Text

Attachment 11 - NSA-TR-SHN-13-05, Revision 1, Shine Physics Validation
	ML14357A354
Person / Time
Site:	SHINE Medical Technologies
Issue date:	12/03/2014
From:	; SHINE Medical Technologies
To:	; Office of Nuclear Reactor Regulation
Shared Package
ML14356A527	List: ML14356A528; ML14357A343; ML14357A344; ML14357A345; ML14357A346; ML14357A348; ML14357A349; ML14357A350; ML14357A351; ML14357A352; ML14357A354; ML14357A358; ML14357A360; ML14357A361; ML14357A362; ML14357A363; ML14357A364;
References
	SMT-2014-040 NSA-TR-SHN-13-05, Rev. 1
	Download: ML14357A354 (54)
	v • d • e

ENCLOSURE 2 ATTACHMENT 11 SHINE MEDICAL TECHNOLOGIES, INC.

SHINE MEDICAL TECHNOLOGIES, INC. APPLICATION FOR CONSTRUCTION PERMIT RESPONSE TO REQUEST FOR ADDITIONAL INFORMATION NSA-TR-SHN-13-05, REVISION 1 SHINE PHYSICS VALIDATION 53 pages follow

6+,1(0HGLFDO7HFKQRORJLHV

16$756+1

5HY

7$%/(2)&217(176

,QWURGXFWLRQ

$VVXPSWLRQV

&RPSXWHU&RGHV

%HQFKPDUNV

,(862/7+(50

+(862/7+(50

0&13(YDOXDWLRQ

$SSURDFK

5HVXOWV

$UHDRI$SSOLFDELOLW\

&RQFOXVLRQV

5HIHUHQFHV

$33(1',;$0&13,QSXW)LOHV

3DJHRI

6+,1(0HGLFDO7HFKQRORJLHV

16$756+1

5HY

/,672)),*85(6

)LJXUH+/-,(862/7+(505HDFWRU

)LJXUH+/-+(862/7+(505HDFWRU

/,672)7$%/(6

7DEOH+/-,(862/7+(506DPSOH&DOFXODWLRQV

7DEOH+/-+(862/7+(506DPSOH&DOFXODWLRQV

7DEOH+/-/LEUDU\'HVLJQDWLRQVIRU0RGHOHG1XFOLGHV

7DEOH+/-,(862/7+(505HVXOWV

7DEOH+/-+(862/7+(505HVXOWV

7DEOH+/-$UHDRI$SSOLFDELOLW\&RPSDULVRQ

3DJHRI

>3URSULHWDU\,QIRUPDWLRQ:LWKKHOGIURPSXEOLFGLVFORVXUHXQGHU&)5 D @

6+,1(0HGLFDO7HFKQRORJLHV

16$756+1

5HY

,1752'8&7,21

6+,1( 0HGLFDO 7HFKQRORJLHV LV GHVLJQLQJ D V\VWHP WR JHQHUDWH PRO\EGHQXP IRU XVH DV D

PHGLFDOLVRWRSH7KH6+,1(V\VWHPLVGHVFULEHGLQGHWDLOLQ5HIHUHQFH,QVXPPDU\WKHV\VWHP

FRQVLVWV RI D QHXWURQ GULYHU GHILQHG E\ DQ DFFHOHUDWRU GHXWHURQ VRXUFH GLUHFWHG LQWR WULWLXP

WDUJHW JHQHUDWLQJ KLJK HQHUJ\ IXVLRQ QHXWURQV WKDW SDVV WKURXJK D>3URSULHWDU\,QIRUPDWLRQ@ QHXWURQ

PXOWLSOLHUUHVXOWLQJLQDVSHFWUXPRI>3URSULHWDU\,QIRUPDWLRQ@QHXWURQVZKLFK

WKHQHQWHU D7DUJHW6ROXWLRQ9HVVHO 769 FRQWDLQLQJXUDQ\OVXOIDWH 82 62 LQVROXWLRQ

7KH SXUSRVH RI WKLV WHFKQLFDO UHSRUW LV WR GRFXPHQW D YDOLGDWLRQ RI WKH FDOFXODWLRQDO PHWKRGV

VSHFLILFDOO\ WKH 0&13 FRGH ZLWK>3URSULHWDU\,QIRUPDWLRQ@ FURVVVHFWLRQV XVHG WR DQDO\]H WKH

6+,1( V\VWHP $16,$16 5HIHUHQFH UHTXLUHV WKDW FDOFXODWLRQDO PHWKRGV XVHG IRU

VWHDG\VWDWH QHXWURQLFV FDOFXODWLRQV RI UHDFWRU V\VWHPV HJ QHXWURQ UHDFWLRQUDWH VSDWLDO

GLVWULEXWLRQV SRZHU GLVWULEXWLRQV DQG HIIHFWLYH QHXWURQ PXOWLSOLFDWLRQ FRQVWDQWV RI QXFOHDU

SRZHUUHDFWRUV EHYDOLGDWHGWRGHWHUPLQHDQ\DSSURSULDWHELDVHVDQGXQFHUWDLQWLHVIRUWKHDUHDV

RI DSSOLFDELOLW\ $R$V %LDV UHSUHVHQWV DQ\ QXPHULFDO GLIIHUHQFH EHWZHHQ WKH UHVXOWV RI

PRGHOLQJEHQFKPDUNH[SHULPHQWVZLWKDFRPSXWHUFRGHDQGWKHH[SHULPHQWDOUHVXOWV

$668037,216

7KH PRGHOLQJ DVVXPSWLRQV PDGH IRU WKH EHQFKPDUN H[SHULPHQWV DUH FRQVLVWHQW ZLWK WKRVH

GHVFULEHGLQ5HIHUHQFH

&20387(5&2'(6

D 0&13 5HIHUHQFH WKH/RV$ODPRV1DWLRQDO/DERUDWRU\ /$1/ 0RQWH&DUOR

13DUWLFOH 0&13 UDGLDWLRQ WUDQVSRUW FRGH ZDV XVHG WR FDOFXODWH HLJHQYDOXHV RI WKH

EHQFKPDUNV\VWHPVDVZHOODVHIIHFWLYHGHOD\HGQHXWURQIUDFWLRQVIRUWKHFDOFXODWLRQRI

PHDQQHXWURQOLIHWLPH0&13LVGHYHORSHGDQGPDLQWDLQHGXQGHUDFRQILJXUDWLRQ

PDQDJHPHQWSODQE\/$1/7KHFRGHLVGLVWULEXWHGE\WKH5DGLDWLRQ6DIHW\,QIRUPDWLRQ

&RPSXWDWLRQDO&HQWHU 56,&&

7KHLQVWDOODWLRQRI0&13YHUVLRQKDVEHHQYHULILHGRQWKH16$V\VWHP7KH16$

V\VWHP LV D FRPSXWHU FOXVWHU FRPSRVHG RI VHYHUDO VHUYHUV WKDW XVH ,QWHO SURFHVVRUV

UXQQLQJWKH)HGRUD/LQX[RSHUDWLQJV\VWHP0&13KDVEHHQLQVWDOOHGLQWKHUHDGRQO\

GLVN DUHD WKH LQVWDOODWLRQ KDV EHHQ YHULILHG ZLWK WKH H[HFXWLRQ RI WKH VDPSOH SUREOHPV

5HIHUHQFH

E 25,*(16 5HIHUHQFH D PRGXOH RI WKH ODUJHU 6&$/( 6WDQGDUGL]HG &RPSXWHU

$QDO\VHV IRU /LFHQVLQJ (YDOXDWLRQV FRPSXWDWLRQDO V\VWHP IURP 2DN 5LGJH 1DWLRQDO

/DERUDWRU\ 251/ ZDVXVHGWRJHQHUDWHILVVLRQSURGXFWLQYHQWRULHVIRUWKHFDOFXODWLRQ

RI PHDQ QHXWURQ OLIHWLPH $V SDUW RI WKH ODUJHU 6&$/( FRPSXWDWLRQDO V\VWHP WKH

25,*(16FRGHLVGHYHORSHGDQGPDLQWDLQHGXQGHUDFRQILJXUDWLRQPDQDJHPHQWSODQE\

3DJHRI

6+,1(0HGLFDO7HFKQRORJLHV

16$756+1

5HY

251/ 7KH FRGH LV GLVWULEXWHG E\ WKH 5DGLDWLRQ 6DIHW\ ,QIRUPDWLRQ &RPSXWDWLRQDO

&HQWHU 56,&&

7KH LQVWDOODWLRQ RI 25,*(166&$/( KDV EHHQ YHULILHG RQW KH 16$ V\VWHP 7KH

16$V\VWHPLVDFRPSXWHUFOXVWHUFRPSRVHGRIVHYHUDOVHUYHUVWKDWXVH,QWHOSURFHVVRUV

UXQQLQJ WKH )HGRUD /LQX[ RSHUDWLQJ V\VWHP 6&$/( KDV EHHQ LQVWDOOHG LQ WKH UHDG

RQO\ GLVN DUHD WKH LQVWDOODWLRQ KDV EHHQ YHULILHG ZLWK WKH H[HFXWLRQ RI WKH VDPSOH

SUREOHPV 5HIHUHQFH

F 0LFURVRIW 2IILFH ([FHO 7 KH ([FHO VSUHDGVKHHW VRIWZDUH ZDV XVHG WR SURFHVV

25,*(16 DQG 0&13 FDOFXODWLRQ UHVXOWV 7KH FDOFXODWLRQV FRQVLVW RI PDWKHPDWLFDO

HTXDWLRQVZKLFKFDQEHYHULILHGE\KDQGFDOFXODWLRQV

&RPSXWHUW\SH'HOO/DWLWXGH(

2SHUDWLQJ6\VWHP0LFURVRIW:LQGRZV

6HULDO1XPEHUV16$

%(1&+0$5.6

7KH IROORZLQJ VXEVHFWLRQV GHVFULEH WZR EHQFKPDUNV LQYROYLQJ XUDQ\O VXOIDWH VROXWLRQV WDNHQ

IURP WKH ,QWHUQDWLRQDO +DQGERRN RI (YDOXDWHG &ULWLFDOLW\ 6DIHW\ %HQFKPDUN ([SHULPHQWV

5HIHUHQFH (DFK RI WKH EHQFKPDUNV LQYROYHV PXOWLSOH LQGLYLGXDO FDVHVW KDW DUH PRGHOHG

KHUHLQ XVLQJ 0&13 7KH 0&13 UHVXOWV DUH WKHQ FRPSDUHG WR WKH VDPSOH UHVXOWV

SUHVHQWHGLQ5HIHUHQFH$SSHQGL[$RIWKLVUHSRUWFRQWDLQVDQ0&13LQSXWOLVWLQJIRUHDFKRI

WKHEHQFKPDUNFDVHV

1RWH WKDW WKH PHWKRGRORJ\ HPSOR\HG KHUHLQ FRPSDUHV WKH 0&13 UHVXOWV WR WKH VDPSOH

FDOFXODWLRQVSURYLGHGLQERWKEHQFKPDUNVXVLQJWKH0&8FRGH ,(862/7+(50 DQGWKH

$32//2025(7 FRGH VXLWH +(862/7+(50 ERWK RI ZKLFK HPSOR\ 0RQWH &DUOR

WHFKQLTXHV 7KH EHQFKPDUN H[SHULPHQWDO UHVXOWV IRU WKHVH WZR EHQFKPDUNV ZHUH GHHPHG WR EH

XQDFFHSWDEOHIRUGLUHFWYDOLGDWLRQEHFDXVHRIWKHXQUHVROYHGKLVWRULFDOGLIIHUHQFHVEHWZHHQWKHP

DQGUHVXOWVFDOFXODWHGE\RWKHUSK\VLFVFRGHV DYHUDJH'N IRU,67DQGDYHUDJH'N

IRU+67 *LYHQWKHODFNRIRWKHUVXLWDEOHXUDQ\OVXOIDWHEHQFKPDUNVLWZDVMXGJHG

WKDW DI DYRUDEOH FRPSDULVRQ RI 0&13 UHVXOWVWR WKH UHVXOWV RI WKHVH RWKHU FRGHV SURYLGHV WKH

EHVWDYDLODEOHPHDVXUHRI0&13 VDELOLW\WRVXLWDEO\PRGHOWKHEHQFKPDUNV\VWHPV

2QHRWKHUSRWHQWLDOEHQFKPDUNZDVLGHQWLILHGWKH/232ORZSRZHUUHDFWRUEXLOWLQDWWKH

/RV $ODPRV 1DWLRQDO /DERUDWRU\ 7KLV UHDFWRU FRQVLVWHG RI DR QH IRRW GLDPHWHU VWDLQOHVV VWHHO

VSKHULFDO VKHOO UHIOHFWHG E\EH U\OOLXP R[LGH RQ DJ UDSKLWH EDVH 7KH YHVVHO ZDV ILOOHG ZLWK D

KRPRJHQHRXVXUDQ\OVXOIDWHVROXWLRQHQULFKHGWRZW 8+RZHYHUVXIILFLHQWGDWDFRXOG

QRWEHORFDWHGWRDFFXUDWHO\PRGHOWKHUHDFWRUDQGLWZDVGLVPLVVHGDVDEHQFKPDUN

3DJHRI

6+,1(0HGLFDO7HFKQRORJLHV

16$756+1

5HY

,(862/7+(50

7KH SXUSRVH RI WKHVH H[SHULPHQWV SHUIRUPHG DW WKH 5XVVLDQ 5HVHDUFK &HQWHU ³.XUFKDWRY

,QVWLWXWH' LQ ZDV WR LQYHVWLJDWH QXFOHDU VDIHW\ LVVXHV IRU DVSHFLDOSXUSRVH FRPSDFW

UHDFWRU ZLWK DQ DTXHRXV VROXWLRQ RI XUDQ\O VXOIDWH a ZW 8 DQG JUDSKLWH UHIOHFWRU

)RXU FRQILJXUDWLRQV RI FULWLFDO DVVHPEOLHV ZLWK GLIIHUHQW FRQFHQWUDWLRQV RI XUDQLXP LQ WKH

VROXWLRQZHUHLQFOXGHGZLWKWKHVROXWLRQYROXPHFRQWUROOHGWRDFKLHYHFULWLFDOLW\

$QDTXHRXVVROXWLRQRIXUDQ\OVXOIDWHZDVSODFHGLQWKHFRUHYHVVHODZHOGHGVWHHOF\OLQGHUZLWK

DKHPLVSKHULFDOERWWRPDQGDOLGWKHODWWHUSHQHWUDWHGE\YHUWLFDOO\DUUDQJHGVWHHOSLSHVZKLFK

IRUPOHDNWLJKWFKDQQHOV&RUHYHVVHOVRIWZRZDOOWKLFNQHVVHVZHUHXVHG FPDQGFP

ERWKZLWKDQLQQHUGLDPHWHURIPP7KHWKLFNHUYHVVHOZDVFPKLJKIURPLWVHQGWRWKH

LQQHUVXUIDFHRIWKHERWWRP DORQJWKHD[LV DQGLWVF\OLQGULFDOSDUWLVFPORQJ$FRLOHG

FRROLQJSLSHZDVSODFHGLQVLGHWKHYHVVHO

7KHFRUHYHVVHOZDVVXUURXQGHGZLWKDJUDSKLWHUHIOHFWRUZKLFKFRQWDLQVILYHYHUWLFDOFKDQQHOV

DQGRQHKRUL]RQWDOFKDQQHOPDFKLQHGLQWRWKHJUDSKLWHEORFNV7KHYHVVHOZDVUHFHVVHGLQWRWKH

JUDSKLWHUHIOHFWRUWRDGHSWKRIFPIURPWKHUHIOHFWRUWRS7KHVLGHVXUIDFHVRIWKHJUDSKLWH

UHIOHFWRUZHUHVXUURXQGHGE\DVKLHOGRIERUDWHGSRO\HWK\OHQH2QWRSRIWKHUHIOHFWRUZDVDVWHHO

SODWH

7KHJHRPHWU\RIWKHH[SHULPHQWLVGHSLFWHGLQ)LJXUH

3DJHRI

6+,1(0HGLFDO7HFKQRORJLHV

16$756+1

5HY

)LJXUH+/-,(862/7+(505HDFWRU

3DJHRI

6+,1(0HGLFDO7HFKQRORJLHV

16$756+1

5HY

7KH EHQFKPDUN PRGHO ZDV GHYHORSHG IURP FDOFXODWLRQDO PRGHOV GHVFULELQJ WKH DFWXDO FULWLFDO

H[SHULPHQWV ,Q 5HIHUHQFH WKH PRGHO ZDV VLPSOLILHG ZKLOH SUHSDULQJ WKH EHQFKPDUN

VSHFLILFDWLRQV 7KH IROORZLQJ FRPSRQHQWV RI WKH DVVHPEO\ ZKRVH HIIHFWV RQ FULWLFDOLW\ ZHUH

IRXQGWREHLQVLJQLILFDQWLQ5HIHUHQFHZHUHH[FOXGHG

x LPSXULWLHVLQILVVLOHVROXWLRQDQGJUDSKLWH

x VRPHVWUXFWXUDOHOHPHQWVLQWKHDVVHPEO\DQGDURXQGLW

x URRPUHIOHFWLRQ

7KHVDPSOHFDOFXODWLRQUHVXOWVIURPWKHEHQFKPDUNVXPPDU\UHSRUWDORQJZLWKSHUWLQHQWQXFOHDU

SDUDPHWHUV IRU HDFK FDVH DUH SUHVHQWHG LQ 7DEOH 6HH 5HIHUHQFH IRU PRUH GHWDLOHG

