ML20133E157
| ML20133E157 | |
| Person / Time | |
|---|---|
| Site: | 07109103 |
| Issue date: | 07/18/1985 |
| From: | Clay Johnson NAC INTERNATIONAL INC. (FORMERLY NUCLEAR ASSURANCE |
| To: | Macdonald C NRC OFFICE OF NUCLEAR MATERIAL SAFETY & SAFEGUARDS (NMSS) |
| References | |
| 25585, CRJ-85-110-ETS, NUDOCS 8508070586 | |
| Download: ML20133E157 (47) | |
Text
!
[
b o
Nuclear Assurance Corporation e
5720 Peachtree Parkway Norcross, Georgi.2 30092 /D (404)447-1144 Telex: 6827020
%%inbergstrasse 9 8001 Zurich, Switzerland 1-470844 Telex: 57275 July 18,1985 CRJ/85/110/ETS l
hfj Mr. Charles E. MacDonald, Chief Transportation Certification Branch of Division of Fuel Cycle and Material Safety jf13 U.S. Nuclear Regulatory Commission s=
F Washington, D.C.
20555 2
Dear Mr. MacDonald:
o NLI-6502 Spent Fuel Shipping Cask (AECL Cask)
Docket No. 71-9103 v)
The Nuclear Assurance Corporation (NAC) hereby requests Revision 3 to Certificate of Compliance No. 9103, dated May 3,1978. This revision is to permit shipment of miscellaneous fuel rods totaling no more than 15.4 kg U-235, the maximum quanity currently permitted. This revision is required because the maximum U-235 loading per centimeter of fuel element length is different for some of the rods. Specifically, it is requested that:
Page 3, Section 5(b) of the Certificate of Compliance be changed to:
(i) Type and Form of Material Irradiated NRU-NRX aluminum-uranium alloy fuel, enriched in the isotope U-235, with specifications given in the Table I attached. provides the analyses to substantiate the safety of the miscellaneous rods, and that shipment of these rods can be accomplished in the NLI-6502 (AECL) cask in full compliance with the appropriate federal regulations.
Plans are currently being made to ship miscellaneous rods from Chalk River, Canada to Savannah River in September,1985.
p
~
4 Docmtg
,'[3, f$'
?
h iT F
A us uc s
Nn $.id '/. 6.V.E.V.'.'..'.'.'.'.E$
G s
w E
~
ggL 3 01985 >
.r.u m n e c.. A / G.7 /.d 3
Sz ro m
'4)
.i;.; e. a $ w ; l a n. F
@f B
nss h
UMa ChecX : *'J.d[kcW.
/
a
.: dad 2.l s
~~
d' 1
2 I
v y
on 8508070586 850718 PDR ADOCK 07109103 Y h /)/
gjQ $)7
/
C PDR
e Your expeditious review of this request is greatly appreciated.
In accordance with the requirements of 10CFR170, a check for $150.00 is enclosed.
If you have any questions regarding this matter, please contact me at your earliest convenience.
Very truly yours, NUCLEAR ASSURANCE CORP.
G E 3 L, Q dp d d $. 1 C. R. Johnson Group Vice President Encl.
S
TABLE l' NRU.U/Al Alloy NRX.U/AL Alloy Misc U/Al Alloy Fuel Fuel Rods Fuel Rods (Mixed Loading)
No. of assemblies or shipping cans per package 20 28 28-No. of elements per assembly or shipping can 12 7
- Variable Maximum wt% U in U/A1 21 28-40 Maximum linear density (g/cm) per assembly or shipping can 1.8 2.0 4.0 Maximum U-235' content per assembly or shipping can (pre-irradiation weight) 495 grams 550 grams.
550 grams Maximum U-235 per package (pre irradiation weight) 9.9 kg 15.4 Iq) 15.4 kg Maximum decay heat, load per package 14,000 BTU 14,000 BTU 14,000 BTU Minimum average burnup, % per package 45%
45%
45%
Minimum decay time, days 120 120 120 eMay be a mixture of NRX fule rods, NRX fule rod element sections in a can, bundles of SLOWP0KE fuel elements in a can and sections of fast neutron fuel tubes and plugs in a can.
1985 May 01 4
9
1.
==
Introduction:==
Evaluations of-Shielding, Radionuclide Release, Thermal, and Structural considerations of the proposed Miscellaneous fuel shipments were performed. A detailed Criticality analysis using the AMPX/ KENO-IV system was performed because of difficulties in estimating the nuclear behavior of the fuel without such an analysis. The results of these analyses show that the NLI-6502 cask design is adequate to carry the proposed shipments.
2.
Criticality Analysis:
A.
==
Introduction:==
Shipment of the desired miscellaneous fuel rods in the NLI-6502 cask must be evaluated for nuclear criticality safety because although the total U-235 mass will be no more than the current limit of 550g U-235, the arrangement of the fissile material will be somewhat different.
This is because some of the miscellaneous rods will have denser U-235 loadings, 4.0 g/cm U-235 versus 2.0 g/cm U-235 for NRX fuel.
B.
Method:
A criticality analysis was performed for the NRX fuel and for the proposed miscellaneous fuel. These analyses used the Babcock & Wilcox NULIF code to calculate the Dancoff correction factor and effective moderator cross section used by the NITAWL code. NITAWL was used to perform U-235 resonance calculations, and the resulting cross-sections were spatially weighted (" homogenized") using the XSDRNPM code. The KEN 0 code was then used to calculate K effective for both fuel types within the cask using a three-dimensional model of the cask basket. A common procedure for criticality analyses with PWR and BWR fuel is to also perform an analysis in which the fuel is allowed to fill the maximum possible cask cavity volume, so this type of model was also analyzed for the NRX and miscellaneous fuels. The data used in the analysis are presented in Appendix A, and the computer runs are in Appendix B.
1 i
C.
Results and Discussion:
The KEN 0 results, corrected for bias and uncertainties, are tabulated in Table 1.
Table 1 Criticality Analysis Results Case Ks NRX Fuel, 0.868 Normal Operation NRX Fuel, 0.830 Maximum Volume Misc. Fuel, 0.806 Normal Operation Misc. Fuel, 0.733 Maximum Volume These results show that a water layer surrounding the fuel, as modeled in the nornal operation case, acts as a reflector that isolates the fuel from the Boral poison of the basket. This water layer, as modeled, is much thicker (1.4 cm nominal) than similar situations for PWR and BWR fuel, and is thus more effective as a reflector. The normal operation cases have higher reactivities as a result.
The results show that the denser U-235 loading of the miscellaneous fuel proposed shipments is less reactive than the NRX shipments. Note that both fuel types are limited to 550 g U-235, resulting in a smaller fuel volume for miscellaneous fuel in the KEN 0 model, which used the maximum fuel loading density. The actual shipments will be a mixture of 4.0 g/cm U-235 fuel and lesser density fuel, so the actual shipment reactivity would fall between the two analyzed cases, i.e.
between 0.868 and 0.806.
The subcritical multiplication of the fuel is measured as the cask is loaded, further ensuring subcriticality. The fuel loading is restricted to 75% of the experimentally predicted critical mass.
D.
==
Conclusion:==
The AECL cask, NLI-6502, will remain subcritical with the proposed miscellaneous fuel load..__
3.
Shielding:
The proposed Miscellaneous Fuel shipments will contain at most the same i
amount of U-235 initial as the NRX fuel shipments, with the same cool time. These parameters determine the available radionculide inventory and hence the shielding source term.
Since the maximum shielding source term values are the same for both NRX and Miscellaneous fuel, the shielding of the cask, which has proven adequate for the HRX fuel, will be adequate for the Miscellaneous fuel.
4.
Radionuclide Release:
The inventory of fission products and other radionuclides, as described in the shielding section, will be no greater for the Miscellaneous fuel than for the NRX fuel. Since the material available for release in a Hypothetical Accident is no greater for the Miscellaneous fuel, the potential consequences of such an event are no greater than for the NRX fuel.
It should be noted that the cask does not employ a rupture disk for the cask cavity and is shipped dry, making release unlikely.
5.
Thermal:
The maximum heat load for the Miscellaneous fuel will be the same, 4.1 KW, as for the NRX fuel. Therefore the cask body temperatures will be the same as for the NRX fuel. Pin temperatures may vary because of the different fuel arrangements for the Miscellaneous fuel during normal operation, but these temperatures are significantly less than the Hypotetical Accident Fire temperatures. The NLI-6502 cask SAR used conditions of (Table III-3) 15,060 Btu /hr (licensed: 14,000 Btu /hr), and a peaking factor of 1.3.
The resulting maximum pin temperature was (Table III-4) 9020F with abnormal distribution of the heat load. The Miscellaneous fuel will impose conditions no more severe than the conditions analyzed given the 1060 Btu /hr margin of the SAR.
6.
Structural The mass of the fuel rods is approximately the same for the proposed Miscellaneous fuel loading as for NRX fuel, given a maximum U-235 mass of 15.4 kg U-235 in both instances. The mass for cladding and fitting (i.e.
shipping cans) will not vary significantly. The total fuel load weight of 28 NRX rods is 176.4kg, (388.08 pounds) per loaded cask. Since the total cask loaded weight i.e. 45,300 pounds, the fuel payload is but a small fraction (0.9%) of the total weight. Any small fuel lading weight variation due to the miscellaneous fuel will therefore have no significant effect upon the cask structural safety margins.
l Appendix A AECL Cask Criticality Analysis 1.
NRX fuel modeling:
Rod containing 7 pins (or " elements")
28% by weight U in U/AL alloy Pin Radius: 0.3175 cm Cladding R: 0.3937 cm (Cladding is Aluminum) 7 Pins per rod, 28 Rods per cask load Rod Initial U (Mark IV) 590.8 grams per rod (Ref: Appendix A No. 33)
Rod Initial U-235 549.5 g Post-Irradiation:
Final U content: 343. g Ave.
Final U-235 content:
259. g Ave.
% burnup average = 53%
Active fuel length:
108 inches $
- Fuel volume = 7
- v (0.3175) 108
- 2.54 Fuel Road volume = 608.12cm3 Fuel Road 00: 4.83cm Fuel pins are finned, so effective pin OD is 1.054 cm Fins have negligible effect on criticality N
D Model as triangular pitch of 1.983 cm.
D *go@*
Pitch = 1.983 Cell N@
Area = 3.405cm2 g.9 Rod Effective Area = 7 x Cell Area
= 23.84cm2 os moderator = os AL = 1.5 barns (from Table 4-1 in KENO-IV manual)
- 83 4 effective rod radius = 2.75 cm 7 x cell Area
=
n 2.
Number Densities: NRX Fuel Post-Irradiation Based on Appendix A Agreenent (No. 33. under contract No. DE-AC09-765R01033 with AECL) data (Pin Densities).
1.097x1021 atoms 1.
260.2gU-235 x 1 mole x 6.024x1023 atoms
=
608.12cm3 235g 1 mole cm3 i
or N25 = 1.097 - 3 atoms / barn-cm 2.
U238:
1.611x1020 atoms 38.79U-238 x 1 mole x 6.024x1023 atoms
=
'608.12cm3 238g 1 mole cm3 or N28 = 1.611 - 4 atoms / barn-cm 3.
U236:
1.851x1020 atoms
'44.1g0-236 x 1 mole x 6.024x1023 atoms
=
608.12cm3 236g 1 mole cm3 or N26 = 1.851 - 4 atoms / barn-cm 4.
A1:
5.573x1022. atoms 15199 _ x 1 mole x 6.024x1023 atons
=
608.12cm3 27g 1 mole cm3 Page 6: Appendix A-33 gives 499 U 343g U 0.16g Np 260.2 U-235* g 379 U-235 Per Element Per Rod 44.1g U-236 6.3g U-236 38.79 U-238 0.008g Pu Maximum
- Treating Np and Pu as if they were U-235 3.
Cask Cavity Modeling:
Horizontal Top & Bottom Plates have Longitudinal 3" gaps between 281/4" long Boral segments are neglected.
