ML20155K503

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Application for Amend to Certificate of Compliance 5942, Adding New Section 5.(b)(2)(x) to Read as Stated.Criticality Evaluation Encl.W/O Attachment B.Fee Paid
ML20155K503
Person / Time
Site: 07105942
Issue date: 02/28/1986
From: Cunningham G
GENERAL ELECTRIC CO.
To: Macdonald C
NRC OFFICE OF NUCLEAR MATERIAL SAFETY & SAFEGUARDS (NMSS)
References
26557, NUDOCS 8806210248
Download: ML20155K503 (92)
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GENER AL $ ELECTRIC NUCLEAR ENERGY BUSINESS OPERATIONS GENERAL ELECTRIC COMPANY e VALLECTOS NUCLEAR CENTER e PLEASANTON CAQL FORNtA 94566 O

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O February 28, 1986 D

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Reference:

Certificate of Compliance No. 5942.

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Dear Mr. MacDonald:

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The General Electric Company requests that Certificate.of Compliance No. 5942 be amended to add a new section 5.'(b)(2)(x) to readi Tx) 7,000 gTA U-235 provided the fuel is in the form of MTR _ type fuel sections with each section containing no more than 175 gm U-235 inserted in a spaced stainless steel fuel shipping basket described in GE Drawing No 'SK-172.

L' hen a shipment contains less than the maximum number (40) of fuel. sections, empty fuel section basket spaces shall be provided with an aluminum or steel spacer in the form of an M

open ended pipe with a minimum outer diameter of 2.5, inches and a minimum wall thickness of 0.125 inches. The spacer shall be sufficient length to replace the absent fuel sections."

Justification for this request is contained in a critihality evaluation enclosed as Attachment A to this letter.

The evaluation is in the format of USNRC Regu)atory Guide 7.9.

The maximum weight of the fully loaded basket'is approximately 400 pounds (well below the 700 pound limit);

The empty. basket weighs approximately 180 pounds, and each fuel se.ction weighs less than 5.5 pounds.

General Electric also requests.that the following sentence be added to Section 5 (b)(2)(ix):

"A shipment may contain les's than 20 elements provided each

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absent element is replaced by an aluminum'or steel spacer in the form of an open-ended pipe with a minimum outer diameter of 2.5 inches'and a minimum wall thickness of 0.125 inches."

Use of the spacers will prevent shifting of basket components during shipment.

The new loading request is submitted by General Electric on behalf of the National Bureau of Standards (NBS) and is for their sole use, as the fuel described in the criticality evaluation is unique to the NBS facility. As a Federal agency, NBS has requested the waiving of all review fees.

A copy of their letter is enclosed as Attachment B.

Accordingly, no application fee is j

enclosed.

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GENER AL $ ELECTRIC C. E. MacDonald February 28, 1986 f

If you have any questions concerning this submittal, please contact me at (415) 862-4330.

Sincerely, a

G. E. Cunn ngham Senior Licensing Engineer

/ca Enclosures 1

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CRITICALITY EVALUATION A criticality evaluation of the General Electric 700 cask containi'ng 40 National Bureau of Standards (NBS) fuel sections prepared for reprocessing is given below. This cask has a cavity that is 15 inches in diameter by 54.75 inches long for holding material, including special nuclear material. The cask is of steel-encased lead-shielded construction.

6.1 Conclusions Compliance with 10CFR71.61 for Fissile Class III shipments is demonstrated below for one loading.

This loading involves 40 MTR-type fuel sections cut for reprocessing and inserted in a stainless steel basket in the cask cavity.

The basket provides a fixed neutron poison for the fuel sections.

Each fuel section has 17 plates originally containing 10.294 grams U-235 of fully enriched uranium per plate. This gives 175 grams U 235 per fuel section and 7,000 grams U-235 per cask, without consideration of U 235 burnup.

Although the actual shipment will be made dry, the contents of the cask were assumed to be wet, as after the accident described in 10CFR71.73 the contents of the cask would be wet, and the loading and unloading activities for this shipment were assumed to be made under water.

In the discussion below, details of the package fuel loading are presented first. Then, a description of the models used to calculate the k-effective values for the fuel loading is presented. This is followed by the criticality calculation discussion for each of the models.

Finally, the criticality benchmark experiments section is presented.

6.2 Packace Fuel Loadine The type, form, and maximum quantity of special nuclear material per package are:

7,000 grams U-235 provided the fuel is in the form of MTR type fuel sections with each section containing no more than 175 grams U-235 as described in NBS Drawing No. E 04 039, Revision 3 (attached) and inserted in a spaced 1

stainless steel fuel shipping basket described in GE Drawing No. SK-861 (Figure 6.3.1-2).

The loading above qualifies as Fissile Class III under provisions of 10CFR71.61, and the maximum number of packages per shipment is one (1).

6.3 Model Soecification The model for normal conditions is two casks side by side, touching, and reflected on all sides by 12 inches of water. A cask outside diameter of 36.875 inches is used in this evaluation. This diameter provides the minimum spacing between the casks.

When overpacks are installed on each of the casks, the separation distance between the casks is larger; so use of the 36.875 inch cask OD is conservative.

Each cask contains a stainless steel fuel basket, and each fuel basket contains 40 plate-type fuel sections.

The available space inside the cask is filled with water.

6.3.1 Descrintion of Calculational Models In the discussion below, the fuel modeling is presented first followed by the basket and cask modeling.

Each of these models is prepared as input to the SCALE System using the 27GROUPNDF4 cross section set and the KENO IV criticality code to perform the k-effective calculations.

Each fuel section contains 19 plates:

17 plates are in the middle of the fuel section and an aluminum end plate is at each outer end of each fuel section, respectively.

Each fuel plate contains fuel meat that is 2.415 inches wide, 0.020 inches thick, and 10.90625 inches long.

Each fuel plate contains 10.294 grams U 235 in this fuel meat space.

The fuel meat is clad with 0.015 inches of aluminum such that the fuel plate thickness becomes 0.05 inches.

Each fuel plate is separated by a gap of 0.116 inches.

Each aluminum end plate is 0.065 inches thick.

The aluminum side plates are 0.188 inches thick, 3.265 inches high, 10.90625 inches long, and provide an overall width to the fuel

  • Bucholz, J.

A., "SCALE, A Modular Code System for Performing Standardized Computer Analyses for Licensing Evaluation", NUREG/CR-0200, ORNL/NUREG/CSD/2, Volume 1, Oak Ridge National Laboratory; July,1980.

2

section of 3 inches. This leaves a space of 0.1045 inches between each aluminum side plate and the fuel meat, which is assumed to be filled with water. There is also a space of 1.15625 inches on the top end and the bottom end of each fuel section that is assumed to be water.

See Figure 6.3.1-1.

The numerical results of this modeling also may be seen in Table 6.3.1-5 on page 72.

The basket is modeled as a 304 stainless steel structure that has 10 locations to contain the fuel sections. A plan view of the basket is shown in Figure 6.3.1 2.

The 304 stainless steel plates in this basket are 0.1875 inches thick, except for the three plates in the center of the basket which are 0.25 inches thick. The fuel basket extends the entire length of the cask cavity, and four fuel sections from Figure 6.3.1-1 (NBS Drawing ho. E-04 039, Revision

3) are stacked on top of each other in e.ach hole, giving a cask load of 40 fuel sections.

The GE 700 cask is modeled radially as having a cavity of 15 inches in diameter, and then a radial thickness of 0.25 inches of 304 stainless steel, and then a radial thickness of 10.3125 inches of lead, and then a radial thickness of 0.375 inches of carbon steel; this gives an outside cask diameter of 36.875 inches.

The bottom of the cask also is modeled as having a 0.25 inch thick plate of 304 stainless steel, a 10.3125-inch thick lead space, and a 0.375 inch thick carbon steel plate on the bottom. The top of the cask is modeled to be the same as the bottom of the cask except that the 0.375 inch thick plate on the top of the cask is modeled as 304 stainless steel rather than carbon steel.

I A model of this fuel section-basket-cask arrangement is prepared as input to the criticality codes on the SCALE System using a fuel homogenization feature 1

with the XSDRNPM code and a generalized geometry option available on the KENO IV code.

This model is described below.

Input to obtain homogenized fuel cross sections on a tape is shown in Table 6.3.1-1.

Fuel homogenization is accomplished by two actions:

the use of the SYMMSLABCELL card coupled with the use of material 500 to describe the fuel in Box Type 1 or Box Type 2.

When the SCALE System encounters this input, the XSDRNPM code is then used to flux and volume weight the cross sections for the 3

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0.020 inch thick meat, the 0.015 inch thick aluminum clad, and the 0.116 inch thick water between the plates, as specified on the SYMMSIABCELL card (in centimeters), into a homogeneous fuel material represented by material 500.

The cross sections for all of the materials modeled in Table 6.3.1-1, including the homogenized fuel material, are captured on a magnetic tape (Tape No. 3 in the SCALE System) and may be used later in other calculations.

Input for two GE 700 casks that are side by side is shown in Table 6.3.1-2.

This input uses the free-standing KENO-IV code on the SCALE System and the generalized geometry option available on that KENO IV code.

Cross section information reflecting the input shown in Table 6.3.1-1 was written on Tape No.

18643, and this tape is read in on Tape No. 4 in the two-cask model as shown in Table 6.3.1-2.

Each cask contains a NBS stainless steel basket, and each basket contains 40 NBS fuel sections for reprocessing. All of the voids inside the cask are filled with water, and the two-cask array is reflected on all sides by 12 inches of water.

The input in Table 6.3.1-2 also contains information for the starting of some c eutrons in each column of fuel that exists in the two cask array.

The fuel section basket cask arrangement is modeled with generalized geometry input, and this input may be seen in Table 6.3.1-3.

This input may be checked with the Picture Code A plan view of a cask containing a basket and 40 fuel sections that represents the results from the generalized geometry description and the Picture Code may be seen in Figures 6.3.1 3A through -3F.

Figures 6.3.1-3A through -3C show the fueled portion of the model, and each enlargement shows more details of this model.

Figures 6,3.1-3D through -3F show the details of the nonfueled portion of the model immediately above or below each fueled section vertically, where the stainless steel basket extends through the model but the aluminum and fuel are replaced by water.

  • Irving, D. C. and Morrison, C.

V., "PICTURE: An Aid In De-Bugging Geom Input Data", ORNL TM 2892; May 14, 1970.

4

In the generalized geometry mods 1 discussed thus far, the fuel sections are positioned in a basket such that they are as close to one another as they can be.

It is not clear whether this case is more reactive, or one in which the outer fuel sections are pushed out as close as they can be to the lead in the cask.

Therefore, some of the generalized geometry input in Table 6.3.1-3 was changed, and the results are shown in Figures 6.3.1-4A through -4C.

The alterations made to the generalized geometry input are shown in Table 6.3.1-4.

Since the calculations made to validate the criticality codes on the SCALE System using the 27GROUPNDF4 cross-section set did not use homogenized fuel or generalized geometry, two additional models are required.

In Table 6.3.1-5, a model for a 2x2 array of single NBS fuel sections prepared for reprocessing is shown in which the fuel, clad, and water gap details in the fuel section are modeled discretely.

The space between the fuel plates and the space on the top and the bottom of each fuel section are filled with water, and the 2x2 array is reflected on all sides by 12 inches of water.

In Table 6.3.1-6, the same model is prepared as input to the free-standing KENO-IV code on the SCALE System using a generalized geometry description for the fuel meat-clad-water gap in each fuel section and using cross sections prepared by the fuel homogenization process.

6.3.2 Fackage Recional Densities The number densities for the materials used in this analysis may be seen in Tables 6.3.1-1 and 6.3.1-2.

The number density used for the fuel meat was 0.00305685 atom / barn-cm for U-235.

This corresponds to a mass of 175 grams U-235 for each NBS fuel section prepared for reprocessing. A molecular weight of 235.043933 gram / gram mole and an Avogadro's number of 6.025 E23 gram atom / gram mole were used in calculating this number density.

Other materials in the fuel meat,

<u n as U 238, silicon, etc., were not modeled.

The number densities for the materials specified in Tables 6.3.1-1 and 6.3.1-2 that are provided by the SCALE System for the 27GROUPNDF4 cross-scetion set are shown in Tables 6.4-1 through 6.4 4.

5

6.4 Criticality calculations The results of four k effective calculations are presented in this section.

The SCALE System that is running on the control Data Corporation 7600 Computer at General Electric's Nuclear Energy Business Operations was used for the k effective calculations. The 27CROUPNDF4 cross-section set for the KENO IV criticality code in the SCALE System was used.

The results of these calculations may be seen in Tables 6.4-1 through 6.4-4.

These results are discussed below.

In Table 6.4-1, a k-effective result is given for two casks side by side, each loaded with 40 NBS fuel sections prepared for reprocessing with the sections in each basket pusned as close to each other as possible.

This condition represunts the woro.: condition possible for this evaluation.

These results give a mean k-effcetive of 0.892 and a one sigma value of 0.00460 for 30,000 neutron histories.

However, when a bias of 2.3 percent is applied to the mean value and 0.3 percent is applied to the one sigma value, the peak k effective at 2 sigma, rounded up, becomes 0.928 for 30,000 neutron histories. The bias is discussed is Section 6.5.

This bias also is applied to all other k-effective results described below.

In Table 6.4-2, k-effective results are given for a similar model to those in Table 6.4 1, but with four of the fuel sections in each basket pushed out as closely as possible to the lead in the cask.

These results give a mean value of 0.834, a one sigma value of 0.00538, or a peak value of 0.869 for 30,000 neutron histories when the biases are applied.

In Tables 6.4-3 and 6.4 4, the k-effective results for the 2x2 array for the discrete fuel section modeling and for the generalized geometry homogenized fuel section modeling are given, respectively.

These results show the peak k effective to be 0.7259 for the discrete fuel section modeling and 0.7242 for the homogenized fuel section modeling, giving a difference of 0.0017 in k effective.

These results are nearly identical.

6

6.5.1 Benchmark Experiments and Anolicability Uranium with enrichments varying from 1.3 w/o to fully enriched and plutonium are the fissile materials that a a considered in the validation of SCALE for this evaluation. The forms include fully enriched homogeneous uranium-water mixtures, low-enriched heterogeneous uranium dioxide water mixtures, and homogeneous plutonium water mixtures.

In Table 6.5.1 1 below, critical experiments suitable for validation are identified.

6.5.2 Details of the Benchmark Calculations Models of TRX-1 and TRX-2 prepared as input to the SCALE System are shown in Tables 6.5.2-1 and 6.5.2-2, respectively. Models of ORNL-1 and ORNL-2 are shown in Table 6.5.2-3.

Models of PNL-1 and PNL-2 are shown in Table 6.5.2 4.

Models of the B&W UO r d and M0 r d are shown in Table 6.5.2-5 2

2 6.5.3 K-Effective Results of the Benchmark Calculations K-effective results are presented for the ORNL, PNL, TRX, and B&W critical experiments in Table 6.5.3-1.

It is concluded that use of the SCALE System using the 27GROUPNDF4 cross-section set requires a negative 0.3 percent bias on the one sigma deviation for fully enriched uranium solutions and no bias for plutonium solutions; a negative bias of 2.3 percent on the mean value and 0.3 percent on the one sigma deviation for the multiplication factor must be applied for low enriched, clumped uranium rods in water.

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1 i

i I

i I

t t

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FIGURE 6.3.1-3F CENTRAL CASK LOWER RIGHT CORNER BELOW OR ABOVE FUIL ELEMENT X

0.

0.1700E 02 Y

0.

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-0.1600E 02

-0.16005 02 NU=

48 NV= 100 DELUa 0.3$42E 00 DELV= 0.1700E 00 4

fftttMttMtttttttMtMtSSS 99MtttMtt991 3

SSettttttttttttMttet S31<t99999999999t1 SStttttMtttttMt SS 4

S 55>t9999999999999 S

S ttttttttti 30;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;

MSSO;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;.

S 3S - 9999999999999f999991 S

SS S

S 99991 SSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSS$$3SSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSS MSS; ; ; ; ; ; ; ; ; ;;; ;; ; ;;;; ; ; ;; ;;; ;; ;;; ;;;;;; ; ; ; ; ;; ;;;; ; ; ; ; ; ;;; ; ;; ; ; ; ;. 999999999t1 ttttttttttttttf ** ? *ttttt1SSSetttttttttttMtt; ; ; ; ; ; ; ; ; ;; ; ; ;;;;; ;; ; ;; ; ;;; ; ; ; ; ; ; ;; ; ; ; ;; ; ; ;; ; ; ; ; ; ; ; ;;; ; ; ;.

tttttttttttttttMt. MttttSSS:;;; ;;;;; ;; ;;;;;;;;;;;;;;;;; ; ; ;;;;;; ;;;;;;;;;;;;;;;;;; ;;;;;; ; ; ;;; ; ;;;;;;;.

MSC;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;.

ftttttttttttttt ttttttttt5SSttt ; ;; ;; ; ; ; ; ; ;;; ; ; ; ;;; ; ; ; ; ; ; ; ; ; ; ; ; ; ;; ; ; ; ; ; ; ; ; ; ;; ; ; ; ; ; ; ;;; ; ; ; ; ; ; ; ; ; ; ; ; ; ;;;;

MS 2999999994 6 5S>t99999999 658tt9999M99999995 fMet9MettMettMettttMt -999991 MS MSSP9991 6Sittet.