LQIRUPDWLRQ

7DEOH+/-,(862/7+(506DPSOH&DOFXODWLRQV

6DPSOH 6DPSOH

&DVH &DVH +8 J8O J8O

N ()) V

LVW

7KLVLVWKHPRGHUDWLRQUDWLRWKHUDWLRRIK\GURJHQDWRPVWR8DWRPVLQWKHIXHOVROXWLRQ

+(862/7+(50

$ VHULHV RI VXEFULWLFDO KLJKPXOWLSOLFDWLRQ DSSURDFKHV DQG FULWLFDO H[SHULPHQWV ZDV SHUIRUPHG

ZLWKWKH3URVHUSLQHVROXWLRQUHDFWRULQWKURXJKDW6DFOD\)UDQFHXVLQJKRPRJHQHRXV

DTXHRXVVROXWLRQVRIXUDQLXPVXOIDWH ZW 8 FRQWDLQLQJ1H[FHVVVXOIXULFDFLG

7KLV EHQFKPDUN LQFOXGHV WKLUWHHQ VXEFULWLFDO DSSURDFKHV ZLWK 8 FRQFHQWUDWLRQV UDQJLQJ

EHWZHHQWRJOLWHU7KHH[SHULPHQWVZHUHSHUIRUPHGWRGHWHUPLQHHPSLULFDOFULWLFDO

PDVVGDWDIRUFULWLFDOLW\VDIHW\JXLGDQFHDQGIRUYHULILFDWLRQRIFDOFXODWLRQDOPHWKRGV

7KHFRUHZDVFRPSULVHGRIWKHILVVLOHVROXWLRQLQVLGHDF\OLQGULFDOWDQNRI=LUFDOR\7KHLQQHU

WDQNZDVFPLQGLDPHWHUDQGFPLQKHLJKWZLWKDFRQLFDOERWWRPVXUURXQGHGE\DQRXWHU

DOXPLQXPDOOR\WDQNDQGUHIOHFWHGE\DPLQLPXPRIFPRIEHU\OOLXPR[LGHIROORZHGE\D

OD\HURIDWOHDVWFPRIJUDSKLWH7KHUHIOHFWRUVFRQWDLQHGVWUXFWXUDOSODWHVRIDOXPLQXPDOOR\

DVZHOODVVHYHUDOSHQHWUDWLRQVWKURXJKRXWWRDFFRPPRGDWHWKHILOOWXEHH[SHULPHQWDOFKDQQHOV

FRQWUROURGVVDIHW\URGVHWF

([SHULPHQWV SHUIRUPHG ZLWK WKLV UHDFWRU ZHUH HLWKHU FULWLFDO ZLWK WKH XVH RI FRQWURO DQG VDIHW\

URGVRUZHUHVXEFULWLFDODSSURDFKHVH[WUDSRODWHGWRFULWLFDOZLWKWKHPXOWLSOLFDWLRQIDFWRUUHDFKHG

EHLQJ YHU\ FORVH WR ,Q WKHVH ODWWHU FDVHV WKH VXEFULWLFDO DSSURDFK SDUDPHWHU ZDV WKH

VROXWLRQKHLJKWLQWKHFRUHZLWKWKHFRQWURODQGVDIHW\URGVLQSRVLWLRQVRXWVLGHWKHUHDFWRU

7KHJHRPHWU\RIWKHH[SHULPHQWLVGHSLFWHGLQ)LJXUH

3DJHRI

6+,1(0HGLFDO7HFKQRORJLHV

16$756+1

5HY

)LJXUH+/-+(862/7+(505HDFWRU

7KHEHQFKPDUNPRGHOIRUWKH3URVHUSLQHH[SHULPHQWVLVDQDFFXUDWHUHSUHVHQWDWLRQRIWKHDFWXDO

DVVHPEO\ ZLWK WKH IROORZLQJ VLPSOLILFDWLRQV DQG WKHLU DVVRFLDWHG ELDVHV LI DQ\ GHULYHG LQ

5HIHUHQFH

x ,QVLJQLILFDQW TXDQWLWLHV RI EORWWLQJ SDSHU XVHG IRU OHDN GHWHFWLRQ EHWZHHQ WDQNV DUH

FRQVLGHUHGQHJOLJLEOHDQGDUHRPLWWHG

x 7KHFRSSHUZLUHLVRPLWWHGDQGDELDVLVLQWURGXFHG

x 7KHJDSVEHWZHHQWKHDOXPLQXPDOOR\WXEHVLQFKDQQHOVDQGWKHUHIOHFWRUVDUHQHJOLJLEOH

DQGDUHRPLWWHG

x 7UDFHLPSXULWLHVLQWKH=UDOOR\DUHRPLWWHGDQGDELDVLVLQWURGXFHG

x ,URQEXLOGXSLQWKHVROXWLRQLVRPLWWHGDQGDELDVLVLQWURGXFHG

x 7KHPPJDSEHWZHHQWKHLQQHU =U DQGRXWHU DOXPLQXPDOOR\ WDQNVLVLQFOXGHGWKH

JDS EHWZHHQ WKH RXWHU WDQN DQG WKH LQQHU %H2 UHIOHFWRU VXUIDFH LV QHJOLJLEOH DQG LV

RPLWWHG

x 1HXWURQUHWXUQ IURP VWUXFWXUHV H[WHUQDO WR WKH JUDSKLWH VXUIDFH LV QHJOLJLEOH DQG LV

RPLWWHG YDFXXPERXQGDU\

3DJHRI

>3URSULHWDU\,QIRUPDWLRQ:LWKKHOGIURPSXEOLFGLVFORVXUHXQGHU&)5 D @

6+,1(0HGLFDO7HFKQRORJLHV

16$756+1

5HY

x 7KH DOXPLQXP DOOR\ XVHG IRU WKH WXEHV DQG VXSSRUW SODWHV LV DVVXPHG WR DOVR EH

%ULOODOXPDJ

7KHVDPSOHFDOFXODWLRQUHVXOWVIURPWKHEHQFKPDUNVXPPDU\UHSRUWDORQJZLWKSHUWLQHQWQXFOHDU

SDUDPHWHUV IRU HDFK FDVH DUH SUHVHQWHG LQ 7DEOH 6HH 5HIHUHQFH IRU PRUH GHWDLOHG

LQIRUPDWLRQ

7DEOH+/-+(862/7+(506DPSOH&DOFXODWLRQV

6DPSOH 6DPSOH

&DVH &DVH +8 J8O J8O

N ()) V

SURV

0&13(9$/8$7,21

$SSURDFK

(DFKRIWKHIRXU,(862/7+(50DQGWKLUWHHQ+(862/7+(50FDVHVDUHPRGHOHG

LQ0&13DQGH[HFXWHGZLWK>3URSULHWDU\,QIRUPDWLRQ@FURVVVHFWLRQVDVOLVWHGLQ7DEOH

,QDGGLWLRQ>3URSULHWDU\,QIRUPDWLRQ@7KH0&13PRGHOUHVXOWVDUHGLUHFWO\FRPSDUHGWRWKH

VDPSOHEHQFKPDUNPRGHOUHVXOWVSURYLGHGLQ5HIHUHQFH

7DEOH+/-/LEUDU\'HVLJQDWLRQVIRU0RGHOHG1XFOLGHV

1SPQSJFUBSZ*OGPSNBUJPO 3DJHRI

>3URSULHWDU\,QIRUPDWLRQ:LWKKHOGIURPSXEOLFGLVFORVXUHXQGHU&)5 D @

6+,1(0HGLFDO7HFKQRORJLHV

16$756+1

5HY

1SPQSJFUBSZ*OGPSNBUJPO

5HVXOWV

7KH0&13UHVXOWVDUHSUHVHQWHGLQ7DEOHVDQGIRU,(862/7+(50DQG+(862/

7+(50 UHVSHFWLYHO\ 1RWH WKDW ZLWK UHVSHFW WR WKH 'NV FROXPQ LQ WKH WZR WDEOHV V

UHSUHVHQWV WKH FRPELQHG XQFHUWDLQW\ ZKLFK LV FDOFXODWHG DV WKH VTXDUHURRW RI WKH VXP RI WKH

VTXDUHGVWDQGDUGGHYLDWLRQVRIWKHVDPSOHDQG0&13FDOFXODWLRQV

7DEOH+/-,(862/7+(505HVXOWV

6DPSOH 6DPSOH 0&13 0&13

&DVH &DVH 'N 'NV

N ()) V N ()) V

LVW

Proprietary Information

LVW

3DJHRI

>3URSULHWDU\,QIRUPDWLRQ:LWKKHOGIURPSXEOLFGLVFORVXUHXQGHU&)5 D @

6+,1(0HGLFDO7HFKQRORJLHV

16$756+1

5HY

7DEOH+/-+(862/7+(505HVXOWV

6DPSOH 6DPSOH 0&13 0&13

&DVH &DVH 'N 'NV

N ()) V N ()) V

SURV

Proprietary

Information

SURV

7KH UHVXOWV GHPRQVWUDWH WKDW WKH 0&13 FDOFXODWLRQV DJUHH YHU\ ZHOO ZLWK WKH WZR VHWV RI

EHQFKPDUNVDPSOHFDOFXODWLRQVZLWKUHDFWLYLW\GLIIHUHQFHVUDQJLQJIURP>3URSULHWDU\,QIRUPDWLRQ@'NRU

>3URSULHWDU\,QIRUPDWLRQ@7KHDYHUDJHUHDFWLYLW\GLIIHUHQFHLV>3URSULHWDU\,QIRUPDWLRQ@,IWKHDYHUDJH

UHDFWLYLW\GLIIHUHQFHVDUHFDOFXODWHGVHSDUDWHO\IRUHDFKEHQFKPDUNGDWDVHWWKHUHVXOWVGHPRQVWUDWHDORZHU

DYHUDJH UHDFWLYLW\ GLIIHUHQFH IRU +(862/7+(50>3URSULHWDU\,QIRUPDWLRQ@ WKDQ IRU ,(862/

7+(50>3URSULHWDU\,QIRUPDWLRQ@

$5($2)$33/,&$%,/,7<

7DEOHSUHVHQWVWKHFRPELQHGDUHDRIDSSOLFDELOLW\IRUWKHWZREHQFKPDUNGDWDVHWVDVZHOODVD

QRPLQDODUHDRIDSSOLFDELOLW\IRUWKH6+,1(V\VWHP

3DJHRI

[Proprietary Information - Withheld from public disclosure under 10 CFR2.390(a)(4)]

7DEOH+/-$UHDRI$SSOLFDELOLW\&RPSDULVRQ

3DUDPHWHU 6+,1(1RPLQDO %HQFKPDUNV

)LVVLOH0DWHULDO 82 62 82 62

)LVVLOH0DWHULDO)RUP 6ROXWLRQ 6ROXWLRQ

+85DWLR >3URSULHWDU\,QIRUPDWLRQ@ +8

&RQFHQWUDWLRQ J8O >3URSULHWDU\,QIRUPDWLRQ@ WR

$YHUDJH1HXWURQ(QHUJ\ [ Proprietary Information ]

>a@ $1(&)

&DXVLQJ)LVVLRQ 0H9

(QULFKPHQW ZW8 WRZW8

[ Proprietary :DWHU*UDSKLWH%H2

>8UDQLXP@]

DWHU>8UDQLXP@7ULWLXP

Information 3RO\HWK\OHQH6WDLQOHVV6WHHO

5HIOHFWLQJ$EVRUELQJ0DWHULDOV $OXPLQXP=LUFDOR\&RQFUHWH

=LUFDOR\$OXPLQXP%RURQ

%RURQ

7HIORQ

HRPHWU\ $QQXODU&\OLQGULFDO6ROXWLRQV &\OLQGULFDO6ROXWLRQV

LYHQ WKH XQLTXH GHVLJQ SDUDPHWHUV RI WKH 6+,1( V\VWHP LW LV QRW SRVVLEOH WR ILQG UHDFWRU

SK\VLFVEHQFKPDUNVWKDWSUHFLVHO\FRUUHVSRQGWRDOODVSHFWVRIWKH6+,1($R$:LWKUHVSHFWWR

PRGHUDWLRQUDWLR$1(&) VHOHFWUHIOHFWLQJDEVRUEHUPDWHULDOV HJ>3URSULHWDU\,QIRUPDWLRQ@PXOWLSOLHU

DQG WULWLXP DQG JHRPHWU\ LH DQ DQQXODU V\VWHP ZLWK FHQWUDO WULWLXP UHJLRQ YHUVXV WKH

EHQFKPDUN F\OLQGULFDO V\VWHPV WKHUH DUH GLVFRQWLQXLWLHV EHWZHHQ WKH EHQFKPDUN DQG 6+,1(

$R$V+RZHYHUZLWKUHVSHFWWRVLJQLILFDQWQXFOHDUSDUDPHWHUVVXFKDVILVVLOHPDWHULDOIRUP LH

XUDQ\O VXOIDWH VROXWLRQV XUDQLXP FRQFHQWUDWLRQV DQG HQULFKPHQW WKH EHQFKPDUN DQG 6+,1(

$R$V FRUUHVSRQG YHU\ ZHOO 7KHUHIRUH LW LV MXGJHG WKDW WKH $R$ RI WKH YDOLGDWLRQ UHVXOWV LV VXIILFLHQWO\UHSUHVHQWDWLYHRIWKH6+,1(V\VWHP

&21&/86,216

7KHIROORZLQJFRQFOXVLRQVFDQEHGUDZQIURPWKHDERYHUHVXOWV

x 7KH0&13FDOFXODWLRQVDJUHHYHU\ZHOOZLWKWKHEHQFKPDUNVDPSOHFDOFXODWLRQVZLWK WKHDYHUDJHUHDFWLYLW\GLIIHUHQFHHTXLYDOHQWWR>3URSULHWDU\,QIRUPDWLRQ@

x ,W LV MXGJHG WKDW GHVSLWH GLIIHUHQFHV EHWZHHQ WKH 6+,1( DQG EHQFKPDUN H[SHULPHQW

$R$V WKH $R$ RI WKH YDOLGDWLRQ UHVXOWV LV VXIILFLHQWO\ UHSUHVHQWDWLYH RI WKH 6+,1(

V\VWHP JLYHQ WKH FORVH FRUUHVSRQGHQFH ZLWK UHVSHFW WR XUDQ\O VXOIDWH FRPSRVLWLRQ

HQULFKPHQWDQGFRQFHQWUDWLRQ

1RWHWKDWWKH$1(&)YDOXHOLVWHGIRUWKH6+,1(V\VWHPUHSUHVHQWVWKH$1(&)DYHUDJHGRYHUWKHHQWLUH

6+,1(V\VWHP LH769DQGQHXWURQPXOWLSOLHUUHJLRQ 7KH$1(&)IRUWKH769DORQHLVDSSUR[LPDWHO\

0H9

$OWKRXJKWKH>3URSULHWDU\,QIRUPDWLRQ@

LWKUHVSHFWWRHQULFKPHQWPRVWRIWKHEHQFKPDUNFDVHVKDYHDVLJQLILFDQWO\KLJKHUHQULFKPHQWWKDQWKH

6+,1( V\VWHP EXW WKH ,(862/7+(50 FDVHV LQYROYH HQULFKPHQWV ZHOO ZLWKLQ WKH H[WUDSRODWLRQ

OLPLWUHFRPPHQGHGE\5HIHUHQFH ZW8

6+,1(0HGLFDO7HFKQRORJLHV

16$756+1

5HY

%DVHGRQWKHDERYHSRLQWVLWLVMXGJHGWKDWWKH0&13FDOFXODWLRQDOWHFKQLTXHVHPSOR\HGIRU

6+,1(QHXWURQLFVFDOFXODWLRQVDUHVXIILFLHQWO\DFFXUDWHWRHVWDEOLVKWKH6+,1(VDIHW\EDVLVZLWK

WKHXVHRIVXLWDEO\FRQVHUYDWLYHPRGHOLQJFRQYHQWLRQVDQGDVVXPSWLRQV

3DJHRI

6+,1(0HGLFDO7HFKQRORJLHV

16$756+1

5HY

5()(5(1&(6

International Handbook of Evaluated Criticality Safety Benchmark Experiments

1($1&6'2& 2UJDQL]DWLRQ IRU (FRQRPLF &RRSHUDWLRQ DQG 'HYHORSPHQW

6HSWHPEHU

MCNP - A General Monte Carlo N-Particle Transport Code, Version 5.0/$85

/RV$ODPRV1DWLRQDO/DERUDWRU\

5HYROLQVNL60Core i7 Linux Computer with Scale 6.0, MCNP 5 1.50 and MCNP 5 1.60

16$6050D\

251/70 ORIGEN-S: Depletion Module to Calculate Neutron Activation, Actinide Transmutation, Fission Product Generation, and Radiation Source Terms9HUVLRQ

6HFWLRQ)-XQH

5HYROLQVNL60Installation and Verification of Scale 6.1 on the Linux Computers16$

6050D\

Forecast of Criticality Benchmark Experiments and Experimental Programs Needed to Support Nuclear Operations in the United States of America: 1994-1999 /$

$SSHQGL[( /RV$ODPRV0DUFK

16$756+1 Initial Hazard Analysis for the SHINE Medical Isotope Production Facility5HY$-XQH