Vertical divider is full axial length.
Boral Thickness = 1/8"
- 12" A
(Page VII-10, also cask basket drawing 650201,NLI) Boral is clad with 1/16" SS304 on both sides l
Bora]l Boral is 9 3/4" high, centered in Rods Top cavity. Top and Bottom plates Stacked have 5 3/8" wide Boral - model as Lead Lead
+ 3" % Q/4-bf
{
Cask Boral inches.
es as
=
g der Body Boral Bottom, ;
Y s V
's s s s 7
7 1
s Rods are stacked vertically in cavity during loading. Some shifting of rods could occur during shipping
- so the geometry may vary. To model this situation, treat the cavity as containing 28 rods with:
a.
Rod to rod contact, 4.83cm pitch, triangular 2
or b.
Equal area allocation of cavity space, 33.18cm per rod or pitch = 6.190cm triangular pitch Since b. would result in fuel cells (U + moderator) separated by 1.78cm of water [14 equal cells occupying one-half of the basket gives U + water layer region area of 3.32cm2 fuel region area of n Reff 2=n (2.75)2 =
23.76. Represented as squares, their edges are 5.76cm and 4.87cm, so the water layer is 0.89cm thick in each cell, for a total water gap of 1.78cm], (a.) is likely more realistic and will be chosen for the Normal Operation model. The Hypothetical Accident model will be formed by treating each pin as a free agent, so that there are 98 pins in each basket half at an effective pitch of 4.64cm.
(A rectangle 6-1/8" = 5 7/8" by 12 inches was used for the basket area here, equally divided among 98 rods for a cell area of 4.64cm2 or a square pitch of 2.154cm.
Normal Operating (case a) is more reactive if the fuel region is surrounded by a water sleeve (average of 1.437cm thick arrived at by taking the water sleeve area [454.8cm2 - 14 x 23.76cm2,= 122.2cm], divided by the perimeter.). The actual water layer is uneven because of the rod arrangement - it has a jagged edge formed by the rods.
- Note: The basket contains metal to minimize such rod movement. The modeling is intended to represent the nominal configuration for Normal Operation and a conservative condition for Hypothetical Accident. l
14.923 cm NLI-6502 CASK BASKET MODEL
=
12.049 2
7 b oral Top k
B
= -S5304 5
6 0
25 g
o p
20
.e Boral Divider 4
3 Plate Not g
to Scale is 10 o
T o
g 1
5 2
U.
Fuel Fuel g
Boral Bottom i
Water Water r
F b
id 10 x
-x
-15.240 (X)
(Y)
(Z)
Box Type 1 Cuboid 1 13.486 1.437 2.8575 1.437 71.755 0.0 Cuboid 2 14.923 0.000 2.8575 0.318 l
Cuboid 3 15.240 0.000 2.8575 0.318 Cuboid 4 15.240 0.000 2.8575 0.000 Materials:
Box Type 3 Cuboid 1 13.486 1.437 24.765 0.000 1 = Fuel 4 = Boral Cuboid 2 14.923 0.000 24.765 0.000 2 = Water 5 = Lead Cuboid 3 15.081 0.000 24.765 0.000 3 = Steel Cuboid 4 15.240 0.000 24.765 0.000 Box Type 5 Cuboid 1 13.486 1.437 1.4205 0.000 Box Types 2,4,6, same Cuboid 2 14.923 0.000 2.5395 0.000 as 1,3,5, but with Cuboid 3 15.240 0.000 2.5395 0.000 negative X values.
Cuboid 4 15.240 0.000 2.8575 0.000.
7-NLI-6502 CASK BASKET MODEL (cont.)
Box Type 2 Cuboid 1 -1.437 -13.486 2.8575 1.437 71.755 0.0 Cuboid 2 0.000 -14.923 2.8575 0.318 Cuboid 3 0.000 -15.240 2.8575 0.318 Cuboid 4 0.000 -15.240 2.8575 0.000 Box Type 4 Cuboid 1 -1.437 -13.486 24.765 0.000 Cuboid 2 0.000 -14.923 24.765 0.000 Cuboid 3 0.000 -15.081 24.765 0.000 Cuboid 4 0.000 -15.240 24.765 0.000 Box Type 6 Cuboid 1 -1.437 -13.486 1.4205 0.000 Cuboid 2 0.000 -14.923 2.5935 0.000 Cuboid 3 0.000 -15.240 2.5395 0.000 Cuboid 4 0.000 -15.240 2.8575 0.000 CORE BDY 15.240 -15.240 30.48 0.00 79.375 0.0 CYLINDER 3 21.56 79.375 0.0 CYLINDER 5 37.47 CYLINDER 3 42.55 Horizontal To allow for axial gap in boron, Box Types 7-12 are introduced.
Plates:
They are duplicates of 1-6, except that all occurrences of material 4 (boral) are replaced with material 3 (steel). This is to represent the steel coupling sections that join the steel-clad Boral sheets. The gap is 3" (7.62cm) long.
1 111 111 111 0
2 221 111 111 0
3 111 221 111 0
Box Arrangement.
4 221 221 111 0
5 111 331 111 0
6 221 331 111 0
7 111 111 221 0
8 221 111 221 0
9 111 221 221 0
10 221 221 221 0
11 111 331 221 0
12 221 331 221 1 L__
- t,-
4.
Number Densities in Cask Cavity (" Homogenized")
FUEL REGION NUMBER DENSITIES: NRX (Irradiated fuel)
Normal Operation:
98 Pins in a rectangle 12.049cm by 27.606cm:
Each pin has a fuel area of n Rfuel2=
x(0.3175cm)2 V ) water = 1-98*n(0.7874/2)2 V ) fuel = 98*n(0.3175)2 = 0.0933 f
f 12.049*27.606 12.049*27.606
= 0.8565 N25 = 0.0933
- 1.097-3 = -1.024-4 atoms / barn-cm V clad = 0.0502 N26 = 0.0933
- 1.851-4 = 1.727-5 atoms / barn-cm f
N28 = 0.0933
- 1.611-4 = 1.503-5 atoms / barn-cm NH = 0.8565
- 6.694-2 = 5.733-2 NO = 0.8565 *.3.347-2 = 2.867-2 NAL = [0.0933
- 5.573-2 = 5.20-3] + [0.0502
- 6.026-2] = 8.225-3 Fuel Pin.
Clad Hypothetical Accident:
98 Pins in a rectangle 14.923cm by 30.48cm (12")
V ) fuel = 98*u(0.3175)2 = 0.0682 V ) water = 0.8951 f
f V ) clad = 0.0367-14.923*30.48 f
Pitch = 2.154cm effectively square N25 = '0.0682
- 1.097-3 = 7.482-5 N26 = 0.7682
- 1.851-4 = 1.262-5 N28 = 0.0682'* 1.611-4 = 1.099-5 NH = 0.8951
- 6.694-2 = 5.992-2 '
NO = 0.8951
- 3.347-2 = 2.996-2 NAL = [0.0682
- 5.573-2 = 3.801-3] + [0.0367
- 6.026-2] = 6.012-3 Per Element:
Fresh fuel has 84.4 grams total U (78.59 U-235, 5.99 U-238)
After irradiatiion, there are 499 total U, 0.16 g Np, 379 U-235, 6.39 U-236, and less than 0.009g Pu. Treating the Np and Pu as U-235 gives 37.179 U-235 or 0.473 of the original U-235, and 5.79 U-238 and 6.3g U-236. Thus the post-irradiation U-235 is 47.3% of the initial, and the U-238 is 96.6%.
5.
AMPX/ KEN 0 Parameters:
NITAWL: Normal Operation:
-C = 1 - 0.95267'
= 0.0473 N28 = 1.611-4 1
= 9885.
NAL os/N28 = 484.3
( o m)ef f = j(pj! + l(((I (AL s = 1.4)
N28 2Epo=0.0921 "I=0.6665 H.A.:
Hypothetical Accident:
C = 1 - 0.97536 = 0.0246 (o m)eff = 10107.
IIpo-=0.0921 "I = 0.6310 XSDRNPM:
R fuel = 0.3175cm N25 = 1.097-3 N28 = 1.611-4 Fuel R clad = 0.3937cm NAL = 5.573-2 N26 = 1.851-4 R cell = 1.041 Normal NAL = 6.026-2 Clad R cell = 1.215 H.A.
NH = 6.694-2 NO = 3.347-2 l
i !
AECL'
- 6. -Results' of Criticality Analysis FUEL CASE Keffective jg; NRX -
Normal 0.84565 + 0.000467 0.868 H.A.
0.80909 + 0.00401 0.830 MISC
- Normal 0.78448 + 0.00536 0.806 H.A.
0.71186 + 0.00535-0.733
Limited to 550g U-235 total.
Ks = Keffective + 0.00981 + 0.001711 + (1.645 a 2 + 0.00722 2)1 2/
-(bias)
(experimental (calculation (benchmarks uncertainty) uncertainty) uncertainty)-
e l '.
t l-
~
l:
I i.
l i l 1.
~
i
Appendix B p1035 cK EtiO.N R X 37401 C 07/16/35 15:19:36 (22) 21 15$ 0 18 SZ 2 27 -1 0 T 18 235 92238 -592235 92235 -592235 3016 -553016 1C01 -551001
'21 4000013027 -513027 24C00 26000 28000 82000 5010 6012 92235 22 3**
92233 294. 2.3175.0473 9835. 1.611-4 1 27 484.3 1 3Z 1.3 22 592233 294. 2.3175.0246 10107. 1.611-4 1 27 484.3 1 3Z 1.0 T ERRORS: N0hE. T1!!E :
0.246 SEC. IMAGE COUNT: 5 I)R ED - IN CONTROL MODE 400*fi1T A WL. flit AWL
THIS-XSDRN WORKING TAPE WAS CREATED THE TITLE OF THE PARENT CASE IS AS FOLLOWS 27 NEUTRON GROUP LIBRARY BASED ON ENDF/B VERSION 4 DATA COMPILED FOR NRC TAPE ID 4321 NUMBER OF NUCLIDES NUMBER OF NEUTRON GROUPS 27 NUMBER OF GAMMA GROUPS FIRST THERMAL GROUP 15 TA9LE OF CONTENTS H 1269 F, 1002 T 218 GP 032475(2)
H 1269 F,
1002 T 21E GP 032475(2) 0-10 1273 21CNGP 042375 P-3 293K C-12 1274 F,1065 T 218 GP 030476 (7) 0-16 1276 218 GP 030476(7) 0216 1E76 213 GP 030476(7)
AL-27 1193 213 GP 040375(5)
AL-27 1193 218'GP 040375(5)
CR 1191 218HGP WT 1/E P-3 293K SIGP=5+4 REC 342375)
FE 213GP'RE 5-17-78(1)
NI 1190 218NGP WT 1/E P-3 293K SIGP=5+4 RE(342375)
'ZRCHAT) 7141 21 NGP WT FIS(0.1T020)-1/E-MAX P-3 PB 1288 21BNGP G42375 P-3 293K U-235 1261 SIGP=5+4 NEWXLACS 218NGP P-3 293K(3)
U-235 1261 SIGP=5+4 NEWXLACS 21ENGP P-3 273K(3)
U-236 1163 SIG0=5+4 NEWXLACS P-3 293K F-1/E-MC1.+5)
U-238 218GP RE 5-17-78(1)
U-238 21EGP RE 5-17-7E(1)
)RKPT PRINT 5
F
-]
l l.
i t
4
)0 3 5
- K E N O. XN R X
)Q1 C 07/12/E 5 17:51:11 (3 4 )
.32 NRX FUEL PIN, 93 W/0 U-235, 2.0 G/CM, NORMAL OP.