S 6Steettit SSS 65 SSL MS SSLL

>t999999M49999999999999155 SSSSLLL SSSLLLLL 6

SSLLLLLL MSSitttttttttttttt.-tttttttttttttttttttt1SSSSLLLLLLLL 4

fttMtttttttttttttttMtttttttttttttttSSSSSM "1 M '

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-0.4700E 02 0.4700E 02 Y

0.4700E 02

-0.4700E 02 Z

0, 0.

NU=

48 NV=

100 DELU= 0.1958E 01 DELV= 0.9400E 00

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= = --

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SAtttMtte FttHSLLLLLU M i M M f M LLf f f t f.f.finCWW WCLUlf f f f f f EU T ' f f f f f f f Y LLSFtttti SittMtitis MtitiSLL11LLLLIELLL111ntf t f f f.f1LLCW WCT T f f f f Ulf f f f f ' f LLLLLLLLSHtt144 Siffttt t tis tiitt f1SLLLLL11LLLLLU ' f ? ' f M '1LLL11CW C1nf f ff f f f f f f f f f f f LLLLL!1LSSSSSSSSSSSSSSS!SSSSSSSSSSSSSSSSSSSSSSSSLLLL11f f f fIf RI1Inf fI1IRI114 et t t t i t i t t i t t t t t t i IEELEELSA AMSM AA HSMA ASRM111R!nInunRIELELC CLLLLLLLLLt1LLin LLLLLLLLLLLLSA AMSM AA HSMA ASLLU T t f f f f f f.f f f f f f f.' ' ' f ' f ' ' ' e et t t t t t t t Inf f f f f f WitnLLLLLSA AMSM AA HSMA ASf f T f t i t f IRLL!nf ' ' ' ' ' ' ' ' f 11C CLLLLLLi t t t t t t t t t t t t t t t t t t t t t SA AMSM AA HSMA ASU f f e r n t r t i t i v e t t e r f e r e t t y Cf f f f f.T Inn? ? Y f ' f f f f f f f LLLLSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSLLLLLLLLintini f.f t f.f.f t1LR11C WCLL11LL11LLLI f f f.f I f.Qt t t t t t t t offfiti StttttMNS MMtfSREEERI.T i f i f f f f f f ' f f f ' ECW WCTffffffffffffYtttttYvvttt n gSgtg9N Stttt PftfiS titttiSRt.f.f f f f.f.f f f f f f f r t EgLgLggrW WWCLLL11LLLLLLLLLLLU Y f M f f f f M i ottN SAFttttttG titNSLU f f f f

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  • wyWWWWet t t t t t t t t i f f f f f f f f gt i f i f i f f 1 t t t i f f f Lt.f.f.f.f.11LQ11LU T t t t t t t t t LLR11L!1LLLLLL11LLf f f f f f f WWWWWW WWWMMWWCLt t t t t t t i f f f f 1,n,!1gf i f f f f f 1 t t t t t t t t t t t t t i t t t t t t t t t t f f i f f f t t t t t t ? LRLMLRLERLRCWWWWWWWW

=ntffvfffvvfff f f f f f f f f f f f f t t t t t t t t t t t t t i t i f f f f r r i Ef.f.f.f f.i f f f f 1 t i t t t t t t t t t ' RL11CWWWWW1MWW N CCER' f f f ' f ' f ? I f f Lf f.f f f.f f.I Lf I f f f f U, f f f f f f f i at i f v v v v ii t t t gf f f f f f 111 f !

T f f f f f f f f f f f I f T 1.f I.f f.f f fit.f f.f.f.f QLt i f f f f f Lt O(. * -------

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LLL1111LL11L!ntnLLtn1RLLLLLLL11LLLLLLLLLLLLLLL' ' ' er* ?. ' ' ' ' ' '

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y, FUEL = *

  • WATER IN CASK = H 304SS = S ARNINUM = A LEAD = L CARBON STEEL = C WATER OUTSIDE CASK = W l

16

FIGURE 6.3.1-4B CENTRAL CASK FUEL 007 Of LEAD X

-0.1700E J2 0.17005 02 Y

0.1700E 02

-0.1700E 02 3

0.

O.

NU=

48 NV= '100 DELU= 0.7083E 00 DELV= 0.3400E 00 t v v v v v r t v v v v v LLLSSSittttttttttttttttNSMAA MAMShtttMttttMtttttttSSST f f f f f f f f LLLLLLL r r r r r r r r r e e r r ngstMtttttttMttttttMHSMAA MMtSittHMMMittttttittiSSSt t t i f f i f LLLLL t.t.t f f f LLLLLSSSettttttttttttiMMtMtNSMAA MAMShttMttttMittttMffittiSSSLLLLLf.LLLLL LLL' ' ' ' ' ' 'M ; ^ ^ ^ ^ ^ ;;;; ^ ; ^ ^ttMMtMt1SMAA MAMSittttt2ftMttttti ttttttttt1SSLLLLL LLLL LLLLLLLSSFttttfMitti titttMHttttMfEMAA MAMSFtMttttMftfMMtittttMttttSSLLLLLLL -

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SLLLLL LLLSSSittttttiA AMSMAA MAMSt%

A!MtttNSSSLLL LLSSFfftt M ttu AMSMAA MAMStu.

Mfttfi MtiSSLL LSSFMtMitttM M1SHAAttttttttttttttM;tt4AMSMA MftMtttttESL SSFtitttttMMA AMSFtMitttttfMitttfitttttiSHA

' NfMittitttiSS FtMffttttttf%

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  1. fftt M tttttti PttMtttttMfM AMSIMtitMitttttttiffttttt1SMA

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  1. GttttttttttttttttttttttHSMA MtMtMtttttN P ; ; ^ ; ; ^ ; ^ ; ^ 'AAAAAAAAAAAAAAAAAAAA/L.

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  1. titMMttttti Effttttttttttu AMS>tittttttttttti fMt ttttt1SHA
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  1. 1SFttttttMftMtttttttMtfGM.
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NEffitttttttttttttttttMttEMA MittMtMitiSS LSShttMtMttu NEMAMittMttttttttttttfMMSHA MtMttttttBSL LISSitttttttNA AMSMAA MAMSHA MtttttttfESLL LLLSSSFtttttt%

AMSPAA VAMSMA

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1 WEL = ' ' VATER IN CASK = M 304SS = S ALUMINUM = A LEAD = L CARBON STEEL = C WATER OUTSIDE CASK = W I

I l

l l

17

}

i l

i FIGURE 6.3.1-4C CENTRAL CASK LOWER RIGHT CORNER FUEL CUT TO LEAD X

0, 0.1700E 02 Y

0,

-0.1700E 02 3

0 C.

NU=

48 NV=

100 DELU= 0.3542E 00 DELY= 0.1709E 00 SSAAAM ttiAAMttMGSSSitMftt%AMti SSAAAM tiiAA#tttfESSSittttttiAAAH1 SSAAM1 M1AAMtMNSSSSittMtt4AMit!

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&#M',$SN#1 MMtitttMttttMttNSSSSLLLLL FliAMtMSSt%M MAftMtMtttttMtESSSSt t t t t t l

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.AAMttttttit1SSSSSLLLLLI.LLLLL tt4AM tiSSSttMft1 titMtt tttti t StittMitMt ! MMtMt Hf 1 Mit *t ttti iSSSSSLLLLLLLI.LLLLL ttiAA>HSSSitttttttH MitMtttttt ttMittttt tttttttttMttttMS-tttESSSSLLLLLLLLLLLLLLL FfiAMtiSSSitH*ttttMt tittttttiH fttifM t Mit t t tt tH IHMitt tiSSSSSCLLLLLLLLLLLLLLLL Ft4AMNSSSHf MtMHtMtttttttttttMMtMittfitMttHMtfitESS$$LLLLLLLLt t t i f f LLLLL tt4AMt !SSSittMittt ;tttttttfMitMittMtitMMittHtttMfiSSSSSLLLLLLLILLLLLLI ',LLLLL l;

FttAAttBSSittt t MittMtttf Mt ttttMMMtMi tMtittttttESSSSSLLLLLLLLLLLLLLLLLLLLLLf, I

ttiAMitSSSitt iMttttfi ftMttitt Mt tittttttMitttMtt1SSSSSSLLLLLLLLLLLLLLLLLLLLLLLLL ttiA#ttSSSFtMttfMtttit t ttt tMtti t MMMttiffMNSSSSSSLLLLLLLLLLLLLLLLLLLLLLLLLLLL ffiAMHSSSFtitMH t tttttttMittMMi t tttt t HttESSSSSLLLLLLLLLLLLLLLLLLLLLLLLLLLLLLL FliAMtiSSSFMtMttit ttMMtitttMit91MttttiSSSSSSSLLLLLLLLLLLLLLLLLLLLLLLLLLLLLLLLL PfiAutiSSSittt ttHtttt t tt tf Ht Hitt tttf ESSSSSSLLLLLLLLLLLLLLLLLLLLLLLLLLLLLLLLLLLLL FHAMtiSSS!MttM Hiti ttt t HMtit tt ttSSSSSSSLLLLLLLLLLLLLLLLLLLLLLLLLLLLLLLLLLLLLLLL NJ. = ' ' WATE*t IN CASX = M 304SS a S ALtHIDiH = A LEAD = L CARBON STEEL = C WATER OUTSIDE CASK = W i

l 16 l

TABLE 6.3.1-1 KEFF NBS FUEL MODEL TO GET HOMOGENIZED FUEL CROSS-SECTION TAPE

$$ ASIS, ROUT (BL),T(:,8,16),KEYW(WRL)

$:IDENT:VXXX,WRL,VVV18,X4447

$:USERID:FS9911$XXX

$:NEED:P1

$ : SELECT:CDCJOB JOBNM,STMFZ,SN,T176.

CHARGE.

STAGE, TAPE 3,PE, POST,RP-730.

ATTACH (LI4YD, PROCLIB,ID-SCALE)

LIBRARY (LLOYD)

SCALE,CSAS2.

EXIT.

      • EOS KEFF NBS FUEL MODEL TO GET HOMOGENIZED FUEL CROSS-SECTION TAPE 27GROUPNDF4 9 9 3 LATTICECELL 0 0 U-235 1 0. 0.003056845 END AL 2 1. END H2O 3 1. END AL 4 1. END H2O 5 8.8 5 END SS304 6 1. END H2O 7 1. IND PB 8 1. END CARBONSTEEL 9 1. END SYMMSLABCELL 0.42164 0.0508 1 3 0.127 2 END KEFF NBS FUEL MODEL TO GET HOMOGENIZED FUEL CROSS-SECTION TAPE 5.0 5 300 3 2 2 1 4 0 BOX TYPE 1

CUBOID 500 3.0670

-3.0670 3.70628

-3.70628 13.8510 -13.8510 -0.5 CUBOID 7 3.0670 -3.0670 3.8605 -3.8605 13.8510 -13.8510 -0.5 CUB 0ID 4 3.8100 -3.8100 3.9875

-3.9875 13.8510 -13.8510 -0.5 CUB 0ID 7 3.8100

-3.8100 4.4082

-4.1466 16.7880 -17.0260 -0.5 CUB 0ID 5 4.28625 -4.28625 4.4082

-4.7933 16.7880 -17.0260 -0.5 CUBOID 6 4.52438 -4.52438 4.6463

-5.0314 16.7880 -17.0260 -0.5 30X TYPE 2

CUBOID 500 3.0670

-3.0670 3.70628

-3.70628 13.8510 -13.8510 -0.5 CUBOID 7 3.0670 -3.0670 3.8605

-3.8605 13.8510 -13.8510 -0.5 CUBOID 4 3.8100

-3.8100 3.9875

-3.9875 13.8510 -13.8510 -0.5 CUBOID 7 3.8100

-3.8100 4.4082

-4.1466 16.7880 -17.0260 -0.5 CUB 0ID 5 4.28625 -4.28625 4.4082

-4.7933 16.7880 -17.0260 -0.5 CUBOID 9 4.52438

-4.52438 4.6463

-5.0314 16.7880 -17.0260 -0.5 ARRAY BDY 5 9.04876 -9.04876 9.6777

-0, 135.256 -0.

-0.5 CUBOID 8 11.58876 -11.58876 12.2177 -2.54 137.796 -2.54 -0.5 CUBOID 6 42.06876 -42.06876 42.6977 -33.02 168.276 -33.02 -0.5 END GEOMETRY 1121111141022211111419 END KENO

      • E0I

$:ENDJOB 19

- TABLE 6. 3.1-2 TWO CASK MODEL INPUT

$$ ASIS, ROUT (BL),T(:,8,16), KEYWORD (WRL).

$:IDENT:VXXX,WRL,VVV18,X4447

$:USERID:FS9911$XXX

$:NEED:P1

$ : SELECT:CDCJOB JOBNM,STMFZ,SN,T4444.

CHARGE.

STAGE, TAPE 4,PE, PRE,VSN-018643.

ATTACH (LIDYD, PROCLIB,ID= SCALE)

LIBRARY (LLOYD)

-KENO.

EXIT.

      • EOS KEFF NBS FUEL SHPNG ARRY WR HOMO FUEL GEN GEOM 1. 2 CSK
15. 103 300 3 27 27116 10 20 19 3 2 1 6 -16 0 0 2000 00 6 1 1 0 0 104 00 0 0 1

-92235 3.05685E-03 10

-92235 3.68295E-04 2

13027 6.02383E-02 10 13027 1.08864E-02 3

1001 6.67555E-02 10 1001 4.66484E-02 3

8016 3.33777E-02 10 8016 2.33242E-02 4

3 6.02383E-02 5

5 5.87448E-06' 5

8 2.93724E-06 6

24304 1.74239E-02 6

25055 1.73634E-03 6

26304 5.93526E-02 6

28304 7.72036E-03 7

6 6.67555E-02 7

9 3.33777E-02 8

82000 3.29882E-02 9

6012 3.92145E-03 9

26000 8.34952E-02 BOX TYPE 1 GENERAL 10 6*0.0 27*0.5 GENERAL 7 6*0.0 27*0.5 GENERAL 6 6*0.0 27*0.5 GENERAL 7 6*0.0 27*0.5 GENERAL 8 6*0.0 27*0.5 GENERAL. 9 6*0.0 27*0.5 GENERAL '4 6*0.0 27*0.5 CUBOID 7 46.84000 -46.84000 46.84000 -46.84000 16.7900 -16.7900 27*0.5 BOX TYPE 2 CYLINDER 8 45.87875 26.19375 -0. 27*0.5 CYLINDER 9 46.83125'26.19375 -0. 27*0.5 CYLINDER 6 46.83125 27.14625 -0.635 27*0.5 CUB 0ID 7 46.84000 -46.84000 46.84000 -46,84000 27.14625 -0.635 27*0.5 BOX TYPE 3 CYLINDER 8 45.87875 26.19375 -0. 27*0.5 CYLINDER 9 46.83125 26.19375

-0, 27*0.5 CYLINDER 6 46.83125 26.82875

-0, 27*0.5 CYLINDER 9 46.83125 26.82875 -0.9525 27*0.5 CUBOID 7 46.84000 -46.84000 46.84000 46.84000 26.82875 -0.9525 27*0.5 CORE BDY 7 93.68 -93.68 46.84 -46.84 94.94125 -94.94125 27*0.5 CUBOID 7 124.16 -124.16 77.32 -77.32 125.42125 -125.42125 27*0.5 112-111116102121111111031211116619 GENERALIZED GEOMETRY GOES HERE 15 1 1 3 8.65 -8.9 0. 30 1 1 3 0.

-9.22 0. 45 1 1 3 8.65 8.9 0, 60 2 1 3 -8.65 8.9 0. 75 2 1 3 0.

-9.22 0. 90 2 1 3 8.65 -8.9 0.

105 1 1 3 -13.33 0. O. 120 1 1 3 -4.5 0. O. 135 1 1 3 4.5 0. O.

150 2 1 3 -13.33 0. O. 165 2 1 3 4.5 0. O. 180 2 1 3 4.5 0. O.

195 1 1 3 13.33 0. O. 210 2 1 3 13.33 0. O.

225 1 1 3 -8.65 8.9 0. 240 1 1 3 0. 9.22 0, 255 1 1 3 8.65 8.9 0.

270 2 1 3 -8.65 8.9 0. 240 2 1 3 0. 9.22 0. 300 2 1 3 8.65 8.? 0.

END KENO

      • E0I

$ :ENDJOB 20

TABLE 6.3.1-3 STEEL BASKET MODEL FOR KENO GENERALIZED GEOMETRY 2

ZONEl XENDS -46.83125,

-4.52438, 4.52438, 46.83125 ZONEl YENDS -46.83125,

-5.08000, 5.08000, 46.83125 ZONEl ZENDS -16.78788, -13.85100, 13.85100, 16.78788 ZONE 1

1 2

BLOK1 XENDS -46.83125, -12.81749, -12.57111, -12.40601, -12.25869,

-5.09081,

-4.94349,

-4.77839,

-4.52439, -4.52438 BLOK1 YENDS -46.83125, -12.70000, -12.22248, -11.95705,

-5.82295,

-5.55752,

-5.08100,

-5.08000 BLOK1 ZENDS -13.85100, 13.85100 BLOCK 1

1 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 2

1 1

MEDIA 2,

3, 5,

6, 4

l SI'RFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 3

1 1

MEDIA 2,

3, 5,

6, 4

l SURFACES 1,

2, 3,

4 l

SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 4

1 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 5

1 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 6

1 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

21

TABLE 6.3.1-3-(Cont-2/50)

STEEL BASKET MODEL FOR-KENO GENERALIZED GEOMETRY SECTOR 0 0 1 -1 SECTOR 0 0 0 l'

' BLOCK 7

1

-1

' SURFACES..