Steady-state Neutronics Methods for Power Reactor Analysis $16,$16

$PHULFDQ1XFOHDU6RFLHW\

3DJHRI

>3URSULHWDU\,QIRUPDWLRQ:LWKKHOGIURPSXEOLFGLVFORVXUHXQGHU&)5 D @

6+,1(0HGLFDO7HFKQRORJLHV

16$756+1

5HY

$33(1',;$0&13,1387),/(6

110 3 1.00102-1 -100 -106 u=4 imp:n=1

&DVHLVW 111 2 8.69368-2 100 -101 -106 u=4 imp:n=1 112 3 1.00102-1 -102 106 u=4 imp:n=1 IEU-SOL-THERM-001, Case1 w/ ENDF7 x-sections 113 2 8.69368-2 102 -103 106 u=4 imp:n=1 and thermal S(a,b) 115 0 (101 -106):(103 106) u=4 imp:n=1 c *** channel under solution 116 0 124 -125 lat=1 fill=4 u=5 imp:n=1 c channel void 119 0 -130 131 144 -145 fill=5 imp:n=1 1 0 ((-9 -12):(-8 12 -23)) imp:n=1 $ first c

channel c channel 4 2 like 1 but trcl=(5.3 -5.3 0) 300 0 -600 -5 1000 imp:n=1 3 like 1 but trcl=(-5.3 5.3 0) c chanel 5 6 7 8 9 c

200 0 -700 -5 50 imp:n=1 c channel thickness 201 like 200 but trcl=(20 0 0) 11 2 8.69368-2 ((-10 9 -12):(-11 8 12 -23))

202 like 200 but trcl=(50 0 0) imp:n=1 203 like 200 but trcl=(50 -20.5 0) 12 like 11 but trcl=(5.3 -5.3 0) c vertical channel 13 like 11 but trcl=(-5.3 5.3 0) 204 0 -800 801 -802 803 804 -401 imp:n=1 c *** supply pipe c

50 3 1.00102-1 23 16 imp:n=1 c cleareance 51 2 8.69368-2 14 23 16 imp:n=1 250 0 -20 4 6 -5 imp:n=1 c *** outlet pipe c ****** Graphite reflector 52 3 1.00102-1 23 19 imp:n=1 c

53 2 8.69368-2 17 23 19 imp:n=1 400 4 8.5235-2 ((-302 -500):(500 -304))

c ***** Core

((303 -500):(305 500)) -301 300 -5 c inside vessel solution 1000 4 1 9.85239-2 ((-1 -6):(-3 -13 6))

1 #2 #3 #4 #41 #5 #9 #11 #12 #13

1 #2 #3 #11 #12 #13

50 #51 #52 #53 Proprietary Information

250

50 #51 #52 #53 #109 #119 #120 #121

109 #120 #121 #122 #123

122 #123 imp:n=1

300 #200 #201 #202 #203 #204 c inside vessel void imp:n=1 41 0 -3 13 -21 C *****Shield

1 #2 #3 #11 #12 #13 500 5 1.1964-1

119 #120 #121 #122 #123

(((302 -500):(304 500)):301:

50 #51 #52 #53 imp:n=1

-300:((-303 -500):(-305 500)) )

c

-402 403 400 -401 -5 1000 c **** Core thickness

1 #2 #3 #4 #41 #5 5 2 8.69368-2 (-2 1 -6):(3 21 6)

50 #51 #52 #53 #204 imp:n=1 imp:n=1 $ core thickness C *** UPPER PLATE c

520 2 8.69368-2 -24 22 -402 403 400 -401 c *****lid

1 #2 #3 #11 #12 #13 9 2 8.69368-2 -4 21 -7

50 #51 #52 #53 imp:n=1

1 #2 #3 #11 #12 #13 c **** VOid

50 #51 #52 #53 600 0 5 402 403 400 -401 imp:n=1 $ vessel lid

9 #1 #2 #3 #11 #12 #13 #41 #5 c

50 #51 #52 #53 imp:n=1 c *****spiral 1000 0 402:-403:-400:401:24:-1000 imp:n=0 $

c in solution outside 100 3 1.00102-1 -100 -106 u=3 imp:n=1 101 2 8.69368-2 100 -101 -106 u=3 imp:n=1 1 sz 60.15 15.25 $ inner bot of the core 102 3 1.00102-1 -102 106 u=3 imp:n=1 vessel 103 2 8.69368-2 102 -103 106 u=3 imp:n=1 2 sz 60.15 15.75 $ outer bot of the core 105 1 9.85239-2 (101 -106):(103 106) u=3 vessel imp:n=1 3 cz 15.25 $ inner cylinder of the core 106 0 124 -125 lat=1 fill=3 u=2 imp:n=1 vessel 109 0 -130 131 134 -135 fill=2 imp:n=1 4 cz 15.75 $ outer cylinder of the core c in between vessel 120 3 1.00102-1 -120 -106 imp:n=1 5 pz 110 $ top of the core vessel 121 2 8.69368-2 120 -121 -106 imp:n=1 6 pz 60.15 $ separation between the sphere 122 3 1.00102-1 -122 106 imp:n=1 and the cylin 123 2 8.69368-2 122 -123 106 imp:n=1 7 pz 116.4 $ top of the lid c in void 8 cz 2.4 $ inner chanel in the vessel 3DJHRI

>3URSULHWDU\,QIRUPDWLRQ:LWKKHOGIURPSXEOLFGLVFORVXUHXQGHU&)5 D @

6+,1(0HGLFDO7HFKQRORJLHV

16$756+1

5HY

9 sz 50.5 2.4 $ inner bot of the channel 1001.70c 6.2040-2 10 sz 50.5 2.6 $ outer bot of the channel 8016.70c 3.5118-2 11 cz 2.6 $ channel thickness 16032.70c 6.9799-4 12 pz 50.5 $ separation between the sphere mt1 lwtr.10t and the cylin channel c c c **** material 2 vessel 13 pz 94.14 $ height of the core (44.9+hc) m2 6000.70c 3.1687-4 c 25055.70c 1.7319-3 14 c/z -2.82 10.53 0.3 16032.70c 2.9669-5 15 c/z -2.82 10.53 0.5 15031.70c 5.3759-5 16 pz 56.9 c original m2 isotopes:

17 c/z 2.82 -10.53 0.3 c 24000.50c 1.6469-2 18 c/z 2.82 -10.53 0.5 c 28000.50c 8.1061-3 19 pz 97.9 c 22000.50c 4.9681-4 20 cz 17.25 c 14000.50c 1.3551-3 21 pz 110.5 c 29000.50c 2.2460-4 22 pz 119 c 26000.55c 5.8153-2 23 pz 120.3 c replacements for ENDF7:

24 pz 124 14028.70c 1.2498E-03 c ***torus inner 14029.70c 6.3283E-05 100 tz 0 0 56.9 13.75 0.3 0.3 14030.70c 4.2008E-05 101 tz 0 0 56.9 13.75 0.5 0.5 22046.70c 3.9745E-05 102 tz 0 0 57.9 13.75 0.3 0.3 22047.70c 3.6267E-05 103 tz 0 0 57.9 13.75 0.5 0.5 22048.70c 3.6665E-04 106 p 210.6 56.4 0 0 22049.70c 2.7325E-05 120 tz 0 0 92.9 13.75 0.3 0.3 22050.70c 2.6828E-05 121 tz 0 0 92.9 13.75 0.5 0.5 Proprietary Information 24050.70c 7.1558E-04 122 tz 0 0 93.9 13.75 0.3 0.3 24052.70c 1.3799E-02 123 tz 0 0 93.9 13.75 0.5 0.5 24053.70c 1.5646E-03 124 pz 56.4 24054.70c 3.8949E-04 125 pz 58.4 26054.70c 3.4310E-03 Proprietary Information 130 cz 14.25 26056.70c 5.3338E-02 131 cz 13.25 26057.70c 1.2212E-03 134 pz 56.4 26058.70c 1.6283E-04 135 pz 92.4 28058.70c 5.5340E-03 144 pz 94.4 28060.70c 2.1157E-03 145 pz 98.4 28061.70c 9.1599E-05 c 28062.70c 2.9101E-04 c ********* graphite 28064.70c 7.3766E-05 300 px -75 29063.70c 1.5536E-04 301 px 75 29065.70c 6.9244E-05 400 px -80 mt2 fe56.12t 401 px 80 c 500 px -25 c ***** material 3 water 302 py 65 m3 1001.70c 6.6735-2 303 py -65 8016.70c 3.3367-2 304 py 66 mt3 lwtr.10t 305 py -66 c 402 py 69 c ****material 4 graphite 403 py -69 m4 6000.70c 8.5235-2 1000 pz 0 mt4 grph.10t 50 pz 35 c c channel 4 c ****material 5 poly 600 c/z -62.5 28.5 5.7 m5 5010.70c 3.1268-4 700 c/z -15.0 31.5 5.7 5011.70c 1.2665-3 c vertical channel 6000.70c 3.9354-2 800 pz 60 1001.70c 7.8708-2 801 pz 46 mt5 poly.10t 802 py -18 print 803 py -32 804 px 00

&DVHLVW

kcode 7500 1.0 50 500 ksrc 3 3 50 IEU-SOL-THERM-001, Case2 w/ ENDF7 x-sections c **** material 1 solution and thermal S(a,b) m1 92234.70c 1.0419-6 Proprietary c *** channel Information under solution 92235.70c 1.3972-4 c channel void 92236.70c 1.4092-6 1 0 ((-9 -12):(-8 12 -23)) imp:n=1 $ first 92238.70c 5.2571-4 channel 3DJHRI

>3URSULHWDU\,QIRUPDWLRQ:LWKKHOGIURPSXEOLFGLVFORVXUHXQGHU&)5 D @

6+,1(0HGLFDO7HFKQRORJLHV

16$756+1

5HY

2 like 1 but trcl=(5.3 -5.3 0) 204 0 -800 801 -802 803 804 -401 imp:n=1 3 like 1 but trcl=(-5.3 5.3 0) c c c cleareance c channel thickness 250 0 -20 4 6 -5 imp:n=1 11 2 8.69368-2 ((-10 9 -12):(-11 8 12 -23)) c ****** Graphite reflector imp:n=1 c 12 like 11 but trcl=(5.3 -5.3 0) 400 4 8.5235-2 ((-302 -500):(500 -304))

13 like 11 but trcl=(-5.3 5.3 0) ((303 -500):(305 500)) -301 300 -5 c *** supply pipe 1000 50 3 1.00102-1 23 16 imp:n=1 #1 #2 #3 #4 #41 #5 #9 #11 #12 #13 51 2 8.69368-2 14 23 16 imp:n=1 #250 c *** outlet pipe #50 #51 #52 #53 #109 #119 #120 #121 52 3 1.00102-1 23 19 imp:n=1 #122 #123 53 2 8.69368-2 17 23 19 imp:n=1 #300 #200 #201 #202 #203 #204 c ***** Core imp:n=1 c inside vessel solution C *****Shield 4 1 9.8344-2 ((-1 -6):(-3 -13 6)) 500 5 1.1964-1

1 #2 #3 #11 #12 #13 (((302 -500):(304 500)):301:

50 #51 #52 #53 -300:((-303 -500):(-305 500)) )

109 #120 #121 #122 #123 -402 403 400 -401 -5 1000 imp:n=1 #1 #2 #3 #4 #41 #5 c inside vessel void #50 #51 #52 #53 #204 imp:n=1 41 0 -3 13 -21 C *** UPPER PLATE

1 #2 #3 #11 #12 #13 520 2 8.69368-2 -24 22 -402 403 400 -401

119 #120 #121 #122 #123 #1 #2 #3 #11 #12 #13

50 #51 #52 #53 imp:n=1 #50 #51 #52 #53 imp:n=1 c c **** VOid c **** Core thickness 600 0 5 402 403 400 -401 5 2 8.69368-2 (-2 1 -6):(3 21 6) #9 #1 #2 #3 #11 #12 #13 #41 #5 imp:n=1 $ core thickness #50 #51 #52 #53 imp:n=1 c Proprietary Information 1000 0 402:-403:-400:401:24:-1000 imp:n=0 $

c *****lid outside 9 2 8.69368-2 -4 21 -7

1 #2 #3 #11 #12 #13 1 sz 60.15 15.25 $ inner bot of the core

50 #51 #52 #53 vessel imp:n=1 $ vessel lid 2 sz 60.15 15.75 $ outer bot of the core c vessel c *****spiral 3 cz 15.25 $ inner cylinder of the core c in solution vessel 100 3 1.00102-1 -100 -106 u=3 imp:n=1 4 cz 15.75 $ outer cylinder of the core 101 2 8.69368-2 100 -101 -106 u=3 imp:n=1 vessel 102 3 1.00102-1 -102 106 u=3 imp:n=1 5 pz 110 $ top of the core vessel 103 2 8.69368-2 102 -103 106 u=3 imp:n=1 6 pz 60.15 $ separation between the sphere 105 1 9.8344-2 (101 -106):(103 106) u=3 and the cylin imp:n=1 7 pz 116.4 $ top of the lid 106 0 124 -125 lat=1 fill=3 u=2 imp:n=1 8 cz 2.4 $ inner chanel in the vessel 109 0 -130 131 134 -135 fill=2 imp:n=1 9 sz 50.5 2.4 $ inner bot of the channel c in between 10 sz 50.5 2.6 $ outer bot of the channel 120 3 1.00102-1 -120 -106 imp:n=1 11 cz 2.6 $ channel thickness 121 2 8.69368-2 120 -121 -106 imp:n=1 12 pz 50.5 $ separation between the sphere 122 3 1.00102-1 -122 106 imp:n=1 and the cylin channel 123 2 8.69368-2 122 -123 106 imp:n=1 c c in void 13 pz 78.398 $ height of the core (44.9+hc) 110 3 1.00102-1 -100 -106 u=4 imp:n=1 c 111 2 8.69368-2 100 -101 -106 u=4 imp:n=1 14 c/z -2.82 10.53 0.3 112 3 1.00102-1 -102 106 u=4 imp:n=1 15 c/z -2.82 10.53 0.5 113 2 8.69368-2 102 -103 106 u=4 imp:n=1 16 pz 56.9 115 0 (101 -106):(103 106) u=4 imp:n=1 17 c/z 2.82 -10.53 0.3 116 0 124 -125 lat=1 fill=4 u=5 imp:n=1 18 c/z 2.82 -10.53 0.5 119 0 -130 131 144 -145 fill=5 imp:n=1 19 pz 97.9 c 20 cz 17.25 c channel 4 21 pz 110.5 300 0 -600 -5 1000 imp:n=1 22 pz 119 c chanel 5 6 7 8 9 23 pz 120.3 200 0 -700 -5 50 imp:n=1 24 pz 124 201 like 200 but trcl=(20 0 0) c ***torus inner 202 like 200 but trcl=(50 0 0) 100 tz 0 0 56.9 13.75 0.3 0.3 203 like 200 but trcl=(50 -20.5 0) 101 tz 0 0 56.9 13.75 0.5 0.5 c vertical channel 102 tz 0 0 57.9 13.75 0.3 0.3 3DJHRI

>3URSULHWDU\,QIRUPDWLRQ:LWKKHOGIURPSXEOLFGLVFORVXUHXQGHU&)5 D @

6+,1(0HGLFDO7HFKQRORJLHV

16$756+1

5HY

103 tz 0 0 57.9 13.75 0.5 0.5 22048.70c 3.6665E-04 106 p 210.6 56.4 0 0 22049.70c 2.7325E-05 120 tz 0 0 76.9 13.75 0.3 0.3 22050.70c 2.6828E-05 121 tz 0 0 76.9 13.75 0.5 0.5 24050.70c 7.1558E-04 122 tz 0 0 77.9 13.75 0.3 0.3 24052.70c 1.3799E-02 123 tz 0 0 77.9 13.75 0.5 0.5 24053.70c 1.5646E-03 124 pz 56.4 24054.70c 3.8949E-04 125 pz 58.4 26054.70c 3.4310E-03 130 cz 14.25 26056.70c 5.3338E-02 131 cz 13.25 26057.70c 1.2212E-03 134 pz 56.4 26058.70c 1.6283E-04 135 pz 76.4 28058.70c 5.5340E-03 144 pz 78.4 28060.70c 2.1157E-03 145 pz 98.4 28061.70c 9.1599E-05 c 28062.70c 2.9101E-04 c ********* graphite 28064.70c 7.3766E-05 300 px -75 29063.70c 1.5536E-04 301 px 75 Proprietary Information 29065.70c 6.9244E-05 400 px -80 mt2 fe56.12t 401 px 80 c 500 px -25 c ***** material 3 water 302 py 65 m3 1001.70c 6.6735-2 303 py -65 8016.70c 3.3367-2 304 py 66 mt3 lwtr.10t 305 py -66 c 402 py 69 c ****material 4 graphite 403 py -69 m4 6000.70c 8.5235-2 1000 pz 0 mt4 grph.10t 50 pz 35 c c channel 4 c ****material 5 poly 600 c/z -62.5 28.5 5.7 m5 5010.70c 3.1268-4 700 c/z -15.0 31.5 5.7 5011.70c 1.2665-3 c vertical channel 6000.70c 3.9354-2 Proprietary Information 800 pz 60 1001.70c 7.8708-2 801 pz 46 mt5 poly.10t 802 py -18 print 803 py -32 804 px 00

