Verde-l Guide Tube Growth 2-5 e
3 Palo Verde-l. Fuel Rod Growth' 2-6 t
,y Appendix A Fuel Assembly Dimensional Change Data A-1 t
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1.0 INTRODUCTION
s This report documents fuel examinations conducted during the End-of-Cycle 2 refueling outage at Palo Verde Nuclear Generating
[
Station-Unit 1.
The inspections were performed to fulfill examination requirements for E00-2 that are specified by the Palo Verde-1
'~
operating license.
The inspections performed were dimensiona'i measurements' to characterize fuel rod and assembly growth. A total of 10 fuel assemblies were' inspected. Table 1 lists the assemblies and provides pertinent data for each.
A L
h 4
1 4
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1-1
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I Table 1 Palo Verde-1 Fuel Assemblies InspectedIII at E0C-2 Number of Cycle-2 E00-2 Assembly Assembly +
Cycles Discharged Core Avg. Burnup Serial Number -
Jyradiated f_[Q M Location (GWd/MTU)
B120*(2) 2 x
H13 30.3 P2B233(2) 2 x
P7 31.1 C002 2
JS 24,9 C005(2) 2 J8 24.8 3
C017 2
K14 22.3 C025(2) 2 M6 24.2' C039 2
H9 24.8 P2C114 2
x K15 30.2 D001*
1 P15 11.5 D002*
1 R14 11.5
+ Serial numbers prefixed by P1 unless otherwise noted.
Characterized fuel assembly.
II) Peripheral fuel rod shoulder gap and guide tube length measurements.
(2) Assembly previously measured at E0C-1.
1-2
-dl
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'c.
]
1 2.0 FUEL ASSEMBLY DIMENSIONAL CHANGE EVALUATION l
b Fuel rod shoulder gap (distance between the top of the fuel rods and the bottom of the upper end fitting) and guide tube length
. measurements were made at Palo Verde-1 during the EOC-2 outage. A total of ten fuel assemblies were measured; two Batch B, six Batch C, and two Batch D.
The specific fuel assemblies inspected are identified in Table 1.
The shoulder gap of peripheral fuel rods on i
d, the four faces of each fuel assembly was measured optically using a periscope, while each of the four outer guide tubes was measured using the guide-tube length measurement tool.
c
'3 2.1 Pre-Shutdown Evaluation The shoulder gap evaluation for Palo Verde-1 Cycle 3 fuel is identical L
to the method used for Palo Verde-1 Cycle 2 (Reference 1), i.e.,
l.
remaining shoulder gap predictions were based on the minimum available shoulder gap at the beginning of life, a conservatively high fuel rod I.
growth prediction, and'a conservatively low guide tube growth prediction. These parameters are discussed in more detail below:
a.
The minimum available shoulder gap at the beginning of life t
L accouated for component dimensional tolerances, elastic l
compression of the guide tubes, and differential thermal expansion between the fuel rods and the guide tubes.
b.
The conservatively low guide tube growth prediction utilized the lower 95% valut calculated using the methods described in Reference 2.
c.
The conservatively high fuel rod growth prediction was taken from the ANO-2 Batch C data as 0.21 inches of growth per unit of fluence (unyt or nyt x 10-21) (Reference 3). This growth rate represents more growth than the 95/95 upper limit for the 2-1
f-e v
i distribution of Batch C data from ANO-2. These data represent the fuel whose high fluence rods had the highest observed gruveth
~
rate of any fuel examined by C-E.
Implementation of this approach for the Palo Verde-1 fuel assemblies
+
showed that all shoulder gaps were predicted to have clearance at the end of Cycle 3.
Therefore, if shed1 der gap and guida-tube length measurements taken on the ten Palo Verde-1 fuel assemblies support the applicability of the design basis, the third cycle fuel would be justified for Cycle 3 operation.
2.2 Dimensional Change Data
{
' The individual shoulder gap measurements are tabulated in Appendix A.
p Tables A-1 through A-10, along with a table of the length change for each measured guide tube, Table A 11. For each shoulder gap measured, the tabulation in Appendix A also contains the initial shoulder gap (measured value if available, otherwise the nominal value from the L
desig a drawings), the resulting shoulder gap change (initial gap -
EOC-2 gap), the inferred fuel rod growth (shoulder gap change plus guide tube growth), fuel rod growth strain. (fuel rod growth / nominal BOL rod length), and the fuel rod's axial average fast fluence. Guide tube information (average growth and average fluence) is included at the bottom of each fuel assembly's shoulder gap tabulation. The s
shoulder gap change data, guide tube grcwth data, and fuel rod growth
'A data are plotted relative to the appropriate fast fluence in Figures 1, 2, and 3, respectively. Also plotted on these figures are data R.
obtained from the measurement of Palo Verde-1 fuel assemblies inspected during the E0C-1 outage (Reference 1).
I 1.
l 2.3 Post-Shutdown Evaluation Guide tube length change data are shown in Figure 2 along with the limiting (lower 95% and upper 957.) length change predictions resulting 2-2
..n_,
a 4-1
- ~
I from the method described. in Reference (2). The figure shows that the measured data are all above the lower 95% predicted growth so it is conclumed that' it is conservative to use the guide tube length change model' when predicting limiting shoulder gap changes.
Fuel rod growth data are shown in Figure 3 along with the growth l
prediction taken from the ANO-2 Batch C data (0.21 inches /unvt). The
[
figure shows that the higher fluence data are all below the design basis and the trend of the data is for increased margin at higher fluences. Therefore, it.is conservative to use the fuel rod growth model when predicting limiting shoulder gap changes.