2, 3,

5, 6,

4 MEDIA:

1, 2,

3, 4

SECTOR -1 0 0 0 SECTOR 1 -1 0- 0 SECTOR 0-1-10 SECTOR O'0 1 -1 SECTOR 0 0, 0 1 BLOCK 8

1 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4

_ SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 01-1 0 SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 9

1 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR 1 0 0 0 SECTOR 1 - l' ' O O SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1

- BLOCK 1

2 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,-

2, 3,

4

- SECTOR -1 0 0 0-SECTOR 1 -1 0 0 SECTOR O ' 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 2

2 1

MEDIA 7

BLOCK 3

2 1

MEDIA 7

BLOCK 4

2 1

MEDIA 7

BLOCK 5

2 1

MEDIA 7

BLOCK 6

2 1

MEDIA' 7

BLOCK 7

2 1

MEDIA 7

BLOCK 8

2 1

MEDIA 7

BLOCK 9

2 1

MEDIA 7

BLOCK 1

3 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

22 4

,-e w e

.--v

-e

-e

4 TABLE '6.3.1 3 (Coat-3/50)

STEEL BASKET MODEL FOR KENO GENERALIZED GEOMETRY

' SECTOR' 0

'0-1 -1 SECTOR 0 0 0-1 BLOCK

~2' 3

1 MEDIA 2

BLOCK 3

3 1

-MEDIA 7

BLOCK 4

3 1

MEDIA 2

BLOCK 5

3 1

MEDIA' 2

BLOCK 6

3 1

MEDIA 2

BLOCK 7

3 1

MEDIA 7

BLOCK 8

3 1

MEDIA 2

BLOCK 9

3 1

MEDIA 2

BLOCK 1

4 l'

MEDIA 2,

3, 5,

6, 4

SUREACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 l '-1 SECTOR 0 0 0 1 BLOCK 2

4 1

MEDIA 2

BLOCK 3

4 1

MEDIA 7

BLOCK.

4 4

1 MEDIA 2

BLOCK 5

4 1

MEDIA 1

BLOCK 6

4 1

MEDIA 2

BLOCK.

7 4

1 MEDIA 7

' BLOCK 8

4 1

MEDIA 2

BLOCK 9

4 1

i MEDIA 2

BLOCK 1

5 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4

' SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1-BLOCK 2

5 1

MEDIA 2

BLOCK 3

5 1

MEDIA 7

BLOCK 4

5 1

MEDIA 2

23

,m

TABLE 6.3.1-3 (Cont-4/50)

STEEL BASKET MODEL FOR KENO GENERALIZED GE0 METRY BLOCK 5

5 1

MEDIA 2

BLOCK 6

5 1

MEDIA 2

BLOCK 7

5 1

MEDIA 7

BLOCK 8

5 1

MEDIA 2

BLOCK 9

5 1

MEDIA 2

BLOCK 1

6 1

MEDIA 2,

3, 5,

6, 4

SUREACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 2

6 1

MEDIA 7

BLOCK 3

6 1

MEDIA 7

BLOCK 4

6 1

MEDIA 7

BLOCK 5

6 1

MEDIA 7

BLOCK 6

6 1

MEDIA 7

BLOCK 7

6 1

MEDIA 7

BLOCK 8

6 i

MEDIA 7

BLOCK 9

6 1

MEDIA 7

BLOCK 1

7 1

MEDIA 2,

3, 5,

6, 4

SURE\\CES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 2

7 1

MEDIA 2

BLOCK 3

7 1

MEDIA 2

BLOCK 4

7 1

MEDIA 2

BLOCK 5

7 1

MEDIA 2

ELOCK 6

7 1

MEDIA 2

BLOCK 7

7 1

MEDIA 2

BLOCK 8

7 1

MEDIA 2

24

(

TABLE 6.3.1-3 (Cont-5/50)

STEEL BASKET MODEL FOR KENO CENERALIZED GEOMETRY s

~

-BL0CK; 9

7-1 MEDIA 2

. ZONE 3

1 2

BLOK1 XENDS 4.52433, 4.52439, 4.77839, 4.94349,

~5.09081, 12.25869, -12.40601, 12.57111, 12.81749, 46.83125 BLOK1 YENDS -46.83125,.-12.70000, -12.22248, -11.95705,

-5.82295,

-5.55752,, -5.08100,

-5.08000 BLOKl ZENDS -13.85100, 13.85100 BLOCK 1-1 1

MEDIA 2,

3, 5,

6, 4

SURFACES ~

1, 2,

3, 4

SECTOR -1 0 0 0 SECTOR. 1 -1 0 0 SECTOR 0 1 -1 0

SECIOR 0 0 1 -1 SEUTOR- 0 0 0 1 BLOCK 2

1 1

MEDIA

.2,

'3, 5,

6,

-4 SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 3

1 1

MFnIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0-0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 4-1 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0

. SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 'l BLOCK 5

1 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1-10 SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK-6 1

1 MEDIA 2,

3, 5,

6, 4

4 SURFACES 1,

2, 3,

4 SECTOR 1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 25 u=-

a.

TABLE 6.3.1-3 (Cont-6/50)

~ STEEL BASKET MODEL FOR KENO GENERALIZED GEOMETRY BLOCK 7

1 1'

1

~

MEDIA 2,

3, 5,

6, 4

SURFACES 1

- 2, 3,

4 SECTOR -1 0 00 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0-SECTOR 0 0 1 -1 SECTOR 0 00 1 BLOCK 8.

1 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR 0 0 0.

SECTOR 1 -1 0 0 SECTOR- 0 1 -1_0 SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 9

1 1

MEDIA 2,

3, 5,

6, 4

' SURFACES

. 1, 2,

3, 4

SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 9

2 1

MEDIA 2,-

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0'0 SECTOR 0 1 -1 0

SECTOR- 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 8

2 1

MEDIA 7

BLOCK 7

2 1

MEDIA 7

-BLOCK 6

2 1

MEDIA 7

BLOCK 5

2 1

MEDIA 7

BLOCK 4

2 1

MEDIA 7

BLOCK 3

2 1

MEDIA 7

BLOCK 2

2 1

MEDIA 7

BLOCK 1

2 1

MEDIA 7

BLOCK 9

3 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR l'-1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 26

Y

~

TABLE' 6.3.1-3 (Cont-7/50).

STEEL BASKET MODEL FOR KENO GENERALIZED GEOMETRY.

BLOCK 8

3 1

MEDIA 2

BLOCK 7

3 1-MEDIA 7

BLOCK 6

3 1

MEDIA 2

BLOCK 5 1 MEDIA 2-BLOCK 4

3 1

MEDIA 2

BLOCK 3

3 1

MEDIA 7

BLOCK 2

3 1

MEDIA 2

BLOCK 1

'3 1

MEDIA 2

BLOCK 9

4 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 00 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 l

BLOCK 8

4 1

MEDIA 2

BLOCK 7

4-1 l

MEDIA

.7 i

BLOCK 6

4 1

l MEDIA 2-BLOCK 5

4 1

MEDIA 1

BLOCK 4

4 1

MEDIA 2

l BLOCK 3

4 1

MEDIA 7

BLOCK 2

4 1

MEDIA 2

BLOCK 1

4 1

MEDIA 2

BLOCK 9

5 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 11 0 SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 8

5 1

MEDIA 2

BLOCK 7

5 1

MEDIA 7

BLOCK 6

5 1

MEDIA 2

BLOCK 5

5 1

MEDIA 2

27

TABLE 6.3.1-3 (Cont-8/50)

STEEL BASKET'MODEL FOR

-KENO-GENERALIZED CEOMETRY

-BLOCK 4

5

'l-MEDIA 2

BLOCK 3

5.

1 MEDIA 7

BLOCK-2 5

1 MEDIA

'2 BLOCK 1

5 1

MEDIA 2

BLOCK 9

6 1

-MEDIA 2,

3, 5,

-6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1

. BLOCK 8

6.

1 MEDIA 7

BLOCK' 7

6 1

MEDIA 7

BLOCK 6

6 1

MEDIA 7

BLOCK 5

6 1

MEDIA 7.

BLOCK 4

6 1

MEDIA 7

. BIhCK 3

6 1

MEDIA 7

BLOCK 2

6 1

MEDIA 7

BLOCK 1

6 1

MEDIA 7

BLOCK 9

7 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,.

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1

-SECTOR 0 0 0 1 BLOCK 8

7 1

MEDIA 2

BLOCK 7

7 1

MEDIA 2

BLOCK 6

7 1

MEDIA 2

BLOCK 5

7 1

MEDIA 2

BLOCK 4

7 1

MEDIA 2

BLOCK 3

7 1

MEDIA 2

BLOCK 2

7 1

MEDIA 2

BLOCK 1

7 1

MEDIA-2 28

l

i t 5

~

TABLE 6.3.1-3 (Cont-9/50)

STEEL BASKET MODEL FOR KENO.CENERALIZED GEOMETRY ZONE l~

3 2

BLOK1 XENDS -46.83125, -12.81749, -12.57111, -12.40601,;-12.25869,.

-5.09081,

-4.94349,

-4.77839,

-4.52439,

-4.52438

' BLOK1 YENDS 5.08000, 5.08100, 5.55752, 5.82295, 11.95705,

.12.22248, 12'70000, 46.83125' BLOK1 ZENDS -13.85100, 13.85100~

BIDCK

-1

.7 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK :

2 7

1 E7DIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR. 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 3

7 1

MEDIA 2,

3, 5,

6, 4

SURFACE 1 1,

2, 3,

4 SECTOR 100 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 4

7 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4

- SECTOR -1 0 0 0 SECTOR 1 -1 0 0

- SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR.0 0 0 1 BLOCK 5

7 1

MEDIA 2,

3, 5,

6, 4

SURFACES.

1, 2,

3, 4

SECTOR 1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 6

7 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 7

7 1

MEDIA 2,

3, 5,

6, 4

29

TABLE 6.3.1-3 (Cont-10/50)

STEEL BASKET MODEL FOR KENO GENERALIZED GEOMETRY SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 8

7 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 9

7 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 1

6 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 2

6 1

MEDIA 7

BLOCK 3

6 1

MEDIA 7

BLOCK 4

6 1

MEDIA 7

BLOCK 5

6 1

MEDIA 7

BLOCK 6

6 1

MEDIA 7

BLOCK 7

6 1

MEDIA 7

BLOCK 8

6 1

MEDIA 7

BLOCK 9

6 1

MEDIA 7

BLOCK 1

5 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 2

5 1

MEDIA 2

30

F TABLE 6.3.1-3 (Cont-11/50)

' STEEL. BASKET MODEL FOR KENO GENERALIZED GEOMETRY

- BLOCK 3

5-1 MEDIA 7

BLOCK 4

5 1

MEDIA 2

BLOCK 5

5 1

MEDIA ~

2 BLOCK -

6 5

El MEDIA' 2

BLOCK 7

5.

1 MEDIA 7

BLOCK 8

5 1

MEDIA 2

BLOCK 9

5 1

MEDIA 2

BLOCK 1

4 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 2

4 1

MEDIA 2

BLOCK 3

4 1

MEDIA 7

~ BLOCK 4

4 1

MEDIA 2

BLOCK 5

4 1

MEDIA 1

BLOCK 6

4 1

MEDIA 2

BLOCK 7

4 1

MEDIA 7

BLOCK 8

4 1-MEDIA 2

BLOCK 9

4 1

MEDIA 2

BLOCK 1

3 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 'l -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 2

3 1

MEDIA 2

BLOCK 3

3 1

MEDIA 7

BLOCK 4

3 1

MEDIA' 2

BLOCK 5

3 1

MEDIA 2

BLOCK 6

3 1

MEDIA 2

31 1

-TABLE6.3.1 3 (Cont-12/50)

STEEL BASKET MODEL FOR KENO GENERALIZED GEOMETRY 1

1 BIDCK

~7 3

1 MEDIA 7

BLOCK 8

3 1

' MEDIA.

2 s

.3 1

BLOCK-9 MEDIA 2

- BLOCK 1

2 l'

MEDIA 2,

.3, 5,.

6, 4

SURFACES 1,

2,.

3, 4

SECTOR 0 0 0 SECTOR 1 -1 0 0 SECTOR. 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0.1 BLOCK 2

2 1

MEDIA 7

BLOCK 3

2 1

MEDIA-7 BLOCK 4

2 1

MEDIA 7

BLOCK 5

2 1

l MEDIA 7

' BLOCK 6

2 1

MEDIA 7

BLOCK 7

2 1

MEDIA 7

BLOCK 8

2 1

MEDIA 7

BLOCK 9

2 1

MEDIA 7

BLOCK 1

1 1

p MEDIA 2,

3, 5,

6, 4

SURFACES 1,

.2, 3,

4 SECTOR -1 0 0 0-SECTOR 1 -1 0 0 SECTOR. 0 1 -1 0

SECTOR 0 0 1 -1

- SECTOR 0 0 0 1 BLOCK

~2 1

1 MEDIA 2

BLOCK 3

1 1

MEDIA 2

BLOCK 4

1 1

MEDIA 2

- BLOCK 5

1 1

MEDIA 2

BLOCK 6

1 1

MEDIA 2

BLOCK 7

1 1

MEDIA 2

BLOCK 8

1 1

MEDIA 2

BLOCK 9

1 1

MEDIA 2

ZONE 3

3 2

BLOK1 XENDS 4.52438, 4.52439, 4.77839, 4.94349, 5.09081, 32

.{

TABLE 6.3.1-3 (Cont-13/50)

STEEL BASKET MODEL FOR KEN 0 'CENERALIZED CEOMETRY 12.25869, 12.40601, 512.57111, 12.81749, 46.83125 BLOK1 YENDS 5.08000, 5.08100, 5.55752, 5.82295, 11.95705, 12.22248, 12.70000, 46.83125 -

BLOK1 ZENDS -13.85100,- 13.85100 BLOCK 1

7 1

MEDIA 2,

3, 5, -

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 2

7 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 11 0 0 SECTOR 0 1 -1 0

SECTOR' O O 1 -1 SECTOR 0 0 0 1 BIOCK 3

7 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 0

SECTOR 0 0 1 SECTOR 0 0 0 1 BLOCK 4

7 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 5

7 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4

-SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 6

7 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR l' -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 7

7 1

l MEDIA 2,

3, 5,

6, 4

(

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 33

TABLE 6.3.1-3 (Cont-14/50)

STEEL BASKET MODEL FOR KENO GENERALIZED GE0 METRY SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 8

7 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 9

7 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 11 SECTOR 0 0 0 1 BLOCK 9

6 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 8

6 1

MEDIA 7

BLOCK 7

6 1

MEDIA 7

BLOCK 6

6 1

MEDIA 7

BLOCK 5

6 1

MEDIA 7

BLOCK 4

6 1

MEDIA 7

BLOCK 3

6 1

MEDIA 7

BLOCK 2

6 1

MEDIA 7

BLOCK 1

6 1

MEDIA 7

BLOCK 9

5 1

MEDIA 2.

3, 5,

6, 4

SURFACES 1,

?,

3, 4

SECTOR -1 0 0 0 SECTOR 1 -1 0 0 l

SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 l

BLOCK 8

5 1

MEDIA 2

BLOCK 7

5 1

l HEDIA 7

1 34

TABLE 6.3.1-3 (Cont-15/50)

STEEL BASKET MODEL FOR' KENO GENERALIZED CEOMETRY BLOCK 6

5 1

MEDIA 2

BLOCK 5

5 1

. MEDIA 2

BLOCK 4

5 1

MEDIA 2

, BLOCK 3

5 1

MEDIA 7

BLOCK-2 5

1 MEDIA 2

BLOCK 5 1

MEDIA 2

BLOCK 9

4 1

_ MEDIA 2,

3, 5,

6, 4

SUREACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 ' O O SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 8

4 1

. MEDIA 2

BLOCK 7

4 1

MEDIA 7

BLOCK 6

4 1

MEDIA 2

BLOCK 5

4 1

. MEDIA 1

BLOCK 4

4 1

MEDIA 2

BLOCK 3

4 1

MEDIA 7

BLOCK 2

4

'l MEDIA 2

BLOCK 1

4 1

MEDIA-2 BLOCK 9

3 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 11 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 8

3 1

MEDIA 2

BLOCK 7

3 1

MEDIA 7

BLOCK 6

3-1 MEDIA 2

BLOCK 5

3 1

MEDIA 2

BLOCK 4

3 1

MEDIA 2

-BLOCK 3

3 1

MEDIA 7

35

=:

TABLE 6.3.1-3 (Cont-16/50)

STEEL BASKET MODEL FOR KENO CENERALIZED GEOMETRY BLOCK' 2

3-1 MEDIA 2

BLOCK 1

3 1

MEDIA.

2 BLOCK 9

2 1

' MEDIA 2,

3, 5,

6, 4

SUREACES.