&DVHLVW

kcode 7500 1.0 50 500 ksrc 3 3 50 IEU-SOL-THERM-001, Case3 w/ ENDF7 x-sections c **** material 1 solution and thermal S(a,b) m1 92234.70c 1.5124-6 c *** channel under solution 92235.70c 2.0281-4 c channel void 92236.70c 2.0456-6 1 0 ((-9 -12):(-8 12 -23)) imp:n=1 $ first 92238.70c 7.6310-4 channel 1001.70c 6.0312-2 2 like 1 but trcl=(5.3 -5.3 0) 8016.70c 3.6063-2 3 like 1 but trcl=(-5.3 5.3 0) 16032.70c 9.9959-4 c mt1 lwtr.10t c channel thickness c 11 2 8.69368-2 ((-10 9 -12):(-11 8 12 -23))

c **** material 2 vessel imp:n=1 m2 6000.70c 3.1687-4 12 like 11 but trcl=(5.3 -5.3 0) 25055.70c 1.7319-3 13 like 11 but trcl=(-5.3 5.3 0) 16032.70c 2.9669-5 Proprietary c *** supply pipe Information 15031.70c 5.3759-5 50 3 1.00102-1 23 16 imp:n=1 c original m2 isotopes: 51 2 8.69368-2 14 23 16 imp:n=1 c 24000.50c 1.6469-2 c *** outlet pipe c 28000.50c 8.1061-3 52 3 1.00102-1 23 19 imp:n=1 c 22000.50c 4.9681-4 53 2 8.69368-2 17 23 19 imp:n=1 c 14000.50c 1.3551-3 c ***** Core c 29000.50c 2.2460-4 c inside vessel solution c 26000.55c 5.8153-2 4 1 9.8344-2 ((-1 -6):(-3 -13 6))

c replacements for ENDF7: #1 #2 #3 #11 #12 #13 14028.70c 1.2498E-03 #50 #51 #52 #53 14029.70c 6.3283E-05 #109 #120 #121 #122 #123 14030.70c 4.2008E-05 imp:n=1 22046.70c 3.9745E-05 c inside vessel void 22047.70c 3.6267E-05 41 0 -3 13 -21 3DJHRI

>3URSULHWDU\,QIRUPDWLRQ:LWKKHOGIURPSXEOLFGLVFORVXUHXQGHU&)5 D @

6+,1(0HGLFDO7HFKQRORJLHV

16$756+1

5HY

1 #2 #3 #11 #12 #13 520 2 8.69368-2 -24 22 -402 403 400 -401

119 #120 #121 #122 #123 #1 #2 #3 #11 #12 #13

50 #51 #52 #53 imp:n=1 #50 #51 #52 #53 imp:n=1 c c **** VOid c **** Core thickness 600 0 5 402 403 400 -401 5 2 8.69368-2 (-2 1 -6):(3 21 6) #9 #1 #2 #3 #11 #12 #13 #41 #5 imp:n=1 $ core thickness #50 #51 #52 #53 imp:n=1 c 1000 0 402:-403:-400:401:24:-1000 imp:n=0 $

c *****lid outside 9 2 8.69368-2 -4 21 -7

1 #2 #3 #11 #12 #13 1 sz 60.15 15.25 $ inner bot of the core

50 #51 #52 #53 vessel imp:n=1 $ vessel lid 2 sz 60.15 15.55 $ outer bot of the core c vessel c *****spiral 3 cz 15.25 $ inner cylinder of the core c in solution vessel 100 3 1.00102-1 -100 -106 u=3 imp:n=1 4 cz 15.55 $ outer cylinder of the core 101 2 8.69368-2 100 -101 -106 u=3 imp:n=1 vessel 102 3 1.00102-1 -102 106 u=3 imp:n=1 5 pz 110 $ top of the core vessel 103 2 8.69368-2 102 -103 106 u=3 imp:n=1 6 pz 60.15 $ separation between the sphere 105 1 9.8344-2 (101 -106):(103 106) u=3 and the cylin imp:n=1 7 pz 116.6 $ top of the lid 106 0 124 -125 lat=1 fill=3 u=2 imp:n=1 8 cz 2.4 $ inner chanel in the vessel 109 0 -130 131 134 -135 fill=2 imp:n=1 9 sz 50.5 2.4 $ inner bot of the channel c in between 10 sz 50.5 2.6 $ outer bot of the channel 120 3 1.00102-1 -120 -106 imp:n=1 11 cz 2.6 $ channel thickness 121 2 8.69368-2 120 -121 -106 imp:n=1 12 pz 50.5 $ separation between the sphere 122 3 1.00102-1 -122 106 imp:n=1 and the cylin channel 123 2 8.69368-2 122 -123 106 imp:n=1 c c in void 13 pz 77.151 $ height of the core (44.9+hc) 110 3 1.00102-1 -100 -106 Proprietary u=4 imp:n=1 Information c

111 2 8.69368-2 100 -101 -106 u=4 imp:n=1 14 c/z -2.82 10.53 0.3 112 3 1.00102-1 -102 106 u=4 imp:n=1 15 c/z -2.82 10.53 0.5 113 2 8.69368-2 102 -103 106 u=4 imp:n=1 16 pz 56.9 115 0 (101 -106):(103 106) u=4 imp:n=1 17 c/z 2.82 -10.53 0.3 116 0 124 -125 lat=1 fill=4 u=5 imp:n=1 18 c/z 2.82 -10.53 0.5 119 0 -130 131 144 -145 fill=5 imp:n=1 19 pz 97.9 c 20 cz 17.55 c channel 4 21 pz 110.5 300 0 -600 -5 1000 imp:n=1 22 pz 119 c chanel 5 6 7 8 9 23 pz 120.5 200 0 -700 -5 50 imp:n=1 24 pz 124 201 like 200 but trcl=(20 0 0) c ***torus inner 202 like 200 but trcl=(50 0 0) 100 tz 0 0 56.9 13.75 0.3 0.3 203 like 200 but trcl=(50 -20.5 0) 101 tz 0 0 56.9 13.75 0.5 0.5 c vertical channel 102 tz 0 0 57.9 13.75 0.3 0.3 204 0 -800 801 -802 803 804 -401 imp:n=1 103 tz 0 0 57.9 13.75 0.5 0.5 c 106 p 210.6 56.4 0 0 c cleareance 120 tz 0 0 76.9 13.75 0.3 0.3 250 0 -20 4 6 -5 imp:n=1 121 tz 0 0 76.9 13.75 0.5 0.5 c ****** Graphite reflector 122 tz 0 0 77.9 13.75 0.3 0.3 c 123 tz 0 0 77.9 13.75 0.5 0.5 400 4 8.5235-2 ((-302 -500):(500 -304)) 124 pz 56.4

((303 -500):(305 500)) -301 300 -5 125 pz 58.4 1000 130 cz 14.25

1 #2 #3 #4 #41 #5 #9 #11 #12 #13 131 cz 13.25

250 134 pz 56.4

50 #51 #52 #53 #109 #119 #120 #121 135 pz 76.4

122 #123 144 pz 78.4

300 #200 #201 #202 #203 #204 145 pz 98.4 imp:n=1 c C *****Shield c ********* graphite 500 5 1.1964-1 300 px -75

(((302 -500):(304 500)):301: 301 px 75

-300:((-303 -500):(-305 500)) ) 400 px -80

-402 403 400 -401 -5 1000 401 px 80

1 #2 #3 #4 #41 #5 500 px -25

50 #51 #52 #53 #204 imp:n=1 302 py 65 C *** UPPER PLATE 303 py -65 3DJHRI

>3URSULHWDU\,QIRUPDWLRQ:LWKKHOGIURPSXEOLFGLVFORVXUHXQGHU&)5 D @

6+,1(0HGLFDO7HFKQRORJLHV

16$756+1

5HY

304 py 66 mt3 lwtr.10t 305 py -66 c 402 py 69 c ****material 4 graphite 403 py -69 m4 6000.70c 8.5235-2 1000 pz 0 Proprietary mt4 grph.10t Information 50 pz 35 c c channel 4 c ****material 5 poly 600 c/z -62.5 28.5 5.7 m5 5010.70c 3.1268-4 700 c/z -15.0 31.5 5.7 5011.70c 1.2665-3 c vertical channel 6000.70c 3.9354-2 800 pz 60 1001.70c 7.8708-2 801 pz 46 mt5 poly.10t 802 py -18 print 803 py -32 804 px 00

&DVHLVW

kcode 7500 1.0 50 500 ksrc 3 3 50 IEU-SOL-THERM-001, Case4 w/ ENDF7 x-sections c **** material 1 solution and thermal S(a,b) m1 92234.70c 1.5124-6 c *** channel under solution 92235.70c 2.0281-4 c channel void 92236.70c 2.0456-6 1 0 ((-9 -12):(-8 12 -23)) imp:n=1 $ first 92238.70c 7.6310-4 channel 1001.70c 6.0312-2 2 like 1 but trcl=(5.3 -5.3 0) 8016.70c 3.6063-2 3 like 1 but trcl=(-5.3 5.3 0) 16032.70c 9.9959-4 c mt1 lwtr.10t c channel thickness c 11 2 8.69368-2 ((-10 9 -12):(-11 8 12 -23))

c **** material 2 vessel imp:n=1 m2 6000.70c 3.1687-4 12 like 11 but trcl=(5.3 -5.3 0) 25055.70c 1.7319-3 13 like 11 but trcl=(-5.3 5.3 0) 16032.70c 2.9669-5 c *** supply pipe 15031.70c 5.3759-5 50 3 1.00102-1 23 16 imp:n=1 cProprietary original m2Information isotopes: 51 2 8.69368-2 14 23 16 imp:n=1 c 24000.50c 1.6469-2 c *** outlet pipe c 28000.50c 8.1061-3 52 3 1.00102-1 23 19 imp:n=1 c 22000.50c 4.9681-4 53 2 8.69368-2 17 23 19 imp:n=1 c 14000.50c 1.3551-3 c ***** Core c 29000.50c 2.2460-4 c inside vessel solution c 26000.55c 5.8153-2 4 1 9.77430-2 ((-1 -6):(-3 -13 6))

c replacements for ENDF7: #1 #2 #3 #11 #12 #13 14028.70c 1.2498E-03 Proprietary

50 Information

51 #52 #53 14029.70c 6.3283E-05 #109 #120 #121 #122 #123 14030.70c 4.2008E-05 imp:n=1 22046.70c 3.9745E-05 c inside vessel void 22047.70c 3.6267E-05 41 0 -3 13 -21 22048.70c 3.6665E-04 #1 #2 #3 #11 #12 #13 22049.70c 2.7325E-05 #119 #120 #121 #122 #123 22050.70c 2.6828E-05 #50 #51 #52 #53 imp:n=1 24050.70c 7.1558E-04 c 24052.70c 1.3799E-02 c **** Core thickness 24053.70c 1.5646E-03 5 2 8.69368-2 (-2 1 -6):(3 21 6) 24054.70c 3.8949E-04 imp:n=1 $ core thickness 26054.70c 3.4310E-03 c 26056.70c 5.3338E-02 c *****lid 26057.70c 1.2212E-03 9 2 8.69368-2 -4 21 -7 26058.70c 1.6283E-04 #1 #2 #3 #11 #12 #13 28058.70c 5.5340E-03 #50 #51 #52 #53 28060.70c 2.1157E-03 imp:n=1 $ vessel lid 28061.70c 9.1599E-05 c 28062.70c 2.9101E-04 c *****spiral 28064.70c 7.3766E-05 c in solution 29063.70c 1.5536E-04 100 3 1.00102-1 -100 -106 u=3 imp:n=1 29065.70c 6.9244E-05 101 2 8.69368-2 100 -101 -106 u=3 imp:n=1 mt2 fe56.12t 102 3 1.00102-1 -102 106 u=3 imp:n=1 c 103 2 8.69368-2 102 -103 106 u=3 imp:n=1 c ***** material 3 water 105 1 9.77430-2 (101 -106):(103 106) u=3 m3 1001.70c 6.6735-2 imp:n=1 8016.70c 3.3367-2 106 0 124 -125 lat=1 fill=3 u=2 imp:n=1 3DJHRI

>3URSULHWDU\,QIRUPDWLRQ:LWKKHOGIURPSXEOLFGLVFORVXUHXQGHU&)5 D @

6+,1(0HGLFDO7HFKQRORJLHV

16$756+1

5HY

109 0 -130 131 134 -135 fill=2 imp:n=1 9 sz 50.5 2.4 $ inner bot of the channel c in between 10 sz 50.5 2.6 $ outer bot of the channel 120 3 1.00102-1 -120 -106 imp:n=1 11 cz 2.6 $ channel thickness 121 2 8.69368-2 120 -121 -106 imp:n=1 12 pz 50.5 $ separation between the sphere 122 3 1.00102-1 -122 106 imp:n=1 and the cylin channel 123 2 8.69368-2 122 -123 106 imp:n=1 c c in void 13 pz 73.956 $ height of the core (44.9+hc) 110 3 1.00102-1 -100 -106 u=4 imp:n=1 c 111 2 8.69368-2 100 -101 -106 u=4 imp:n=1 14 c/z -2.82 10.53 0.3 112 3 1.00102-1 -102 106 u=4 imp:n=1 15 c/z -2.82 10.53 0.5 113 2 8.69368-2 102 -103 106 u=4 imp:n=1 16 pz 56.9 115 0 (101 -106):(103 106) u=4 imp:n=1 17 c/z 2.82 -10.53 0.3 116 0 124 -125 lat=1 fill=4 u=5 imp:n=1 18 c/z 2.82 -10.53 0.5 119 0 -130 131 144 -145 fill=5 imp:n=1 19 pz 97.9 c 20 cz 17.25 c channel 4 21 pz 110.5 300 0 -600 -5 1000 imp:n=1 22 pz 119 c chanel 5 6 7 8 9 23 pz 120.3 200 0 -700 -5 50 imp:n=1 24 pz 124 201 like 200 but trcl=(20 0 0) c ***torus inner 202 like 200 but trcl=(50 0 0) 100 tz 0 0 56.9 13.75 0.3 0.3 203 like 200 but trcl=(50 -20.5 0) 101 tz 0 0 56.9 13.75 0.5 0.5 c vertical channel 102 tz 0 0 57.9 13.75 0.3 0.3 204 0 -800 801 -802 803 804 -401 imp:n=1 103 tz 0 0 57.9 13.75 0.5 0.5 c 106 p 210.6 56.4 0 0 c cleareance 120 tz 0 0 72.9 13.75 0.3 0.3 250 0 -20 4 6 -5 imp:n=1 121 tz 0 0 72.9 13.75 0.5 0.5 c ****** Graphite reflector 122 tz 0 0 73.9 13.75 0.3 0.3 c 123 tz 0 0 73.9 13.75 0.5 0.5 400 4 8.5235-2 ((-302 -500):(500 -304)) 124 pz 56.4

((303 -500):(305 500)) -301 300 -5 125 pz 58.4 1000 Proprietary Information 130 cz 14.25

1 #2 #3 #4 #41 #5 #9 #11 #12 #13 131 cz 13.25

250 134 pz 56.4

50 #51 #52 #53 #109 #119 #120 #121 135 pz 72.4

122 #123 144 pz 74.4

300 #200 #201 #202 #203 #204 145 pz 98.4 imp:n=1 c C *****Shield c ********* graphite 500 5 1.1964-1 300 px -75

(((302 -500):(304 500)):301: 301 px 75

-300:((-303 -500):(-305 500)) ) 400 px -80

-402 403 400 -401 -5 1000 401 px 80

1 #2 #3 #4 #41 #5 500 px -25

50 #51 #52 #53 #204 imp:n=1 302 py 65 C *** UPPER PLATE 303 py -65 520 2 8.69368-2 -24 22 -402 403 400 -401 304 py 66

1 #2 #3 #11 #12 #13 305 py -66

50 #51 #52 #53 imp:n=1 402 py 69 c **** VOid 403 py -69 600 0 5 402 403 400 -401 1000 pz 0

9 #1 #2 #3 #11 #12 #13 #41 #5 50 pz 35

50 #51 #52 #53 imp:n=1 c channel 4 1000 0 402:-403:-400:401:24:-1000 imp:n=0 $ 600 c/z -62.5 28.5 5.7 outside 700 c/z -15.0 31.5 5.7 c vertical channel 1 sz 60.15 15.25 $ inner bot of the core 800 pz 60 vessel 801 pz 46 2 sz 60.15 15.75 $ outer bot of the core 802 py -18 vessel 803 py -32 3 cz 15.25 $ inner cylinder of the core 804 px 00 vessel 4 cz 15.75 $ outer cylinder of the core kcode 7500 1.0 50 500 vessel ksrc 3 3 50 5 pz 110 $ top of the core vessel c **** material 1 solution 6 pz 60.15 $ separation between the sphere m1 92234.70c 1.9983-6 and the cylin 92235.70c 2.6798-4 7 pz 116.4 $ top of the lid 92236.70c 2.7028-6 8 cz 2.4 $ inner chanel in the vessel 92238.70c 1.0083-3 3DJHRI

>3URSULHWDU\,QIRUPDWLRQ:LWKKHOGIURPSXEOLFGLVFORVXUHXQGHU&)5 D @

6+,1(0HGLFDO7HFKQRORJLHV

16$756+1

5HY

1001.70c 5.8250-2 1 1 0.100174 1 imp:n=1 $

8016.70c 3.6901-2 solution in cylindrical part of tank 16032.70c 1.3111-3 2 1 0.100174 -3 imp:n=1 $

mt1 lwtr.10t solution in tapered base of tank c 3 1 0.100174 -4 imp:n=1 $

c **** material 2 vessel solution in drain tube m2 6000.70c 3.1687-4 4 2 4.3243E-02 3 -5 7 imp:n=1 $

25055.70c 1.7319-3 Zircaloy-2 tapered base of tank 16032.70c 2.9669-5 5 2 4.3243E-02 2 3 -6 8 14 imp:n=1 $