5 The predictive models for guide tube growth and fuel rod growth have 7
been shown to be conservative relative to the Palo Verde-1 data.
Therefore,. the shoulder gao evaluation technique is acceptable for determining the fluence capabilities for Palo Verde fuel. 1he fluence capabilities calculated by the technique for all fuel assembiies in Cycle 3 exceed the peak fuel rod fluence at E00-3. Therefore, the i
shoulder gap provided is sufficient and the fuel's operation in
' Cycle 3 will not cause complete closure of any fuel rod shoulder gap.
6 '
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2-3
y -.
~ ' ' ' '
~
Ne-
.g, p..g G U Q E=
1-
~
PALO' VERDE 1 SHOULDER LGAP DECREASE
~
'AT EOC-1 AND EOC-2 i
^
.5 v
w m<
w m
Ow 14 o
a k
a O
m wo 4
a i
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2 4
6 FLUENCE XE-21 (n/cm",E>.821 MeV)
+
EOC-1 DATA A
EOC-2 DATA n,
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<,.,16~r.
~,,,.
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^
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~
- 1
- z. j F
I G U.R E 2
79
- a ; _.
PALO VERDE 1 GUIDE TUBE GROWTH
' AT EOC-1 AND EOC-2.
I i
^
E v
I 3:
O
.'e tr o
w m
3 s
u 9
a O
4 O
O 2
4 6
FLUENCE XE-21 (n/crr 2. E>O.821 MeV)
+
EOC-1 DATA -
A
. EOC-2 DATA
~
m
,.__,_..___,____,m.
c-:
a.
_ r ;-
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~
F.I G U R'E'
.3 PALO VERDE 1 FUEL ROD GROWTH
- AT EOC-1. AND EOC-2
~
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,co O
oo E
J taJ 3
a i
0.0 g
i 0
2 4
6.
FLUENCE XE-21 (n/cm,E>.821 MeV)
+
EOC-1 DATA A
EOC-2 DATA
.-,s
= ' -
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~ -~ ~
~~
l y
3.0 SUMr4ARY AND CONCLUSIONS p
Dimensional measurements of peripheral fuel rod shoulder gap and guide tube length were performed on 10 Palo Verde-1 fuel assemblies L
following Cycle 2.
Fuel rod growth data, determined from the measurements, indicates that the growth of high fluence fuel rods is less than the growth predicted by the model used to determine design limits for shoulder gap.
In addition, the trend of the data is for increased margin between rod growth and the design basis at higher j
fluences.
Guide tube length measurements indicate that the measured assembliesgrewfrom[
]to[
] inches during two cycles of exposure 21 with average guide tube fluences up to 5.49x10 n/cm2 (E >. 821 MeV) and assembly average burnups up to 31.1 GWd/MTU. The measured guide 3
tube growth is greater than *.he lower 95% predicted growth that was t
used to determine design limits for shoulder gap.
Based on the fuel assembly dimensional. measurements performed at EOC-2, the predictive models for guide tube and fuel rod growth have been shown to be conservative for Palo Verde-1 assemblies. As a result, adequate margin for shoulder gap reduction exists in all fuel assemblies designated for operation in Palo Verde-1 Cycle 3.
- 1 3-1
.M D
?
4.0 REFERENCES
(1) CE NPSD-428-P, "Palo Verde Nuclear Generating Station-Unit 1, End-of-Cycle 1 Fuel Examination Report, issued December, 1987.
(2) CENPD-269-P, Rev.1-P, " Extended Burnup Operation of Combustion.
+
Engineering PWR Fuel", issued July,1984.
(3) CEN-309 (A)-P, " Arkansas Nuclear One, Unit 2 Cycle 5 Shoulder Gap Evaluation",' issued July, 1985.
L 1
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6 4-1
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- i.
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a
,e APPENDIX A Palo Verde 1 Cycle 2
..o Fuel Assemb1v Dimensional 'Chanae Data i
e 5
t i
I 1
i NOTE:' " ERR" on Tables A-1 through A-10 identifies values that could not be determined. The rod shoulder gap could not be measured because the gap was so large it was outside the range of optical z.:
measurement.
Fuel rod growth strains were calculated using nominal i
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L..
BOL rod length.
1, A-1
J 0'
l Table A-3
]
ASSEMBLY SERIAL NO P18120 FACE:
0 FACE:
90 L
E0 Cat E0C+2 GAP RQD GROWTN E0Ca2 EOC 2 GAP ROD GROWTN 80L GAP FLUEWCE' SN. GAP Closure GROWTN STRAlk 00L GAP FLUENCE * $N. GAP CLOSURE GROWTN STRAIN ROD (in.) (n/sq.cm) (In.)
(in.)
(in.)
(K) t00 (in.) (n/sq.ca) (In.)
(In.)
(in.)