1, 2,

3, 4

SECTOR -1 0 0 0 SECTOR. 1 -l ' O O-SECTOR. 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 8

2 1

MEDIA 7

BLOCK 7

2 1

MEDIA 7

BLOCK 6

2 1-MEDIA 7

BLOCK 5

2 1

MEDIA 7

BLOCK 4

2 1

MEDIA 7

BLOCK 3

2 1

MEDIA 7

BLOCK 2

2 1

MEDIA 7

BLOCK 1

2 1

MEDIA 7

BLOCK 9

1 1

MEDIA 2,

3, 5,

6, 4

SUREACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1

-SECTOR 0 0 0 1 BLOCK 8

1 1

MEDIA 2

BLOCK 7

1 1

MEDIA 2

BLOCK 6

1 1

MEDIA 2

BLOCK 5

1 1

MEDIA 2

BLOCK 4

1 1

MEDIA 2

BLOCK 3

1 1

MEDIA 2

BLOCK 2

1 1

MEDIA 2

BLOCK 1

1 1

MEDIA 2

ZONE 2

1 2

BLOK1 XENDS

-4.52438,

-4.04813,

-3.81000,

-3.06705,

-3.33248, 3.06705, 3.33248, 3.81000, 4.04813, 4.52438 BLOK1 YENDS -46.83125, -18.50493, -13.37410, 13.12772, -12.96262, 36

TABtA 6.3.1-3 (Cont-17/50)

S'IEL BASKET MODEL FOR KEnv GENERALIZED GEOMETRY

-12.81530,

-5.64742,

-5.50010,

-5.33500,

-5.08100,

-5.08000 BLOK1 ZENDS -13.85100, 13.85100 BLOCK 1

1 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 2

1 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 3

1 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 4

1 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 5

1 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 6

1 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 7

1 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

37

TABLE 6.3.1-3 (Cont-18/50)-

, STEEL BASKET MODEL FOR KENO GENERALIZED GEOMETRY SECTOR 'O O 1 -1 SECTOR 0 0 0 1 BLOCK 8'

1 1

MEDIA 2,

3, 5,

6, 4

' SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0

. SECTOR 1 -1 0 0 SECTOR 0~ 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK' 9

1 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 1

2 1

MEDIA 3-BLOCK 2

2 1

MEDIA 2

BLOCK-3 2

1 MEDIA 2

BLOCK 4

2 1

MEDIA 2

BLOCK 5

2 1

MEDIA 2

BLOCK 6

2 1

MEDIA 2

BLOCK 7

2 1

MEDIA 2

BLOCK 8

2 1

MEDIA 2

BLOCK 9

2 1

MEDIA 3

BLOCK 1

3 1

MEDIA 3

BLOCK 2

3 1

MEDIA 2

BLOCK 3

3 1

MEDIA 7

BLOCK 4

3 1

MEDIA 2

BLOCK 5

3 1

MEDIA 2

-BLOCK 6

3 1

MEDIA 2

BLOCK 7

3 1

' MEDIA 7

BLOCK 8

3 1

MEDIA 2

BLOCK 9

3 1

MEDIA 3

BLOCK 1

4 1

MEDIA 3

38

TABLE 6.3.1-3 (Cont-19/50)

STEEL BASKET MODEL FOR KENO CENERALIZED GEOMETRY BLOCK 2

4 1

MEDIA 2

BLOCK 3

4 1

MEDIA 7

BLOCK 4

4 1

MEDIA 7

BLOCK 5

4 1

MEDIA 7

BLOCK 6

4 1

MEDIA 7

BLOCK 7

4 1

MEDIA 7

BLOCK 8

4 1

MEDIA 2

BLOCK 9

4 1

MEDIA 3

BLOCK 1

5 1

MEDIA 3

BLOCK 2

5 1

MEDIA 2

BLOCK 3

5 1

MEDIA 7

BLOCK 4

5 1

MEDIA 2

BLOCK 5

5 1

MEDIA 2

BLOCK 6

5 1

MEDIA 2

BLOCK 7

5 1

MEDIA 7

BLOCK 8

5 1

MEDIA 2

BLOCK 9

5 1

MEDIA 3

BLOCK

.1 6

1 MEDIA 3

BLCCK 2

6 1

MEDIA 2

BLOCK 3

6 1

MEDIA 7

BLOCK 4

6 1

MEDIA 2

BLOCK 5

6 1

MEDIA 1

BLOCK 6

6 1

MEDIA 2

BLOCK 7

6 1

MEDIA 7

BLOCK 8

6 1

MEDIA 2

BLOCK 9

6 1

MEDIA 3

BLOCK 1

7 1

MEDIA 3

BLOCK 2

7 1

l MEDIA 2

39 J

-TABLE 6.3.1-3 (Cont 20/50)

STEEL BASKET MODEL FOR KENO GENERALIZED GEOMETRY BLOCK-3

-7 1

MEDIA-7 BLOCK-4 7

1-MEDIA 2

BIACK 5

-7 1

MEDIA 2

-BIACK 6

7 1

MEDIA 2

BLOCK 7

7 1

b MEDIA 7

L BLOCK 8

7 1

MEDIA 2

BLOCK-9 7

1 MEDIA 3

BLOCK 1

8 l'

MEDIA 3

BLOCK.

2 8

1 MEDIA-2 BLOCK 3

8 1

MEDIA 7

BLOCK 4

8 1

MEDIA 7

BLOCK 5

8 1

MEDIA 7

BLOCK-6 8

1 MEDIA 7

BLOCK 7

8 1

MEDIA 7

BLOCK 8

8 1

MEDIA.

2 BLOCK 9

8 1

MEDIA 3

BLOCK 1

9 1

MEDIA 3

BLOCK 2

9 1

MEDIA 2

BLOCK 3

9 1

MEDIA 7

BLOCK 4

9 1

MEDIA 2

BLOCK 5

9 1

MEDIA 2

BLOCK 6

9 1

MEDIA 2

BLOCK 7

9 1

MEDIA 7

BLOCK 8

9 1

MEDIA 2

BLOCK 9

9 1

MEDIA 3

BLOCK 1

10 1

MEDIA 3

BLOCK 2

10 1

MEDIA 2

BLOCK 3

10 1

MEDIA 2

40 J

TABLE 6.3.1-3 (Cont-21/50)

STEEL' BASKET MODEL FOR~

KENO GENERALIZED GEOMETRY BLOCK 4

10-1 MEDIA ~

2 BLOCK.

5 10-1 MEDIA 2

' BLOCK

6 10 1 --

MEDIA 2

BLOCK 7

10 1

MEDIA 2

BLOCK 8

10 1

MEDIA 2

BLOCK 9

10 1

. MEDIA 3

ZONE 2

3 2

BLOK1 XENDS

-4.52438,

-4.04813,

-3.81000,

-3.06705,

-3.33248, 3.06705,-

3.33248, 3.81000, 4.04813, 4.52438 BLOK1 YENDS 5.08000, 5.08100, 5.33500, 5.50010, 5.64742, 12.81530,- 12.96262, 13.12772, 13.37410, 18.50493, 46.83125 BLOK1 ZENDS -13.85100, 13.85100 BLOCK 1

10 1

' MEDIA 2,

3, 5,

6, 4

. SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 2

10 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0,1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCF 3

10 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 11 0 SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 4

10 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 5

10 1

MEDIA 2,

3, 5,

6, 4

SURFACES-1, 2,

3, 4

SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 011 0 41

4 TABLE. 6.3.1-3 (Coat-22/50)

STEEL BASKET MODEL FOR KENO GENERALIZED GEOMETRY SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 6

10 1

~ MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1. 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 SECTOR 0 0 0 1 BLOCK 7

10 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTiR 1 0 0 SECTOR 01-1.0 SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 8

10 l'

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0

0- 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 9

10 1

MEDIA.

2, 3,

5, 6,

4 SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 1

9 1

MEDIA 3

BLOCK 2

9 1

4 MEDIA 2

BLOCK 3

9 1

MEDIA 2

BLOCK 4

9 1

MEDIA 2

BLOCK 5

9 1

MEDIA 2

BLOCK 6

9 1

MEDIA 2

BLOCK 7

9 1

MEDIA 2

BLOCK 4

)

1 MEDIA 2

BLOCK 9

9 1

MEDIA 3

' BLOCK 1

8 1

l MEDIA 3

BLOCK 2

8 1

MEDIA 2

42 4

TABLE 6.3.1 3 (Cont-23/50)

STEEL BASKET MODEL FOR KENO GENERALIZED CEOMETRY BLOCK 3

8 1

MEDIA-7

' BLOCK

'4 8

1

. MEDIA 2

BLOCK 5

8 1

MEDIA 2

BLOCK-6 8

1 MEDIA 2

BLOCK' 7-8

~1 MEDIA 7

BLOCK 8

8 1

MEDIA 2

BLOCK 9

8 1

MEDIA 3

BLOCK 1

7 1

MEDIA 3

BLOCK 2

7 1

MEDIA 2

BLOCK 3

7 1

MEDI A '

7 BLOCK 4

7

'l

. MEDIA 7

BLOCK 5

7 1

MEDIA 7

BLOCK 6-7 1

MEDIA 7

BLOCK 7

7 1

MEDIA 7

BLOCK 8

7 1

MEDIA 2

BLOCK-9 7

1 MEDIA 3

BLOCK 1

6 1-MEDIA 3

BLOCK 2

6 1

MEDIA 2

BLOCK 3

6 1

MEDIA 7

BLOCK 4

6 1

MEDIA 2

BLOCK 5

6 1

MEDIA 2

BLOCK 6

6 1

MEDIA 2

BLOCK 7

6 1

MEDIA 7

BLOCK 8

6 1

MEDIA 2

BLOCK 9

6 1

MEDIA 3

BLOCK 1

5 1

MEDIA 3

BLOCK 2

5 1

MEDIA 2

BLOCK 3

5 1

f MEDIA 7

43 1

a.

a

(;

TABLE 6.3.1-3 (Cont-24/50)-

STEEL BASKET MODEL FOR KENO GENERALIZED GEOMETRY BLOCK-4 5

1 MEDIA 2

BLOCK 5

'S 1

MEDIA 1

LBLOCK 6

5 1

.MSDIA 2

BlDCK-7 1.

1 MEDIA 7

BLOCK 8

5 1

-MEDIA 2

BLOCK 9

5 1

MEDIA-3 BLOCK 1

4 1

MEDIA 3

BLOCK 2

4 1

MEDIA 2

BLOCK 3

4 1-MEDIA

-7 BLOCK 4-4 1

MEDIA 2

BIhCK 5

4 1

MEDIA 2

BLOCK 6

4 1

MEDIA 2

BLOCK 7

4 1

MEDIA 7

BLOCK 8

4 1

MEDIA 2

BLOCK 9

4 1

MEDIA 3

BLOCK 1

3-1 MEDIA

'3 BLOCK 2

3 1

MEDIA 2

BLOCK 3

3 1

MEDIA 7

BLOCK 4

3 1

MEDIA 7

BLOCK 5

3 1

MEDIA 7

BLOCK 6

3 1

MEDIA 7

BLOCK 7

3 1

MEDIA 7

BLOCK 8

3 1

MEDIA 2

BLOCK 9

3 1

MEDIA 3

BLOCK l'

2 1

MEDIA 3

BLOCK 2

2 1

MEDIA

?

BLOCK 3

2 1

i MEDIA 7

BLOCK 4

2 1

MEDIA 2

~

44 N

.. +,

l

-TABLE 6.3.1-3'(Cont-25/50)

STEEL BASKET MODEL FOR KENO GENERALIZED GEOMETRY BLOCK 5

2 1

MEDIA 2

BLOCK 6

2 1-MEDIA-2

. BLOCK.

7 2

1 MEDIA 7

LLOCK 8

2 1

MEDIA 2

. BLOCK 9

2 1

MEDIA 3

,:f BLOCK

-1 1

1 MEDIA 3

BLOCK 2

1 1

MEDIA 2

BLOCK 3

1 1

MEDIA 2

BLOCK 4

1 1

MEDIA 2

BLOCK 5

1 1

M..DIA-2 BLOCK 6

1 1

MEDIA 2

BLOCK 7

1 1

MEDIA 2

BLOCK 8

1 1

MEDIA 2

BLOCK 9-1 1

MEDIA 3

ZONE 1

2 2

BLOK1 XENDS -46.83125, -18.36018, -17.14500, -16.66748, -16.40205,

-10.26795, -10.00252,

-9.52501,- -9.52500,

-8.E9000, 7.93750,

-7.45998,

-7.19455,

-4.52438 BLOK1 YENDS -5.08000 4.60375, 4.60374, 4.34974,

-4.20242,

-4.03732, 3.13056, 3.27788, 3.44298, 3.68936, 4.60375, 5.08000 BLOKl ZENDS -13.85100, 13.85100 BLOCK 1

1 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

' SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 1

2 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 1

3 1

MEDIA 2,

3, 5,

6, 4

l SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 45

{-

TABLE 6,3.1 3 (Cont-26/50)

STEEL BASKET MODEL FOR KENO GENERALIZED CEOMETRY SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 1

4 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 1

5 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTCR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 1

6 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 1

7 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 1

8 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 1

9 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 l

SECTOR -1 0 0 0 l

SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 1

10 1

l MEDIA 2,

3, 5,

6, 4

l SURFACES 1,

2, 3,

4 l

SECTOR -1 0 0 0 l

46 l

L

TABLE 6.3.1-3 (Cont-27/50)

STEEL BASKET MODEL FOR KENO GENERALIZED GEOMETRY SECTOR 11 0 0 SECTOR 0 11 0 SECTOP O O 1 -1 1

SECTOR 0 0 0 1 BLOCK 1

11 1

MEDIA 2,

3, 5,

6, 4

SUREACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 2

1 1

MEDIA 3

BLOCK 2

2 1

MEDIA 2

BLOCK 2

3 1

MEDIA 2

BLOCK 2

4 1

MEDIA 2

BLOCK 2

5 1

MEDIA 2

BLOCK 2

6 1

MEDIA 2

BLOCK 2

7 1

MEDIA 2

BLOCK 2

8 1

MEDIA 2

BLOCK 2

9 1

MEDIA 2

BLOCK 2

10 1

MEDIA 2

BLOCK 2

11 1

MEDIA 3

BLOCK 3

1 1

MEDIA 3

BLOCK 3

2 1

MEDIA 2

BLOCK 3

3 1

MEDIA 7

BLOCK 3

4 1

MEDIA 7

BLOCK 3

5 1

MEDIA 7

BLOCK 3

6 1

MEDIA 7

BLOCK 3

7 1

MEDIA 7

BLOCK 3

8 1

MEDIA 7

BLOCK 3

9 1

MEDIA 7

BLOCK 3

10 1

MEDIA 2

BLOCK 3

11 1

MEDIA 3

47

J

-TABLE 6.3.1-3 (Cont-28/50)'

STEEL BASKET MODEL FOR KENO GENERALIZED GEOMETRY

- BLOCK 4

1 1

MEDIA 31 BLOCK 4

2 1

MEDIA 2-BLOCK' 4

3 1

MEDIAL 2

BLOCK.

4.

4-1 MEDIA 7

BLOCK-4 5-11 MEDIA 2

BLOCK 4

6 1

MEDIA

.2 BLOCK

-4 7

1 MEDIA 2

BLOCK 4

8.

1 MEDIA 7

BLOCK 4

9 1

MEDIA 2

BLOCK 4

10 1

MEDIA-2 BLOCK 4

11 1

MEDIA 3

BLOCK 5

1 1

i MEDIA 3

BLOCK ~

5 2

1 MEDIA 2

BLOCK 5

3 1

MEDIA 2

BLOCK 5

4 1

MEDIA 7

. BLOCK 5

5 1

MEDIA 2

BLOCK 5

6 1

- MEDIA 1

BLOCK 5

7 1

MEDIA 2

BLOCK 5

8 1

MEDIA 7

BLOCK 5

9 1

MEDIA 2

BLOCK 5

10 1

MEDIA 2

BLOCK 5

11 1

MEDIA 3

BLOCK 6

1 1

MEDIA 3

BLOCK 6

2 1

MEDIA 2

BLOCK 6

3 1

MEDIA 2

BLOCK 6

4 1

MEDIA 7

BLOCK 6

5 1

MEDIA 2

BLOCK 6

6 1

MEDIA 2

48

c:

E ~I t

~

l TABLE 6.3.1-3 (Cont-29/50)

STEEL BASKET MODEL FOR i

KENO GENERALIZED GEOMETRY BLOCK 6

7 l'

MEDIA 2

BLOCK.

6 8

1 MEDIA 7

BLOCK 6

9 1

MEDIA 2

BLOCK 6

10 1

MEDIA 2

BLOCK

.6

'll 1

-MEDIA.