15031.70c 5.3759-5 Zircaloy-2 cylindrical part of tank c original m2 isotopes: 6 2 4.3243E-02 4 -7 imp:n=1 $

c 24000.50c 1.6469-2 Zircaloy-2 drain tube c 28000.50c 8.1061-3 7 3 5.3248E-05 -8 1 imp:n=1 $

c 22000.50c 4.9681-4 air above solution c 14000.50c 1.3551-3 8 3 5.3248E-05 -9 6 5 10 imp:n=1 $

c 29000.50c 2.2460-4 air around Zircaloy-2 tank c 26000.55c 5.8153-2 9 3 5.3248E-05 -10 5 7 imp:n=1 $

c replacements for ENDF7: air around Zircaloy-2 tube 14028.70c 1.2498E-03 10 4 5.9544E-02 -11 9 12 imp:n=1 $

14029.70c 6.3283E-05 Al-alloy tank 14030.70c 4.2008E-05 11 4 5.9544E-02 -12 10 imp:n=1 $

22046.70c 3.9745E-05 Al-alloy tube 22047.70c 3.6267E-05 12 4 5.9544E-02 -13 11 imp:n=1 $

22048.70c 3.6665E-04 Al-alloy tank lip 22049.70c 2.7325E-05 13 2 4.3243E-02 -14 8 imp:n=1 $

22050.70c 2.6828E-05 Zircaloy-2 tank lip 24050.70c 7.1558E-04 14 5 7.7673E-02 -15 8 imp:n=1 $

24052.70c 1.3799E-02 Teflon gasket/tank lip Proprietary Information 24053.70c 1.5646E-03 15 4 5.9544E-02 -16 17 19 21 imp:n=1 $

24054.70c 3.8949E-04 Al-alloy tank cover 26054.70c 3.4310E-03 16 4 5.9544E-02 -17 18 imp:n=1 $

26056.70c 5.3338E-02 Proprietary Al-alloy center top tubeInformation

(#1) 26057.70c 1.2212E-03 17 4 5.9544E-02 -19 20 imp:n=1 $

26058.70c 1.6283E-04 Al-alloy center top tube (#2) 28058.70c 5.5340E-03 18 4 5.9544E-02 -21 22 imp:n=1 $

28060.70c 2.1157E-03 Al-alloy center top tube (#3) 28061.70c 9.1599E-05 19 3 5.3248E-05 -18 imp:n=1 $

28062.70c 2.9101E-04 air in tube #1 28064.70c 7.3766E-05 20 3 5.3248E-05 -20 imp:n=1 $

29063.70c 1.5536E-04 air in tube #2 29065.70c 6.9244E-05 21 3 5.3248E-05 -22 imp:n=1 $

mt2 fe56.12t air in tube #3 c 30 6 1.4204E-01 -30 11 12 13 14 15 16 17 19 c ***** material 3 water 21 m3 1001.70c 6.6735-2 41 43 47 49 50 51 imp:n=1 8016.70c 3.3367-2 $ BeO section #1 mt3 lwtr.10t 31 6 1.4204E-01 -31 30 12 17 19 21 c 41 43 47 49 imp:n=1 $

c ****material 4 graphite BeO section #2 m4 6000.70c 8.5235-2 32 6 1.4204E-01 -32 31 41 43 imp:n=1 $

mt4 grph.10t BeO section #3 c 33 6 1.4204E-01 -33 17 19 21 imp:n=1 $

c ****material 5 poly BeO top section #4 m5 5010.70c 3.1268-4 34 4 5.9544E-02 -34 17 19 21 imp:n=1 $

5011.70c 1.2665-3 Al-alloy BeO cover 6000.70c 3.9354-2 35 7 8.2737E-02 -35 12 17 19 21 30 31 32 33 1001.70c 7.8708-2 34 mt5 poly.10t 41 43 44 45 47 49 50 51 52 53 imp:n=1 print $ Graphite 40 3 5.3248E-05 -40 imp:n=1 $

air, reflector channel #1

&DVHSURV 41 4 5.9544E-02 -41 40 imp:n=1 $

Al-alloy, reflector channel #1 Proserpine case1, 36.588g U235/L (Table 1) 42 3 5.3248E-05 -42 imp:n=1 $

c Benchmark HEU-SOL-THERM-046, h(crit) = air, reflector channel #2 surface 1Proprietary

= Table 1 & 32 43 4 5.9544E-02 -43 42 imp:n=1 $

Information c Dimensions & materials from HEU-SOL-THERM- Al-alloy, reflector channel #2 046 sections 3.1 - 3.3 44 3 5.3248E-05 -44 imp:n=1 $

air, reflector channel #3 3DJHRI

>3URSULHWDU\,QIRUPDWLRQ:LWKKHOGIURPSXEOLFGLVFORVXUHXQGHU&)5 D @

6+,1(0HGLFDO7HFKQRORJLHV

16$756+1

5HY

45 3 5.3248E-05 -45 imp:n=1 $ 31 rpp -30 30 -35 35 -30.5 60.7 $

air, reflector channel #4 BeO reflector section #2 46 3 5.3248E-05 -46 imp:n=1 $ 32 rpp -20 20 -40 40 -30.5 60.7 $

air, reflector channel #5 BeO reflector section #3 47 4 5.9544E-02 -47 46 imp:n=1 $ 33 rpp -15 15 -15 15 60.7 63.2 $

Al-alloy, reflector channel #5 BeO reflector section #4 (top/cover) 48 3 5.3248E-05 -48 imp:n=1 $ 34 rpp -20 20 -20 20 63.2 65.2 $

air, reflector channel #6 Al-alloy BeO reflector top/cover 49 4 5.9544E-02 -49 48 imp:n=1 $ 35 rpp -90 90 -90 90 -80.5 110.7 $

Al-alloy, reflector channel #6 Graphite reflector 50 3 5.3248E-05 -50 11 imp:n=1 $ 40 rcc 15 -90 4.5 0 180 0 1.5 $

air, reflector channel #7 air, y-axis channel #1 ID 51 3 5.3248E-05 -51 11 imp:n=1 $ 41 rcc 15 -90 4.5 0 180 0 1.7 $

air, reflector channel #8 Al-alloy tube, y-axis channel #1 OD 52 3 5.3248E-05 -52 imp:n=1 $ 42 rcc 90 4.5 0 180 0 1.5 $

air, reflector channel #9 air, y-axis channel #2 ID 53 3 5.3248E-05 -53 imp:n=1 $ 43 rcc 90 4.5 0 180 0 1.7 $

air, reflector channel #10 Al-alloy tube, y-axis channel #2 OD 99 0 35 imp:n=0 $ 44 rcc 50 -90 4.5 0 180 0 2.5 $

outside world air, y-axis channel #3 ID 45 rcc 90 4.5 0 180 0 2.5 $

1 pz 23.875 $ air, y-axis channel #4 ID critical h of solution from base of tapered 46 rcc 25 -90 14.5 0 180 0 0.6 $

base air, y-axis channel #5 ID 2 rcc 0 0 0.87 0 0 23.005 12.5 $ 47 rcc 25 -90 14.5 0 180 0 0.8 $

solution in cylindrical part of tank (max Al-alloy tube, y-axis channel #5 OD critical h) 48 rcc 90 14.5 0 180 0 0.6 $

3 trc 0 0 0 0 0 0.87 0.3 12.5 $ air, y-axis channel #6 ID solution in tapered base 49 rcc 90 14.5 0 180 0 0.8 $

4 rcc 0 0 0 0 0 -80.5 0.3 $ Al-alloy tube, y-axis channel #6 OD solution in drain tube 50 rcc -90 0 9.5 180 0 0 0.9 $

5 trc 0 0 -0.0931 0 0 0.87 0.4 12.6 $ air, x-axis channel #7 ID Zircaloy-2 tank tapered base 51 rcc -90 0 19.5 180 0 0 0.6 $

6 rcc 0 0 0.7769 0 0 29.0 Proprietary 12.6 $ Information air, x-axis channel #8 ID Zircaloy-2 cylindrical tank 52 rcc -90 50 9.5 180 0 0 2.5 $

7 rcc 0 0 0 0 0 -80.5 0.4 $ air, x-axis channel #9 ID (assumed z, Zircaloy-2 drain tube dimension not shown) 8 rcc 0 0 30.7 0 0 -15.16 12.5 $ 53 rcc 50 9.5 180 0 0 2.5 $

air above solution (min critical h) air, x-axis channel #10 ID (assumed z, 9 rcc 0 0 -0.3 0 0 30.0 12.9 $ dimension not shown) air around Zircaloy-2 tank 10 rcc 0 0 0 0 0 -80.5 0.7 $ c UO2SO4 solution (mass density = 1.05607 air around Zircaloy-2 drain tube g/cc) 11 rcc 0 0 -0.5 0 0 30.2 13.1 $ m1 92234.70c 8.0385E-07 Al-alloy tank 92235.70c 9.3399E-05 12 rcc 0 0 -0.3 0 0 -80.2 0.9 $ 92236.70c 1.8632E-07 Al-alloy drain tube 92238.70c 9.4426E-06 13 rpp -15 15 -15 15 29.5 29.7 $ 1001.70c 6.6149E-02 Al-alloy tank lip 8016.70c 3.3787E-02 14 rpp -15 15 -15 15 29.7 29.8 $ 16032.70c 1.3383E-04 Zircaloy-2 tank lip mt1 lwtr.10t 15 rpp -15 15 -15 15 29.8 30.7 $ c Zircaloy-2 (mass density = 6.56 g/cc)

Teflon gasket/tank lip m2 40090.70c 2.1893E-02 16 rpp -15 15 -15 15 30.7 33.5 $ 40091.70c 4.7743E-03 Al-alloy tank cover 40092.70c 7.2977E-03 17 rcc 0 0 30.7 0 0 80 1.0 $ 40094.70c 7.3955E-03 Al-alloy center top tube #1 OD 40096.70c 1.1915E-03 18 rcc 0 0 30.7 0 0 80 0.9 $ 50112.70c 4.6806E-06 Al-alloy center top tube #1 ID 50114.70c 3.1365E-06 19 rcc 10 0 30.7 0 0 80 1.0 $ 50115.70c 1.7371E-06 Al-alloy 2nd 2cmOD top tube #2 50116.70c 7.0113E-05 20 rcc 10 0 30.7 0 0 80 0.9 $ 50117.70c 3.7059E-05 Al-alloy 2nd 2cmOD top tube #2 ID 50118.70c 1.1687E-04 21 rcc -10 0 30.7 0 0 80 0.5 $ 50119.70c 4.1402E-05 Al-alloy 1cmOD top tube #3 50120.70c 1.5726E-04 22 rcc -10 0 30.7 0 0 80 0.4 $ 50122.70c 2.2342E-05 Al-alloy 1cmOD top tube #3 ID 50124.70c 2.7939E-05 30 rpp -40 40 -25 25 -20.5 50.7 $ 26054.70c 5.8429E-06 BeO reflector section #1 26056.70c 9.0833E-05 3DJHRI

>3URSULHWDU\,QIRUPDWLRQ:LWKKHOGIURPSXEOLFGLVFORVXUHXQGHU&)5 D @

6+,1(0HGLFDO7HFKQRORJLHV

16$756+1

5HY

26057.70c 2.0797E-06 82207.70c 5.6846E-09 26058.70c 2.7729E-07 82208.70c 1.3478E-08 24050.70c 3.3012E-06 28058.70c 6.1995E-08 24052.70c 6.3661E-05 28060.70c 2.3701E-08 24053.70c 7.2178E-06 28061.70c 1.0261E-09 24054.70c 1.7969E-06 28062.70c 3.2600E-09 28058.70c 2.2977E-05 28064.70c 8.2636E-10 28060.70c 8.7842E-06 6000.70c 1.4791E-04 28061.70c 3.8031E-07 5010.70c 9.8103E-09 28062.70c 1.2083E-06 5011.70c 3.9488E-08 28064.70c 3.0627E-07 mt6 be/o.10t o/be.10t al27.12t fe56.12t mt2 fe56.12t c Graphite (mass density = 1.65 g/cc) c air m7 6000.70c 8.2718E-02 m3 7014.70c 4.1985E-5 5010.70c 3.6580E-09 8016.70c 1.1263E-5 5011.70c 1.4724E-08 c AL-alloy (mass density = 2.66 g/cc) 1001.70c 1.6267E-05 m4 13027.70c 5.7529E-02 11023.70c 8.2120E-07 12024.70c 1.5618E-03 20040.70c 7.2103E-07 12025.70c 1.9772E-04 20042.70c 4.8123E-09 12026.70c 2.1769E-04 20043.70c 1.0041E-09 26054.70c 6.0080E-07 20044.70c 1.5515E-08 26056.70c 9.3398E-06 20046.70c 2.9751E-11 26057.70c 2.1384E-07 20048.70c 1.3909E-09 26058.70c 2.8512E-08 62149.70c 1.1343E-10 14028.70c 1.8411E-05 Proprietary 22046.70c Information 8.3008E-09 14029.70c 9.3223E-07 22047.70c 7.5745E-09 14030.70c 6.1882E-07 22048.70c 7.6575E-08 22046.70c 1.6059E-07 22049.70c 5.7068E-09 22047.70c 1.4654E-07 22050.70c 5.6030E-09 22048.70c 1.4815E-06 26054.70c 2.0995E-09 22049.70c 1.1041E-07 26056.70c 3.2639E-08 22050.70c 1.0840E-07 26057.70c 7.4729E-10 Proprietary 25055.70c Information 8.7474E-07 26058.70c 9.9638E-11 23000.70c 9.4337E-07 42092.70c 1.5537E-08 30000.70c 4.2870E-06 42094.70c 9.6848E-09 mt4 al27.12t fe56.12t 42095.70c 1.6668E-08 c Teflon (mass density = 2.15 g/cc) 42096.70c 1.7464E-08 m5 6000.70c 2.5891E-02 42097.70c 9.9989E-09 9019.70c 5.1782E-02 42098.70c 2.5264E-08 c 42100.70c 1.0083E-08 c BeO (mass density = 2.95 g/cc) 23000.70c 6.2418E-07 m6 4009.70c 7.0937E-02 17035.70c 7.4327E-08 8016.70c 7.0937E-02 17037.70c 2.3768E-08 13027.70c 9.8763E-06 mt7 grph.10t fe56.12t 26054.70c 9.3840E-08 kcode 10000 1.0 50 600 26056.70c 1.4588E-06 ksrc 0 0 5 26057.70c 3.3401E-08 print 26058.70c 4.4534E-09 14028.70c 2.9170E-06 14029.70c 1.4770E-07 &DVHSURV

14030.70c 9.8044E-08 12024.70c 2.8868E-07 Proserpine case2, 37.597g U235/L (Table 1) 12025.70c 3.6546E-08 c Benchmark HEU-SOL-THERM-046, h(crit) =

12026.70c 4.0237E-08 surface 1 = Table 1 & 32 25055.70c 3.2337E-08 c Dimensions & materials from HEU-SOL-THERM-48106.70c 5.9265E-11 046 sections 3.1 - 3.3 48108.70c 4.2197E-11 1 1 0.100176 1 imp:n=1 $

48110.70c 5.9218E-10 solution in cylindrical part of tank 48111.70c 6.0687E-10 2 1 0.100176 -3 48112.70c 1.1441E-09 Proprietary Informationimp:n=1 $

solution in tapered base of tank 48113.70c 5.7937E-10 3 1 0.100176 -4 imp:n=1 $

48114.70c 1.3621E-09 solution in drain tube 48116.70c 3.5512E-10 4 2 4.3243E-02 3 -5 7 imp:n=1 $

47107.70c 4.2281E-09 Zircaloy-2 tapered base of tank 47109.70c 3.9282E-09 5 2 4.3243E-02 2 3 -6 8 14 imp:n=1 $

29063.70c 1.9337E-07 Zircaloy-2 cylindrical part of tank 29065.70c 8.6188E-08 6 2 4.3243E-02 4 -7 imp:n=1 $

82204.70c 3.6011E-10 Zircaloy-2 drain tube 82206.70c 6.1990E-09 3DJHRI

>3URSULHWDU\,QIRUPDWLRQ:LWKKHOGIURPSXEOLFGLVFORVXUHXQGHU&)5 D @

6+,1(0HGLFDO7HFKQRORJLHV

16$756+1

5HY

7 3 5.3248E-05 -8 1 imp:n=1 $ 51 3 5.3248E-05 -51 11 imp:n=1 $

air above solution air, reflector channel #8 8 3 5.3248E-05 -9 6 5 10 imp:n=1 $ 52 3 5.3248E-05 -52 imp:n=1 $

air around Zircaloy-2 tank air, reflector channel #9 9 3 5.3248E-05 -10 5 7 imp:n=1 $ 53 3 5.3248E-05 -53 imp:n=1 $

air around Zircaloy-2 tube air, reflector channel #10 10 4 5.9544E-02 -11 9 12 imp:n=1 $ 99 0 35 imp:n=0 $

Al-alloy tank outside world 11 4 5.9544E-02 -12 10 imp:n=1 $

Al-alloy tube 1 pz 22.785 $

12 4 5.9544E-02 -13 11 imp:n=1 $ critical h of solution from base of tapered Al-alloy tank lip base 13 2 4.3243E-02 -14 8 imp:n=1 $ 2 rcc 0 0 0.87 0 0 23.005 12.5 $

Zircaloy-2 tank lip solution in cylindrical part of tank (max 14 5 7.7673E-02 -15 8 imp:n=1 $ critical h)

Teflon gasket/tank lip 3 trc 0 0 0 0 0 0.87 0.3 12.5 $

15 4 5.9544E-02 -16 17 19 21 imp:n=1 $ solution in tapered base Al-alloy tank cover 4 rcc 0 0 0 0 0 -80.5 0.3 $

16 4 5.9544E-02 -17 18 imp:n=1 $ solution in drain tube Al-alloy center top tube (#1) 5 trc 0 0 -0.0931 0 0 0.87 0.4 12.6 $