(3)
.............................................................g
.............................g..............................g, 1
2.469 5.780 1
2.500 5.700 2
2.453 5.809 2
2.516 5.736 3
2.453 5.928 3
2.500 5.859 4
2.453 5.977 4
2.516 5.914 5
2.437 5.978 5
2.484 5.921 6
2.437 5.972 6
2.500 5.924 7
2.437 6.012 7
2.469 5.974 8
2.437 6.042 8
2.484 6.018 9
2.453 6.011 9
2.484 6.039 10 2.437 5.963 10 2.484 6.006 11 2.422 5.908 11 2.469 5.970 i
12 2.422 5.898 12 2.469 5.979
' 13 2.406 5.881 13 2.453 5.980 l
14 2.406 5.816 14 2.469 5.932 15 2.406 5.679 15 2.453 5.813 16 2.422 5.629 16 2.500 5.750 l
1 FACE:
180 FACE:
270 EOC 2 EOC+2 GAP ROD GROWTN EOC 2 EOC 2 GAP ROD GROWTN l
BOL '.AP FLUENCE' SN. CAP CLOSURE GROWTH STRAIN BOL GAP FLUENCE' SN. GAP CLOSURE GROWTH STRAIN 4
l ROD (in.) (n/sq.cm) (in.)
(in.)
(In.)
(1)
RCD (in.) (r/sq.cm) (In.)
(in.)
(In.)
(1)
~
~
1 2.453 5.644 1
2.422 5.629 2
2.422 5.668 2
2.422 5.633 1
3
- 422 5.771 3
2.422 5.723 4
2.422 5.80S 4
2.437 5.750 5
2.422 5.804 5
2.453 5.738 6
2.422 5.798 6
2.437 5.72) 7 2.437 5.838 7
2.437 5,760 8
2.437 5.8 74 8
2.437 5.792 9
2.422 5.900 9
2.437 5.779 10 2.437 5.871 10 2.434 5.751 11 2.422 5.837 11 2.500 5.720
'12' 2.453 5.848 12 2.437 5.738 l
13 2.453 5.855 13 2,453 5. 75 5 14 2.500 5.822 14 2.453 5.732 15 2.453 5.721 15 2.437 5.645 16 2.500 5.700 16 2.433 5.644
- 1) NOMINAL 80L SHOULDER CAP. CHARACTERIZED
- 2) EOC 2 AVC GUIDE TUBE GROWTN.
(
)in.
- 3) foc 2 AVG GUIDE TL'8E FLUENCE.
5.486 X1E21,n/sq.cm.
- 4) BOL ROD LENGTN.
161.168 in.
- FLUENCE E. 0.821 MeV A-2
,3, *.
q a
1 Table A 2 1
~ ASSEMBLY SERI AL wo P2b233 FACE :
0 FACE:
GROWTM EOC 2 E0C+2 GAP RCD GROWTH 80L GAP FLUENCE *. GM. GAP CLOSURE GRobfM STRAIN 80L GAP FLUENCE
- SM. GAP CLOSURE GROWTM $1 RAIN RCD (In.) (Wsq.cm) (In.)
(in.)
(In.)
(1)
RCD (In.) (Wsq.am) (in.)
(in.)
(In.)
(1) er....................................
...............................................................J 4
~
~
1 1.682 5.853 1
1.682 5.956 2
1.682 5.878 2
1.M2 5.986 3
1.682 5.983 3
1.682 6.108 4
1.682 L.02C-4 1.682 6.159 5
1.682 6.015 5
1.M2 6.158 6
1.682 6.006 6
1.682 6.149 7
1.682 6.S44 7
1.682 6.188 8
1.682 6.076 8
1.682 6.218 9
1.682 6.056 9
1.682 6.213 10.
1.682 6.026 10 1.682 6.169 11 1.642 5.992 11 1.682 6.116 0
12 1.682 6.004 12 1.682 6.110 13 1.682 6.014
- 13 1.682 6.096 14 1.682 5.982 14 1.682 6.033 15 1.682 5.884 15 1.682 5.898 16 1.682 5.869 16
,1.682 5.855 FACE:
180 FACE:
2 70 EOC 2 E0C 2 GAP RCD GROWTM EOC 2 ECC 2 GAP RCD GROWTM SQL GAP FLUENCE' SM. GAP CLOSURE GROWTM $1 RAIN 80L GAP FLUENCE' SM. GAP CLOSURE GROJTM $ TRAIN RCD (in.) (Wsq.cm) (In.)
(in.)
(in.)
(3)
RCD (In.) (Wsq.cm) (in.)
(In.)
(in.)
(t)
~
~
1 1.682 5.857 1
1.682 5.869 2
1.682 5.889 2
1.682 5.898 3
1.682 6.005 3
1.682 6.012 4
1.682 6.054 4
1.682 6.059 5
1.682 6.059 5
1.682 6.060 6
1.682 6.058 6
1.682 6.056 7
1.682 6.103 7
1.682 6.096 8
1.682 6.141 8
1.682 6.130 9
1.682 6.168 9
1.682 6.127 10 1.682.
6.140 10 1.682 6.094 11 1.682 6.106 11 1.682 6.053 12 1.682 6.116 12 1.682 6.056 13 1.682 6.122 13 1.682 6.053
'f4 1.682 6.084 14 1.682 6.005 15 1.682 5.9 77 15 1.682 5.889 16 1.682 5.956 16 1.682 5.857
- 1) NOMINAL SQL SHOULDER GAP.
1.682 in.
- 2) EDC 2 AVG GUIDE TUsE GRouTM.
[
]In.
- 3) E0C 2 AVG GUIDE TUBE FLUENCE.
5.666 X1E21,Wsq.cm.
- 4) BOL R00 LENGIM.
161.168 in.
- FLUENCE E > 0.821 MeV A-3
. c.:
3 Table A 3 1
. Al8ENBLT SERIAL NO PIC002 F ACE : '
O FACE:
90 1
E0C 2 E0C+2 '
GAP RCD GROWTH E0C 2 EOC 2 GAP RCD GR M N f:0L fd* FLUENCE SN.' GAP CLOSURE GROWTH STRAIN 80L GAP FLUENCE' SN. GAP CLOSURE GROWTH STRAIN
' RCD
( is..' (Wsq.es) (in.)