3-BLOCK 7

1 1

MEDIA 3

BLOCK 7

2 1

MEDIA 2

BLOCK 7

3 1

MEDIA 7

BLOCK 7

4 1

MEDIA 7

BLOCK 7

5 1

MEDIA 7

BLOCK 7

6 1

MEDIA 7

BLOCK 7-7 1

MEDIA 7

BLOCK 7

8 1

MEDIA 7

BLOCK 7

9 1

MEDIA-7 BLOCK ~

7 10 1

MEDIA 2

BLOCK 7

11 1

MEDIA 3

BLOCK 8

1 1

MEDIA 3

BLOCK 8

2 1

MEDIA 2

BLOCK 8

3 1

MEDIA 2

BLOCK 8

4 1

MEDIA 2

BLOCK 8

5 1

MEDIA 2

BLOCK 8

6 1

MEDIA 2

BLOCK 8

7 1

MEDIA 2

BLOCK 8

8 1

MEDIA 2

l BLOCK 8

9 1

MEDIA 2

BLOCK 8

10 1

l MEDIA 2

l BLOCK 8

11 1

I MEDIA 3

I BLOCK 9

1 1

MEDIA 3

49 t-

5 4

4' TABLE.6.3.1-3 (Cont 30/50)

. STEEL BASKET MODEL FOR KENO CENERALIZED GEOMETRY B14CK 9

2 1

MEDIA' 3

BLOCK' 9

3' 1

MEDIA 3

BLOCK 9

4 1

MEDIA

.3 BLOCK 9

5 1

MEDIA

.3

- BLOCK 9

'6 1

MEDIA 3

BLOCK 9

7 1

MEDIA 3

BIACK 9

8 1s MEDIA 3

e BLOCK 9-

-9 1

MEDIA 3

BIACK 9

10 1

MEDIA 3

BLOCK 9

11 1

MEDIA

-3 BLOCK 10 1

1 MEDIA 3

BLOCK 10 2

1 MEDIA 2

BLOCK 10 3

1

- MEDIA 2

BLOCK 10 4

1 MEDIA 2

BLOCK 10 5

1 MEDIA 2

BLOCK 10 6

1 MEDIA 2

BLOCK 10 7

1 MEDIA 2

BLOCK 10 8

1 MEDIA 2

BLOCK 10 9

1 MEDIA 2

~ BLOCK 10 10 1

MEDIA 2

BLOCK 10 11 1

j MEDIA 3

i BLOCK 11 1

1 MEDIA 3

BLOCK 11 2

1 MEDIA 2

BLOCK 11 3

1 MEDIA 7

BLOCK 11 4

1 MEDIA 7

f BLOCK 11 5

1 MEDIA 7

BLOCK 11 6

1 MEDIA 7

l BLOCK 11 7

1 l

MEDIA 7

50 i_

f 1

TABLE 16.3.1-3 (Cont 31/50)

STEEL BASKET MODEL FOR KENO GENERALIZED GEOMETRY BLOCK 11 8

1

- MEDIA 7-B1OCK 11 9

1 MEDIA' 7

BLOCK 11 10 1

MEDIA 2

BLOCK 11 11 1

~ MEDIA 3

BLOCK 12 1

1 MEDIA 3

BLOCK 12 2

1

- MEDIA 2

. BLOCK 12

'3 1

MEDIA 2

BLOCK 12 4

1 MEDIA 7

BLOCK 12 5

-1 MEDIA 2

BLOCK 12 6

1 MEDIA 2

BLOCK 12 7

1 MEDIA 2

BLOCK 12 8

1 MEDIA 7

BLOCK 12 9

1 MEDIA 2

- BLOCK 12 10 1

MEDIA 2

BLOCK 12 11 1

MEDIA 3

BLOCK 13 1

1 MEDIA 3

BLOCK 13 2

1

' MEDIA 2

l BLOCK 13 3

1 MEDIA 2

BLOCK 13 4

1 MEDIA 7

BLOCK 13 5

1 l

MEDIA 2

l BLOCK 13 6

1 MEDIA 1

BLOCK 13 7

1 MEDIA 2

BLOCK 13 8

1 MEDIA 7

BLOCK 13 9

1 MEDIA 2

BLOCK 13 10 1

MEDIA 2

BLOCK 13 11 1

MEDIA 3

i ZONE 3

2 2

BLOK1 XENDS 4,52438, 7,19455, 7,45998, 7,93750, 8,89000, 9.52500, 9.52501, 10,00252, 10.26795, 16,40005, 16,66748, 17,14500, 18.36018, 46,83125 51 1

TABLE 6.3.1-3 (Cone-32/50)

STEEL BASKET MODEL FOR KENO GENERALIZED GEOMETRY BLOK1 YENDS

-5.08000,

-4.60375,

-4.60374,

-4.34974, 4.20242,

-4.03732,-

3.13056, 3.27788, 3.44298, 3.68936, 4.60375, 5.08000 BLOK1 ZENDS -13.85100, 13.85100 BLOCK 13 1

1 MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 13 2

1 MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 4

SECTOR -1 0 0 0 SECTOR 11 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 11 SECTOR 0 0 0 1 BLOCK 13 3

1 MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR 1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 13 4

1 MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR 1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 13 5

1 MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 13 6

1 MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 13 7

1 MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 52 t_

TABLE 6.3.1-3 (Cont-33/50)

STEEL BASKET MODEL FOR KENO CENERALIZED CEOMETRY SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 13 8

1 MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 13 9

1 MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 13 10 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 13 11 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 11 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 12 1

1 MEDIA 3

BLOCK 12 2

1 MEDIA 2

BLOCK 12 3

1 MEDIA 2

BLOCK 12 4

1 MEDIA 2

BLOCK 12 5

1 FEDIA 2

BLOCK 12 6

1 MEDIA 2

BLOCK 12 7

1 MEDIA 2

BLOCK 12 8

1 MEDIA 2

BLOCK 12 9

1 MEDIA 2

BLOCK 12 10 1

MEDIA 2

53

y TABLE 6.3.1 3 (Cont-34/50)

STEEL BASKET MODEL FOR KENO GENERALIZED GEOMETRY BLOCK 12 11 1

MEDIA 3

BLOCK 11 1

1 MEDIA 3

BLOCK 11 2

1 MEDIA 2

BLOCK 11 3

l' MEDIA 7

BLOCK 11 4

1 MEDIA 7

BLOCK 11 5

1 MEDIA 7

BLOCK 11 6

1 MEDIA 7

BLOCK 11 7

1 MEDIA 7

BLOCK 11 8

1 MEDIA 7

BLOCK 11 9

1 MEDIA 7

BLOCK 11 10 1

MEDIA 2

BLOCK 11 11 1

MEDIA 3

BLOCK 10 1

1 MEDIA 3

BLOCK 10 2

1 MEDIA 2

BLOCK 10 3

1 MEDIA 2

BLOCK 10 4

1 MEDIA 7

BLOCK 10 5

1 MEDIA 2

BLOCK 10 6

1 MEDIA 2

BLOCK 10 7

1 MEDIA 2

BLOCK 10 8

1 MEDIA 7

BLOCK 10 9

1 MEDIA 2

BLOCK 10 10 1

MEDIA 2

BLOCK 10 11 1

MEDIA 3

BLOCK 9

1 1

MEDIA 3

BLOCK 9

2 1

MEDIA 2

BLOCK 9

3 1

MEDIA 2

BLOCK 9

4 1

MEDIA 7

BLOCK 9

5 1

MEDIA 2

54

TABLE 6.3.1-3 (Cont-35/50) u STEEL BASKET MODEL FOR KENO GENERALIZED GEOMETRY BLOCK 9

6 1

MEDIA 1

BLOCK 9

7 1

MEDIA 2

BLOCK 9

8 1

MEDIA 7

BLOCK 9

9_.

1 MEDIA 2

BLOCK 9

10 1

MEDIA 2

BLOCK 9

11 1

MEDIA 3

BLOCK 8

1 1

MEDIAL 3

BLOCK 8-2 1

MEDIA 2

BLOCK 8

3 1

MEDIA 2

BLOCK 8

4 1

MEDIA 7

BLOCK-8 5

1 MEDIA 2

BLOCK 8

6 1

MEDIA 2

BLOCK 8

7 1

MEDIA 2

BLOCK 8

8 1

^ MEDIA 7'

BLOCK 8

9 1

MEDIA 2

BLOCK 8

10 1

MEDIA 2

+

BLOCK 8

11 1

MEDIA 3

BLOCK ~

7 1

1 MEDIA 3

BLOCK 7

2 1

MEDIA 2

BLOCK 7

3 1

MEDIA 7

BLOCK 7

4 1

MEDIA 7

BLOCK 7

5 1

MEDIA 7

BLOCK 7

6 1

MEDIA 7

BLOCK 7

7 1

MEDIA 7

BLOCK 7

8 1

MEDIA 7

BLOCK 7

9 1

MEDIA 7

BLOCK 7

10 1

MEDIA 2

BLOCK 7

11 1

MEDIA 3

55 t

1 TABLE 6.3.1 3 (Cont 36/50)

STEEL BASKET MODEL FOR KENO GENERALIZED GEOMETRY l

MEDIA 3 _

1.

BLOCK 6

1 BLOCK 6

2 1

MEDIA 2

BLOCK 6

3 1-MEDIA 2

BLOCK 6

4-1 MEDIA 2

BLOCK-6 5

1 MEDIA 2

. BLOCK 6

6 1

MEDIA 2

BLOCK

-6 7

1 MEDIA 2

BLOCK-6 8

1 MEDIA 2

BLOCK 6

9 1

MEDIA 2

-BLOCK 6

10 1

MEDIA 2

BIACK 6

11 1

MEDIA 3

. BIACK 5

1 1

MEDIA 3

BLOCK 5

2 1

MEDIA 3

BLOCK 5

3 1

MEDIA 3

BLOCK 5

4 1

MEDIA 3

BLOCK 5

5 1

MEDIA 3

BLOCK 5

6 1

MEDIA 3

BLOCK 5

7 1

MF.DIA 3

BLOCK 5

8 1

MEDIA 3

BLOCK 5

9 1

MEDIA 3

BLOCK 5

10 1

MEDIA 3

BLOCK 5

11 1

MEDIA 3

BLOCK 4

1 1

MEDIA 3

BLOCK 4

2 1

MEDIA 2

BLOCK 4

3 1

MEDIA 2

BLOCK 4

4 1

MEDIA 2

- BLOCK 4

5 1

MEDIA 2

BLOCK 4

6 1

MEDIA 2

56

TABLE 6.3.1-3 (Cont-37/50)

STEEL BASKET MODEL FOR i

KENO CENERALIZF,D GEOMETRY BLOCK 4

7 1

MEDIA ~

2 BLOCK 4

8 1

MEDIA 2

BLOCK 4'

9 l'

-MEDIA 2

BLOCK 4

.10 1

MEDIA' 2

BLOCK 4

11 1

MEDIA 3

BLOCK 3

1 1

MEDIA' 3

BLOCK 3

2 1

MEDIA 2

s BLOCK 3

3 1

MEDIA 7

BLOCK 3

4 1

MEDIA 7

BLOCK 3-5-

1-MEDIA 7

BLOCK 3

6 1

MEDIA 7

BLOCK 3

7 1

MEDIA 7

BLOCK 3

8 1

MEDIA 7

BLOCK 3

9 1

MEDIA 7

BLOCK 3

10-1 MEDIA 2

BLOCK 3

11 1

MEDIA 3

BLOCK 2

1 1

' MEDIA 3

BLOCK 2

2 1

MEDIA 2

BLOCK 2

3 1

MEDIA 2

BLOCK 2

4 1

MEDIA 7

BLOCK 2

5 1

MEDIA 2

BLOCK 2

6 1

MEDIA 2

BLOCK 2

7 1

MEDIA 2

BLOCK 2

8 1

MEDIA 7

BLOCK 2

9 1

MEDIA 2

BLOCK 2

10 1

s MEDIA 2

BLOCK 2

11 1

MEDIA 3

BLOCK 1

1 1

MEDIA 3

57

TABLE 6.3.1-3 (Cont-38/50) y STEEL BASKET MODEL FOR KENO GENERALIZED GEOMETRY BLOCK 1

2 1

MEDIA 2

BLOCK 1

3 1

MEDIA 2

BLOCK 1

4 1

MEDIA 7

BLOCK 1

5 1

MEDIA 2

BLOCK 1

6 1

MEDIA 1

BLOCK 1

7 1

MEDIA 2

BLOCK 1

8 1

MEDIA 7

BLOCK 1

9 1

MEDIA 2

BLOCK 1

10 1

MEDIA 2

BLOCK 1

11 1

MEDIA 3

ZONE 2

2 2

BLOK1 XENDS

-4.52438,

-1.06045,

-0.79502,

-0.31751,

-0.31750, 0.31750, 0.31751, 0.79502, 1.06045, 4.52438 BLOK1 YENDS

-5.08000, 4.60375,

-4.60374,

-4.34974,

-4.20242,

-4.03732, 3.13056, 3.27788, 3.44298, 3.68936, 4.60375, 5.08000 BLOK1 ZENDS -13.85100, 13.85100 BLOCK 1

1 1

MEDIA 3

BLOCK 1

2 1

MEDIA 2

BLOCK 1

3 1

MEDIA 2

BLOCK 1

4 1

MEDIA 7

BLOCK 1

5 1

MEDIA 2

BLOCK 1

6 1

MEDIA 1

BLOCK 1

7 1

MEDIA 2

BLOCK 1

8 1

MEDIA 7

BLOCK 1

9 1

MEDIA 2

BLOCK 1

10 1

MEDIA 2

BLOCK 1

11 1

MEDIA 3

BLOCK 9

1 1

MEDIA 3

BLOCK 9

2 1

MEDIA 2

BLOCK 9

3 1

MEDIA 2

BLOCK 9

4 1

58

TABLE 6.3.1 3 (Cont-39/50)

STEEL BASKET MODEL FOR KENO GENERALIZED CEOMETRY MEDIA 7

BLOCK 9

5 1

MEDIA 2

BLOCK 9

6 1

MEDIA 1

BLOCK 9

7 1

MEDIA 2

BLOCK 9

8 1

MEDIA 7

BLOCK 9

9 1

MEDIA

?

BLOCK 9

10 1

MEDIA 2

BLOCK 9

11 1

MEDIA 3

BLOCK 2

1 1

MEDIA 3

BLOCK 2

2 1

MEDIA 2

BLOCK 2

3 1

MEDIA 2

BLOCK 2

4 1

MEDIA 7

BLOCK 2

5 1

MEDIA 2

BLOCK 2

6 1

MEDIA 2

BLOCK 2

7 1

MEDIA 2

BLOCK 2

8 1

MEDIA 7

BLOCK 2

9 1

MEDIA 2

BLOCK 2

10 1

MEDIA 2

BLOCK 2

11 1

MEDIA 3

BLOCK 8

1 1

MEDIA 3

BLOCK 8

2 1

MEDIA 2

BLOCK 8

3 1

MEDIA 2

BLOCK 8

4 1

MEDIA 7

BLOCK 8

5 1

MEDIA 2

BLOCK 8

6 1

MEDIA 2

BLOCK 8

7 1

MEDIA 2

BLOCK 8

8 1

MEDIA 7

BLOCK 8

9 1

MEDIA 2

BLOCK 8

10 1

59

1 V

TABLE 6.3.1-3 (Cont-40/50)

STEEL BASKET MODEL FOR KENO GENERALIZED GE0 METRY MEDIA 2

BLOCK 8

11 1

MEDIA 3

BLOCK 3

1 1

MEDIA 3

BLOCK 3

2 1

MEDIA 2

BLOCK 3

3 1

MEDIA 7

BLOCK 3

4 1

MEDIA 7

BLOCK 3

5 1

MEDIA 7

BLOCK 3

6 1

MEDIA 7

BLOCK 3

7 1

MEDIA 7

BLOCK 3

8 1

MEDIA 7

BLOCK 3

9 1

MEDIA 7

BLOCK 3

10 1

MEDIA 2

BLOCK 3

11 1

MEDIA 3

BLOCK 7

1 1

MEDIA 3

BLOCK 7

2 1

MEDIA 2

BLOCK 7

3 1

MEDIA 7

BLOCK 7

4 1

MEDIA 7

BLOCK 7

5 1

MEDIA 7

BLOCK 7

6 1

MEDIA 7

BLOCK 7

7 1

MEDIA 7

BLOCK 7

8 1

MEDIA 7

BLOCK 7

9 1

MEDIA 7

BLOCK 7

10 1

MEDIA 2

BLOCK 7

11 1

MEDIA 3

BLOCK 4

1 1

MEDIA 3

BLOCK 4

2 1

MEDIA 2

BLOCK 4

3 1

MEDIA 2

BLOCK 4

4 1

MEDIA 2

BLOCK 4

5 1

60

TABLE 6.3.1-3 (Cont-41/50)

STEEL BASKET MODEL FOR KENO CENERALIZED CEOMETRY MEDIA 2

BLOCK 4

6 1

MEDIA 2

BLOCK 4

7 1

MEDIA 2

BLOCK 4

8 1

MEDIA 2

BLOCK 4

9 1

MEDIA 2

BLOCK 4

10 1

MEDIA 2

BLOCK 4

11 1

MEDIA 3

BLOCK 6

1 1

MEDIA 3

BLOCK 6

2 1

MEDIA 2

BLOCK 6

3 1

MEDIA 2

BLOCK 6

4 1

MEDIA 2

BLOCK 6

5 1

MEDIA 2

BLOCK 6

6 1

MEDIA 2

BLOCK 6

7 1

MEDIA 2

BLOCK 6

8 1

MEDIA 2

BLOCK 6

9 1

MEDIA 2

BLOCK 6

10 1

MEDIA 2

BLOCK 6

11 1

MEDIA 3

BLOCK 5

1 1

MEDIA 3

BLOCK 5

2 1

MEDIA 3

BLOCK 5

3 1

MEDIA 3

BLOCK 5

4 1

MEDIA 3

BLOCK 5

5 1

MEDIA 3

BLOCK 5

6 1

MEDIA 3

BLOCK 5

7 1

MEDIA 3

BLOCK 5

8 1

MEDIA 3

BLOCK 5

9 1

MEDIA 3

BLOCK 5

10 1

l MEDIA 3

l BLOCK 5

11 1

61 l

TABLE 6.3.1-3 (Cone 42/50)

STEEL BASKET MODEL FOR KENO GENERALIZED GEOMETRY MEDIA 3

ZONE 1

1 1

BLOK1 XENDS -46.83125, 4.52438 BLOKl YENDS -46.83125, 5.08000 BLOK1 ZENDS -16.78788, -13.85100 BLOCK 1

1 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 ZONE 1

3 1

BLOK1 XENDS -46.83125,

-4.52438 BLOK1 YENDS 5.08000, 46.83125 BLOK1 ZENDS -16.78788, -13.85100 BLOCK 1

1 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 ZONE 3

1 1

BLOK1 XENDS 4.52438, 46.83125 BLOKl YENDS -46.83125,

-5.08000 BLOK1 ZENDS -16.78788, -13.85100 BLOCK 1

1 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR 1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 ZONE 3

3 1

BLOK1 XENDS 4.52438, 46.83125 BLOK1 YENDS 5.08000, 46.83125 BLOK1 ZENDS -16.78788, -13.85100 BLOCK 1

1 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 11 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 ZONE 2

1 1

BLOK1 XENDS

-4,52438,

-4.04813, 4.04813, 4.52438 BLOK1 YENDS -46.83125

-18.50493,

-5.08000 BLOK1 ZENDS -16,78788, -1?.85100 BLOCK 1

1 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 62

h, TABLE 6.3.1 3 (Cont 43/50)

STEEL BASKET MODEL FOR KENO GENERALIZED GE0 METRY SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 11 0 SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 2

1 1

MEDIA

?