34 155 2 3 20 1 3 3 34 S31 2R20 FO 30 255 -2 F0 30 355 1 3Z 1000 22 1 FD 30 455 -1 27 0 -2 E T 34 1355 4R1 2 2R3 9R1 9R2 9R3 34 1451 92235 92238 92236 513027 513027 555016 551001 30 5016 1001 13027 82000 24000 26000 28000 30 5010 6012 209 34 15** 1.097-3 1.611-4 1.851-4 5.573-2 6.026-2 3.347-2 6.694-2 F1.-15 T 3C 33** F1.0 T 34 35** 9I0.0.3175.3176 7I.3937 1.041 3C 3651 10R1 2R2 8R3 32 38** 10R1.0 1.0 F1.0 30 3955 1 23 30 4055 F3 30 5151 1 234 56789 10 11 12 13 14 15 16 17 18 19 20 30 21 22 23 24 25 26 27 T
}RRORS: NONE. TIME:
0.224 SEC. IMAGE COUNT: 18 f*XSDRNPM.XSDRNPM L
)
i i
~ _. _. _ _. _
NRX. FUEL PIN, 93 W/0 U-235, 2.0 G/CM, NORMAL OP.
135 ARRAY 34 ENTRIES READ 145-ARRAY 34 ENTRIES READ' 15* ARRAY 341 ENTRIES READ OT DATA BLOCK 2 (MIXING TABLE, ETC.)
NUCLIDES-CCCC MIXING TABLE ON TAPE-IDENTIFICATION MIXTURE COMPONENT ATOM DENSITY 1-1001 1
92235
.10970-002
-2' 551001 1
92238
.16110-003 3
5010 1
92236
.18510-003 4
6012 1
513027
.55730-001 5
'8016 2
513027
.60260-001 6 -558016 3
558016
.33470-001 7
.13027 3
551001
.'66940-001 8.
513027 1
8016
.10000-314 9
24000 1
1001
.10000-014 1
10-26000 1
13027
.10000-014 11 28000 1
32000
.10000-014 12 40000 1
24000
.10000-014
- 13-82000 1
26000
.10003-014 s14 92235 1
28000
.10000-014 15' 592235 1
5010
.10000-014 16 92236 1
6012
.10000-014 17 92238 2
8016
.10000-014
'18 592238 2
1001
.10000-014 19L-592238-2 13027
.10000-014
'20~
592238 2
_82000
.10000-014 21 592238 2
24000
.10000-014 22 592238 2
26000
.10000-014 23: 592238 2
28000
.10000-014 24' 592238 2
5010
.10000-014
- 25 592238 2
6012
.10000-014 26 592238 3
8016
.10000-014 27' 592238 3
1001
.10000-014._
28 592238 3
13027
.10000-014 29' 592238 3
82000
.10000-014 30 592238 3
24000
.10000-014 31 592238 3
26000
.10000-014 32 592238 3
28000
.10000-014'
-33 592238 3
5010
.10000-014
~ 34~
592238 3
6012
.10000-014 (INISHED MIXING CROSS SECTIONS l ELAPSED TIME
.00000000 MIN.
{
-13628 LOCATIONS WILL BE USED l.
' t33* ARRAY 540 ENTRIES READ l
l 0T
OUTER INNER BALANCE UPSCATTER PATIO EIGENVALUE LAMBDA 1 1
269 1 0000006+000 1.1162031+000 1.4317601+000 1.4446352+000
.0 2
414 1.0000006+000 1.0029236+000 1.4447990+000 1.0003454+000 1.3 3
496 1.0000006+000 9.9782126-001 1.4455164+000 1.0000674+000 1.0 4
566 1.0000006+000 9.9949238-001 1.4454731+000 1.0001139+000 9.9 5
625 1.0000005+0C0 9.9995891-001 1.4453227+000 9.9903066-001 9.9 6
668 1.0000005+000 1.0000305+000 1.4456632+000 1.C002415+000 0.9 7
695 1.0000006+000 1.0000081+000 1.4457424+000 1.0000526+000 1.0 GRP.
1 REQUIRED 1 ITERATIONS. MFD OF 1.56848-005 0CCURRED IN INT.
20 COARS GRP.
2 REQUIRED 1 ITERATIONS. MFD OF 5.62157-006 OCCURRED IN INT.
20 COARS GPP.
3 REGUIRED 1 ITERATIONS. MFD OF 6.89910-006 OCCURRED IN INT.
20 C0ARS GRP.
4 REGUIRED 1 ITERATIONS. MFD OF 7.59584-006 OCCURRED IN INT.
20 COARS GRP.
5 REQUIRED 1 ITERATIONS. MFD OF 5.32153-006 0CCURRED IN INT.
20 COARS GRP.
6 REQUIRED 1 ITERATIONS. MFD OF 4.93799-006 OCCURRED IN INT.
20 COARS GRP.
7 REQUIRED 1 ITERATIONS. MFD OF 4.88247-006 0CCURRED IN INT.
20 C0ARS GRP.
3 PEQUIRED 1 ITERATIONS. MFD OF 5.05339-006 0CCURPED IN INT.
20 C0ARS GRP.
O RECUIRED 1 ITERATIONS. MFD OF 6.01466-006 OCCURRED IN INT.
20 C0ARS GRP.
10 )EQUIRED 1 ITERATIONS. MFD OF 7.21946-006 0CCURRED IN INT.
20 COARS GRP.
11 REQUIRED 1 ITERATIONS. MFD OF B.66549-006 CCCURRED IN INT.
20 COARS GRP.
12 R EGUIR ED 1 ITERATIONS. MFD OF 1.26959-005 0CCURRED IN INT.
20 COARS GRP.
13 REQUIRED 1 ITERATIONS. MFD OF 1.52278-005 OCCURRED IN INT.
20 COAPS GRP.
14 REQUIRED 1 ITERATIONS. MFD OF 1.66055-005 OCCURRED IN INT.
20 C0ARS; GPP.
15 REGUIRED 1 ITERATIONS. MFD OF 7.02427-005 OCCURRED IN INT.
20 COARS GRP.
16 REQUIRED 1 ITERATIONS. MFD OF 7.74515-005 OCCURRED IN INT.
20 C0 AR S' GRP.
17 REGUIRED 1 ITERATIONS. MFD OF 8.268C4-005 OCCURRED IN INT.
20 COARS GRP.
18 REQUIRED 1 ITERATIONS. MFD OF S.13727-005 OCCURRED IN INT.
20 C0ARS; GRP.
19 REQUIRED 1 ITERATIONS. MFD OF 7.35883-005 OCCURRED IN INT.
20 COARSl GRP.
20 REGUIRED 1 ITERATiCNS. MFD OF 4.74000-005 OCCURRED IN INT.
20 COARS' GRP.
21 REQUIRED 1 ITERATIONS. MFD OF 4.75404-005 OCCURRED IN INT.
15 COARSs GRP.
22 REQUIRED 1 ITERATIONS. MFD OF 5.16651-005 OCCURRED IN INT.
20 COARS; GRP.
23 REGUIRED 1 ITERATIONS. MFD OF 2.05556-005 OCCUPRED IN INT.
20 COARS GRP.
24 REQUIRED 1 ITERATIONS. MFD OF 3.70206-006 OCCURRED IN INT.
3 C0ARS GRP.
25 REQUIRED 1 ITERATIONS. MFD OF 2.40076-006 0CCURRED IN INT.
20 C0ARS GRP.
26 REQUIRED 1 ITERATIONS. MFD OF 2.0EE63-006 OCCURRED IN INT.
19 C0ARS.
GRP.
27 REQUIRED 1 ITERATIONS. MFD OF 2.62495-0C6 OCCURPED IN INT.
14 COARSl 8
722 1.000C005+000 9.9999890-001 1.4457188+000 1.0000180+000 1. 01 FINAL MINITOR LAMBDA 1.4437473+000 ANGULAR FLUX ON 1;
ELAPSED TIME 2.4835166c MIN.
r 135cKENO.XNRXHA
'It 07/12/85 17:55:45 (36) 35 NRX FUEL PIN, 93 W/0 U-235, 2.0 G/CM, H.A.
34 1$$ 2 3 20 1 3 3 34 831 2R20 F0 32 255 -2 FO 32 355 1 37 1000 2Z 1 FO 32 455 -1 27 0 -2 E T 34
.135! 4R1 2 2R3 OR1 9R2 9R3 36 1451 592235 592238 92236 513027 513027 558016 551001 32 8016 1001 13027 82000 24000 26000 28000 32 5010 6012 209 34 15**
1.097-3 1.611-4 1.851-4 5.573-2 6.026-2 3.347-2 6.694-2 F1.-15 T 32 33** F1.0 T 35 35** 910.0.3175.3176 71.3937 1.215 32 3655 10R1 2R2 8R3 32 38**
10R1.0 1.0 F1.0 32 395$ 1 23 32 40$$ F3 32 5155 1 234 5678 9 10 11 12 13 14 15 16 17 18 19 20 32 21 22 23 24 25 26 27 T
RORS: NONE. TIME:
0.226 SEC. IMAGE COUNT: 18
'XSDRNPM.XSDRNPM
_ - - __ - - _ _ - - - _ - - _ _ _ _ _ _ - - _ _ _ _ =
r NRX FUEL PIN, 93 W/0 U-235, 2.0 G/CM, H.A.
135 ARRAY 34 ENTRIES READ 1 4 5' A R R'A Y 34 ENTRIES READ 15* ARRAY'
- 34. ENTRIES READ OT DATA BLOCK 2 (MIXING TABLE, ETC.)
NUCLIDES CCCC MIXING TABLE ON TAPE IDENTIFICATION MIXTURE COMPONENT ATOM DENSITY
'1 1001 1
592235
.10970-002 2
551001 1
592238
.16110-003 31 5010 1
92236
.18510-003 4
'6012 1
513027
.55730-001 5-
.3016 2
513027
.60260-001 6.
558016 3
558016
.33470-001 7
13027 3
551001
.66940-001 8
513027 1
8016
.10000-014 9'
24000 1
1001
.10000-014 10- '26000-1 13027
.10000-014 11 28000 1
82000
.10000-014 (12-40000 1
24000
.10000-014 13 82000 1
26000
.10000-014 14 92235 1
28000
.10000-014 11 5 592235 1
5010
.10000-014-16'
.92236 1
6012
.10000-014 17 92238 2
8016
.10000-014 18 592238 2
1001
.10000-014 19 592238 2
13027
.10000-014 20 ~592238 2
82000
.10000-014 21 592238 2-24000
.10000-014-22-592238 2
26000
.10000-014 23 592238 2
28000
.10000-014 24 592238 2
5010
.10000-014 H2 5 ' 592238 2
6012
.10000-014 26-592238 3
8016
.10000-014 27 592238 3
1001
.10000-014 28 592238 3
13027
.10000-014 29 592238 3
82000
.10000-014 30 592238-3 24000
.10000-014 31 592238 3
26000
.10000-014
- 32 592238 3
2E000
.10000-014
~33.592238 3
5010
.10000-014
.34 592238 3
6012
.10000-014 INISHED MIXING CROSS SECTIONS L ELAPSED TIME
.00000000 MIN.
13628 LOCATIONS WILL BE USED 33*-ARRAY 540 Ef4TRIES READ OT i
\\
'0 UTER INNER DALANCE UPSCATTER' RATIO EIGENVALUE LAMBDA 1 I
.0h 1
271 1.0000005+000 1.0800473+300 1.2920082+000 1.2985092+000 2
393 1.0000005+000 1.0017005+000 1 2939166+000 9.9656562-001 1.42 3
480 1.0000004+000 9.9820417-001 1.2938509+000 9.9971094-001 1.0%
4 556 1.0000005+000 9.9959514-001 1.2935278+000 9.9984449-001 9.91 5
613 1.0000005+000 9.9997973-001 1.2934001+000 9.9992626-001 9.9%
6 652 1.0000005+000 1.0000266+000 1.2936903+000 1.0002277+000 9.99 7
684 1.0000004+000 1.0000092+000 1.2937858+000 1.0000728+0C0
.1.00 GRP.