(in.)
(in.)
(E)
RCD (in.) (Waq.ce) (in.)
(in.)
(In.) -
(t) es e ns u n.m.
u........u.....
...un.n u u s...... w..
..... u.....u.... u........ u..... u u n u...u.n u u n u u a
1 2.382 5.329
~
1 2.382 3.403 J
2-2.382 - 5.385 2
2.382 3.633 i
3 2.382 5.445 3
2.382 3.865 '
l 4
~2.382 S.472 4
2.382 4.069 5
2.382' 5.485 5
2.182 4.251
'6 2.382 5.491 6
2.382 4.418 7
2.382 5.493 7
2.382 4.575 i
8 2.382 5.486 8
2.382 4.723
~
'9 2.382 5.486 9
2.382 4.816 l
' 10 2.382 5.493 -
. 10 2.382 4.936
~
11
.2.382 5.491 11 2.382 5.044 12 2.382 5.485' 12 2.382 5.143 13 2.382 5.472-13 2.382 5.226 14 2.382 5.445-14 2.382 5.288 15.
2.382 5.385,
15 2.382 5.312 16 2.382 :5.329 16 2.382 5.329 L
?-
FACE:
180 FACE:
270 EOC 2 EOC.2 GAP RCD Ga0WTH EOC 2 ECC 2 GAP RCD GROWTN 80L GAP FLUENCE
- SN. SAP CLOSURE GROWTN STRAIN SQL GAP FLUENCE
- SN. GAP CLOSURE GROWTN STRAIN RCD (In.) (n/sq.cm) (in.)
(In.)
(in.)
(E)
R00 (In.) (n/sq.ce) (In.) -
( I n.".
(In.)
(t) i es.............................................................
l}
1' 2.382 3.403 1
2.382' 5.329 J
~
~
2 2.382.
3.450' 2
2.382 5.312
(~
-3 2.382 ' ' 3.453.
3 2.382 5.288 4
2.382 3.455 4
2.382 5.226 l
5 2.382 3.453 5
2.342 5.143 i
6' 2.382 3.449 6
2.342 5.044 7
2.382.
3.444 -
7 2.382 4.936
- 8 2.342 3.432 8
2.382 4.816
?
9
- 2.382 3.432 9
2.382 4.723 I
L 10 2.382 3.444 10 2.382 4.575 11 2.382 3.449 11 2.382 4.418
(
12 2.382 3.453 12 2.382 4.251 i.
13 2.382 3.455 13 2.382 4.069 14l 2.382 3.453 14 2.382 3.865 lL 15 2.382 3.430 15 2.342 3.633 l
16 2.382 3.403 16 2.382 3.403
- 1) NOMINAL 80L SHOULDER GAP.
2.382 in.
- 2) EDC 2 AVG GUIDE TUSE GROWTN.
(
31n.
- 3) EOC+2 AVG GUIDE TUBE FLUENCE.
4.412 X1E21,n/sq.ca.
1
- 4) BOL RCD LENGTN.
161.168 in.
It
- FLUENCE E > 0.821 MeV l..
l l
l l
l 1
A-4 1
- ~. -
,,,.,,.m-.
m.,..,
m_ - _ -.. -,. -., -..,
(
o 9
[.
e Table A 4 ASSEMBLY SERIAL bo P1C005 FACE:
0 FACE:
90 l'
E0C+2 E0C 2 GAP RCD GROWTH E0C 2 EOC 2 GAP RCD Ga0WTu BOL GAP FLUENCE
- SN. GAP CLOSURE GROWTH STRAIN tot GAP FLUENCE
- SN. GAP CLOSURE GROWTM STRAIN RCD (In.) (n/sq.om) (In.)
(In.)
(in.)
(X)
RCD (In.) (W sq.am) (In.)
(In.)
(in.)
(S)
.Stase.ceessemees. as.cossessessessesseseassososenessesse.essene sossees.nessesseossesseess ao..seessasses.seassesse..s.cos...es
~
~
~
~
1 2.382 3.292 1
2.382 5.356 2-2.342 3.322 2
2.382 5.336 3
2.382 3.348 3
2.382 5.306 4
2.342 3.354 4
2.342 5.237 5
2.342 3.356 5
2.382 5.144 6
2.382 3.358 6
2.382 5.033 7
2.382 3.360 7
2.382 4.908 8
2.382 3.356 8
2.382 4.767 9
2.382 3.356 9
2.382 4.742 to 2.362 3.360 i 10 2.382 4.566 11 2.382 3.358
! 11 2.382 4.387 I'
12 2.382 3.356 12 2.382 4.203 13 2.382 3.354 13 2.382 4.003 14 2.382 3.348 14 2.382 3.783 15 2.382 3.322 15 2.382 3.537 16 2.382 3.292 16 2.382 3.1292 FACE:
180 FACET 270 ECC 2 EOC 2 GAP RCD GROWTN EOCa2 EOC 2 GAP RQD tiROWTH BOL GAP FLUENCE
- SN. GAP CLOSURE GROWTH STRAIN SQL GAP FLUENCE' SN. GAP CLOSURE GROWTH STRAfW RCD (In.) (n/sq.om) (In.)
(In.)
(In.)
(X)
RCD (In.) (n/sq.om) (In.)