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 11 0 SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 3

1 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 1

2 1

MEDIA 3

BLOCK 2

2 1

MEDIA 2

BLOCK 3

2 1

MEDIA 3

ZONE 2

3 1

BLOK1 XENDS 4,52438, 4.04813, c 04813.

4.52438 BLOK1 YENDS 5.08000, 18.50493, 46.83125 BLOK1 ZENDS 16.78788, 13.85100 BLOCK 1

2 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR 1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 2

2 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR 1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 11 0 SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 3

2 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 11 SECTOR 0 0 0 1 BLOCK 1

1 1

63

m, TABLE 6.3.1 3 (Cont 44/50)

STEEL BASKET MODEL FOR KENO CENERALIZED CEOMETRY=

MEDIA 3

BLOCK 2

1 1

MEDIA 2-BLOCK 3

1 1

MEDIA 3

ZONE 1

2 1

. BLOK1 XENDS -46.83125, 18,36018,

-9,52500,

-8,89000, 4.52438 BIOK1 YENDS -5.08000

-4.60375, 4.60375, 5.08000 BLOK1 ZENDS -16,78788, -13.85100 BLOCK 1

1 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR 1-0 0 0 SECTOR 1 -1 0 0 SECTOR' O 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 1

2 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0~ 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BIDCK 1

3 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 2

1 1

MEDIA 3

BLOCK 2

2 1

MEDIA 2

BLOCK 2

3 1

NEDIA 3

BLOCK 3

1 1

MEDIA 3

BLOCK 3

2 1

MEDIA 3

BLOCK 3

3 1

MEDIA 3

BLOCK 4

1 1

MEDIA 3

BLOCK 4

2 1

MEDIA 2

BLOCK 4

3 1

MEDIA 3

ZONE 3

2 1

BLOK1 XENDS 4.52438, 8.89000, 9.52500, 18,36018, 46.83125 BLOK1 YENDS 5.08000, 4,60375, 4,60375, 5,08000 BLOKl ZENDS 16,78788, 13.85100 BLOCK 4

1 1

64

TABLE 6.3.1-3 (Cont 45/50)

STEEL BASKET MODEL FOR KENO GENERALIZED GEOMETRY MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 4

2 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 4

3 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 11 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 3

1 1

MEDIA 3

BLOCK 3

2 1

MEDIA 2

BLOCK 3

3 1

MEDIA 3

BLOCK 2

1 1

MEDIA 3

BLOCK 2

2 1

MEDIA 3

BLOCK 2

3 1

MEDIA 3

BLOCK 1

1 1

MEDIA 3

BLOCK 1

2 1

MEDIA 2

BLOCK 1

3 1

MEDIA 3

ZONE 2

2 1

BLOK1 XENDS

-4.52438,

-0.31750, 0.31750, 4.52438 BLOK1 YENDS

-5.08000,

-4.60375, 4.60375, 5.08000 BLOK1 ZENDS -16.78788, -13.85100 BLOCK 1

1 1

MEDIA 3

BLOCK 1

2 1

MEDIA 2

BLOCK 1

3 1

MEDIA 3

BLOCK 3

1 1

MEDIA 3

BLOCK 3

2 1

MEDIA 2

BLOCK 3

3 1

65

TABLE 6.3.1-3L(Cont-66/50)

STEEL BASKET MODEL FOR

'l KENO CENERALIZED GEOMETRY MEDIA 3

BLOCK 2

1

.1 MEDIA' 3

BLOCK' 2

2 1

MEDIA 3

BLOCK 2

3 1

MEDIA:

3 ZONE 1_

1 3

BLOK1 XENDS 46.83125,

-4.52438 BLOK1 YENDS

'e6.83125,

-5.08000 BLOK1 ZENDS ?.3.85100, 16.78788

- BIDCK 1

1 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR 1 0 3 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 00 1 -1 SECTOR 0 0 01 ZONE 1

3 3

BLOK1 XENDS -46.83125, 4.52438 BLOK1 YENDS 5.08000, 46.83125 BLOK1 ZENDS 13.85100, 16.78788 BLOCK 1

1 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR 1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 ZONE 3

1 3

BLOK1 XENDS-.4.52438, 46.83125 BLOK1 YENDS 46.83125,

-5.08000 BLOK1 ZENDS 13.85100, 16.78788 BLOCK 1

1 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 11 0 0 SECTOR 0 1 -1 0

4

' SECTOR 0 0 1 -1 SECTOR 0 0 0 1 ZONE 3

3 3

BLOK1 XENDS 4.52438, 46.83125 4

BLOK1 YENDS 5.08000, 46.83125 BLOK1 ZENDS 13.85100, 16,78788 BLOCK 1

1 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 ZONE 2

1 3

66

TABLE 6.3.1-3 (Cont 47/50)

STEEL BASKET MODEL FOR KENO GENERALIZED GEOMETRY BLOK1 XENDS

-4.52438, 4.04813, 4.04813, 4.52438 BLOK1 YENDS 46.83125, -18.50493,

-5.08000 BLOK1 ZENDS 13.85100, 16.78788 BLOCK 1

1 1

MEDIA 2,

3, 5,

6, 4

SUREACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 2

1 1

MEDIA 2,

3, 5,

6, 4

SUREACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 3

1 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 1

2 1

MEDIA 3

BLOCK 2

2 1

MEDIA 2

BLOCK 3

2 1

MEDIA 3

ZONE 2

3 3

BLOK1 XENDS

-4.52438,

-4.04813, 4.04813, 4.52438 BLOK1 YENDS 5.08000, 18.50493, 46.83125 BLOX1 ZENDS 13.85100, 16.78788 BLOCK 1

2 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 2

2 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR 1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 11 SECTOR 0 0 0 1 BLOCK 3

2 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 67

TABLE 6.3.1-3 (Cont 48/50)

_ STEEL BASKET MODEL FOR KENO GENERALIZED CEOMETRY l

SECTOR -1 0.

0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1_

SECTOR 0 0 0 1 BIDCK 1

1 1

MEDIA 3

BLOCK 2

1 1

MEDIA 2

BLOCK 3

1 1

l MEDIA 3

ZONE 1

2 3

BLOK1 XENDS -46.83125, -18.36018,

-9.52500,

-8.89000,

-4.52438

~

BLOK1 YENDS

-5.08000,

-4.60375, 4.60375, 5.08000 BLOK1 ZENDS 13.85100, 16.78788 BLOCK

-1 1

1 MEDIA

2, 3,

5, 6,

4

'[

SURFACES

' 1, 2,

3, 4

1

-SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR' O 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 1

2 1

MEDIA 2,

3, 5,

6, 4

SURFACES

.0 0

1, 2,

3, 4

SECTOR -1 0

SECTOR 1 -1 0-0 SECTOR 0 1 -1 0

SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 1

3 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4

~

SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1-10 SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 2

1 1

MEDIA 3

BLOCK 2

2 1

MEDIA 2

BLOCK 2

3 1

i MEDIA 3

BLOCK 3

1 1

I MEDIA 3

BLOCK 3

2 1

l MEDIA 3

BLOCK 3

3 1

MEDIA 3

BLOCK 4

1 1

MEDIA 3

BLOCK 4

2 1

MEDIA 2

BLOCK 4

3 1

68

y j?

TABLE 6.3.1 3 (Cont-49/50)

STEEL BASKET MODEL FOR KENO CENERALIZED CEOMETRY MEDIA 3

ZONE 3

2 3

BLOK1 - XENDS 4.52438, 8.89000, 9.52500, 18.36018, 46.83125 BLOK1 YENDS

-5.08000,

-4.60375, 4.60375, 5.08000 BLOK1 ZENDS 13.85100, 16.78788 BLOCK 4

1 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 11 0 SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 4

2 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR -1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 1 -1 0

SECTOR 0 0 11 SECTOR 0 0 0 1 BLOCK 4

3 1

MEDIA 2,

3, 5,

6, 4

SURFACES 1,

2, 3,

4 SECTOR 1 0 0 0 SECTOR 1 -1 0 0 SECTOR 0 11 0 SECTOR 0 0 1 -1 SECTOR 0 0 0 1 BLOCK 3

1 1

MEDIA 3

BLOCK 3

2 1

MEDIA 2

BLOCK 3

3 1

MEDIA 3

BLOCK 2

1 1

MEDIA 3

BLOCK 2

2 1

MEDIA 3

BLOCK 2

3 1

MEDIA 3

BLOCK 1

1 1

MEDIA 3

BLOCK 1

2 1

MEDIA 2

BLOCK 1

3 1

MEDIA 3

ZONE 2

2 3

BLOKl XENDS

-4,52438,

-0.31750, 0.31750, 4.52438 BLOK1 YENDS

-5.08000,

-4.60375, 4.6037'.

5.08000 BLOK1 ZENDS 13.85100, 16,78788 BLOCK 1

1 1

MEDIA 3

BLOCK 1

2 1

MEDIA 2

BLOCK 1

3 1

69

)

4 TABLE 6.3.1 3 (Cont-50/50)

STEEL BASKET MODEL FOR KENO GENERALIZED GEOMETRY MEDIA 3

BLOCK

-3 1

1 MEDIA 3

BLOCK 3

2 1

MEDIA 2

BLOCK 3

3 1

MEDIA 3

BLOCK 2

1 1

MEDIA 3

BLOCK 2

2 1

MEDIA 3

BLOCK 2

3 1

MEDIA 3

4 1.0 XSQ 1,0 YSQ

-362.9025 1.0 XSQ 1.0 YSQ

-387.4992 1.0 XSQ 1.0 YSQ

-2104.860 1.0 XSQ 1.0 YSQ

-2193.166 70

TABLE 6.3.1 4 GENERALIZED GEOMETRY INPUT CHANGES TO MOVE FUEL ELEMENTS OUT TO THE LEAD ZONE 2

1 2

BLOK1 YENDS -46.i.. -18.50493, 18.50490, -18.25852, -18.09342,

-17.94610, -10.77822

-10.63090, -10.46580, -10.21180, 5.08000 ZONE 2

3 2

BLOK1 YENDS 5.08000, 10.21180, 10.46580, 10.63090, 10.77822, 17.94610, 18.09342, 18.25852, 18.50490, 18.50493, 46.83125 ZONE 1

2 2

BLOK1 XENDS -46.83125, -18.36018 -18.36010, 17.88258, -17.61715,

-11.48305, -11.21762, 10.74010 9.52500,

-8.89000,

-7.93750,

-7.45998,

-7.19455, 4.52438 ZONE 3

2 2

BLOK1 XENDS 4.52438, 7.19455, 7.45998, 7.93750, 8.89000, 9.52500, 10.74010, 11.21762, 11.48305, 17.61715, 17.88258, 18.36010, 18.36018, 46,83125 t

I 71

(

TABLE 6.3.1-5 KEFF NBS FUEL MODEL 2X2 ARRAY OF SINGLE CELLS DISCRETE WR

$ $ ASIS, ROUT (BL), T( ;,8,16), KEW(WRL)

$ :IDENT:VXXX,WRL,VW18,X4447

^:USERID:FS9911$XXX.

F 4"' 0: P11

CT
CDCJOB -

m ~E

'TMFZ, SN. T4444.

OYD,PROCLIB,ID-SCALE)

LOYD).

AS2.

. e.

  • 1dEOS' KEFF NBS ' FUEL MODEL 2X2 ARRAY OF SINGLE CELLS DISCRETE WR

- 27GROUPNDF4 9 9-3 LATTICECELL 0 0 U 235 1 0. 0.003056845 END AL' 2 1. END H2O 3 1. END AL 4 1. END H2O 5 8.8-5 END SS304 6 1. -Flu)

H2O 7 1. END PB 8 1. END CARBONSTEEL 9 1. END SYMMSIABCELL~

0.43603 0.0508 1 3 0.127 2 END KEFF NBS VUEL MODEL 2X2 ARRAY OF SINGLE CELLS DISCRETE WR 15.0 100 ?)0 3 2 2 2 3 0 BOX TYPE 1

- CUB 0ID 1 3.0670 -3.0670

.0254

.0254 13.8510 -13.8510 -0.5 CUBOID 2 3.0670 -3.0670

.0635

.0635 13.8510 -13.8510 -0.5 CUBOID 3 3.0670 -3.0670

.3581

.3581 13.8510 -13.8510 -0.5 CUBOID 2 3.0670 -3.0670

.3962

.3962 13.8510 -13.8510 -0.5 CUBOID 1 3l0670 -3,0670

.4470

. 4470 13.8510 -13.8510 -0.5 CUBOID 3.0670 -3.0670

.4851

.4851 13.8510 -13.8510 -0.5 CUBOID 3 3.0670 -3.0670

.7797

.7797 13.8510 -13.8510 -0.5 CUBOID 2 3.0670 -3.0670

.8178

.8178 13.8510 -13.8510 -0.5 CUBOID 1 3.0670 -3.0670

.8686

.8686 13.8510 -13.8510 -0.5 CUBOID 2 3.0670 -3.0670

.9067

.9067 13.8510 -13.8510 -0.5 CUBOID 3 3.0670 -3.0670 1.2013 -1.2013 13.8510 -13 8510 -0.5 CUBOID 2 3.0670 3.0670 1.2394

-1.2394 13.8510 -13.8510 -0.5 l

CUBOID 1 3.0670 -3.0670 1.2902

-1.2902 13.8510 -13.8510 -0.5 CUBOID 2'

3.0670 -3.0670 1.3283

-1.3283 13.8510 -13.8510 -0.5 CUB 0If 3

3.0670 -3,0670 1.6229 -1.6229 13.8510 -13.8510 -0.5 CUB 01u 2 3.0670 -3.0670 1.6610 -1.6610 13.8510 -13.8510 -0.5 CUBOID 1 3.0670 -3.0670 1.7118 -1.7118 13.8510 -13.8510 -0.5 CUB 0ID 2 3.0670 3.0670 1.7499 -1.7499 13.8510 -13.8510 -0.5 CUBOID 3 3.0670 -3.0670 2.0445 -2.0445 13.8510 -13.8510 -0.5 CUBOID 2 3.0670 -3.0670 2.0826 -2.0826 13.8510 -13.8510 -0.5 CUB 0ID 1 3.0670 -3.0670 2.1334 -2.1334 13.8510 -13.8510 -0.5 CUBOID 2 3.0670 -3.0670 2.1715 -2.1715 13.8510 -13.8510 -0.5 CUB 0ID 3 3.0670

-3.0670-2.4661 -2.4661 13.8510 -13.8510 -0.5 CUBOID 2 3.0670 -3.0670 2.5042

-2.5042 13.8510 -13.8510 -0.5 CUBOID 1 3.0670 3.0670 2.5550 -2.5550 13.8510 -13.8510 -0.5 CUBOID 2 3.0670 3.0670 2.5931 -2.5931 13.8510 -13.8510 -0.5 CUB 0ID 3 3.0670 -3.0670 2.8877

-2.8877 13.8510 -13.8510 -0.5 CUBOID 2 3.0670 -3.0670 2.9258

-2.9258 13.8510 -13.8510 -0.5 CUBOID 1 3.0670 -3.0670 2.9766 -2.9766 13.8510 -13.8510 -0.5 CUBOID 2 3.0670 -3,0670 3.0147

-3.0147 13.8510 13.8510 -0.5 72 r

w__._.....

TABLE 6.3.1 5 KEFF NBS FUEL MODEL 2X2 ARRAY OF SINGLE CELLS DISCRETE FWR CUBOID 3 3.0670 -3.0670 3.3093 -3.3093 13.8510 -13.8510 -0.5 CUB 0ID 2 3.0670

-3.0670 3.3474

-3.3474 13.8510 -13.8510 -0.5 CUBOID 1 3.0670 -3.0670 3.3982 -3.3982 13.8510 -13.8510 0.5 CUBOID 2 3.0670 -3.0670 3.4363

-3.4363 13.8510 -13.8510 -0.5 CUBOID 3 3.0670 -3.0670 3.7309

-3.7309 13.8510 -13.8510 -0.5 CUBOID 3 3.3325

-3.3325 3.7313

-3.7313 13.8510 -13.8510 -0.5 CUB 0ID 2 3.3325

-3.3325 3.8964 -3.8964 13.8510 -13.8510 -0.5 CUBOID 3 3.3325

-3.3325 4.1428

-4.1504 13.8310 -13.8510 -0.5 CUBOID 2 3.8100

-3.8100 4.1428 4.1504 13.8510 -13.8510 -0.5 BOX TYPE 2 CUBOID 3 3.3325

-3.3325 4.1428 -4.1504 2.9380

-0.