1 REQUIRED 1 ITERATIONS. MFD OF 1.14927-005 OCCURRED IN INT.
20 COARS@
GRP.
2 REQUIRED 1 ITERATIONS. MFD OF 3.30515-006 0CCURRED IN INT.
20 COARS2 GRP.
3 REQUIRED 1 ITERATIONS. MFD OF 4.27567-006 OCCURRED IN INT.
20 COARS@
GRP.
4 REQUIRED 1 ITERATIONS. MFD OF 4.59517-006 OCCURRED IN INT.
20 COARS$
GRP.
5 REQUIRED 1 ITERATIONS. MFD OF 3.43605-006 0CCUPRED IN INT.
20 COARSQ GRP.
6 REQUIRED 1 ITERATIONS. MFD OF 2.90142-006 OCCURRED IN INT.
20 COARS@,
GRP.
7 REQUIRED 1 ITERATIONS. MFD OF 2.66984-006 OCCURRED IN INT.
20 COARSE GRP.
8 REQUIRED 1 ITERATIONS. MFD OF 2.50702-006 OCCURRED IN INT.
20 COARS@
GRP.
9 REQUIRED 1 ITERATIONS. MFD OF 2.72007-006 OCCURRED IN INT.
6 COARS@
GRP.-
10 REQUIRED 1 ITERATIONS. MFD OF 3.01582-006 OCCURRED IN INT.
2 COARS2 GRP.
11 REQUIRED 1 ITERATIONS. MFD OF 3.32807-006 0CCURRED IN INT.
9.COARS@
GRP.
12 REQUIRED 1 ITERATIONS. MFD OF 4.56143-006 OCCURRED IN INT.
5 COARS@
GRP.
13 REQUIRED 1 ITERATIONS. MFD OF 5.43299-006 0CCURRED IN INT.
4 COARS2 GRP.
14 REQUIRED 1 ITERATIONS. MFD OF 6.10219-006 OCCURRED IN INT.
20 COARS@
GRP.
15 REQUIRED 1 ITERATIONS. MFD OF 5.04572-005 OCCURRED IN INT.
14 COARS@
GRP.
16 REQUIPED 1 ITERATIONS. MFD OF 5.33172-005 OCCURRED IN INT.
14 COARS@
GRP..
17 REQUIRED 1 ITERATIONS. MFD OF 5.76491-005 OCCURRED IN INT.
14 COARS2 GRP.
If REQUIRED 1 ITERATIONS. MFD OF 5.66316-005 OCCURRED IN INT.
14 COARS@
GRP.
19 REQUIRED 1 ITERATIONS. MFD OF 5.11625 2005 OCCURRED IN INT.
14 COARS@
.GRP.
20 REQUIRED 1 ITEPATIONS. MFD OF 7.23191-005 OCCURRED IN INT.
20 COARS@
'GRP.
21 REQUIRED 1 ITERATIONS. MFD OF 7.25190-005 OCCURRED IN INT.
20 COARS@
GRP.
22 REQUIRED 1 ITERATIONS. MFD OF 7.91955-005 OCCURRED IN INT.
20 COARS@
GRP.
23 REQUIRED 1 ITERATIONS. MFD OF 2.01069 005 OCCURRED IN INT.
20 COARSQ GRP.
24 REQUIRED 1 ITERATIONS. MFD OF 5.40874-006 0CCURRED IN INT.
13 COARS@
.GRP.
25 REQUIRED 1 ITERATIONS. MFD OF 6.44405-006 0CCURRED IN INT.
20 C0ARS@
GRP.
26 REQUIRED 1 ITERATIONS. MFD OF 7.50399-006 OCCURRED IN INT.
20 COARSQ
- GRP.
27 REQUIRED 1 ITERATIONS. MFD OF 4.74937-006 OCCURRED IN INT.
19 COARS@
8 711 1.0000005+000 1.0000026+000 1.2938087+000 1.0000165+000 1.0Q FINAL MINITOR LAMBDA 1.2937890+000 ANGULAR FLUX ON' 16 ELAPSED TIME 2.48576665 MIN.
40.KNRX P/12/85'18:00:14 (6) 02 AECL CASK WITH NRX FUEL, NORMAL OP.
06 200. 53 403 3 27 27 15 6 16 53 1223 2 -15 1 0 2000 0 1 SZ 02
-1 3R0 2R-1 06 1
-92235 1.02424 1
92236 1.503-5 1
513327 8.825-3 06 1
558016 2.867-2 1
551001 5 733-2 1
92236 1.727-5 02 2
8016 3.347-2 2
1001 6.694-2 02-3 24000 1.839-2 3
28000 1.815-3 3
26000 5.994-2 02 4
5010 8.361-3 4
6012 1.083-2 4
13027 3.013-2 02 5
82000 3.299-2 02 6
13027.6.026-2
.02 BOX TYPE 1
05 CUB 0ID 1
13.486 1.437 2.8575 1.437 71.755 0.0 27*D.5 05 CUBOID 2
14.923 0.000 2.8575 0.318 71.755 0.0 27*0.5 05 CUBOID 3
15.240 0.000 2.8575 0.318 71.755 0.0 27*0.5 05 CUBOID 4-15.240 0.000 2.8575 0.000 71.755 0.0 27*0.5 02 00X TYPE 2
05 CUBOID 1
-1.437 -13.486 2.8575 1.437 71.755 0.0 27*0.5 05 CUBOID 2
0.000 -14.923 2.8575 0.318 71.755 0.0 27*0.5 05 CUBOID. 3 0.000 -15.240 2.8575 0.318 71.755 0.0 27*0.5
' 05 CUBOID 4
0.000 -15.240 2.8575 0.000 71.755 0.0 27*0.5 02 BOX TYPE 3
05 CUB 0ID 1
13.486 1.437 24.765 0.000 71.755 0.0 27*0.5 05 CU0010. 2 14.923 0.000 24.765 0.000 71.755 0.0 27*0.5 05 Cue 0ID 3
15.081 0.000 24.765 0.000 71.755 0.0 27*0.5 05 CUBOID 4
15.240 0.000 24.765 0.000 71.755 0.0 27*0.5 02 80X TYPE 4
05 CUBOID 1
-1.437 -13.486 24.765 0.000 71.755 0.0 27*0.5 05 CUDOID 2
0.000 -14.923 24.765 0.000 71.755 0.0 27*0.5 05 CUDOID 3
0.000 -15.081 24.765 0.000 71.755 0.0 27*0.5 05 Cuboid 4
0.000 -15.240 24.765 0.000 71.755 0.0 27*0.5 02 BOX TYPE 5
05 CUDOID 1
13.486 1.437 1.4205 0.000 71.755 0.0 27*0.5 05 Cue 0I0 2
14.923 0.000 2.5395 0.000 71.755 0.0 27*0.5 05 CUBOID 3
15.240 0.0 00 2.5395 0.000 71.755 0.0 27*0.5 H05 CUBOID 4
15.240 0.000 2.8575 0.000 71.755 0.0 27*0.5 02 00X TYPE 6
05~
cua010 1
-1.437 -13.486 1.4205 0.000 71.755 0.0 27*0.5 05 CUE 0I D 2
0.000 -14.923 2.5395 0.000 71.755 0.0 27*0.5 05 CUDOID 3
0.000 215.240 2.5395 0.000 71.755 0.0 27*0.5 05 Cun0ID 4
0.000 -15.240 2.8575 0.000 71.755 0.0 27*0.5 02 BOX TYPE 7
05 CUBOID 1
13.486 1.437 2.8575 1.437 7.62 0.0 27*0.5 05 CUBOID 2
14.923 0.000 2.8575 0.318 7.62 0.0 27*0.5 05 CUDOID 3
15.240 0.000 2.8575 0.318 7.62 0.0 27*3.5 05 CUDOID 3
15.240 0.000 2.8575 0.000 7.62 0.0 27*0.5 02 BOT TYPE S
05 CUBOID 1
-1.437 -13.486 2.8575 1.437 7.62 0.0 27*0.5 05 CUDOID 2
0.000 -14.923 2 8575 0.318 7.62 0.0 27*0.5 05 Cue 01D 3
0.000 -15.240 2.8575 0.318 7.62 0.0 27*0.5 05
-CUBOID 3
0.000 -15.240 2.8575 0.000 7.62 0.0 27*0.5 02 BOX TYPE 9
05 Cue 0ID 1
13.486 1.437 24.765 0.000 7.62 0.0 27*0 5 05 CUDOID 2
14.923 0.000 24.765 0.000 7.62 0.0 27*0.5 05 CUB 010 3
15.081 0.000 24.765 0.000 7.62 0.0 27*0.5 05 CUDOID 4
15.240 0.000 24.765 0.000 7.62 0.0 27*0.5
,02 00X L TYPE 10 LOS CUBOID 1~
-1.437 213.486 24.765 0.000 7.62 0.0 27*3.5 05 CUDOID 2
0.000 -14.923 24.765 0.000 7.62 0.0 27*0.5 IOS CUDOID 3
0.000 -15.081 24.765 0 000
-7.62 0.0 27*0.5
! 05-CUDOID 4
0.000 -15.240 24.765 0.000 7.62 0.0 27*0.5 02 BOX TYPE-11 LOS CUDOID.
1 13.486 1.437 1.4205 0.000 7.62 0.0 27*0.5
' 05 ~
CUBOID 2-14.923
.0.000 2.5935 0.000 7.62 0.0 27*0.5
'05-CUBOID 3-15.240 0.000 2.5935 0.000 7.62 0.0 27*0.5 l'05 CUBOID 3-15.240 0.000 2.8575 0.000 7.62 0.0 27*0.5
' 02 ~
DOX TYPE 12 05:
Cue 01D 1
-1.'437 213.486 1.4205 0.000 7.62 0.0 27*0.5
'05 CUBOID
.2
~0.000 -14.923 2.5935 0.000 7.62 0.0 27*0.5 05 Cue 0ID 3
0.000 -15.240 2.5935 0.000 7.62 0.0 27*0.5 05_
CUDOID 3
0.000 -15.240 2.8575 0.000- 7.62 0.0 27*0.5
,02
. CORE BDY 0
.15.240'-15.240 15.240 -15.240 79.375 0.00 27*0.5
'02 CYLINDER 3
21.56 79.375 0.00 27*0.5 02
' CYLINDER 5-37.47 79.375 0.00 27*0.5 LO2-CYLINDER 3
42.55.,
79.375 0.00 27*0.5-02.
CUDOID 2_42.56. -70.
70.
-70. 79.375 0.00 27*0.5 l.02 1
1 1 1 1 1 1 1 1 1 0
'02' 2
221 1 1 1 1 1 1 0
l02 3
1 1 1 2'2 1 1 1 1 0
L O2=
4 221 22 1 1 1 1 0
- G2
.5-1 1 1
.3 3 1 1 1 1 0
02 6
-2 2 1 331 1 1 1 0
02:
7
.1 1 1 1 1 1 221 0
l 02 8
221 11 1 2 2 4 0
l 02;
'9 11 1 22 1 22 1 0
'02 10-22 1 221 221 0
02 11 1 1 1 33 1 221 0
, 02 12 221 33 1 22 1 1
' 02.
END KENO.
[NONE.-TIME:
0.616 SEC. IMAGE COUNT: 88 o
h.. CONTROL MODE' i
- 0. KEN 066' f
fI.
c
.-.,n,,
-.n,
p L A E C'L' C A SK, WITH.' N R X FUEL, NORMAL.0P.
LNUMBER OF' GENERATIONS 53 START. TYPE G E N E R A T I NUMBER'PER' GENERATION.
403
= NUMBER OF GENERATIONS'TO BE SKIPPED 3
LIST INPUT X-SEC" NUMBER 0F ENERGY' GROUPS 27 LIST 1-D MIXTURE
- 1
~ MAX.' NUMBER 0F~ ENERGY TRANSFERS 27 LIST 2-D MIXTURE
-NUMBER OF. INPUT NUCLIDES 15 LIST FISS.'AND A.