(In.)
(In.)
(1)
...s................es.......e..................s
....o....se................................................r,..
1 2.382 5.356 1
2.382 3.292 2
2.382 5.383 2
2.382 3.537 3
2.382 5.417 3
2.382 3.783 4
2.382 5.422 4
2.382 4.003 5
2.382 5.414 5
2.382 4.203 6
2.382 5.403 6
2.382 4.387 7
2.382 5.397 7
2.382 4.566 8
2.382 5.393 8
2.382 4.742 9
2.382 5.393 9
2.382 4.76 7 to 2.382 5.397 10 2.382 4.908 11 2.382 5.403 11 2.382 5.C33 12 2.382 5.414 12 2.382 5.144 13 2.382 5.422 13 2.382 3.237 14 2.3G2 5.417 14 2.382 5.306 15 2.382 5.383 15 2J82 5.336 16 2.382 5.356 16 2.382 5.356
.a
- 1) NOMINAL BOL SHOULDER CAP.
2.382 In.
- 2) E0Ca2 AVG GUIDE TUBE GROWTH.
( 3 In.
- 3) EOC 2 AVG GUIDE TUBE FLUEN:E.
4.384 x1E21,n/sq.cm.
- 4) Bol ROD LENGTH.
161.168 In.
- 7LUENCE E > 0.821 MeV
-E
a.
Table A-5 j
ASSEMBLY SERIAL N0 P1C017 FACE:
0 FACE:
90 EOC 2 E')C 2 GAP RCD GROWTH EOC 2 EOC 2 GAP RCD GROWTH 80L GAP FLUENCE
- SN. GAP CLOSURE GROWTH STRAIN 80L GAD FLUENCE
- SN. GAP CLOSURE GROWTN STRAIN R@
(in.) (n/sq.ce) (in.)
(in.)
(In.)
(1)
RCD (in.) (n/sq.cm) (in.)
(In.)
(in.)
(1) s6.............................................................
~
~
~
1 2.342 5.247 1
2.382 4.003 2
2.342 5.225 2
2.342 4.188 3
2.382 5.197 3
2.382 4.365 i
4 2.382 5.134 4
2.382 4.505 5
2.382 5.052 5
2.382 4.624 6
2.342 4.958 6
2.382 4.750
.7 2.382 4.857 7
2.382 4.829 8
2.382 4.748 8
2.382 4.918 9
2.382 4.667 9
2.382 4.970 10 2.382 4.533 10 2.382 5.037
/
11 2.382 4.391 11 2.382 5.097 9
'12 2.382 4.242 12 2.382 5.154
-(
13 2.382 4.079 13 2.382 5.203 14 2.382 3.897 14 2.382 5.237 15 2.382 3.685 15 2.382 5.240
.16 2.382 3.482 16 2.382 5.247 FACET 180' FACE:
270 E0C=2 E0C=2 GAP ROD GROWTH EOC 2 EDC 2 GAP ROU GROWTN 90L GAP FLUEN*E' SN. GAP CLOSURE GROWTH STRAIN BOL GAP FLUENCE' $N. GAP CLOSURE GROWTH STRAlu ROD (In.) (n/sq.cm) (In.)
(in.)
(in.)
(S)
ROD (in.) (n/sq.ca) (In.)
(in.)
(in.)
(S)
............r...................................................
............................r..................................
~
~
~
1 2.382 2.777 1
2.382 3.482 7
2 2.382 2.861 2
2.382 3.4 78 3
2.382 2.948 3
2.382 3.471 4
2.382 3.019 4
2.382 3.441 5
2.382 3.086 5
2.382 3.404 6
2.382 3.154 6
2.382 3.364 7
2.382 3.225 7
2.382 3.321 8
2.382 3.297 8
2.382 3.2 72 9
2.382 3.356 9
2.382 3.236 10 2.382 3.435 10 2.382 3.191 11 2.382 3.517 11 2.382 3.138 l
12 2.382 3.607 12 2.382 3.082 l
13 2.382 3.707; 1'l 2.382 3.022 l
14 2.382 3.813 14 2.382 2.953 l
15 2.382 3.905 15 2.382 2.866 16 2.382 4.003 16 1.382 2.777 j
- 1) NOMINAL BOL SHOULDER CAP.
2.382 in.
l
- 2) EOC 2 AVG GUIDE TL BE GROWTH.
[
]in.
I
- 3) EOC+2 AVG Gul0E TU8E FLUENCE.
3.915 x1E21,n/sq.cm.
- 4) SQL ROD LENGTH.
161.168 in.
- FLUENCE E > 0.821 MeV 1
I l
1^
hU
o Table A*b g
\\
,e AlHe't? MalAL to P1C025 n-fact 0
Fact:
90 l
10Ca2 50C 2 tsAP top WMN 80C*2 10 Cat GAP kte Gt M k 00L f.AP FLWhCt' BN. GAP CLOSUtt Sm M N
$1*dW 80L GAP FLWWF(' $N. GAP CLDBurt GA M N $1RAlt B00 (in.) (Wee.se) (In.)
(In.)
(In.)
(t) t0D (in.) W eq.en) (in.)
(In.)
(in.)
(t) e..............................................................