17 4 5.9544E-02 -19 20 imp:n=1 $ Zircaloy-2 tank tapered base Al-alloy center top tube (#2) 6 rcc 0 0 0.7769 0 0 29.0 12.6 $

18 4 5.9544E-02 -21 22 imp:n=1 $ Zircaloy-2 cylindrical tank Al-alloy center top tube (#3) 7 rcc 0 0 0 0 0 -80.5 0.4 $

19 3 5.3248E-05 -18 imp:n=1 $ Zircaloy-2 drain tube air in tube #1 8 rcc 0 0 30.7 0 0 -15.16 12.5 $

20 3 5.3248E-05 -20 imp:n=1 $ air above solution (min critical h) air in tube #2 9 rcc 0 0 -0.3 0 0 30.0 12.9 $

21 3 5.3248E-05 -22 imp:n=1 $ air around Zircaloy-2 tank air in tube #3 10 rcc 0 0 0 0 0 -80.5 0.7 $

30 6 1.4204E-01 -30 11 12 13 14 15 16 17 19 air around Zircaloy-2 drain tube 21 Proprietary Information 11 rcc 0 Proprietary 0 -0.5 Information 0 0 30.2 13.1 $

41 43 47 49 50 51 imp:n=1 Al-alloy tank

$ BeO section #1 12 rcc 0 0 -0.3 0 0 -80.2 0.9 $

31 6 1.4204E-01 -31 30 12 17 19 21 Al-alloy drain tube 41 43 47 49 imp:n=1 $ 13 rpp -15 15 -15 15 29.5 29.7 $

BeO section #2 Al-alloy tank lip 32 6 1.4204E-01 -32 31 41 43 imp:n=1 $ 14 rpp -15 15 -15 15 29.7 29.8 $

BeO section #3 Zircaloy-2 tank lip 33 6 1.4204E-01 -33 17 19 21 imp:n=1 $ 15 rpp -15 15 -15 15 29.8 30.7 $

BeO top section #4 Teflon gasket/tank lip 34 4 5.9544E-02 -34 17 19 21 imp:n=1 $ 16 rpp -15 15 -15 15 30.7 33.5 $

Al-alloy BeO cover Al-alloy tank cover 35 7 8.2737E-02 -35 12 17 19 21 30 31 32 33 17 rcc 0 0 30.7 0 0 80 1.0 $

34 Al-alloy center top tube #1 OD 41 43 44 45 47 49 50 51 52 53 imp:n=1 18 rcc 0 0 30.7 0 0 80 0.9 $

$ Graphite Al-alloy center top tube #1 ID 40 3 5.3248E-05 -40 imp:n=1 $ 19 rcc 10 0 30.7 0 0 80 1.0 $

air, reflector channel #1 Al-alloy 2nd 2cmOD top tube #2 41 4 5.9544E-02 -41 40 imp:n=1 $ 20 rcc 10 0 30.7 0 0 80 0.9 $

Al-alloy, reflector channel #1 Al-alloy 2nd 2cmOD top tube #2 ID 42 3 5.3248E-05 -42 imp:n=1 $ 21 rcc -10 0 30.7 0 0 80 0.5 $

air, reflector channel #2 Al-alloy 1cmOD top tube #3 43 4 5.9544E-02 -43 42 imp:n=1 $ 22 rcc -10 0 30.7 0 0 80 0.4 $

Al-alloy, reflector channel #2 Al-alloy 1cmOD top tube #3 ID 44 3 5.3248E-05 -44 imp:n=1 $ 30 rpp -40 40 -25 25 -20.5 50.7 $

air, reflector channel #3 BeO reflector section #1 45 3 5.3248E-05 -45 imp:n=1 $ 31 rpp -30 30 -35 35 -30.5 60.7 $

air, reflector channel #4 BeO reflector section #2 46 3 5.3248E-05 -46 imp:n=1 $ 32 rpp -20 20 -40 40 -30.5 60.7 $

air, reflector channel #5 BeO reflector section #3 47 4 5.9544E-02 -47 46 imp:n=1 $ 33 rpp -15 15 -15 15 60.7 63.2 $

Al-alloy, reflector channel #5 BeO reflector section #4 (top/cover) 48 3 5.3248E-05 -48 imp:n=1 $ 34 rpp -20 20 -20 20 63.2 65.2 $

air, reflector channel #6 Al-alloy BeO reflector top/cover 49 4 5.9544E-02 -49 48 imp:n=1 $ 35 rpp -90 90 -90 90 -80.5 110.7 $

Al-alloy, reflector channel #6 Graphite reflector 50 3 5.3248E-05 -50 11 imp:n=1 $ 40 rcc 15 -90 4.5 0 180 0 1.5 $

air, reflector channel #7 air, y-axis channel #1 ID 3DJHRI

>3URSULHWDU\,QIRUPDWLRQ:LWKKHOGIURPSXEOLFGLVFORVXUHXQGHU&)5 D @

6+,1(0HGLFDO7HFKQRORJLHV

16$756+1

5HY

41 rcc 15 -90 4.5 0 180 0 1.7 $ c air Al-alloy tube, y-axis channel #1 OD m3 7014.70c 4.1985E-5 42 rcc 90 4.5 0 180 0 1.5 $ 8016.70c 1.1263E-5 air, y-axis channel #2 ID c AL-alloy (mass density = 2.66 g/cc) 43 rcc 90 4.5 0 180 0 1.7 $ m4 13027.70c 5.7529E-02 Al-alloy tube, y-axis channel #2 OD 12024.70c 1.5618E-03 44 rcc 50 -90 4.5 0 180 0 2.5 $ 12025.70c 1.9772E-04 air, y-axis channel #3 ID 12026.70c 2.1769E-04 45 rcc 90 4.5 0 180 0 2.5 $ 26054.70c 6.0080E-07 air, y-axis channel #4 ID 26056.70c 9.3398E-06 46 rcc 25 -90 14.5 0 180 0 0.6 $ 26057.70c 2.1384E-07 air, y-axis channel #5 ID 26058.70c 2.8512E-08 47 rcc 25 -90 14.5 0 180 0 0.8 $ 14028.70c 1.8411E-05 Al-alloy tube, y-axis channel #5 OD 14029.70c 9.3223E-07 48 rcc 90 14.5 0 180 0 0.6 $ 14030.70c 6.1882E-07 air, y-axis channel #6 ID 22046.70c 1.6059E-07 49 rcc 90 14.5 0 180 0 0.8 $ 22047.70c 1.4654E-07 Al-alloy tube, y-axis channel #6 OD 22048.70c 1.4815E-06 50 rcc -90 0 9.5 180 0 0 0.9 $ 22049.70c 1.1041E-07 air, x-axis channel #7 ID 22050.70c 1.0840E-07 51 rcc -90 0 19.5 180 0 0 0.6 $ 25055.70c 8.7474E-07 air, x-axis channel #8 ID 23000.70c 9.4337E-07 52 rcc -90 50 9.5 180 0 0 2.5 $ 30000.70c 4.2870E-06 air, x-axis channel #9 ID (assumed z, mt4 al27.12t fe56.12t dimension not shown) c Teflon (mass density = 2.15 g/cc) 53 rcc 50 9.5 180 0 0 2.5 $ m5 6000.70c 2.5891E-02 air, x-axis channel #10 ID (assumed z, 9019.70c 5.1782E-02 dimension not shown) c c BeO (mass density = 2.95 g/cc) c UO2SO4 solution (mass density = 1.05759 m6 4009.70c 7.0937E-02 g/cc) Proprietary Information 8016.70c 7.0937E-02 m1 92234.70c 8.2601E-07 13027.70c 9.8763E-06 92235.70c 9.5974E-05 26054.70c 9.3840E-08 92236.70c 1.9144E-07 26056.70c 1.4588E-06 92238.70c 9.7030E-06 26057.70c 3.3401E-08 1001.70c 6.6135E-02 26058.70c 4.4534E-09 8016.70c 3.3798E-02 14028.70c 2.9170E-06 16032.70c 1.3669E-04 14029.70c 1.4770E-07 mt1 lwtr.10t 14030.70c 9.8044E-08 c Zircaloy-2 (mass density = 6.56 g/cc) 12024.70c 2.8868E-07 m2 40090.70c 2.1893E-02 12025.70c 3.6546E-08 40091.70c 4.7743E-03 12026.70c 4.0237E-08 40092.70c 7.2977E-03 25055.70c 3.2337E-08 40094.70c 7.3955E-03 48106.70c 5.9265E-11 40096.70c 1.1915E-03 48108.70c 4.2197E-11 50112.70c 4.6806E-06 48110.70c 5.9218E-10 50114.70c 3.1365E-06 48111.70c 6.0687E-10 50115.70c 1.7371E-06 48112.70c 1.1441E-09 50116.70c 7.0113E-05 48113.70c 5.7937E-10 50117.70c 3.7059E-05 48114.70c 1.3621E-09 50118.70c 1.1687E-04 48116.70c 3.5512E-10 50119.70c 4.1402E-05 47107.70c 4.2281E-09 50120.70c 1.5726E-04 47109.70c 3.9282E-09 50122.70c 2.2342E-05 29063.70c 1.9337E-07 50124.70c 2.7939E-05 29065.70c 8.6188E-08 26054.70c 5.8429E-06 82204.70c 3.6011E-10 26056.70c 9.0833E-05 82206.70c 6.1990E-09 26057.70c 2.0797E-06 82207.70c 5.6846E-09 26058.70c 2.7729E-07 82208.70c 1.3478E-08 24050.70c 3.3012E-06 28058.70c 6.1995E-08 24052.70c 6.3661E-05 28060.70c 2.3701E-08 24053.70c 7.2178E-06 28061.70c 1.0261E-09 24054.70c 1.7969E-06 28062.70c 3.2600E-09 28058.70c 2.2977E-05 28064.70c 8.2636E-10 28060.70c 8.7842E-06 6000.70c 1.4791E-04 28061.70c 3.8031E-07 5010.70c 9.8103E-09 28062.70c 1.2083E-06 5011.70c 3.9488E-08 28064.70c 3.0627E-07 mt6 be/o.10t o/be.10t al27.12t fe56.12t mt2 fe56.12t c Graphite (mass density = 1.65 g/cc) 3DJHRI

>3URSULHWDU\,QIRUPDWLRQ:LWKKHOGIURPSXEOLFGLVFORVXUHXQGHU&)5 D @

6+,1(0HGLFDO7HFKQRORJLHV

16$756+1

5HY

m7 6000.70c 8.2718E-02 13 2 4.3243E-02 -14 8 imp:n=1 $

5010.70c 3.6580E-09 Zircaloy-2 tank lip 5011.70c 1.4724E-08 14 5 7.7673E-02 -15 8 imp:n=1 $

1001.70c 1.6267E-05 Teflon gasket/tank lip 11023.70c 8.2120E-07 15 4 5.9544E-02 -16 17 19 21 imp:n=1 $

20040.70c 7.2103E-07 Al-alloy tank cover 20042.70c 4.8123E-09 16 4 5.9544E-02 -17 18 imp:n=1 $

20043.70c 1.0041E-09 Al-alloy center top tube (#1) 20044.70c 1.5515E-08 17 4 5.9544E-02 -19 20 imp:n=1 $

20046.70c 2.9751E-11 Al-alloy center top tube (#2) 20048.70c 1.3909E-09 18 4 5.9544E-02 -21 22 imp:n=1 $

62149.70c 1.1343E-10 Al-alloy center top tube (#3) 22046.70c 8.3008E-09 19 3 5.3248E-05 -18 imp:n=1 $

22047.70c 7.5745E-09 air in tube #1 22048.70c 7.6575E-08 20 3 5.3248E-05 -20 imp:n=1 $

22049.70c 5.7068E-09 air in tube #2 22050.70cInformation Proprietary 5.6030E-09 21 3 5.3248E-05 -22 imp:n=1 $

26054.70c 2.0995E-09 air in tube #3 26056.70c 3.2639E-08 30 6 1.4204E-01 -30 11 12 13 14 15 16 17 19 26057.70c 7.4729E-10 21 26058.70c 9.9638E-11 41 43 47 49 50 51 imp:n=1 42092.70c 1.5537E-08 $ BeO section #1 42094.70c 9.6848E-09 31 6 1.4204E-01 -31 30 12 17 19 21 42095.70c 1.6668E-08 41 43 47 49 imp:n=1 $

42096.70c 1.7464E-08 BeO section #2 42097.70c 9.9989E-09 32 6 1.4204E-01 -32 31 41 43 imp:n=1 $

42098.70c 2.5264E-08 BeO section #3 42100.70c 1.0083E-08 33 6 1.4204E-01 -33 17 19 21 imp:n=1 $

23000.70c 6.2418E-07 BeO top section #4 17035.70c 7.4327E-08 34 4 5.9544E-02 -34 17 19 21 imp:n=1 $

17037.70c 2.3768E-08 Al-alloy BeO cover mt7 grph.10t fe56.12t 35 7 8.2737E-02 -35 12 17 19 21 30 31 32 33 kcode 10000 1.0 50 600 34 ksrc 0 0 5 Proprietary 41 43 Information 44 45 47 49 50 51 52 53 imp:n=1 print $ Graphite 40 3 5.3248E-05 -40 imp:n=1 $

air, reflector channel #1

&DVHSURV 41 4 5.9544E-02 -41 40 imp:n=1 $

Al-alloy, reflector channel #1 Proserpine case3, 38.224g U235/L (Table 1) 42 3 5.3248E-05 -42 imp:n=1 $

c Benchmark HEU-SOL-THERM-046, h(crit) = air, reflector channel #2 surface 1 = Table 1 & 32 43 4 5.9544E-02 -43 42 imp:n=1 $

c Dimensions & materials from HEU-SOL-THERM- Al-alloy, reflector channel #2 046 sections 3.1 - 3.3 44 3 5.3248E-05 -44 imp:n=1 $

1 1 0.100177 1 imp:n=1 $ air, reflector channel #3 solution in cylindrical part of tank 45 3 5.3248E-05 -45 imp:n=1 $

2 1 0.100177 -3 imp:n=1 $ air, reflector channel #4 solution in tapered base of tank 46 3 5.3248E-05 -46 imp:n=1 $

3 1 0.100177 -4 imp:n=1 $ air, reflector channel #5 solution in drain tube 47 4 5.9544E-02 -47 46 imp:n=1 $

4 2 4.3243E-02 3 -5 7 imp:n=1 $ Al-alloy, reflector channel #5 Zircaloy-2 tapered base of tank 48 3 5.3248E-05 -48 imp:n=1 $

5 2 4.3243E-02 2 3 -6 8 14 imp:n=1 $ air, reflector channel #6 Zircaloy-2 Proprietary cylindrical Information part of tank 49 4 5.9544E-02 -49 48 imp:n=1 $

6 2 4.3243E-02 4 -7 imp:n=1 $ Al-alloy, reflector channel #6 Zircaloy-2 drain tube 50 3 5.3248E-05 -50 11 imp:n=1 $

7 3 5.3248E-05 -8 1 imp:n=1 $ air, reflector channel #7 air above solution 51 3 5.3248E-05 -51 11 imp:n=1 $

8 3 5.3248E-05 -9 6 5 10 imp:n=1 $ air, reflector channel #8 air around Zircaloy-2 tank 52 3 5.3248E-05 -52 imp:n=1 $

9 3 5.3248E-05 -10 5 7 imp:n=1 $ air, reflector channel #9 air around Zircaloy-2 tube 53 3 5.3248E-05 -53 imp:n=1 $

10 4 5.9544E-02 -11 9 12 imp:n=1 $ air, reflector channel #10 Al-alloy tank 99 0 35 imp:n=0 $

11 4 5.9544E-02 -12 10 imp:n=1 $ outside world Al-alloy tube 12 4 5.9544E-02 -13 11 imp:n=1 $ 1 pz 22.38 $

Al-alloy tank lip critical h of solution from base of tapered base 3DJHRI

>3URSULHWDU\,QIRUPDWLRQ:LWKKHOGIURPSXEOLFGLVFORVXUHXQGHU&)5 D @

6+,1(0HGLFDO7HFKQRORJLHV

16$756+1

5HY

2 rcc 0 0 0.87 0 0 23.005 12.5 $ 47 rcc 25 -90 14.5 0 180 0 0.8 $

solution in cylindrical part of tank (max Al-alloy tube, y-axis channel #5 OD critical h) 48 rcc 90 14.5 0 180 0 0.6 $

3 trc 0 0 0 0 0 0.87 0.3 12.5 $ air, y-axis channel #6 ID solution in tapered base 49 rcc 90 14.5 0 180 0 0.8 $

4 rcc 0 0 0 0 0 -80.5 0.3 $ Al-alloy tube, y-axis channel #6 OD solution in drain tube 50 rcc -90 0 9.5 180 0 0 0.9 $

5 trc 0 0 -0.0931 0 0 0.87 0.4 12.6 $ air, x-axis channel #7 ID Zircaloy-2 tank tapered base 51 rcc -90 0 19.5 180 0 0 0.6 $

6 rcc 0 0 0.7769 0 0 29.0 12.6 $ air, x-axis channel #8 ID Zircaloy-2 cylindrical tank 52 rcc -90 50 9.5 180 0 0 2.5 $