1 NUMBER O F f4 I X T U R E S '.
6 USE X-SECTIONS F'
NUMBER 0F-MIXING' TABLE ENTRIES 16 USE GEOMETRY FR0 NUMBER OF GEOMETRY. CARDS 53 USE VELOCITIES F
'NUPBER OF BOX TYPES 12 COMPUTE MATRIX K NUMDER OF. UNITS.IN X DIRECTION 2
c.,MPUTE MATRIX Kl
> NUMBER'0F UNITS-IN Y DIRECTION 3
LIST FISS' PROB M
~
NUMBER,0F UNITS IN Z DIRECTION 2
ADJOINT CALCULAT:
. NUMBER'OF-NUCLIDES READ FROM TAPE
-15 USE EXPONENTIAL ALBEDO TYPE-1 CALCULATE FLUX SEARCHLTYPE O
CALCULATE FISSIO NHIS--PROBLEM'WILL DE RUN WITH SPECULARLY REFLECTING BOUNDARY-CONDITION s
/THE ALBEDOS'ARE
+X = 1.'00000 +000
-X
.00000 00000
,Y
.00000
+Y
=
=
=
'f7 A X I M U M : T I M E = 200.0000 MINUTES-STORAGE' LOCATIONS REQUIRED FOR THIS JOB =
31133 REMAINING-AVAILABLE' LOCATIONS =
34867 4
4 e
w
-wvm
-,e,
--,-,e ie,-wm < w
.r-,m-y=
r
.,m-ge,,m.e,,et,-
.,m-
=y=,--.,+.
e
+
AECL CASK WITH NRX FUEL,-NORMAL OP.
MIXTURE' NUCLIDE DENSITY 1
-92235-1.02400-004 1
92238 1.50300-005 1'
513027 8.82500-003 1
558016 2.86700-002 1
551001 5.73300;002 1
92236 1.72700-005 2
8016
-3.34700-002 2'
1001 6.69400-002 3
24000-
'1.83900-002 3
28000 1.81500-003 3
26000 5.99400-002 4
5010 8 36100-003 4
6012 1.08300-002 4
13027 3.01300-002 5
82000 3.29900-002 6
13027 6.02600-002
. CROSS SECTIONS READ FROM TAPE NUCLIDE =
1001 H'1269 F,
1002 T 218 GP 032475(2) 551001 H 1269 F,
1002 T 218 GP 032475(2)
NUCLIDE =
5010 B-10 1273 218NGP 042375 P-3 293K NUCLIDE =
NUCLIDE =
6012 C-12.1274F,1065T 218 GP 030476(7)
NUCLIDE =
8016 0@16 1276 218'GP 030476(7)
NUCLIDE'=
558016 0-16 1276 218 GP 030476(7)
NUCL8DE.=
13027 AL-27 1193 218 GP 040375(5) 513027 AL-27 1193 218 GP 040375 (5)
NUCLIDE =
24000 CR-1191 218NGP WT 1/E P-3 293K SIGP=5+4 RE(042375)
AUCLIDE
=
26000
'FE 218GP RE 5-17-78(1)
NUCLIDE =
28000 NI 1190 218NGP WT 1/E P-3,293K SIGP=5+4 R E(042 375)
NUCLIDE =
82000 PB 1288 218NGP 042375 P-3 293K NUCLIDE
=
- NUCLIDE =
92235 U-235 1261 SIGP=5+4 NEWXLACS 218NGP P-3 293KC3) l U 236 1163 SIG0=$+4 NEWXLACS P-3 293K F-1/E-M(1.+5)
NUCLIDE =
'92236-92238 U-238 218GP RE 5-17-78(1)
. NUCLIDE =
I
AECL CASK WITH NRX FUEL, NORMAL OP.
. ARRAY DESCRIPTION Z =
1 5
6 3
4 1
2 2 =
2 11 12 9
10 7
8 1
l
.AECL CASK.WITH'NRX FUEL,-NORMAL OP.
7.83680-005
=
1.09197-004 + OR,
9.88771-037
' GENERATION TIME =
', LIFETIME LNO. OF J INITIAL
-GENERATIONS AVERAGE 67 PER CENT 95 PER CENT SKIPPED
.K-EFFECTIVE-DEVIATION CONFIDENCE INTERVAL CONFIDENCE INTE'
.00467
.84098 To
.85031^
.83631 To
.85 3
.84565
+ OR
.00467
.84007 TO
.84942
.83540 To
.35 i
4
. 84475
+ OR E
5
.84363~
+ OR 2
.00463
.83899 To
.84826
.83436 TO'
.85 m4
.00473
.83886 To
.64832
.83412 To
.85
' a 6
.84359
+ OR
.00480
.S3935 To
.84896
.83455.To. 85 7
.84416
+ OR
.00470
.84083 TO
.85024
.83613 To
.35 8
.84554
+ OR l
.00481
.84086 To
.85047
.83605 To
.85 9
.84567'
+ OR
.00485
.84165 To
.85134
.83680 To
.85 10
.84650
+ OR
.00489
.84242 TO
.85221
.83752 TO
.35
.11
. 84731
+ OR
.00496
.84311 TO
.85302
.83815 TO
.85 12
.54806
+ OR
.00516
.84034 To
.85065
.33518 To
.85 17
.84550
+ OR
.00529
.83873 To
.84931
.83344 To
.85 22
.84402
+ OR
.00547
.83425 To
.84520
.32877 To
.85 27
.83972
+ OR
.00651
. 83081 TO
.84383
.82430 TO
.85 32
.83732
+ OR
.C0805
.82467 TO
.84077
.81662 TO
.84 l
37
.83272
+ OR c:
.00705
.83210 TO
.84621
.82505 TO
.85 42
.83915
+ 0R i
-.01063
.83741 To
.85868
.52678 To-.36 47 ~
.84805
+ OR i
i 4
i b
i i
l
_.... _._ _.,. _, _ _. _,~.. _. _., -
9 i
NO.KNRXHA
- 7/13/85 14: 15:35 (8) 07 AECL CASK WITH NRX FUEL, H.A.
06 200. 53 403 3 27 27 15 6 16 53 12 2 3 2 -15 1 0 2000 0 1 BZ 90 4
-1 3R0 2R-1 08 1
-592235 7.482-5 1
592238 1.099-5 1
513027 6.012-3 07 1
558016 2.996-2 1
551001 5.992-2 1
92236 1.262-5 04 2
8016 3.347-2 2
1001 6.694-2 04 3
24000 1.839-2 3
28000 1.815-3 3
26000 5.994-2 04 4
5010 8.361 4 6012 1.083-2 4
13027 3.013-2 04 5
82000 3.299 04 6
13027 6.026-2
'04 BOX TYPE 1
05 CUB 0ID 1
13.486 1.437 2.8575 1.437 71.755 0.0 27*0.5 07 CUBOID 1
14.923 0.000 2.8575 0.318 71.755 0.0 27*0.5 05 CUBOID 3-15.240 0.000 -2.8575 0.318 71.755 0.0 27*0.5 05 CUBOID 4
15.240 0.000 2.8575 0.000 71.755 0.0 27*0.5
-04 BOX TYPE 2
- - 05 CUBOID 1
-1.437 113.486 2.8575 1.437 71.755 0.0 27*0.5 07 CUB 0ID 1
0.000 -14.923 2.8575 0.318 71.755 0.0 27*0.5 05
. CUBOID 3.
0.000 -15.240 2.8575 0.318 71.755 0.0 27*0.5 05 CUBOID 4
0.000 -15.240 2.8575 0.000 71.755 0.0 27*0.5 04 BOX TYPE 3
05 CUBOID 1
13.486 1.437 24.765 0.000 71.755 0.0 27*0.5 07 CUBOID 1
14.923 0.000 24.765 0.000 71.755 0.0 27*0.5 05 CUBOID 3
15.081 0.000 24.765 0.000 71.755 0.0 27*0.5 05 CUBOID 4
15.240 0.000 24.765 0.000 71.755 0.0 27*0.5 04 BOX TYPE 4
05 CUBOID 1
-1.437 -13.486 24.765 0.000 71.755 0.0 27*0.5 07 CUBOID 1
0.000 -14.923 24.765 0.000 71.755 0.0 27*0.5 05 CUBOID 3
0.000 -15.081 24.765 0.000 71.755 0.0 27*0.5 05
' CUBOID 4
0.000 -15.240 24.765 0.000 71.755 C.0 27*0.5 04 BOX TYPE 5
05 CUBOID 1
13.486 1.437 1.4205 0.000 71.755 0.0 27*0.5 07.
CUBOID 1
14.923 0.000 2.5395 0.000 71.755 0.0 27*0.5 05 CUB 0ID 3
15.240 0.000 2.5395 0.000 71.755 0.0 27*0.5 05 CUBOID 4
15.240 0.000 2.8575 0.000 71.755 0.0 27*0.5 04 BOX TYPE 6
05 CUB 0ID 1
-1.437 -13.486 1.4205 0.000 71.755 0.0 27*0.5 07 CUB 0ID 1
0.000 -14.923 2.5395 0.000 71.755 0.0 27*0.5 05 CUBOID 3
0.000 -15.240 2.5395 0.000 71.755 0.0 27*0.5 05 CUBOID 4
0.000 -15.240 2.8575 0.000 71.755 0.0 27*0.5 04 00X TYPE 7
05 CUBOID 1
13.486 1.437 2.8575 1.437 7.62 0.0 27*0.5 07 CUBOID 1
14.923 0.000 2.8575 0.318 7.62 0.0 27*0.5 05 CUBOID 3
15.240 0.000 2.8575 0.312 7.62 0.0 27*0.5 05 CUB 0ID 3
15.240 0.000 2.8575 0.000 7.62 0.0 27*0.5 04 BOX TYPE 8
05 CUB 0ID 1
-1.437 -13.486 2.8575 1.437 7.62 0.0 27*0.5 c 07 CUB 0ID 1
0.000 -14.923 2.8575 0.318 7.62 0.0 27*0.5 05-CUBOID 3
0.000 -15.240 2.8575 0.31P 7.62 0.0 27*0.5 05 CUBOID 3
0.000 -15.240 2.8575 0.000 7.62 0.0 27*0.5 04 BOX TYPE 9
- 05 CUBOID 1
13.486 1.437 24.765 0.000 7.62 0.0 27*0.5 07 CUBOID 1
14.923 0.000 24.765 0.000 7.62 0.0 27*0.5 05 CUBOID 3
15.081 0.000 24.765 0.000 7.62 0.0 27*0.5 05 CUBOID 4
15.240 0.000 24.765 0.000 7.62 0.0 27*0.5
..=
~...
u04 BOX TYPE 10 05 CUBOID 1-
-1.437 -13.486 24.765 0.000 7.62 0.0 27*0.5 10 7 CUDOID. 1 0.000 -14.923 24.765 0.000 7.62 0.0 27*0.5 05 CUBOID 3-0.000 -15.081 24.765 0.000 7.62 0.0 27*0.5
- 05 CUBOID 4
0.000 -15.240 24.765 0.000 7.62 0.0 27 0.5 04 BOX TYPE 11 05-CUBOID 1
13.486 1.437 1.4205-0.000 7.62 0.0 27*0.5 07 CUBOID 1
14.923 0.000 2.5935 0.000 7.62 0.0 27*0.5 05 CUBOID 3
15.240.
0.000 2.5935 0.000 7.62 0.0 27*0.5 05 CUBOID 3
15.240
.0.000 2 8575 0.000 7.62 0.0 27*0.5 04
.80X TYPE 12 05 CUBOID 1
-1.437'-13.486 1.4205 0.000 7 62 0.0 27*0.5
.07 CUBoIO 1
'O.000 114.923 2.5935 0.000 7.62 0.0 27*0.5 05 CUB 0ID 3.