...............................................................i 1
2.M2 f.916 1
2.M2 4.366
)
~
1 f.M2 3.038 2
2.342 4.291 3
f.M2 3.159 3
2.342 4.212 4
2.341 3.261 4
2.342 4.110 5
2.342
).M0 5
2.342 4.006 i
'6 2.342 3.457 6
2.342 3.907 T
2.342 3.552 F
> *M U.011 8
f.M2 3.N3 8
2.M2 3.715 9
2.M2 3.715 9
2.342 3,.642 i
10 2.M2 3 411 10 2.342 3.552 11 2.M2 3.907 11 2.M2 3.457 t
12
- 2. 5" 4.006 12 2.342, 3.360 13 2.342 4.110 13 2.342 3.762 14 2.342 4.212 14 2.342 3.159 15 2.M2 4.292 15 2.342 3.037 t
16 2.342 4.M7 16 2.342 2.916 FACE:
100 FACR 270 E:k".2 10C*2 tiAP 900 GR M N E0 Cat 80C 2 GAP 900 Gt M N DOL GAP FluthCt' $N. fsAP CLOBURE fik M N $fAAlt SOL GAP FLUIPCt* $N. MP CLOSukt Gt M N $1kAIN 800 (In.) Weg.cs) (in.)
(in.)
(In.)
(1) too (In.) Wsq.as) (in.)
(In.)
(In.)
(t) e3.............................................................
~
i 1
2.342 5.575 1
2.342 4.MT
~
~
2 2.342 5.5 72 2
2.22 4.519
(
3 2.342 5.570 3
2.342 4.672 4
2.M2 5.533 4
2.342 4.806 5
f.M2 5.441 5
2.342 4.918 6
2.M2 5.420 6
2 342 5.019 7
2.342 5.35' 7
2.342 5.118 4
2.342 5.285 4
2.342 5.212 9
2.342 5.213 9
2.342 5.243 10 2.M2 5.119 10 2.342 5.356 11 2.D2 5.020 11 2.342 5.420 12 2.342 4.958 12 2.M2 5.641 13 2.342 4.406 13 2.342 5.534 14 2.M2 4.677 14 2.342 5.570
+
15 2.342 4.519 15 1.342 5.5 73 16 ~
2.342 4,366 16 2.342 5.5 75
- 1) WDMlWAL BOL $h:kJL0f t CAP.
2.M2 in.
- 2) EM'2 AVG G'.;IDE TL4! CRMM.
(
)in.
- 3) IfX*2 AVG GUIDE TUlf fluth:t.
4,299 31(21,v sq.co.
4* BDL ROD LENGTN.
161.168 in.
- FlutWCC (. 0.421 MeV A.-
4
t t
t Table A 7 i
Al6tatti Sill &L WO P1CO39 i
i Fact 0
Fact 90 1
00C 2 00C+t MP R@
at M W
$0C+2 L oC 2 GAP ROD Ot M N
{
DOL f.4P FLUCWCi' St. ts4P CL'Igutt Sk M N linAlk DOL (AP FlutWCt'
$N. GAP CLOSutt Ga M u $1 talk 400 (in.) (n/6q.en) (In.)
(in.)
(in.)
(3; B00 (In.) (W64.om) (in.)
(in. )
(In.)
(t) c:.............................,...................
6...........
..............................;............................. 4 5 1
f.M2 S.3M 1
2.38?
5.3%
2 2.342 5.3M i
2.342 5.M3 3
f.M2 l.hd,
3 f.382 S.417 4
2.342 5.237 4
2.342
$.422 5
f.342 5.144 5
f.342 S.4t4 i
6 2.382
$ 033 6
2.342 5.403 l
7 f.M2 4.808 7
2.342 5.397 8
2.342 4.767 8
2.342
$.393 9
2.342 4. 74 2 9
f.342 5.393 s
10 2.M2 4.M6 10 2.342 5.397 11 2.M2 4.M7 11 2.342 5.403 12 2.342 4.203 12 2.M2 5.414 13 -
2.M2 4.003 13 f.22 5.422 i
14 3.342 3.743 14 2.382
$.417 15 2.342 3.537 15 f.M2 5.M3 14 f.342 3.292 16 2.342 5.3%
4,.
Facts 180 Facts 2 70 EOC 2 80C+2 (AP 90D SD M N EOC+2 EOC !
GAP R(o t.RM m DOL GAP FlutWCE* SN. GAP CLOSURE GR M N STRAIN DOL GAP FlutNCt* $N. GAP Ct0sutt Ga m p $ttals RCD (In.) (voq.ce) (In.)
tin.)
(in.)
(1) toD (In.) (voq.ce) (In.)
(In.)
(In.)
(t) ese............................................................
1 2.M2 3.292 1
2.342 3.292 2
2.342 3.537 2
2.M2 3.322 3
f.342 3.743 3
2.M2 3.M8 4
2.342 4.003 4
2.382 3.354 t.M2 4.203 5
2.M2 3.3%
6 2.342 4.M7 6
f.342 3.358 7
f.M2 4.M6 7
2.362 3.360
?
8 2.342 4.742 4
f.382 3.356 9
'.M2 4.767 9
2.M2 3.356 s
10 2.M2 4.90$
10 2.382 3.M0 11 2.342 5.033 11 2.382 3.358 12 2.342 5.%4 12 2.342 3.356 13 2.342
$.237 13 2.M?
3.354 14 2.M2
$.306 14 2.362 3.M8 15 f.M2
$.336 15 2.382 3.322 2.342 5.3%
16 2.342 3.292
- 1) W3MihAL SQL $N00LD[t GAP.
2.342 in.
- 2) (DCa2 Ava GUIDE tutt GRMM.
(
)n.
- 3) EDCat AVG CUIDE Tutt FLuthCE.