-0.5 CUBOID 2 3.8100

-3.8100 4.1428

-4.1504 2.9380 -0.

-0.5 ARRAY BDY 3 7.62 -7.62 8.2932 -8.2932 16.789 -16.789 -0.5 CUBOID 3 38.1 -38.1 38.7732 -38.7732 47.269 -47.269 -0.5 END GEOMETRY l121121131021211211329 END KENO

      • E0I

$ : ENDJOB l

l l

l l

l l

73 J

4 TABLE 6.3.1-6 KEFF NBS FUEL MODEL 2X2 ARRAY OF' SINGLE CE1.LS GEN GEOM FWR

$$ ASIS, ROUT (BL),T(:,8,16),KEYU(WRL)

$:IDENT:VXXX,WRL,VVV18,X4447

$:USERID:FS9911$XXX.

$:NEED:P1

$: SELECT:CDCJOB JOBNM,STMFZ,SN,T4444 CHARGE.

STAGE. TAPE 4,PE, PRE,VSN-018643.

ATTACH (LLOYD,PROCLIB,ID-SCALE)

LIBRARY (LLOYD)

KENO.

EXIT.

- ***EOS KEFF NBS FUEL MODEL 2X2 ARRAY OF SINGLE CELLS GEN GEOM FWR

15. 100 300 3 27 27 16 10 20 9 2 2 2 3 -16 0 0 2000 00 6 1 1 0 0 104 00 0 0 p

1

-92235 3.05685E-03 10

-92235-3.68295E 2 13027 6.02383E 02 10 13027 1.08864E-02 3

1001 6.67555E-02 10 1001 4.66484E-02 3

8016 3.33777E-02 10 8016 2.33242E-02 4

3 6.02383E-02 5

5 5.87448E-06 5

8 2.93724E-06 6-24304 1.74239E-02 6

25055 1.73634E-03 6

26304~

5.93526E-02 6

28304' '7.72036E-03 7

6-6.67555E-02 7

9 3.33777E-02 8

82000 3.29882E-02

'9 6012 3.92145E-05 9

26000 8.34952E-02 BOX TYPE 1 GENERAL 10 6*0. 27*0.5 CUBOID 3 3.3325

-3.3325 3.7313

-3.7313 13.8510 -13.8510 27*0.5 CUBOID 2 3.3325

-3.3325 3.8964

-3.8964 13.8510 -13.8510 27*0.5 CUBOID 3 3.3325

-3.3325 4.1428

-4.1504 13.8510 -13.8510 27*0.5 CUBOID 2 3.8100

-3.8100 4.1428

-4.1504 13.8510 -13.8510 27*0.5 BOX TYPE 2 CUBOID 3-3.3325 -3.3325 4.1428

-4.1504 2.9380 -0. 27*0.5 CUB 0ID 2 3.8100 -3.8100 4.1428

-4.1504 2.9380

-0, 27*0.5 CORE BDY 3 7.62 -7.62 8.2932 -8.2932 16./89 -16.789 27*0.5 CUBOID 3 38.1 -38.1 38.7732 -38.7732 47.269 -47.269 27*0.5 m

1-1 2 1 1-2 1 1 3 1 0 2 1 2 1 1 2 1 1 3 2 9 2

ZONEl-XENDS

-3,06700, 3.06700 ZONEl YENDS

-3.58400, 3.58400 ZONE 1 YENDS -13.85100, 13.85100 ZONE 1

1 1

BLOKl XENDS

-3,06700, 3.06700 BLOK1 YENDS

-3.58400, 3.58400 BLOK1 YENDS -13.85100, 13.85100

- BLOCK 1

1 1

MEDIA 1

0 75 1 1 2 0. O. O. 150 2 1 2 0. O. O. 225 1 2 1 0. O. O. 300 2 2 2 0. O. O.

END KENO

      • E0I

$:ENDJOB 74

TABLE 6.4-1

. KEFF NBS FUEL SHPNG ARRY FWR HOMO FUEL GEN GE0M'1. 2 CSK MIXTURE NUCLIDE DENSITY' MIXTURE NUCLIDE DENSITY

-1

-92235 3.05685E-03 10

-92235 3.68295E 04 2

13027 6.02383E 02 10 13027 1.08864E-02 3

1001 6.67555E-02 10 1001 4.66484E-02 3

8016 3.33777E 02 10 8016 2.33242E-02 4

.3 6.02383E-02

^

5 5

5.87448E 06 5

8 2.93724E 06-6 24304 1.74239E 02

.6 25055 1.73634E-03 6

26304 5.93526E-02 6

28304 7.72036E-03 7

6 6.67555E-02 7

9 3.33777E-02 8

82000 3.29882E-02 9

6012 3.92145E-03 9

26000 8.34952E-02 CROSS SECTIONS READ FROM TAPE NUCLIDE -

1001 H 1269 F, 1002 T 218 GP 032475(2)

NUCLIDE -

5 H 1269 F, 1002 T 218 GP 032475(2)

NUCLIDE -

6 H 1269 F, 1002 T 218 GP 032475(2)

NUCLIDE -

601.

C-12 1274F,1065T 218 GP 030476(7)

NUCLIDE -

8016 0-16 1276 218 GP 030476(7)

NUCLIDE -

8 0-16 1276 218 GP 030476(7)

NUCLIDE -

9 0-16 1276 218 GP 030476(7)

NUCLIDE -

13027 AL 27 1193 218 GP 040375(5)

NUCLIDE -

3 AL-27 1193 218 GP 040375(5)

NUCLIDE -

24304 CR 1191 WT SS-304(1/EST) P-3 293K SP-5+4(42375)'

NUCLIDE -

25055 MN-55 1197 SIGP-5+4 NEWXLACS 218NGP P-3 293K NUCLIDE -

26000 FE 218CP RE 5-17-78(1)

NUCLIDE -

26304 FE 1192 WT SS-304(1/EST) P-3 293K SP-5+4(42375)'

NUCLIDE -

~28304 NI 1190 WT SS-304(1/EST) P-3 293K SP-5+4(42375)'

NUCLIDE -

82000 PB 1288 218NGP 042375 P-3 293K NUCLIDE -

92235 U-235'1261 SIGP-5+4 NEWXLACS 218NGP P-3 293K(3)

ARRAY DESCRIPTION 2

2 1

1 1

1 1

1 1

1 3

3 NO. OF INITIAL GENERATIONS AVERAGE NUMBER OF SKIPPED K-EFFECTIVE DEVIATION HISTORIES 3

.89219

+ OR -

.00460 30000 FREQUENCY FOR GENERATIONS 4 TO 103

.7652 TO.7883

.7883 TO.8114

.8114 TO.8345

.8345 TO

.8576

.8576 TO.8806

.8806 TO.9037

.9037 TO.9268

.9268 TO.9499

.9499 TO.9730

.9730 TO.9961

.9961 TO 1.0192 1.0192 TO 1.0423 75

a l

TABLE 6.4 2-KEFF NBS FUEL SHPNG ARRY~FWR HOMO FUEL GEN GEOM 1. 2 CSK FUEL OUT.

MIXTURE NUCLIDE

-DENSITY MIXTURE NUCLIDE DENSITY 1

-92235 3.05685E-03 10

-92235 3.68295E-04 2

13027 6.02383E-02 10 13027 1.08864E 02 3

1001 6.67555E-02 10 1001-4.66484E-02 3

8016~

3.33777E-02 10 8016 2.33242E 4 3

6.02383E-02 5

5 5.87448E-06 5-8 2.93724E-06 6

24304-1.74239E-02 6

25055 1.73634E-03 6

26304 5,93526E-02 6

28304 7.72036E-03 l

7 6

6.67555E-02 7

9 3.33777E-02 8

82000 3.29882E-02 9

6012 3.92145E-03 9

26000 8.34952E-02 CROSS SECTIONS READ FROM TAPE NUCLIDE -'

1001 H 1269 F, 1002 T 218 GP 032475(2)

NUCLIDE -

5 H 1269 F, 1002 T 218 GP 032475(2)

NUCLIDE -

6 H 1269 F, 1002 T 218 GP 032475(2)

NUCLIDE -

6012-C-12 1274F,1065T 218 GP 030476(7)

NUCLIDE -

8016 0-16 1276 218 GP 030476(7)

NUCLIDE -

8 0-16-1276 218 GP 030476(7)

NUCLIDE -

9 0-16 1276 218 GP 030476(7)

NUCLIDE -

13027 AL-27_1193 218 GP 040375(d)'

NUCLIDE -

. 3 AL-27 1193 218 GP 040375(5)

NUCLIDE -

24304 CR 1191 KT SS-304(1/EST) P-3 293K SP-5+4(42375)'

NUCLIDE -

25055 MN 55 1197 SIGP-5+4 NEWXLACS 218NGP P-3 293K NUCLIDE -

26000 FE 218GP RE 5-17-78(1)

NUCLIDE -

26304 FE 1192 WT-SS-304(1/EST) P-3 293K SP-5+4(42375)'

NUCLIDE -

28304 NI 1190 WT SS-304(1/EST) P-3 293K SP-5+4(42375)'

NUCLIDE -

82000 PB 1288 218NGP 042375 P-3 293K NUCLIDE -

92235 U-235 1261 SIGP-5+4 NEWXLACS 218NGP P-3 293K(3)

ARRAY DESCRIPTION 2

2 1

1 1

1 1

1 1

1 3

3 l

NO. OF INITIAL GENERATIONS AVERAGE NUMBER SKIPPED K-EFFECTIVE DEVIATION HISTORIES 3

.83377

+ OR -

.00538 30000 FREQUENCY FOR GENERATIONS 4 TO 103

.7067 TO..7298

.7298 TO.7529

.7529 TO.7760

.7760 TO.7991

.7991 TO.8222

.8222 TO.8453

.8453 TO.8684

.8684 TO.8915 l

.8915 TO.9146

.9146 TO.9377

.9377 TO.9608

.9608 TO.9839 l

76

TABLE 6.4-3 KEFF NBS FUEL MODEL 2X2 ARRAY OF SINGLE CELLS DISCRETE FWR MIXTURE -NUCLIDE DENSITY-MIXTURE NUCLIDE DENSITY 1

-92235 3.05685E-03 10

-92235 3.56140E-04 2

13027 6.02383E-02 10 13027 1~.05272E-02 3

1001 6.67555E-02 10 1001 4.73120E 02 3

.8016

'3.33777E-02 10 8016 2.36560E-02 4

3 6.02383E-02 5

5 5.87448E 06 3

8 2.93724E 06 7

6 6.67555E 02 7

9 3.33777E-02 6

24304 1.74239E-02 6

25055 1.73634E-03 6

26304 5.93526E-02 6

28304 7.72036E-03 8

82000 3.29882E 02 9

6012 3.92145E-03 9-26000- 8.34952E 02 CROSS SECTIONS READ FROM TAPE NUCLIDE -

1001-H 1269 F, 1002 T 218 GP 032475(2)

NUCLIDE -

5 H 1269 F, 1002 T 218 GP 032475(2)

NUCLIDE -

6 H 1269 F, 1002 T 218 GP 032475(2)

NUCLIDE -

6012 C 12 1274F,1065T 218 GP 030476(7)

NUCLIDE -

8016 0-16 1276 218 GP 030476(7)

NUCLIDE -

8 0-16 1276 218 GP 030476(7)

NUCLIDE -

9 O-16 1276 218 GP 030476(7)

NUCLIDE -

13027 AL 27 1193 218 GP 040375(5)

NUCLIDE -

3

'AL-27 1193 218 GP 040375(5)

NUCLIDE -

24304 CR 1191 WT SS-304(1/EST) P-3 293K SP-5+4(42375)'

NUCLIDE -

25055 MN-55 1197 SIGP-5+4 NEWXLAGS 218NGP P-3 293K NUCLIDE -

26000 FE 218GP RE 5-17-78(1)

NUCLIDE -

26304 FE 1192 WT SS-304(1/EST) P-3 293K SP-5+4(42375)'

NUCLIDE -

28304 NI 1190 WT SS-304(1/EST) P-3 293K SP-5+4(42375)'

NUCLIDE -

82000 PB 1288 218NGP 042375 P-3 293K NUCLIDE -

92235 U-235 1261 SIGP-5+4 NEWXLACS 218NGP P-3 293K(3)

ARRAY DESCRIPTION 2

-2 2

2 1

1 1

1 2

2 2

2 NO. OF INITIAL GENERATIONS AVERAGE NUMBER OF SKr.PPED K-EFFECTIVE DEVIATION HISTORIES 3

.68854

+ OR -

.00487 29100 FREQUENCY FOR GENERATIONS 4 TO 100

.5846 TO.6077

.6077 TO

.6308

.6308 TO

.6539

.6539 TO.6770

.6770 TO.7001

.7001 TO.7232 l

.7232 TO.7463 l

.7463 TO.7694

.7694 TO.7925

.7925 TO.8156

.8156 TO.8386 i

77 i.

[

TABLE -6.4 4 KEFF NBS FUEL MODEL 2X2 ARRAY OF SINGLE CELLS GEN GEOM WR MIXTURE NUCLIDE DENSITY MIXTURE NUCLIDE DENSITY l

-92235' -3.05685E 03 10

-92235 3.68295E-04 2

13027 6.02383E-02 10 13027 1.08864E-02 3

1001 6.67555E-02 10 1001 4.66484E-02 3

8016 3.33777E-02 10 8016' 2.33242E-02 4

3 6.02383E-02 5

5

~5.87448E-06 5

8 2.93724E-06 6

24304 1.74239E-02 6

25055 1.73634E 6 26304 5.93526E-02 6

28304 7.72036E-03 7

6 6.67555E 02 7

9 3.33777E-02

-8 82000 3.29882E 02 9

6012 3.92145E-03 9

26000 8.34952E-02 CROSS SECTIO:IS READ FROM TAPE NUCLIDE -

1001' H 1269 F, 1002 T 218 GP 032475(2)

NUCLIDE -

5 H 1269 F, 1002 T 218 GP 032475(2)

NUCLIDE -

6 H 1269 F, 1002 T 218 GP 032475(2)

NUCLIDE -

6012 C-12 1274F,1065T 218 GP 030476(7)

NUCLIDE -

8016 0 16 1276 218 GP 030476(7)

NUCLIDE -

8-0-16 1276 218 GP 030476(7)

NUCLIDE -

9 0-16 1276 218 GP 030476(7)

NUCLIDE -

13027 AL-27 1193 218 GP 040375(5)

NUCLIDE -

3 AL-27 1193 218 GP 040375(5)

NUCLIDE -

24304 CR 1191 WT SS-304(1/EST) P-3 293K SP-5+4(42375)

NUCLIDE -

25055 HN-55 1197 SIGP-5+4 NEWXLACS 218NGP P-3 293K NUCLIDE -

26000 FE 218GP RE 5-17-78(1)

.NUCLIDE -

26304 FE 1192 WT SS-304(1/EST) P-3 293K SP-5+4(42375)'

NUCLIDE -

28304 NI 1190 WT SS-304(1/EST) P-3 293K SP-5+4(42375)'

.NUCLIDE -

82000 PB 1288 218NGP 042375 P-3 293K NUCLIDE -

92235 U-235 1261 SIGP-5+4 NEWXLACS 218NGP P-3 293K(3)

ARRAY DESCRIPTION 2

2 2'

2 1

1 1

1 2

2 2

-2 NO. OF INITIAL GENERATIONS AVERAGE NUMBER OF SKIPPED K-EFFECTIVE DEVIATION HISTORIES 3

.68696

+ OR -

.00485 29100 FREQUENCY FOR GENERATIONS 4 TO 100

.5599 TO

.5830

.5830 TO

.6061

.6061 TO

.6292

.6292 TO

.6523

.6523 TO

.6754

.6754 TO

.6985

.6985 TO

.7216

.7216 TO

.7447-

.7447 TO

.7678

.7678 TO.7909

.7909 TO

.8140 78

l.

TABLE 6.5.1-1 Critical Experiments for Computational Tool Evaluation Experiment Name

~ References A.

TRX-1 a' TRX-2 A.1.

J. Hardy, Jr., D. Klein and h

Low-Enriched Uranium Rods J. J. Volpe; "A Study of Physics in Water Parameters In Several Water-Moderated Lattices of Slightly -

Enriched and Natural Uranium",

WAPD-TM-931; March,1970.

l A.2.

J. Hardy, Jr., D. Klein and J. J. Volpe; Nucl. Sci. Eng.

l 40, 101 (1970).

J. J. Volpe, l

T Hardy, Jr., and D. Klein, L

Nucl. Sci. Eng. 40, 116 (1970).

f I

A.3.

J. Hardy, Jr., D. Klein and R. Dannels; Nucl. Sci. Eng. 26, 462 (1966).

(

A.4.

J. R. Brown et al., "Kinetics and Buckling Measurements In Lattices of Slightly Enriched U or UO 2 Rodis In H 0", WAPD-176 (January, 21958).