0.000'-15.240 2.5935 0.000 7.62 0.0 27*0.5 05 CUBOID L3 0.000 -15.240 2.8575 0.000 7.62 0.0 27*0.5 04 CORE BDY 0
15.240 -15.240 15.240 -15.240 79.375 0.00 27*0.5 04
' CYLINDER 3
21.56 79.375 0.00 27*0.5 04 CYLINDER 5
37.47 79.375 0.00 27*0.5 04 CYLINDER 3.
42.55 79.375 0.00 27*0.5 07 CUBOID 2.
42.56. -70. 70.
-70.
79.375 0.30 27*0.5 04 1
1 1 1 1 1 1 1 1 1 0
04 2
221 1 1 1 1 1 1 0
04 3
1.1 1 221 1 1 1-0 04 4~
22 1 22 1 1 1 1 0
04 5
.1 1
1-33 1 1 1 1 0
-04
.6 221 331 1 1 1 0
04
-7 1 11 1 1 1 221 0
04 8
221 1 1 1 22 1 0
04 9
1 1 1 22 1 221 0
04 -
10 22 1 221 22 1 0
~04 11 1 1 1 33 1 221 0
04 12 2.2 1 331 22 1 1
04 END KENO.
t NONE. TIME:
0.665 SEC. IMAGE COUNT: 88 N' CONTROL-MODE
- 30. KEN 066 1
LAECL CASK WITH NRX FUEL, H.A.
NUMBER OF GENERATIONS 53 START TYPE NUMBER PER GENERATION 403 GENERATIONS BETWE i
. NUMBER OF GENERATIONS'TO BE SKIPPED 3
LIST INPUT'X-SECY
. N U'M B E R OF ENERGY _ GROUPS 27 LIST 1-D' MIXTURE) l MAX. NUMBER OF-ENERGY TRANSFERS 27 LIST 2-D MIXTURE l NUMBER OF INPUT NUCLIDES ~
15 LIST FISS.AND-Ah NUMBER OF MIXTURES 6
USE X-SECTIONS F@
- NUMBER OF MIXING TABLE ENTRIES 16 USE GEOMETRY FR09
- NUMBER OF GEOMETRY ' CARDS 53 USE VELOCITIES FE NUMBER
- 0F BOX TYPES 12 COMPUTE MATRIX ~Kc
-NUMBER OF UNITS IN X DIRECTION 2
COMPUTE MATRIX-(E NUMBER OF1 UNITS IN'Y DIRECTION 3
LIST FISS' PROB MC
- NUMBER OF UNITS IN Z DIRECTION 2
ADJOINT CALCULATI NUMBER OF NUCLIDES READ FROM TAPE
-15 USE EXPONENTIAL-5 ALBEDO TYPE 1
CALCULATE FLUX
-SEARCH TYPE O
CALCULATE FISSIOR
~ THIS PROBLEM WILL BE RUN.WITH SPECULARLY. REFLECTING BOUNDARY CONDITION
.00000
.00000
-Y
=
.00000
+Y
=
1.00000+000
-X
=
THE:ALDEDOS ARE
+X
=
MAXIMUM TIME = 200.0000 MINUTES
-STORAGE LOCATIONS. REQUIRED FOR THIS J00 =
31133 REMAINING AVAILABLE LOCATIONS =
34867
~AECL CASK WITH NRX-FUEL, H.A.
MIXTURE NUCLIDE.
OsNSITY
)
592235 7.48200-005
-1 1
592238 1.09900.005 1
.513027 6.01200-003 J
1 558016 2.99600-002 l
1 551001 5.99200-002 1
92236 1 26200-005 2
8016 3.34700-002 2
1001
'6.69400f002 3
24000 1.83900-002 3
28000 1.81500-003 3-26000 5.99400-002 4
5010 8.36100-003 4:
6012 1.08300-002 4
13027 3.01300-002 4
-5 82000 3.29900-002
-6 13027 6.02600-002 CROSS: SECTIONS READ FROM TAPE 1001 H 1269 F,
1002 T 218 GP 032475(2)
NUCLIDE =
LNUCLIDE =
551001 H,1269 F,
1002 T 218 GP 032475(2) 5010 e-10 1273 218NGP 042375 P-3 293K NUCLIDE =
NUCLYDE =
6012 C-12 1274F,1065T'218 GP 030476(7) 8016 0-16 1276 218 GP 030476(7)
}.
NUCLIDE
=
j NUCLIDE =
. 556016 0-16 1276 218 GP 030476(7)
NUCLIDE =
13027 AL-27 1193 218.GP 040375 (5) i' NUCLfDE =
513027 AL-27 1193 218 GP 040375(5) 24000 CR 1191 218NGP WT 1/E P-3 293K SIGP=5+4 - RE(042 375)
NUCLIDE =
26000 FE 218GP RE 5-17-7B(1) l'.NUCLIDE
=
28000 NI 1190 218NGP WT 1/E P-3 293K SIGP=5+4 RE(042375)
NUCLIDE
=
NUCLIDE =
82000
'PD 1238 213NGP 042375 P-3 293K j; NUCLIDE =
592235 U-235 1261 SIGP=5+4 NEWXLACS 21SNGP P-3 293K(3) 92236 U-236 1163 SIGO:5+4 NEWXLACS P-3 293K F-1/E-M(1.+5) l NUCLIDE =
NUCLIDE =
592238 U-238 218GP RE 5-17-78(1)
I 1
~
.,.--,,~.,,,,-,.,,,r.,--,c.,6.,,.,,_,,.,.,.~%.,,w o u-,,,.,,,,_,_,_%,_...,_,o._, ~ -,,,.,.,,,, _ _ _,,,.,,.,,
,,.,,,y,.y~.
l 1
i
'AECL. CASK WITH NRX FUEL, H.A.
]
-ARRAY DESCRIPTION
)
Z =
1 5
6 3
4 1
2 2-=
2 11 12 9
10 7
8 l
l l
l l
l 1
.=
AECL CASK WITH NRX FUEL,-H.A.
9.04277-001 LIFETIME =
1.22202-004 + OR 8.96372-007' GENERATION TIME =
NO. 0F INITIAL GENERATIONS
. AVERAGE 67.PER CENT 95 PER CENl SKIPPED K-EFFECTIVE DEVIATION.
CONFIDENCE INTERVAL CONFIDENCE INT l
.00401
.80508 To
.S1310
.80107 To
.8.
3-
.80909
+ OR
.00406
.80552 To
.81364
.80146 To
.8 4
.80958
+ OR 4
.00414
.80524 To
.81352
.80110 To
. S' 5
.80938
+ OR l
.00401
.80670 To
.81471
.80269 To
.B' 6
.81071
+ OR
.00409
.50684 To
.81502
.80275 To~
.8 7
1.61093
+ OR
.00418
.80663 To
.81499
.80245 To
.8 8
.61081
+ OR
.00426
.80686 To
.81539
.80260 TO
.8 9
.81112
+ OR 1
.00436
.80650 To
.51521
.80214 To
.8
-10
.81085
+ OR
.00433
.80549 TO
.81416-
.80116'TO
.8 11:
.80983
+ OR L
.00442
.80496 TO
.81380
.80054 To
.8 12
.80938
+ OR 1
17
.80946
' + OR -
.00469
.80477 To
.81416
.80007 To
. B:
.00484
.80391 To
.81360
.79907 TO
.8 22
.80876
+ OR
.00509
.80418 To
.81437
.79909 TO
-.8 27
.80927
+ OR 1
.00602
.80252 TO
.81456
.79650 To
.8 32
.80854
+ OR
.00775
.80015-To
.81566
.79239 TO
.B 37
.80790
+ OR
.01004
.79600 To
.81607'
.78596 TO
.8 42
.80603
+ OR
.01046
.79739 TO
.81831
.78693 TO
.8 47
.80785
+ OR
)
l
JN04.KNRX4 37/12/85 22:00:04 (8) 07' AECL CASK WITH NRX-FUEL, NORMAL OP.,
4.0 G/CM, 40% U IN AL 06 200. 53 403 3 27 27 15 6 16 53 12 2 3 2 -15 1 0 2000 0 1 3Z 04
~1 3R0 2R-1 07 1 ~ -92235 2.048-4 1
92238 3.006-5 1
513327 6.177-3 07 1
558016 2.867-2 1
551001 5.733-2 1
92236 3.454-5 04 2
8016 3.347-2 2
1001 6.694-2 04 3
24000 1.839-2 3
28000 1.815-3 3
26000 5.994-2 04 4
5010 8.361-3 4
6012 1.083-2 4
13027 3.013-2 04 5
82000 3.299-2 04 6-13027 6.026-2 04 BOX TYPE 1
08 CUBOID 2
13.486 1.437 2.8575 1.437 71.755 0.0 27*0.5 05 CUBOID 2
14.923 0.000 2.8575 0.318 71.755 0.0 27*0.5 05 CUBOID 3
15.240 0.000 2.S575 0.318 71.755 0.0 27*0.5 05 CUBOID 4
15.240-0.000 2.8575 0.000 71.755 0.0 27*0.5 04 BOX. TYPE 2
08 Cue 0ID 2
-1.437 -13.486 2.8575 1.437 71.755 0.0 27*0.5 05 CUDOID 2
0.000 -14.923 2 8575 C.318 71.755 0.0 27*0.5 05 CUBOID 3
0.000 -15.240 2.8575 0.318 71.755 0.0 27*0.5 05-CUD 010 4
0.000 -15.240 2.8575 0.000 71.755 0.0 27*0.5 04 BOX TYPE 3'
08 CUDOID 1
11.100 3.820 23.800 0.963 71.755 0.0 27*C.5 JO S CUDOID 2
14.923 0.000 24.765 0.000 71.755 0.0 27*0.5 05 CUBOID 3
15.081 0.000 24.765 0.000 71.755 0.0 27*0.5 05 CUBOID 4
15.240 0.000 24.765 0.000 71.755 0.0 27*0.5 04 00X TYPE 4
08 CUBOID 1
-3.320 -11.100 23.800 0.963 71.755 0.0 27*0.5 05 CUDOID 2
0.000 -14.923 24.765 0.000 71.755 0.0 27*0.5 05 CUBOID 3
0.000 -15.081 24.765 0.000 71.755 0.0 27*0.5 05 CUBOID 4
0.000 -15.240 24.765 0.000 71.755 0.0 27*0 5 04 BOX TYPE 5
08 C00010 2
13.486 1.437 1.4205 0.000 71.755 0.0 27*0.5 05 CUBOID 2
14.923 0.000 2.5395 0.000 71.755 0.0 27*0.5 05 CUBOID 3
15.240 0.000 2.5395 0.000 71.755 0.0 27*3.5 05 CUDOID 4
15.240 0.000 2.8575 0.000 71.755 0.0 27*0.5 04 00X TYPE 6
08 CUDOID 2
-1.437 -13.486 1.4205 0.000 71.755 0.0 27*0.5 05 CUB 010 2
0.000 -14.923 2 5395 0.000 71.755 0.0 27*0.5 05 CUDOID 3
0.000 -15.240 2.5395 0.000 71.755 0.0 27*0.5 05 Cun01D 4
0.000 -15.240 2.8575 0.000 71.755 0.0 27*0.5 i
04 DOX TYPE 7
i 08.