4.344 X1(21. W sq.ca.
- 4) SQL ROD LthCTM.
161.168 in.
- FLuthCE E. 0.421 NeV
/c 8 w
t us--
r-.-
-g-
-e w
w-+yn
o.
Tcble A 8
[
AlltettLT titlAL WO Pittle Fact 0
F Att i 90 80C*R 80 Cat MP RCD 9tMN 80C 2 E0C !
(4P t0D DMN l
I 90L SAP FLutwCt' $N. (AP CLOIUtt DMN linAIN tol MP FLUENCl' SN. fAP CLClutt Gt M N likelt te (In.) ( W og.se) (In.)
(in.)
(in.)
(4)
RCD (in.) (Woq.en) (In.)
(In.)
(in,)
(t) cm..................
.......g.............................
..............................gg.......................,.......
1 f.342 5.276 1
f.M2 5.52 2.342
.5.205 2
2.X2 5.785 3
2.342 5.327 3
2.342 5.859 4
2.M2 5.3r?
4 2.382 5.893 j
5 2.M2 5.379 5
2.362 5.877 6
3.M2 S.218 6
2.342 5.851 7
2.342 5.190 7
2.342 5.862 8
f.M2 5.155 8
2.342 5.460 9
2.21 5.107 9
2.342 5.k1 i
10 2.342 5.00s to 2.M2 5. 7 73 11 2.342 4.903 11 2.342 5.696 l,
12 2.342 4.830 12 2.M2 5.657 13 2.M2 4.746 13 2.342 5.604 16 2.342 4.617 14 2.342 5.503
+
15 2.342 6.656 15 2.342 5.M6 16 2.M2 4.328 16 2.342 5.276 i
Facts 180 FACit 270 E0 Cat IOCat MP RCD 0* M N EOC*t E0C*!
f4P 900 Gt M N i
DOL fAP FLUENCE' $N. (AP CLOsutt at M N 81 LAIN DOL r.AP FluthCt' $N. GAP CLO$Utt Gt M M $1tAIN toD (In.) ( Woq.oe) (in.)
(in.)
(In.)
(4)
ROD (In.) (Wsq.cs) (in.)
(in.)
(In.)
(t) j es.............................................................
~
~
~
~
1 2.M2 5.575 1
2.342 6.328 2
2.M2 5.629 2
2.342 4.493 3
2.342 5.54 3
2.342 4.697 4
2.342 5.002 4
2.342 4.467 5
2.342 5.420 5
2.M2 6.96' 6
2.M2 5.429 6
2.M2 5.089 7
2.342 5.881 7
2.342 5.221 4
2.M2 5.927 8
2.342 5.342 9
2.342 5.913 9
2.22 5.412 r
10 2.342 5.096 10 2.M2 5.662 t
11 2.342 5.869 11 2.342 5.500 12 2.342 5.846 12 2.M2 5.570 13 2.342 5.396 13 2.342 5.623 14 2.342 5.859 14 2.342 5.624 15 2.342 5.742 15 2.342 5.540 16 2.342 5.752 16 2.342 5.575 i
- 1) W;mlhAL BOL $Netr Dtt GAP.
- 2. M2 In.
- 2) 80C+2 AVG GUIDE TUSE CA M N.
[
)in.
- 3) 10C+2 AVG OulDE Tutt FLutWCt.
5.214 mit21.n/sq.cm.
- 4) DOL RCD LthCTN.
161.168 in.
- FlutWCE t. 0.421 MeV l
l A-9 i
t e
i
{
o s
t Table A 9 i
i AlltutLY titl AL NO P19001 F Act:
0 Fact:
90 10C 2 80C 2 MP 90D Sk M N 80C 2 toc 2 MP RCD et M N 00L MP fluthCt* DN. MP CL0eukt OR M N linAIN SOL MP flut#Ct' DN. M*
CLOtutt Ga M N sinals i
te
( In. ) ( W 64.es) (in.)
(in.)
(in.)
(t) 800 (in.) (Waq.es) (In.)
(In.)
(In.)
(t) u s............................................................
............................................................... ?
1 2.474 1.834 1
2.640 2.228
~
2 2.49 1.815 3
2.649 2.244 3
2.643 1.799 3
2.642 2.262 l
4 2.450 1.7M 4
2.458 2.259 5
2.49 1.723 5
2.645 2.249 6
2.640 1.679 6
2.452 2.234 7
2.4 72 1.04 7
2.431 2.217 8
2.49 1.587 6
2.449 2.194 9
2.452 1.553 9
2.649 2.142 i
10 2.426 1.494 10 2.451 2.147 11 2.666 1.02 11 2.436 2.110 U
12 2.41 1.M7 12 2.642 2.070 4
13 2.4 72 1.299 13 2.46 2.025 14 2.45 1.226 14 2.470 1.973 il 2.45 1.140 15 2.470 1.901 16 2.432 1.057 16 2.474 1.834 t
facti 140 fact 270 80C 2 50C 2 MP 900 GA M N EOC 2 EOC 2 MP 90D ct M N l
OOL MP FLUENCt* SN. SAP CLOSutt Ge M M $ftAlk DOL GAP fluthCE. $N. (shi CL0$utt GA M N $1tAtt i
80D (In.) (W sq.en) (In.)
(in.)
(in.)
(1)
ROD (In.) (W6q.cm) (In.)
(in.)
(in,)
(1) es...e s..e.a..s.s.s s e s.e s s e...s.e s.....s.s s.....s s s e s..s s s e e.