7 rcc 0 0 0 0 0 -80.5 0.4 $ air, x-axis channel #9 ID (assumed z, Zircaloy-2 drain tube dimension not shown) 8 rcc 0 0 30.7 0 0 -15.16 12.5 $ 53 rcc 50 9.5 180 0 0 2.5 $

air above solution (min critical h) air, x-axis channel #10 ID (assumed z, 9 rcc 0 0 -0.3 0 0 30.0 12.9 $ dimension not shown) air around Zircaloy-2 tank 10 rcc 0 0 0 0 0 -80.5 0.7 $ c UO2SO4 solution (mass density = 1.05853 air around Zircaloy-2 drain tube g/cc) 11 rcc 0 0 -0.5 0 0 30.2 13.1 $ m1 92234.70c 8.3978E-07 Al-alloy tank 92235.70c 9.7575E-05 12 rcc 0 0 -0.3 0 0 -80.2 0.9 $ 92236.70c 1.9464E-07 Al-alloy drain tube 92238.70c 9.8648E-06 13 rpp -15 15 -15 15 29.5 29.7 $ 1001.70c 6.6126E-02 Al-alloy tank lip 8016.70c 3.3804E-02 14 rpp -15 15 -15 15 29.7 29.8 $ 16032.70c 1.3847E-04 Zircaloy-2 tank lip mt1 lwtr.10t 15 rpp -15 15 -15 15 29.8 30.7 $ c Zircaloy-2 (mass density = 6.56 g/cc)

Teflon gasket/tank lip m2 40090.70c 2.1893E-02 16 rpp -15 15 -15 15 30.7 33.5 $ 40091.70c 4.7743E-03 Al-alloy tank cover 40092.70c 7.2977E-03 17 rcc 0 0 30.7 0 0 80 1.0 $ 40094.70c 7.3955E-03 Al-alloy center top tube #1 OD Proprietary Information 40096.70c 1.1915E-03 18 rcc 0 0 30.7 0 0 80 0.9 $ 50112.70c 4.6806E-06 Al-alloy center top tube #1 ID 50114.70c 3.1365E-06 19 rcc 10 0 30.7 0 0 80 1.0 $ 50115.70c 1.7371E-06 Al-alloy 2nd 2cmOD top tube #2 50116.70c 7.0113E-05 20 rcc 10 0 30.7 0 0 80 0.9 $ 50117.70c 3.7059E-05 Al-alloy 2nd 2cmOD top tube #2 ID 50118.70c 1.1687E-04 21 rcc -10 0 30.7 0 0 80 0.5 $ 50119.70c 4.1402E-05 Al-alloy 1cmOD top tube #3 50120.70c 1.5726E-04 22 rcc -10 0 30.7 0 0 80 0.4 $ 50122.70c 2.2342E-05 Al-alloy 1cmOD top tube #3 ID 50124.70c 2.7939E-05 30 rpp -40 40 -25 25 -20.5 50.7 $ 26054.70c 5.8429E-06 BeO reflector section #1 26056.70c 9.0833E-05 31 rpp -30 30 -35 35 -30.5 60.7 $ 26057.70c 2.0797E-06 BeO reflector section #2 26058.70c 2.7729E-07 32 rpp -20 20 -40 40 -30.5 60.7 $ 24050.70c 3.3012E-06 BeO reflector section #3 24052.70c 6.3661E-05 33 rpp -15 15 -15 15 60.7 63.2 $ 24053.70c 7.2178E-06 BeO reflector section #4 (top/cover) 24054.70c 1.7969E-06 34 rpp -20 20 -20 20 63.2 65.2 $ 28058.70c 2.2977E-05 Al-alloy BeO reflector top/cover 28060.70c 8.7842E-06 35 rpp -90 90 -90 90 -80.5 110.7 $ 28061.70c 3.8031E-07 Graphite reflector 28062.70c 1.2083E-06 40 rcc 15 -90 4.5 0 180 0 1.5 $ 28064.70c 3.0627E-07 air, y-axis channel #1 ID mt2 fe56.12t 41 rcc 15 -90 4.5 0 180 0 1.7 $ c air Al-alloy tube, y-axis channel #1 OD m3 7014.70c 4.1985E-5 42 rcc 90 4.5 0 180 0 1.5 $ 8016.70c 1.1263E-5 air, y-axis channel #2 ID c AL-alloy (mass density = 2.66 g/cc) 43 rcc 90 4.5 0 180 0 1.7 $ m4 13027.70c 5.7529E-02 Al-alloy tube, y-axis channel #2 OD 12024.70c 1.5618E-03 44 rcc 50 -90 4.5 0 180 0 2.5 $ 12025.70c 1.9772E-04 air, y-axis channel #3 ID 12026.70c 2.1769E-04 45 rcc 90 4.5 0 180 0 2.5 $ 26054.70c 6.0080E-07 air, y-axis channel #4 ID 26056.70c 9.3398E-06 46 rcc 25 -90 14.5 0 180 0 0.6 $ 26057.70c 2.1384E-07 air, y-axis channel #5 ID 26058.70c 2.8512E-08 3DJHRI

>3URSULHWDU\,QIRUPDWLRQ:LWKKHOGIURPSXEOLFGLVFORVXUHXQGHU&)5 D @

6+,1(0HGLFDO7HFKQRORJLHV

16$756+1

5HY

14028.70c 1.8411E-05 22046.70c 8.3008E-09 14029.70c 9.3223E-07 22047.70c 7.5745E-09 14030.70c 6.1882E-07 22048.70c 7.6575E-08 22046.70c 1.6059E-07 22049.70c 5.7068E-09 22047.70c 1.4654E-07 22050.70c 5.6030E-09 22048.70c 1.4815E-06 26054.70c 2.0995E-09 22049.70c 1.1041E-07 26056.70c 3.2639E-08 22050.70c 1.0840E-07 26057.70c 7.4729E-10 25055.70c 8.7474E-07 26058.70c 9.9638E-11 23000.70c 9.4337E-07 42092.70c 1.5537E-08 30000.70c 4.2870E-06 Proprietary 42094.70cInformation 9.6848E-09 mt4 al27.12t fe56.12t 42095.70c 1.6668E-08 c Teflon (mass density = 2.15 g/cc) 42096.70c 1.7464E-08 m5 6000.70c 2.5891E-02 42097.70c 9.9989E-09 9019.70c 5.1782E-02 42098.70c 2.5264E-08 c 42100.70c 1.0083E-08 c BeO (mass density = 2.95 g/cc) 23000.70c 6.2418E-07 m6 4009.70c 7.0937E-02 17035.70c 7.4327E-08 8016.70c 7.0937E-02 17037.70c 2.3768E-08 13027.70c 9.8763E-06 mt7 grph.10t fe56.12t 26054.70c 9.3840E-08 kcode 10000 1.0 50 600 26056.70c 1.4588E-06 ksrc 0 0 5 26057.70c 3.3401E-08 print 26058.70c 4.4534E-09 14028.70c 2.9170E-06 14029.70c 1.4770E-07 &DVHSURV

14030.70c 9.8044E-08 12024.70c 2.8868E-07 Proserpine case4, 39.17g U235/L (Table 1) 12025.70c 3.6546E-08 c Benchmark HEU-SOL-THERM-046, h(crit) =

12026.70c 4.0237E-08 surface 1 = Table 1 & 32 25055.70c 3.2337E-08 c Dimensions & materials from HEU-SOL-THERM-48106.70c 5.9265E-11 046 sections 3.1 - 3.3 48108.70c 4.2197E-11 1 1 0.100180 1 imp:n=1 $

Proprietary 48110.70c Information 5.9218E-10 solution in cylindrical part of tank 48111.70c 6.0687E-10 2 1 0.100180 -3 imp:n=1 $

48112.70c 1.1441E-09 solution in tapered base of tank 48113.70c 5.7937E-10 3 1 0.100180 -4 imp:n=1 $

48114.70c 1.3621E-09 solution in drain tube 48116.70c 3.5512E-10 4 2 4.3243E-02 3 -5 7 imp:n=1 $

47107.70c 4.2281E-09 Zircaloy-2 tapered base of tank 47109.70c 3.9282E-09 5 2 4.3243E-02 2 3 -6 8 14 imp:n=1 $

29063.70c 1.9337E-07 Zircaloy-2 cylindrical part of tank 29065.70c 8.6188E-08 6 2 4.3243E-02 4 -7 imp:n=1 $

82204.70c 3.6011E-10 Zircaloy-2 drain tube 82206.70c 6.1990E-09 7 3 5.3248E-05 -8 1 imp:n=1 $

82207.70c 5.6846E-09 air above solution 82208.70c 1.3478E-08 8 3 5.3248E-05 -9 6 5 10 imp:n=1 $

28058.70c 6.1995E-08 air around Proprietary Information Zircaloy-2 tank 28060.70c 2.3701E-08 9 3 5.3248E-05 -10 5 7 imp:n=1 $

28061.70c 1.0261E-09 air around Zircaloy-2 tube 28062.70c 3.2600E-09 10 4 5.9544E-02 -11 9 12 imp:n=1 $

28064.70c 8.2636E-10 Al-alloy tank 6000.70c 1.4791E-04 11 4 5.9544E-02 -12 10 imp:n=1 $

5010.70c 9.8103E-09 Al-alloy tube 5011.70c 3.9488E-08 12 4 5.9544E-02 -13 11 imp:n=1 $

mt6 be/o.10t o/be.10t al27.12t fe56.12t Al-alloy tank lip c Graphite (mass density = 1.65 g/cc) 13 2 4.3243E-02 -14 8 imp:n=1 $

m7 6000.70c 8.2718E-02 Zircaloy-2 tank lip 5010.70c 3.6580E-09 14 5 7.7673E-02 -15 8 imp:n=1 $

5011.70c 1.4724E-08 Teflon gasket/tank lip 1001.70c 1.6267E-05 15 4 5.9544E-02 -16 17 19 21 imp:n=1 $

11023.70c 8.2120E-07 Al-alloy tank cover 20040.70c 7.2103E-07 16 4 5.9544E-02 -17 18 imp:n=1 $

20042.70c 4.8123E-09 Al-alloy center top tube (#1) 20043.70c 1.0041E-09 17 4 5.9544E-02 -19 20 imp:n=1 $

20044.70c 1.5515E-08 Al-alloy center top tube (#2) 20046.70c 2.9751E-11 18 4 5.9544E-02 -21 22 imp:n=1 $

20048.70c 1.3909E-09 Al-alloy center top tube (#3) 62149.70c 1.1343E-10 3DJHRI

>3URSULHWDU\,QIRUPDWLRQ:LWKKHOGIURPSXEOLFGLVFORVXUHXQGHU&)5 D @

6+,1(0HGLFDO7HFKQRORJLHV

16$756+1

5HY

19 3 5.3248E-05 -18 imp:n=1 $ 7 rcc 0 0 0 0 0 -80.5 0.4 $

air in tube #1 Zircaloy-2 drain tube 20 3 5.3248E-05 -20 imp:n=1 $ 8 rcc 0 0 30.7 0 0 -15.16 12.5 $

air in tube #2 air above solution (min critical h) 21 3 5.3248E-05 -22 imp:n=1 $ 9 rcc 0 0 -0.3 0 0 30.0 12.9 $

air in tube #3 air around Zircaloy-2 tank 30 6 1.4204E-01 -30 11 12 13 14 15 16 17 19 10 rcc 0 0 0 0 0 -80.5 0.7 $

21 air around Zircaloy-2 drain tube 41 43 47 49 50 51 imp:n=1 11 rcc 0 0 -0.5 0 0 30.2 13.1 $

$ BeO section #1 Al-alloy tank 31 6 1.4204E-01 -31 30 12 17 19 21 12 rcc 0 0 -0.3 0 0 -80.2 0.9 $

41 43 47 49 imp:n=1 $ Al-alloy drain tube BeO section #2 13 rpp -15 15 -15 15 29.5 29.7 $

32 6 1.4204E-01 -32 31 41 43 imp:n=1 $ Al-alloy tank lip BeO section #3 14 rpp -15 15 -15 15 29.7 29.8 $

33 6 1.4204E-01 -33 17 19 21 imp:n=1 $ Zircaloy-2 tank lip BeO top section #4 15 rpp -15 15 -15 15 29.8 30.7 $

34 4 5.9544E-02 -34 17 19 21 imp:n=1 $ Teflon gasket/tank lip Al-alloy BeO cover 16 rpp -15 15 -15 15 30.7 33.5 $

35 7 8.2737E-02 -35 12 17 19 21 30 31 32 33 Al-alloy tank cover 34 17 rcc 0 0 30.7 0 0 80 1.0 $

41 43 44 45 47 49 50 51 52 53 imp:n=1 Al-alloy center top tube #1 OD

$ Graphite 18 rcc 0 0 30.7 0 0 80 0.9 $

40 3 5.3248E-05 -40 imp:n=1 $ Al-alloy center top tube #1 ID air, reflector channel #1 19 rcc 10 0 30.7 0 0 80 1.0 $

41 4 5.9544E-02 -41 40 imp:n=1 $ Al-alloy 2nd 2cmOD top tube #2 Al-alloy, reflector channel #1 20 rcc 10 0 30.7 0 0 80 0.9 $

42 3 5.3248E-05 -42 imp:n=1 $ Al-alloy 2nd 2cmOD top tube #2 ID air, reflector channel #2 21 rcc -10 0 30.7 0 0 80 0.5 $

43 4 5.9544E-02 -43 42 imp:n=1 $ Al-alloy 1cmOD top tube #3 Al-alloy, reflector channel #2 22 rcc -10 0 30.7 0 0 80 0.4 $

44 3 5.3248E-05 -44 imp:n=1 $ Al-alloy 1cmOD top tube #3 ID air, reflector channel #3 Proprietary Information 30 rpp -40 40 -25 25 -20.5 50.7 $

45 3 5.3248E-05 -45 imp:n=1 $ BeO reflector section #1 air, reflector channel #4 31 rpp -30 30 -35 35 -30.5 60.7 $

46 3 5.3248E-05 -46 imp:n=1 $ BeO reflector section #2 air, reflector channel #5 32 rpp -20 20 -40 40 -30.5 60.7 $

47 4 5.9544E-02 -47 46 imp:n=1 $ BeO reflector section #3 Al-alloy, reflector channel #5 33 rpp -15 15 -15 15 60.7 63.2 $

48 3 5.3248E-05 -48 imp:n=1 $ BeO reflector section #4 (top/cover) air, reflector channel #6 34 rpp -20 20 -20 20 63.2 65.2 $

49 4 5.9544E-02 -49 48 imp:n=1 $ Al-alloy BeO reflector top/cover Al-alloy, reflector channel #6 35 rpp -90 90 -90 90 -80.5 110.7 $

50 3 5.3248E-05 -50 11 imp:n=1 $ Graphite reflector air, reflector channel #7 40 rcc 15 -90 4.5 0 180 0 1.5 $

51 3 5.3248E-05 -51 11 imp:n=1 $ air, y-axis channel #1 ID air, reflector channel #8 41 rcc 15 -90 4.5 0 180 0 1.7 $

52 3 5.3248E-05 -52 imp:n=1 $ Al-alloy tube, y-axis channel #1 OD air, reflector channel #9 42 rcc 90 4.5 0 180 0 1.5 $

53 3 5.3248E-05 -53 imp:n=1 $ air, y-axis channel #2 ID air, reflector channel #10 43 rcc 90 4.5 0 180 0 1.7 $

99 0 35 imp:n=0 $ Al-alloy tube, y-axis channel #2 OD outside world 44 rcc 50 -90 4.5 0 180 0 2.5 $

air, y-axis channel #3 ID 1 pz 21.83 $ 45 rcc 90 4.5 0 180 0 2.5 $

critical h of solution from base of tapered air, y-axis channel #4 ID base 46 rcc 25 -90 14.5 0 180 0 0.6 $

2 rcc 0 0 0.87 0 0 23.005 12.5 $ air, y-axis channel #5 ID solution in cylindrical part of tank (max 47 rcc 25 -90 14.5 0 180 0 0.8 $

critical h) Al-alloy tube, y-axis channel #5 OD 3 trc 0 0 0 0 0 0.87 0.3 12.5 $ 48 rcc 90 14.5 0 180 0 0.6 $

solution in tapered base air, y-axis channel #6 ID 4 rcc 0 0 0 0 0 -80.5 0.3 $ 49 rcc 90 14.5 0 180 0 0.8 $

solution in drain tube Al-alloy tube, y-axis channel #6 OD 5 trc 0 0 -0.0931 0 0 0.87 0.4 12.6 $ 50 rcc -90 0 9.5 180 0 0 0.9 $

Zircaloy-2 tank tapered base air, x-axis channel #7 ID 6 rcc 0 0 0.7769 0 0 29.0 12.6 $ 51 rcc -90 0 19.5 180 0 0 0.6 $