Cun0ID 2
13.486 1.437 2 8575 1.437 7.62 0.0 27*0.5 05 CUGOID 2
14.923 0.000 2.8575 0.318 7.62 0.0 27*0.5 05 CUPOID 3
15.240 0.000 2.8575 0.318 7.62 0.0 27*0.5 05 CUB 0ID 3
15.240 0.000 2.6575 0.000 7.62 0.0 27*0.5 04 00X TYPE 8
]
08 CUB 0ID 2
-1.437 -13.486 2 8575 1.437 7.62 0.0 27*3.5 05 CUBOID 2
0.000 -14.923 2.8575 0.318 7.62 0.0 27*0.5 05 CUBOID 3
0 000 -15.240 2.8575 0.318 7.62 0.0 27*0 5 3
01 5 CUBOID 3
0.000 -15.240 2.8575 0.000 7.62 0.0 27*D.5 04 00X TYPE 9
08 CUBOID 1
11.100 3.820 23.800 0.963 7.62 0.0 27*0.5 05 CUGOID 2
14.923 0.000 24.765 0.000 7.62 0.0 27*0.5 05 CUDOID 3
15.081 0.000 24.765 C.00C 7.62 0.0 27*0.5 05 CUBOID 4
15.240 0.000 24.765 0.000 7.62 0.0 27*0.5 L
._.--,.--m
.-._.m.,
04 BOX TYPE 10 08 CUBOID 1
-3.820 -11.100 23.800 C.963 7.62 0.0 27*3.5 05 Cue 0ID 2
0.000 -14.923 24.765 0.000 7.62 0.0 27 0.5 05 Cue 01D 3
0.000 -15.081 24.765 0.000 7.62 0.0 27*0.5 05 CUBOID 4
0.000 -15.240 24.765 0.000 7.62 0.0 27*0.5 04 BOX TYPE 11 08 CUuoID 2
13.486 1.437 1.4205 0.000 7.62 0.0 27*3.5 05 Cue 0I0 2
14.923 0.000 2.5935 0.000 7.62 0.0 27*0.5 05 CUDOID 3
15.240 0.000 2.5935 0.000 7.62 0.0 27*0.5 05 CUB 0ID 3
15.240 0.000 2.8575 0.000 7.62 0.0 27*0.5 04 00X TYPE 12 08 CUBOID 2
-1.437 -13.486 1.4205 0.000 7.62 0.0 27*0.5 05 Cue 01D 2
0.000 -14.923 2.5935 0.000 7.62 0.0 27*0.5 05 CUDOID 3
0.000 -15.240 2.5935 0.000 7.62 0.0 27*0.5 05 CUBOID 3
0.000 -15.240 2.8575 0.000 7.62 0.0 27*0.5 04 CORE BDY 0
15.240 -15.240 15.240 -15.240 79.375 0.00 27*0.5 04 CYLINDER 3
21.56 79.375 0.00 27*0.5 04 CYLINDER 5
37.47 79.375 0.00 27*0.5 04 CYLINDER 3
42.55 79.375 0.00 27*0.5 04 CUBOID 2
42.56.
-70.
70.
-70.
79.375 0.00 27*0.5 04 1
1 1 1 1 1 1 1 1 1 0
04 2
22 1 1 1 1 1 1 1 0
04 3
1 1 1 22 1 1 1 1 0
04 4
22 1 22 1 1 1 1 0
04 5
1 1 1 33 1 1 1 1 0
04 6
2 2 1 331 1 1 1 0
04 7
1 1 1 1 1 1 22 1 0
04 8
2 2 1 1 1 1 22 1 0
04 9
1 1 1 22 1 22 1 0
04 10 221 22 1 22 1 0
04 11 1 1 1 33 1 22 1 0
04 12 2 2 1 331 22 1 1
04 END KENO.
4: NONL. TIME:
0.660 SEC. IMAGE COUNT: SS GN CONTROL MODE
[NO. KEN 066
~
t, i
AECL CASK WITH NRX' FUEL, NORMAL'OP., 4.'O G/CM, 40% U IN AL N' UMBER OF GENERATIONS 53 START TYPE i
(NUMBER'PER-GENERATION 403 GENERATIONS DETd
. NUMBER OF GENERATIONS TO BE-SK IPP ED 3-LIST INPUT X-SEC
- NUMBER-OF= ENERGY GROUPS 27 LIST 1-D MIXTURE-
-RAX. NUMBER OF ENERGY TRANSFERS-27 LIST'2-D MIXTURE i
NUMBER OF INPUT-NUCLIDES 15 LIST FISS. AND A NUMBER OF MIXTURES 6
USE X-SECTIONS F NUMBER OF MIXING TABLE ENTRIES 16 USE GEOMETRY FR0 NUMBER OF GEOMETRY CARDS 53 USE VELOCITIES F NUMBER OF BOX-TYPES 12 COMPUTE MATRIX K NUMBER OF UNITS IN X DIRECTION 2
COMPUTE MATRIX K NUMBER OFLUNITS IN Y DIRECTION 3
LIST FISS PROB M NUMBER OF UNITS IN Z-DIRECTION 2
ADJOINT CALCULAT l-NUMBER OF NUCLIDES READ FROM TAPE
-15 USE EXPONENTIAL ~
ALBEDO TYPE 1
CALCULATE FLUX SEARCH TYPE O
CALCULATE FISSIO THIS PROBLEM WILL DE RUN WITH SPECULARLY REFLE CTING 00UND ARY CONDITION
.00000
-Y
=
.00000 THE ALDEDOS ARE.+X =-1.00000+000
-X
.00000
+Y
=
=
200.0000 MINUTES MAXIMUM TIME =
31133 STORAGE LOCATIONS REQUIRED FOR THIS J00 =
REMAINING AVAILAULE. LOCATIONS =
34867 I
w:
AECL CASK WITH NRX FUEL, NORMAL OP.,
4.9 G/CM, 40% U IN AL MIXTURE NUCLIDE DENSITY 1
-92235 2.04800-004 1
92238 3.00600-005 1
513027 6.17700-003 1
558016 2.86700-002 1
551001 5.73300-002 1
92236 3.45400-005 2
8016 3.34700-002 2
1001 6.69400-002 3
24000 1.83900-002 3
28000 1.81500-003 3
26000 5.99400-002 4
5010 8.36100-003 4
6012 1.08300-002 4
13027 3.01300-002 5
82000 3.29900-002 6
13027 6.02600-002 CROSS SECTIONS READ FROM TAPE 1001 H 1269 F,
1002 T 218 GP 032475(2)
NUCLIDE =
NUCLIDE =
551001 H 1269 F,
1002 T 213 GP 0?2475(2) 5010 E-10 1273 218NGP 042375 P-3 293K NUCL7DE
=
NUCLIDE =
6012 C-12 1274F,1065T 218 GP 030476(7)
S016 0-16 1276 218 GP 030476(7)
NUCLfDE =
558016 0-16 1276 218 GP 030476(7)
NUCLIDE =
13027 AL-27 1193 218 GP 040375(5)
NUCLIDE =
513027 AL-27 1193 218 GP 040375(5)
NUCLIDE =
24000 CR 1191 218NGP WT 1/E P-3 293K SIGP=5+4 RE(042375)
NUCLIDE =
26000 FE 218GP RE 5-17-7S(1)
NUCLIDE
=
NUCLIDE =
28000 NI 1190 218NGP WT 1/E P-3 293K SIGP=5+4 RE(042375) 820C0 PB 1288 218NGP 042375 P-3 2 9 3 K NUCLIDE
=
92235 U-235 1261 SIGP=5+4 NEdXLACS 218NGP P-3 293K(3)
NUCL?DC
=
92236 U-236 1163 SIG0=5+4 NEWXLACS P-3 293K F-1/E-M(1.+5)
NUCL2DE
=
NUCL IDE =
92238 U-238 218GP RE 5-17-78(1)
AECL CASK WITH NRX FUEL, NORMAL OP.,
4.0 G/CM, 40% U IN AL
~ ARRAY DESCRIPTION Z a 1
5 6
3 4
1 2
2 I =
11 12 9
10 7
8
~.
4 i:
-A CLLCASK WITH.NRX FUEL, NORMAL-OP., 4.0'G/CM,'40% U IN AL LIFETIME =
1.10195-004 + OR -
1.03636-006 GENERATION TIME =
7.02769-00 NO. OF' INITIAL-GENERATIONS AVERAGE-67 PER CENT 95 PER CEN'
- SKIPPED K-EFFECTIVE DEVIATION CONFIDENCE INTERVAL, CONFIDENCE INT!
3
.78448
+ OR
.00536
.77913 T0,
.78934
.77377 To
.7 41
.78420'
'+ OR
.00546
.77874 To
.78966
.77328 To
.7
'5
.78402
+ OR
.00557
.77845 TO
.78959
.77288 To
.7 i
6
.78550
+OR
.00549
.78 002 To
.79099
.77453 To
. 7:
i 7
.78478
+ OR
.00556
.77922 T0
.79033
.77366 TO
.7; 8
.78480
+ OR
.00568
.77911 TO
.79048
.77343 TO
. 7:
-.00581
.77904 To
.79067
.77323 To
.7 9
.78485
+ OR
.00595
.77892 To
.79082
.77297 To
.7 10
.78487
+ OR 11
.78493
+ OR -
.00609
.77883 To
.79102
.77274 To
.7
.00610
.78010 TO
.79231
.77400 TO
.7 j
12
.78620
+ OR
.00662
.77956'TO
.79281
.77294 TO 17
'17
.78618
+ OR
.00661
.77359 To
.78681
.76699 To.
7.
22
.78020
+ OR I
.00715
.77391 To
.78821
.76676 To
.7-27
.78106
+ OR
.00800
.76887 To
.78487
.76087 To
. 7.