A.S.

R. Sher and S. Fiarman, "Studies of Thermal Reactor Benchmark Data Interpretation:

Experi-I mental Corrections", EPRI NP-209; October, ' 1976.

B.

ORNL 1-4 a ORNL 10 B.1.

R. Gwin and D. W. Magnuson, Fully Enriched Uranium "Eta of U-233 and U-235 for Spherical Solutions Critical Experiments", Nuc. Sci.

Eng

,12, 364 (1962).

B.2.

A. Staub et al., "Analysis of A Set of Critical Homogeneous U-H O Spheres", Nuc. Sci. Eng.

3,2263 (1968).

'(

79 I-

.J

1; 4

TABL E 6.5.1-1

[. I-(Continued) i~

Experiment Name References L-C.

PNL 1-5 C.1.

R. C. Lloyd et al., -"Criticality Plutonium Spherical Solutions Studies With Plutonium Solutions",

Nuc. Sci. Eng. ~ 25, 165 (1966).

C.2.

L. E. Hansen and E. D. Clayton, "Theory-Experiment Tests Using ENDF/B Version 11 -Cross-Section Data", Trans. Amer. Nuc. Soc.

15, 309 (June,1972).

C.3.

F. E. Kruesi et al., "Critical Mass Studies of Plutonium-Nitrate Solution", HW-24514 (1952).

D.

Babcock & _Wilcox D.1, M. N. Baldwin et al., "Physics Small Lattice Facility Verification Program - Part Ill",

Low-Enriched UO Rods B AW-3647-6, Babcock & Wilcox, 2

in Water 1970.

MO Rods in Water D.2.

G. T. Fairburn et al., "Pu Lattice 2

(

Experiments In Uniform Test Lattice of UO -1.5% Pu O,3 Fuel",

_9 B AW-1357, Bancock & Wilc6x; Au gust, 1970.

(

80

r

,' ('

TABLE 6.5.2-1 TRX-1 NEFF RX-1763 U lETAL RODS 1.291W/0 WD 176 M.195%

271R00PCF4 710 4 LATTICECILL 0 0

>235 1 0. 6.253-4 EE F238 1 0. 0.047205 E2 E 2 0. 4.N025 OfD R 3 0. 0.W76 EO O 3 0. 0 03338 E@

1820 4 8.O-5 EE 11 5 0. 0.N676 EE O 5 0. 0.03338 E O FE 6 1. En l

AL 7 0. 4.N025 EE TRIA e lTCH 1. W 0.983 1 3 1.1506 2 1.0084 4 EC IETF TRX-1763 U lETAL RODS 1.291W/0 WAPD 176 M.1958 15 0 103 300 3 6 60 33 2 0 301 TYPE 1 M MICn+X 7 0.5753 0. -15.24 -4.5 CLSCID 5 0.903 4. 0.782 4.782 0. -15.24 4.5 i

CUB 0ID 500 0.903 4. 0.M2 4.M2 0. -76.20 4.5 CL30!D 6 0.903 4. 0.M2 -0.782 5.00 -76.20 4.5 SDI TTPE 2 I

M MIC R-X 7 0.5753 0. -15.24 4.5 l

CUB 0ID 5 0. 4.903 0.782 4.782 0. -15.24 4.5 I

CUB 01D 500 0. 4.M3 0.782 4.782 0. -74.20 4.5 CUBOID 4 0. 4.M3 0.7t2 4.782 5.00 -76.20 4.5 30X TYPE 3 l

M M!CniX 7 0.5753 20.32 4. 4.5 CUB 0ID 5 0.903 4. 0.M2 4.782 20.32 4. 4.5 l

CUDOID 500 0.M3 4. 0.32 4.782 81.28 4. 4.5 CL201D 6 0.903 4. 0.782 -0.782 81.28 -1.27 4.5 30X TYPE 4 l

M MICR-X 7 0.5753 20.32 -0. 4.5 CU30!D 5 0. 4.903 0.782 4.782 M.32 -4. 4.5 CUB 0ID 500 0. 4.903 0.732 4.M2 8120 4. 4.5 CLSOID 6 0. 4.903 0.782 4.782 81.28 -1 27 4.5 30X TYPE 5 CL30!D 5 0.903 -4. 0 782 4.732 0. -76.20 4.5 CUB 0ID 6 0.903 4. 0.782 4.782 5.00 -76.20 4.5 30X TTPE 6 l

CUDOID 5 0.M3 4. 0.782 4.M211.20 4. 4.5 CUB 0ID 6 0.903 4. 0.782 4.782 81.28 -127 4.5 ARRAY 3DT 5 27.090 -27.090 25.006 -25.906 II.t15 41.915 4.5 CUDOID 5 57.090 -57.090 55.W -55.906 ti.t15 41.915 4.5 l

l'i(

81

i(

TABLE 4.5.2-1 TRX-1 (CONTIlllD)

BEU TRX-1743 U EN. RODS 1.291W/0 WAPD 174 JAN.1958 Bt K0PETRY 51M1 1 33 1 2 2 1 0 6 1 # 1 1 32 1 1 1 1 0 2 24 38 2 1 33 2 2 2 1 0 1 25 39 2 1 33 2 2 2 1 0 2 17 43 2 2 12 2 2 2 1 0 1 18 44 2 2 32 2 2 2 1 0 2 14 46 2 3 31 2 2 2 1 0 1 15 47 2 3 31 2 2 2 1 0 2 13 47 2 4 30 2 2 2 1 0 114482 43022210212482 52922210113492 52922210 2 9512 43 22210110522 428222102 8522 72722210 1 9532 727222102 7532 826222101 8542 02622210 2 6 54 2 9 25 2 2 2 1 0 1 7 55 2 9 25 2 2 2 1 0 2 5 55 2 10 24 2 2 2 1 0 1 4 54 2 10 24 2 2 2 1 0 2 4 56 2 11 23 2 2 2 1 0 1 5 57 2 11 23 2 2 2 1 0 2 3 57 2 12 22 2 2 2 1 0 1 4 58 2 12 22 2 2 2 1 0 2 2 58 2 13 21 2 2 2 1 0 1 35921321222102 159216Il222101 260216II22210 424382 13321110325392 133'1110417432 23221110 3 II 44 2 2 32 2 1 1 1 0 4 '4 46 2 3 31 2 1 1 1 0 3 15 47 2 3 31 2 1 1 1 0 413472 43021110314482 43021110412482 52921110 313492 529211104 9512 62821110310522 62821110 4 8 52 2 7 27 2 1 1 1 0 3 9 53 2 7 27 2 1 1 1 0 4 7 53 2 8 26 2 1 1 1 0 3 8542 826211104 6542 925211103 7552 92521110 4 55521024211103 45621024211104 4 56 2 11 23 2 1 1 1 0 3 5 57 2 11 23 2 1 1 1 0 4 3 57 2 12 22 2 1 1 1 0 3 4 58 2 12 22 2 i 1 1 0 4 2 58 2 13 21 2 1 1 1 0 3 3 59 2 13 21 2 1 1 1 0 4 1 59 2 16 18 2 1 1 1 0 3 2 60 2 16 II 2 1 1 1 9 iI DtD KEWO 82

)

TABLE 6.5.2-3 TRI-3 KETF TRI-3 577 U ETAL RODS 1.291W/0 WAPD 176 N. 1958 279ROUPEF4 710 4 LATTICECELL 0 0 U-235 10. 6.253-4 EE U-238 1 0. 0.047205 EE

.(

E 2 0. 0.M025 END H 3 0. 0. W 76 E E O 3 0. 0.0D38 EE N20 4 0.0-5 EE N 5 0. 0.W76 END 0 50.0.0D38EE FE 61. EE E 7 0. 0.N025 EMD TRIAN6 PITCH 2.174 0.983131.1506 21.0084 4 EE RETF TRI-2 577 U ETAL RODS 1.291W/0 WAPD 176 R.1958 15.0 103 300 3 6 52 29 2 0 30X TYPE 1 M MICTL+X 7 0.5753 0. -15.24 4.5 CUB 0!D 5 1.M7 -0 0.9414.9410. -15.24 4.5 CUB 01D 5001.M7 -0. 0.9414.9410. -76.20 4.5 CUPO!D 61.M7 4. 0.9414.9415.06 -76.20 4.5 ICI TYPE 2 M MICTL-X 7 0.5753 0. -15 24 4.5 C180!D 5 0. -1.M7 0.9414.9410. -15.24 4.5 CLB01D 500 0. -1.M7 0.9414.9410. -76 20 -0.5 CUBOID 6 0. -1.M7 0.9414.9415.M -76.20 4.5 30I TYPE 3 M MICTLfX 7 0.5753 20.32 4. 4.5 (Ut0!D 5 1.M7 -0. 0.9414.94120.32 -0. 4.5 CLDOID 500 1 087 4. 0 941 -0.941 81 29 -0. 4.5 CUB 0ID 41.087 -0. 0.9414.94181.26 -1.27 -0.5 g

30I TYPE 4 M MICTL-X 7 0.5753 20.32 -0. -0.5 CUBOID 5 0. -1.M7 0.9414.94120.32 -0. 4.5 CUB 0!D 500 0. -1.087 0.9414.94181.29 4. -0.5 CUB 0ID 6 0. -1.M7 0.9414.94181.28 -1.27 4.5 901 TYPE 5 CUB 0ID 51.M7 4. 0.9414.9410. -76.20 -0.5 cut 0!D 41.M7 4. 0.9414.9415.M -76.20 -0.5 30I TYPE &

CUB 0ID 51.M7 4. 0.9414.941 B1.29 4. 4.5 CUIDID 41.M7 4. 0.94. 4.94131.26 -1.27 4.5 NtRAT 3DY 5 29.262 -29.262 27.299 -27.299 81.715 4 1.915 4.5 CUICID 5 M.262 48.262 57.209 -57.209 81915 41915 4.5 EE EDETRY 5 121 1 M 12 210 6 191 1 M 11110 2 D D 2 1 M 2 2 210 1 23 33 2 1 29 2 2 2 1 0 2 15 77 2 2 28 2 2 2 1 0 1 16 38 2 2 28 2 2 2 1 0 212402 32722210113412 32722210211412 42622210 1 12 42 2 4 26 2 2 ) 1 0 2 10 42 2 5 25 2 2 2 1 0 1 11 43 2 5 25 2 2 2 1 0 2 7 45 2 6 24 2 2 2 1 0 1 8 44 2 6 24 2 2 2 1 0 2 6 46 2 7 23 2 2 2 1 0 1 7 47 2 7 D 2 2 210 2 5 0 2 8 D 2 2 2101 6 M 2 S D 2 2 210 2 4 44 2 9 21 2 2 2 1 0 1 5 49 2 9 21 2 2 2 1 0 2 3 49 2 10 20 2 2 2 1 0 1 4 50 2 10 20 2 2 2 1 0 2 2 50 2 11 19 2 2 2 1 0 1 3 51 2 11 19 2 2 2 1 0 2 15121416222101 2522141622210422322 12921110 3 23 33 2 1 M 2 1 1 1 0 4 15 37 2 2 28 2 1 1 1 0 3 16 30 2 2 28 2 1 1 1 0 4 12 40 2 3 27 2 1 1 1 0 3 13 41 2 3 27 2 1 1 1 0 4 11 41 2 4 26 2 1 1 1 0

-II 3 12 42 2 4 26 2 1 1 1 0 4 10 42 2 3 25 2 1 1 1 0 3 11 43 2 5 25 2 1 1 1 0 4 7 5 2 6 N 21110 3 0 4 2 6 N 21110 4 6 4 2 7 D 21110 3 7472 723211104 5472 022211103 6402 02221110 4 4 M 2 9 M 21110 3 5 # 2 9 2 21114 4 3 # 210 M 21110 3 4 50 2 10 20 2 1 1 1 0 4 2 50 2 11 19 2 1 1 1 0 3 3 51 2 11 19 2 1 1 1 0 4 1 51 2 14 14 2 1 1 1 0 3 2 9 2 14 14 2 1 1 1 9 83 NY

r

.(

TABLE 6.5 2-3 WK-18 (UK-2 E (UK-1 NSE 34 263-274 (1968P) SCALE EDEL 279ROUPEF4 171 11FHOMEDilM 10 F 235 1 0. 4.0066-5 E E F 238 1 0. 2 907-6 E E F234 19. 5.38 7 EE F236 10 1.38-7 EE N 10.1.869-4 EMD D 1 0. 0.033736 EE H 10. 0.W228 EE ISN12!!R40 ICR270 IUS=1 E E E DRE-1 NSE 34 263-274 (1968P) SCALI M L 15.0 103 300 3 0 0 0 0 0 M G E 1 34.5948 -0.5 DC E0ETRY DID END E ORE-2 NSE 34 263-274 (1968F) SCALE MODEL 279ROUPEF4 101 INDOMMEDIUM 10 F 235 1 0. 5.6205-5 E E l

p-238 10. 3.28-6 EE F234 1 0 6.31-7 EE

. (

U-236 10 163-7 EE N 1 0 2 129-4 E E 0 1 0. 0.0338 EE N 1 0. 0. W 148 EE B-10 10 10286-6 EE

!$m 12 !! >40 ICm 70 IUS=1 E E E DRE-2 NSE 34 263-274 (1968P) SCALE EL 15.0 103 300 3 0 0 0 0 0 MBE 1 34.5948 -0.5 EMD EOMETRY END ENO I

i 84

i(

1ARLE 6.5.2-4 PM.-1 1 PIL-2 EEFF PNL-116E 25165 (!?66) 27liROUP@r4 151 IFHOMf0Ilm 10 PU-239 1 0. 9.373-5 EMD PU-240 10. 4.501-6 DD N 1 0. 4.216-4 END 0 10. 0.03456 EE N 10. 0.06563 END IS*12 !!k40 ICM*70 IUS21 EE REFT Pr.-1 NSE 25 165 (1966) 15.103300300000 SPtERE 1 19.509 -0.5 EE E0 METRY DG KEC KEFF Pit-2 NSE 25165 (1966) 279POUPCF4 151 tilFHOMED!lm 10 PU-239 1 4. 4 141-4 EG PU-240 10.1996-5 DO N 1 6. 4.720-3 E E O 1 0. 0.03977 END N 1 0. 0.05416 E G

,(

ISW12 !!Mt40 ICMs70105:1 DO EFT PNL-2 NSE 25165 (1966) 15.103300300000 SPHERI 1 19.509 -0.5 EE E0fETRT DG EC 85 J

/

.I 1

TABLE 6.5.2-5 SW U021 M02 DPERIENTS BW UD2 EYP ELL SCALE lEEL DGFFIV LATilE SELFCit 270ROUP@f4 3 7 3 LATTIKELL 00 0

1 0. 4.472785-2 DG U-235 1 9. 5.570208-4 DfD U-238 1 6. 2.100490-2 EMD AL 2 9. 6.051481-2 DG H

3 0. 6.668320-2 DG F10 3 0. 2.243000-5 DG 0

3 0. 3.334160-2 DG 900AREPliCH 1.6254 1.0434 1 312060 2 DG SW UO2 EXP ELL SCALE MODEL DOO-IV LATTIE SELFSHLD

15. 103 300 3 4R1 1 6R1 CTLIIGER 1.521716.3128.t128

.5 CTLil@ER 2.603

.3128.8128

.5 CUB 0!D 3.9128

.8128.8128

.9128.8128.8128

.5 DG KOMETRY DG KEND k

i BW W EXPDtil O f SCALE MDEL LATTIKELL ELTSHIELBIN 27ROUPDF4 312 3 LATTIECELL 00 l

0 1 6. 4.358350-2 DtD l

F235

16. 1.543510-4 De l

F238 1 6. 2 131199 2 DG PU-239 1 6. 2.646750-4 DG l

PU-240 1 4. 5.295900-5 DG f

PU-241 1 8. 5.271000-6 DG PU-242 1 9. B.320000-7 DID 1

AM-241 1 8. 1 616000-6 DG I

ZlRCALLOY 2 1 019225 DID M

3 4 6.668320-2 DID F10 3 8. 2 465000-5 DID 0

3 4. 3.334160-2 DG SOU#iPITCH 189738 12751 1 3 14275 2 De i

BW W EXPERIENT SCALI ICKL LATTIE ILF90!IG

10. 103 300 3 411 1 4R1 CTLilGDt 1.63754.94869

.94869

.5 CTLilGDt 2.71374.94849.94069

.5

(

CUB 0!D 3.94869.94869.94869

.94869.f4869

.94469.5 DG KDETRT DG KDIO 86 8

J

TABLE 6.5.3-1 i

K-Effective Results Computational Tool Evaluation SCALE Results Name of No. of Critical Neutron Experiment Feature K-eff 2 Sigma Histories ORNL-1 Fully Enriched 1.0021 0.0060 30,000 l

ORNL-2 U-235 Nitrate 0.9977 0.0068 30,000 TRX-1 Low Enriched 0.9773 0.0060 30,000 TRX-2 U-235 Rods 0.9820 1 0.0060 30,000 PNL-1 Plutonium 1.0157 ! 0.0108 30,000 PNL-2 Nitrate (5Pu240) 1.0105 0.0114 30,000 B&W UO Rod 0.9920*1 0.0046 30,000 B&W MO Rod 0.9972* 0.0054 30,000

(

I

  • k-infinity values l

87

.4

.1 Attachment B I.

I i

I l

)

-

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