.ssses..sp ses..s..s.a s.e s.e s es. s sssssssseess.a. s e s s es. s.es
~
~
~
1 2.642 1.969 1
2.42 1.057 2
2.642 2.032 2
2.454 1.149 3
2.420 2.098 3
2.449 1.243 4
2.628 2.164 4
2.667 1.324 i
5 2.4M 2.182 5
2.439 1.401 6
2.410 2.215 6
2.629 1.475 7
2.425 2.245 7
2.434 1.546
[
8 2.431 2.271 8
2.439 1.615 t
9 J.432 2.275 9
2.433 1.656 10 2.420 2.294 10 2.412 1.712 11 2.404 2.303 11 2.433 1.767 i
12 2.4M 2.307 12 2.458 1.821 13 2.431 2.306 13 2.458 1.871 14 2.401 2.297 14 2.446 1.914 i
15 2.08 2.263 15 2.44 1.94 0 16 2.640 2.228 16 2.44?
1.969 I
- 1) NOMihAL DOL SM:11LDtt GAP.
CHARAcittitt0
- 2) (OC 2 AVC QUIDE tutt GtMNe
(
)in.
i
- 3) 10C 2 AVG GUIDE tutt FLUENCE.
- 1. M 7 X1f21. W 64.cm.
- 4) 80L 200 LENGTMs 161.168 In.
i
- FluthCE E 0.821 MeV e
A 10
i i
i t
Table A.30 5
6sst ate See:At m0 p10002 l
PACE:
0 Fact:
90 00C.)
80C+!
w h@
SkMN BOC 2 80C*t W
BOD ga M a l
e0L w ftutoCE. sa. w cteaunt enevra SinA n e0L w flutect. Sn. w CL0 sung ea M a staAta BOD' tin.) (Naq.an) (In.)
(In.)
(in.)
(1) top (In.) (Waq.en) (In.)
(In.)
(In.)
(t) cc.............................................................
.......................................e.......................
i
~*
1 2.446 1.969 1
f.470 2.228
~
~
2 f.428 1.M0 2
2.478 f.M3 i
3 f.400 1.914 3
f.413 2.797 4
f.4.N) 1.8 71 4
2.418 2.306 i
l 5
f.435 1.821 5
2.405 2.307 6
2.390 1.76 '
6 2.382 f.303 i
7 2.430 1.712 7
2.403 f tM i
8 f.432 1.656 8
f.420 2.278 9
f.435 1.615 9
2.396 2.271 l
10 2.392 1.546 10 2.412 2.745
[
11 2.435 1.475 11 2.385 2.215 L
12 f.431 1.401 12 2.402 2.182 13 2.435 1.334 13 2.423 f.144 14 2.388 1.243 14 2.425 2.098 i
15 2.436 1.149 15 2.421 2.032 16 2.447 1.057 16 2.446 1.969 l
s FAtt 180 FACE:
270 EOC*t 80C 2 GAP R@
GR M N ED>t t0Ca2 GAP R@
Gt M k 80L GAP ftutWCt* SN. 8AP Ct00URE $40WTN 81kAIN BOL GAP fluttCt* $N. GAP Ct0sutt Ga M M sinatk t
400 (in.) (West.en) (In.)
(In.)
(In.)
(1)
RS fin.) (Waq.cm) (In.)
(In.)
(in.)
(1) e..................e.........................................................................................................
1 3.435 1.834 1
f.447 1.057 t
2.431 1.901 2
2.418 1.140 3
2.410 1.973 3
2.387 1.226 4
2.402 1.025 4
t.430 1.299 5
2.418 t.070 5
2.403 1.M7 6
2.397 2.110 6
2.429 1.432 7
2.394 2.147 7
2.620 1.494 4-2.404 2.182 8
2.426 1.553 9
f.431 2.194 9
2.421 1.547 10 2.415 2.217 to 2.420 1.634 11 2.428 f.234 11 P.423 1<679 12 2.419 2.N 9 12 2.428 1.723 13 2.399 2.259 13 2.434 1.764 14 2.402 2.262 14 2.420 1.799 15 2.418 2.244 15 2.440 1.815 16
?.420 2.228 16 2.435 1.834
- 1) WOMihAt 80i $w:ULDtt GAP.
CHARAcittl280
- 2) t0C*2 AVG GUIDE tutt GA M M.
{
)in.
- 3) EOC 2 AVG GUIDI iUBt FLUENCE.
1.867 X1821,W an.cm.
- 4) DOL ROD LthCTM.
161.168 in.
- FluthCE E
- 0.421 meV A-11
l e
i a
Table A-ll 1
i i
f PAID VERDE-1 EOC-2 GUIDE TUBE GROWTH DATA Average GUIDE TUBE GROWTH (in.)
Average G.T.
G.T.
G.T.
G.T.
G.T.
Growth j
Assembly Fluence
- f1 f2 03 (in.)
=======menemme===============me==================#
4
====n=======gi r
P15120 5.49 PIC002 4.41 i
PIC005 4.38 i
P1C017 i 3.92 PIC025 4.30 P1C039 4.38 P1D001+
1.87 P1D002+
1.87 I
P2B233 5.67
)
t P2C114 5.21 FLUENCE XE-21, n/sq. ca., E>0.821MeV.
+
CHARACTERIZED ASSEMBLY GUIDE TUBE IDENTIFICATION: $1-NE,#2-SE,#3-SW,#4-NW.
t i
f 7
O a
i l
A-12
- -. I