32
.77687
+ OR
.00939 76280 To
.78157
.75342 To
.7 37
.77219
+ OR
{
42
.76615
+ OR
.01263
.75352 To
.77878
.74089 To
.7:
.01817
.73701 TO
.77335
.71884 TO
.7 47
.75518
+' OR 1
4 J
I j
a i
i 1-1
)
t
_, _ _,. _. _ - _ _,, _.. - - - -. _ _ _ -., _ _ _. _.....,.. ~.. _ - - _ - _... _.., _ - _ -.. _ -. _,, _, - _... -. -
.N04eKNRX4HA 17/13/85 14: 13:29 (10) 09 AECL CASK WITH NRX FUEL, H.A.,
4.0 G/CM, 40% U IN AL 06 200. 53 403 3 27 27 15 6 16 53 12 2 3 2 -15 1 0 2000 0 1 SZ 06
-1 3R0 2R-1 09 1
-592235 1.496-4 1
592238 2.198-5 1
513027 4.209-3 09 1
558016 2.996;2 1
551001 5.992-2 1
92236 2.524-5 06 2
8016 3.347-2 2
1001 6.694-2 06 3
24000 1.839-2 3
28000 1.815-3 3
26000 5.994-2 06 4
5010 S.361-3 4
6012 1.083-2 4
13027 3. 013 -2 06 5
82000 3.299-2 06 6
13027 6.026-2
'10 DOX TYPE 1
10 CUB 0ID 2
13.486 1.437 2.8575 1.437 71.755 0.0 27*0.5 10 CUBOID 2
14.923 0.000 2.8575 0.318 71.755 0.0 27*0.5 10' CUBOID 3
15.240 0 000 2.8575 0.315 71.755 0.0 27*0.5 10 CUDOID 4
15.240 0.000 2.8575 0.000 71.755 0.0 27*0.5
'10 00X TYPE 2
10 CUDOID 2
-1.437 -13.486 2.8575 1.437 71.755 0.0 27*0.5 10 CUBOID 2
0.000 -14.923 2.8575 0.318 71.755 0.0 27*0.5 10 CUBOID 3
0.000 -15.240 2.8575 0.318 71.755 0.0 27*0.5 10 CUB 0ID 4
0.000 -15.240 2.8575 0.000 71.755 0.0 27*0.5 10 00X TYPE 3
10 CUD 010 1
11.100 3.820 23.800 0.963 71.755 0.0 27*0.5 10 CU0010 2
14.923 0.000 24.765 0.000 71.755 0.0 27*0.5 10 CUBOID 3
15.081 0.C00 24.765 0.000 71.755 0.0 27*0.5 10 CUDOID 4
15.240 0.000 24.765 0.000 71.755 0.0 27*0.5 10 00X TYPE 4
10 CUBOID 1
-3.820 -11.100 23.800 0.963 71.755 0.0 27*0.5 10 Cue 010 2
0.000 -14.923 24.765 0.000 71.755 0.0 27*0.5 10 CUDOID 3
0.000 -15.081 24.765 0.000 71.755 0.0 27*0.5 10 CUDOID 4
0.000 -15.240 24.765 0.000 71.755 0.0 27*0.5 10 00X TYPE 5
10 Cue 01D 2
13.486 1.437 1.4205 0.000 71.755 0.0 27*0.5 10 CUDOID 2
14.923 0.000 2 5395 0.000 71.755 0.0 27*0.5 10 Cue 01D 3
15.240 0.000 2.5395 0.000 71.755 0.0 27*0.5 10 C00010 4
15.240 0.000 2.8575 0.000 71.755 0.0 27*0.5 10 00X TYPE 6
10 CUGOID 2
-1.437 -13.486 1.4205 0.000 71.755 0.0 27*0.5 10 CUDOID 2
0.000 -14.923 2.5395 0.000 71.755 0.0 27*0.5 10 CUDOID 3
0.000 -15.240 2.5395 0.000 71.755 0.0 27*0.5 10 CUDOID 4
0.000 -15.240 2.8575 0.000 71.755 0.0 27*0.5 10 DOX TYPE 7
10 Cue 010 2
13.486 1.437 2.S575 1.437 7.62 0.0 27*0.5 10 CUB 0ID 2
14.923 0.000 2.8575 0.318 7.62 0.0 27*0.5 10 CUBOID 3
15.240 0.000 2.8575 0.318 7.62 0.0 27*0.5
-10 C000ID 3
15.240 0.000 2.8575 0.000 7.62 0.0 27*0.5 10 00X TYPE 8
10 CUB 0ID 2
-1.437 -13.486 2.8575 1.437 7.62 0.0 27*0.5 10 CUBOID 2
0.000 -14.923 2.8575 0.31E 7.62 0.0 27*0.5 10 CUB 0ID 3
0.000 -15.240 2.8575 0.318 7.62 0.0 27*0.5 10 CUE 010 3
0.000 -15.240 2.8575 0.000 7.62 0.0 27*0.5
-10 P0X TYPE 9
10 CUBOID 1
11.100 3.820 23.300 0.963 7.62 0.0 27*0.5 10 C00010 2
14.923 0.000 24.765 0.000 7.62 0.0 27*0.5 10 CODOID 3
15.061 0.000 24.765 0.000 7.62 0.0 27*0.5 10 CUBOID 4
15.240 0.000 24.765 0.000 7.62 0.0 27*0.5
10 00X TYPE 10 10 CUBOID 1
-3.820 511.100 23.800 0.963 7.62 0.0 27*0.5-
-10 CUBOID 2
0.000 -14.923 24.765 0.000 7 62 0.0 27*0.5 10 CUBOID
.3 0.000 115.081 24.765 0.000 7.62 0.0 27*0.5
~1-0 CUDOID 4
0.000 -15.240 24.765 0.000 7.62 0.0 27*0.5 10 BOX TYPE 11 10 CUB 0ID 2
13.486
'1.437 1.4205 0.000 7.62 0.0 27*0.5 10 CUBOID
-2 14.923 0.000 2.5935 0.000 7.62 0.0 27*0.5 10 CUB 0ID 3
15.240 0.000 2.5935 0.000 7.62 0.0 27*0.5 10 CUDOID-3 15.240 0.000 2.8575 0.000
.7.62 0.0 27*0.5 10 BOX TYPE 12 10 CUBOID 2 - -1.437 -13.486.
1.4205 0.000 7.62 0.0 27*0.5
.10 CUDOID. 2 0.000 -14.923 2.5935 0.000 7.62 0.0 27*0.5 10 CUBOID 3
0.000 -15.240 2.5935 0.000 7.62 0.0 27*0.5 10 CUB 0ID 3
0.000 -15.240 2.8575 0.000 7.62 0.0 27*C.5 10 CORE DDY 0
15.240 -15.240 15.240 -15.240 79.375 0.00 27*0.5 10 CYLINDER 3
21.56 79.375 0.00 27*0.5 10 CYLINDER 5
37.47 79.375 0.00 27*0.5 10 CYLINDER 3
42.55 79.375 0.00 27*0.5 10 CU0010 2
42.56. -70.
- 70. -70. 79.375 0 00 27*0.5 10 1
1 1 1 1 11 1 1 1 0
10 2
221 1 1 1 1 1 1 0
10 3
1 1 1 22 1 1 1 1 0
10 4
22 1 22 1 1 1 1 0
10 5
1 1 1 33 1 1 1 1 0
10 6
221 33 1 1 1 1 0
10 7
1 1 1 1 1 1 221 0
10 8
22 1 1 1 1 22 1 0
'10 9
1 1 1 221 22 1 0
10 10 221 221 221 0
10 11 1 1 1 33 1 22 1 0
10 12 221 331 22 1 1
10 END KENO.
5: NONE. TIME:
0.655 SEC. IMAGE COUNT: SE IN CONTROL MODE ENO. KEN 066 i
i
'AECL CASK WITH NkX FUEL, H.A.,
4.0 G/CM, 40% U IN AL NUMBER OF GENERATIONS 53 START TYPE NUMBER 1PER' GENERATION 403 GENERATIONS BETd NUMBER;0F GENERATIONS TO BE SKIPPED 3
. LIST INPUT X-SE@
NUMBER OF' ENERGY GROUPS 27 LIST 1-D MIXTUR@
= MAX. NUMBER OF. ENERGY TRANSFERS 27 LIST 2-D MIXTURE NUMB ER 10 F - INPUT NUCLIDES 15 LIST FISS. AND C NUMBER OF MIXTURES 6
USE X-SECTIONS F NUMBER OF MIXING TABLE ENTRIES 16 USE GEOMETRY FR@
NUMBER:0F GEOMETRY CARDS 53 USE VELOCITIES 9 NUMBER'0F 00X TYPES 12 COMPUTE MATRIX Q INUFDER OF UNITS IN X DIRECTION 2
COMPUTE MATRIX Q
-NUMDER OF UNITS'IN Y' DIRECTION 3
LIST FISS PROB G NUMBER OF UNITS IN Z DIRECTION 2
ADJOINT CALCULAE NUMDER OF NUCLIDES READ FROM TAPE
-15 USE EXPONENTIAL
. ALBEDO TYPE 1
CALCULATE FLUX
' SEARCH TYPE O
CALCULATE FISSI@
THIS PROBLEM WILL BE RUN WITH.SPECULARLY REFLECTING DOUNDARY CONDITION
.00000
-Y
=
.00000 1.00000+000
-X
.00000
+Y
=
.THE ALBEDOS ARE
+X
=
=
' MAXIMUM TIME = 200.0000 MINUTES
-STORAGE LOCATIONS REQUIRED FOR THIS J00 =
31133 REMAINING AVAILADLE LOCATIONS:
34867 t
[.
I AECL CASK'WITH NRX FUEL, H.A.,
4.0 G/CM,- 40% U IN AL MIXTURE NUCLIDE DENSITY 1
-592235-1.49600-004 1
1 592238 2.19800-005 1
- 513027 4.20800-003 1
558016 2.99600-002 1
551001
'5.99200-002 1-92236 2.52400-005 2
8016 3.34700-002.
2 1001 6.69400-002-3
.24000 1.83900-002 3
28000 1.81500 003 7
3
'26000 5.99400-002 4
5010 8.36100-003 4
6012 1.08300-002 4
13027 3.01300-002 5
82000 3.29900-002 6
13027 6.02600-002 l
l ' CROSS SECTIONS READ FROM TAPE j
NUCLIDE-=
1001 H 1269 F,
1002 T 213 GP 032475(2)
NUCLIDE~=
551001 H 1269 F,
1002 T 218 GP 032475(2) 5010 B710 1273 218NGP 042375 P-3 293K l
NUCLIDE =
NUCLIDE =
6012 C-12 1274F,1065T 218 GP 030476(7)
, -NUCLIDE =
8016 0-16 1276 218 GP 030476(7) 558016 0-16 1276 218 GP 030476(7)
NUCLIDE =
NUCLIDE =-
13027 AL-27 1193 218 GP 040375 (5)
NUCLIDE =
513027 AL-27 1193 218 GP 040375 (5) l 'NUCLIDE =
24000 CR 1191 218NGP WT 1/E P-3 293K SIGP=5+4 RE(042375) 26000 FE 218GP RE 5-17-78(1)
NUCLIDE =
28000 NI 1190 218NGP WT 1/E P-3 293K SIGP=5+4 RE(042375)
NUCLIDE
=
82000 PB
'1288 218NGP 042375 P-3 293K NUCLIDE =
l NUCLIDE 592235 U-235-1261 SIGP=5+4 NEWXLACS 218NGP P-3 293K(3)
=
l 92236 U-236 1163 SIG0=5+4 NEWXLACS P-3 293K F-1/E-M(1.+5)
NUCLIDE
=
l NUCLIDE =
592238 U-238 218GP RE 5-17-78(1) l l
I I
1
)
t
.I i
l L
v-+
.. w w
,r m n,r~ne, s,m p-.
r-w.p m s m m e-.
, y m,w wwww w-w
-,ee me m w
,-w r mw-w n,yvn, v.r
,,,, e e.m w e w w m e wsm--e.g.,-mw w m m e- -,-, -
re e
AECL CASK WITH NRX FUEL, H.A.,
4.0 G/CM, 40% U IN AL ARRAY DESCRIPTION Z =
1 5
6 3
4 1
2 Z-=
2 11 12 9
10 7
8
n
- Q,J, u.
x AECL CASK.WITH NRX FUEL, H.A.,
4.0 G/CM, 40% u IN AL 8.48957-005 1.24996-004 + OR 1.01905-006 GENERATION TIME =
- LIFETIME =
NO.HOF' INITIAL GENERATIONS AVERAGE 67 PER CENT 95 PER CEN9
$KIPPED K-EFFECTIVE DEVIATION CONFIDENCE INTERVAL CONFIDENCE INT @I
.00535
.70651 To
.71721
.70117 To
.7d 3
.71186
+ 'OR 4
.71142
+ OR
.00544
.70598 TO
.71686
.70055 TO
.78 5
.71139
+ OR
.00555
.70584 T<0
.71695
.70029 TO
.75 6
.71162-
+ OR 1
.00567
.70596 TO
.71729
.70029 TO
.78 7
.71125
+ OR
.00578
.70547 To
.71703
.69969 To
.7-
'8
.71028
+ OR
~.00583 ~
.70446JTO
.71611
.69863 TO
.71 Oi -
.00596
.70432-To
.71624
.69836 TO
.7 9
.71028
+
10
.71208
+ OR,-
.00582
.70626 To
.71789
.70044 TO.
.7 11
.71160
+ OR
--.00594-
.70567 To
.71754
.69973 TO
.7 12
.71070
+ OR
.00601
.70469 To
.71671
.69867 To
.7 17
.70862
+ OR
.00637
.70225 TO
.71499
.69589 To
.7 22
.71109
+ OR
.00712
.70397 To
.71821
.69685 To
.7 27
.71510
+ OR
.00756
.70754 To
.72267
.69997 To
.7 32
.71396
+ OR
.00,921
. 70474 To
.72317
.69553 To
.7 37
.72214
+ OR -. 00899
.71315 TO
.73112
.70416 TO
.7 42
.71345
+ OR
.01098~
.70247 To
.72442
.69149 To
.7h 47
.72903
+ OR R'
.01027' '
.71876 To
.73931
.70849 To
.7(
s w *,,
4 t
4 i -
1 J.
I i
1 s
DOCKET NO.
[~
/M
> CONTROL NO._ OOO((
y DATE OF DOC..
07l/fl [ ~
l
-DATE RCVD.__
[ /[J f/g f N
l PD FCAF LPDR W
I&E REF.
WUR SAFEGUARDS FCTC OTHER i
DESCRIPTION:
_MLe&&
L
~3;V/L &ukXin
&&~,b/Le 4
4 y
J I
i 4
4 t
,+g