Zircaloy-2 cylindrical tank air, x-axis channel #8 ID 3DJHRI

>3URSULHWDU\,QIRUPDWLRQ:LWKKHOGIURPSXEOLFGLVFORVXUHXQGHU&)5 D @

6+,1(0HGLFDO7HFKQRORJLHV

16$756+1

5HY

52 rcc -90 50 9.5 180 0 0 2.5 $ 30000.70c 4.2870E-06 air, x-axis channel #9 ID (assumed z, mt4 al27.12t fe56.12t dimension not shown) c Teflon (mass density = 2.15 g/cc) 53 rcc 50 9.5 180 0 0 2.5 $ m5 6000.70c 2.5891E-02 air, x-axis channel #10 ID (assumed z, 9019.70c 5.1782E-02 dimension not shown) c c BeO (mass density = 2.95 g/cc) c UO2SO4 solution (mass density = 1.05997 m6 4009.70c 7.0937E-02 g/cc) 8016.70c 7.0937E-02 m1 92234.70c 8.6057E-07 13027.70c 9.8763E-06 92235.70c 9.9991E-05 26054.70c 9.3840E-08 92236.70c 1.9946E-07 26056.70c 1.4588E-06 92238.70c 1.0109E-05 26057.70c 3.3401E-08 1001.70c 6.6114E-02 26058.70c 4.4534E-09 8016.70c 3.3814E-02 14028.70c 2.9170E-06 16032.70c 1.4116E-04 14029.70c 1.4770E-07 mt1 lwtr.10t 14030.70c 9.8044E-08 c Zircaloy-2 (mass density = 6.56 g/cc) 12024.70c 2.8868E-07 m2 40090.70c 2.1893E-02 12025.70c 3.6546E-08 40091.70c 4.7743E-03 12026.70c 4.0237E-08 40092.70c 7.2977E-03 25055.70c 3.2337E-08 40094.70c 7.3955E-03 48106.70c 5.9265E-11 40096.70c 1.1915E-03 48108.70c 4.2197E-11 50112.70c 4.6806E-06 48110.70c 5.9218E-10 50114.70c 3.1365E-06 48111.70c 6.0687E-10 50115.70c 1.7371E-06 48112.70c 1.1441E-09 50116.70c 7.0113E-05 48113.70c 5.7937E-10 50117.70c 3.7059E-05 48114.70c 1.3621E-09 50118.70c 1.1687E-04 48116.70c 3.5512E-10 50119.70c 4.1402E-05 Proprietary Information 47107.70c 4.2281E-09 50120.70c 1.5726E-04 47109.70c 3.9282E-09 50122.70c 2.2342E-05 29063.70c 1.9337E-07 50124.70c 2.7939E-05 29065.70c 8.6188E-08 26054.70c 5.8429E-06 82204.70c 3.6011E-10 26056.70c 9.0833E-05 82206.70c 6.1990E-09 26057.70c 2.0797E-06 82207.70c 5.6846E-09 26058.70c 2.7729E-07 82208.70c 1.3478E-08 24050.70c 3.3012E-06 28058.70c 6.1995E-08 24052.70c 6.3661E-05 28060.70c 2.3701E-08 24053.70c 7.2178E-06 28061.70c 1.0261E-09 24054.70c 1.7969E-06 28062.70c 3.2600E-09 28058.70c 2.2977E-05 28064.70c 8.2636E-10 28060.70c 8.7842E-06 6000.70c 1.4791E-04 28061.70c 3.8031E-07 5010.70c 9.8103E-09 28062.70c 1.2083E-06 5011.70c 3.9488E-08 28064.70c 3.0627E-07 mt6 be/o.10t o/be.10t al27.12t fe56.12t mt2 fe56.12t c Graphite (mass density = 1.65 g/cc) c air m7 6000.70c 8.2718E-02 m3 7014.70c 4.1985E-5 5010.70c 3.6580E-09 8016.70c 1.1263E-5 5011.70c 1.4724E-08 c AL-alloy (mass density = 2.66 g/cc) 1001.70c 1.6267E-05 m4 13027.70c 5.7529E-02 11023.70c 8.2120E-07 12024.70c 1.5618E-03 20040.70c 7.2103E-07 12025.70c 1.9772E-04 20042.70c 4.8123E-09 12026.70c 2.1769E-04 20043.70c 1.0041E-09 26054.70c 6.0080E-07 20044.70c 1.5515E-08 26056.70c 9.3398E-06 20046.70c 2.9751E-11 26057.70c 2.1384E-07 20048.70c 1.3909E-09 26058.70c 2.8512E-08 62149.70c 1.1343E-10 14028.70c 1.8411E-05 22046.70c 8.3008E-09 14029.70c 9.3223E-07 22047.70c 7.5745E-09 14030.70c 6.1882E-07 22048.70c 7.6575E-08 22046.70c 1.6059E-07 22049.70c 5.7068E-09 22047.70c 1.4654E-07 22050.70c 5.6030E-09 22048.70c 1.4815E-06 26054.70c 2.0995E-09 22049.70c 1.1041E-07 26056.70c 3.2639E-08 22050.70c 1.0840E-07 26057.70c 7.4729E-10 25055.70c 8.7474E-07 26058.70c 9.9638E-11 23000.70c 9.4337E-07 42092.70c 1.5537E-08 3DJHRI

>3URSULHWDU\,QIRUPDWLRQ:LWKKHOGIURPSXEOLFGLVFORVXUHXQGHU&)5 D @

6+,1(0HGLFDO7HFKQRORJLHV

16$756+1

5HY

42094.70c 9.6848E-09 41 43 47 49 imp:n=1 $

42095.70c 1.6668E-08 BeO section #2 42096.70c 1.7464E-08 32 6 1.4204E-01 -32 31 41 43 imp:n=1 $

42097.70c 9.9989E-09 BeO section #3 42098.70c 2.5264E-08 33 6 1.4204E-01 -33 17 19 21 imp:n=1 $

42100.70c 1.0083E-08 BeO top section #4 Proprietary Information 23000.70c 6.2418E-07 34 4 5.9544E-02 -34 17 19 21 imp:n=1 $

17035.70c 7.4327E-08 Al-alloy BeO cover 17037.70c 2.3768E-08 35 7 8.2737E-02 -35 12 17 19 21 30 31 32 33 mt7 grph.10t fe56.12t 34 kcode 10000 1.0 50 600 41 43 44 45 47 49 50 51 52 53 imp:n=1 ksrc 0 0 5 $ Graphite print 40 3 5.3248E-05 -40 imp:n=1 $

air, reflector channel #1 41 4 5.9544E-02 -41 40 imp:n=1 $

&DVHSURV Al-alloy, reflector channel #1 42 3 5.3248E-05 -42 imp:n=1 $

Proserpine case5, 39.665g U235/L (Table 1) air, reflector channel #2 c Benchmark HEU-SOL-THERM-046, h(crit) = 43 4 5.9544E-02 -43 42 imp:n=1 $

surface 1 = Table 1 & 32 Al-alloy, reflector channel #2 c Dimensions & materials from HEU-SOL-THERM- 44 3 5.3248E-05 -44 imp:n=1 $

046 sections 3.1 - 3.3 air, reflector channel #3 1 1 0.100179 1 imp:n=1 $ 45 3 5.3248E-05 -45 imp:n=1 $

solution in cylindrical part of tank air, reflector channel #4 2 1 0.100179 -3 imp:n=1 $ 46 3 5.3248E-05 -46 imp:n=1 $

solution in tapered base of tank air, reflector channel #5 3 1 0.100179 -4 imp:n=1 $ 47 4 5.9544E-02 -47 46 imp:n=1 $

solution in drain tube Al-alloy, reflector channel #5 4 2 4.3243E-02 3 -5 7 imp:n=1 $ 48 3 5.3248E-05 -48 imp:n=1 $

Zircaloy-2 tapered base of tank air, reflector channel #6 5 2 4.3243E-02 2 3 -6 8 14 imp:n=1 $ 49 4 5.9544E-02 -49 48 imp:n=1 $

Zircaloy-2 cylindrical part of tank Al-alloy, reflector channel #6 6 2 4.3243E-02 4 -7 imp:n=1 $ Proprietary 50 3 5.3248E-05 -50 11 Information imp:n=1 $

Zircaloy-2 drain tube air, reflector channel #7 7 3 5.3248E-05 -8 1 imp:n=1 $ 51 3 5.3248E-05 -51 11 imp:n=1 $

air above solution air, reflector channel #8 8 3 5.3248E-05 -9 6 5 10 imp:n=1 $ 52 3 5.3248E-05 -52 imp:n=1 $

air around Zircaloy-2 tank air, reflector channel #9 9 3 5.3248E-05 -10 5 7 imp:n=1 $ 53 3 5.3248E-05 -53 imp:n=1 $

air around Zircaloy-2 tube air, reflector channel #10 10 4 5.9544E-02 -11 9 12 imp:n=1 $ 99 0 35 imp:n=0 $

Al-alloy Proprietary tank Information outside world 11 4 5.9544E-02 -12 10 imp:n=1 $

Al-alloy tube 1 pz 21.418 $

12 4 5.9544E-02 -13 11 imp:n=1 $ critical h of solution from base of tapered Al-alloy tank lip base 13 2 4.3243E-02 -14 8 imp:n=1 $ 2 rcc 0 0 0.87 0 0 23.005 12.5 $

Zircaloy-2 tank lip solution in cylindrical part of tank (max 14 5 7.7673E-02 -15 8 imp:n=1 $ critical h)

Teflon gasket/tank lip 3 trc 0 0 0 0 0 0.87 0.3 12.5 $

15 4 5.9544E-02 -16 17 19 21 imp:n=1 $ solution in tapered base Al-alloy tank cover 4 rcc 0 0 0 0 0 -80.5 0.3 $

16 4 5.9544E-02 -17 18 imp:n=1 $ solution in drain tube Al-alloy center top tube (#1) 5 trc 0 0 -0.0931 0 0 0.87 0.4 12.6 $

17 4 5.9544E-02 -19 20 imp:n=1 $ Zircaloy-2 tank tapered base Al-alloy center top tube (#2) 6 rcc 0 0 0.7769 0 0 29.0 12.6 $

18 4 5.9544E-02 -21 22 imp:n=1 $ Zircaloy-2 cylindrical tank Al-alloy center top tube (#3) 7 rcc 0 0 0 0 0 -80.5 0.4 $

19 3 5.3248E-05 -18 imp:n=1 $ Zircaloy-2 drain tube air in tube #1 8 rcc 0 0 30.7 0 0 -15.16 12.5 $

20 3 5.3248E-05 -20 imp:n=1 $ air above solution (min critical h) air in tube #2 9 rcc 0 0 -0.3 0 0 30.0 12.9 $

21 3 5.3248E-05 -22 imp:n=1 $ air around Zircaloy-2 tank air in tube #3 10 rcc 0 0 0 0 0 -80.5 0.7 $

30 6 1.4204E-01 -30 11 12 13 14 15 16 17 19 air around Zircaloy-2 drain tube 21 11 rcc 0 0 -0.5 0 0 30.2 13.1 $

41 43 47 49 50 51 imp:n=1 Al-alloy tank

$ BeO section #1 12 rcc 0 0 -0.3 0 0 -80.2 0.9 $

31 6 1.4204E-01 -31 30 12 17 19 21 Al-alloy drain tube 3DJHRI

>3URSULHWDU\,QIRUPDWLRQ:LWKKHOGIURPSXEOLFGLVFORVXUHXQGHU&)5 D @

6+,1(0HGLFDO7HFKQRORJLHV

16$756+1

5HY

13 rpp -15 15 -15 15 29.5 29.7 $ 1001.70c 6.6106E-02 Al-alloy tank lip 8016.70c 3.3818E-02 14 rpp -15 15 -15 15 29.7 29.8 $ 16032.70c 1.4255E-04 Zircaloy-2 tank lip mt1 lwtr.10t 15 rpp -15 15 -15 15 29.8 30.7 $ c Zircaloy-2 (mass density = 6.56 g/cc)

Teflon gasket/tank lip m2 40090.70c 2.1893E-02 16 rpp -15 15 -15 15 30.7 33.5 $ 40091.70c 4.7743E-03 Al-alloy tank cover 40092.70c 7.2977E-03 17 rcc 0 0 30.7 0 0 80 1.0 $ 40094.70c 7.3955E-03 Al-alloy center top tube #1 OD 40096.70c 1.1915E-03 18 rcc 0 0 30.7 0 0 80 0.9 $ 50112.70c 4.6806E-06 Al-alloy center top tube #1 ID 50114.70c 3.1365E-06 19 rcc 10 0 30.7 0 0 80 1.0 $ 50115.70c 1.7371E-06 Al-alloy 2nd 2cmOD top tube #2 50116.70c 7.0113E-05 20 rcc 10 0 30.7 0 0 80 0.9 $ 50117.70c 3.7059E-05 Al-alloy 2nd 2cmOD top tube #2 ID 50118.70c 1.1687E-04 21 rcc -10 0 30.7 0 0 80 0.5 $ 50119.70c 4.1402E-05 Al-alloy 1cmOD top tube #3 50120.70c 1.5726E-04 22 rcc -10 0 30.7 0 0 80 0.4 $ 50122.70c 2.2342E-05 Al-alloy 1cmOD top tube #3 ID 50124.70c 2.7939E-05 30 rpp -40 40 -25 25 -20.5 50.7 $ 26054.70c 5.8429E-06 BeO reflector section #1 26056.70c 9.0833E-05 31 rpp -30 30 -35 35 -30.5 60.7 $ 26057.70c 2.0797E-06 BeO reflector section #2 26058.70c 2.7729E-07 32 rpp -20 20 -40 40 -30.5 60.7 $ 24050.70c 3.3012E-06 BeO reflector section #3 24052.70c 6.3661E-05 33 rpp -15 15 -15 15 60.7 63.2 $ 24053.70c 7.2178E-06 BeO reflector section #4 (top/cover) 24054.70c 1.7969E-06 34 rpp -20 20 -20 20 63.2 65.2 $ 28058.70c 2.2977E-05 Al-alloy BeO reflector top/cover 28060.70c 8.7842E-06 35 rpp -90 90 -90 90 -80.5 110.7Proprietary $ Information28061.70c 3.8031E-07 Graphite reflector 28062.70c 1.2083E-06 40 rcc 15 -90 4.5 0 180 0 1.5 $ 28064.70c 3.0627E-07 air, y-axis channel #1 ID mt2 fe56.12t 41 rcc 15 -90 4.5 0 180 0 1.7 $ c air Al-alloy tube, y-axis channel #1 OD m3 7014.70c 4.1985E-5 42 rcc 90 4.5 0 180 0 1.5 $ 8016.70c 1.1263E-5 air, y-axis channel #2 ID c AL-alloy (mass density = 2.66 g/cc) 43 rcc 90 4.5 0 180 0 1.7 $ m4 13027.70c 5.7529E-02 Al-alloy tube, y-axis channel #2 OD 12024.70c 1.5618E-03 44 rcc 50 -90 4.5 0 180 0 2.5 $ 12025.70c 1.9772E-04 air, y-axis channel #3 ID 12026.70c 2.1769E-04 45 rcc 90 4.5 0 180 0 2.5 $ 26054.70c 6.0080E-07 air, y-axis channel #4 ID 26056.70c 9.3398E-06 46 rcc 25 -90 14.5 0 180 0 0.6 $ 26057.70c 2.1384E-07 air, y-axis channel #5 ID 26058.70c 2.8512E-08 47 rcc 25 -90 14.5 0 180 0 0.8 $ 14028.70c 1.8411E-05 Al-alloy tube, y-axis channel #5 OD 14029.70c 9.3223E-07 48 rcc 90 14.5 0 180 0 0.6 $ 14030.70c 6.1882E-07 air, y-axis channel #6 ID 22046.70c 1.6059E-07 49 rcc 90 14.5 0 180 0 0.8 $ 22047.70c 1.4654E-07 Al-alloy tube, y-axis channel #6 OD 22048.70c 1.4815E-06 50 rcc -90 0 9.5 180 0 0 0.9 $ 22049.70c 1.1041E-07 air, x-axis channel #7 ID 22050.70c 1.0840E-07 51 rcc -90 0 19.5 180 0 0 0.6 $ 25055.70c 8.7474E-07 air, x-axis channel #8 ID 23000.70c 9.4337E-07 52 rcc -90 50 9.5 180 0 0 2.5 $ 30000.70c 4.2870E-06 air, x-axis channel #9 ID (assumed z, mt4 al27.12t fe56.12t dimension not shown) c Teflon (mass density = 2.15 g/cc) 53 rcc 50 9.5 180 0 0 2.5 $ m5 6000.70c 2.5891E-02 air, x-axis channel #10 ID (assumed z, 9019.70c 5.1782E-02 dimension not shown) c c BeO (mass density = 2.95 g/cc) c UO2SO4 solution (mass density = 1.06070 m6 4009.70c 7.0937E-02 g/cc) 8016.70c 7.0937E-02 m1 92234.70c 8.7144E-07 13027.70c 9.8763E-06 92235.70c 1.0125E-04 26054.70c 9.3840E-08 92236.70c 2.0198E-07 26056.70c 1.4588E-06 92238.70c 1.0237E-05 26057.70c 3.3401E-08 3DJHRI

>3URSULHWDU\,QIRUPDWLRQ:LWKKHOGIURPSXEOLFGLVFORVXUHXQGHU&)5 D @

6+,1(0HGLFDO7HFKQRORJLHV

16$756+1

5HY

26058.70c 4.4534E-09 14028.70c 2.9170E-06

&DVHSURV

14029.70c 1.4770E-07 Proserpine case6, 40.383g U235/L (Table 1) 14030.70c 9.8044E-08 c Benchmark HEU-SOL-THERM-046, h(crit) =

12024.70c 2.8868E-07 surface 1 = Table 1 & 32 12025.70c 3.6546E-08 c Dimensions & materials from HEU-SOL-THERM-12026.70c 4.0237E-08 046 sections 3.1 - 3.3 25055.70c 3.2337E-08 1 1 0.100181 1 imp:n=1 $

48106.70c 5.9265E-11 solution in cylindrical part of tank 48108.70c 4.2197E-11 2 1 0.100181 -3 imp:n=1 $

48110.70c 5.9218E-10 solution in tapered base of tank 48111.70c 6.0687E-10 3 1 0.100181 -4 imp:n=1 $

48112.70c 1.1441E-09 solution in drain tube 48113.70c 5.7937E-10 4 2 4.3243E-02 3 -5 7 imp:n=1 $

48114.70c 1.3621E-09 Zircaloy-2 tapered base of tank 48116.70c 3.5512E-10 5 2 4.3243E-02 2 3 -6 8 14 imp:n=1 $

47107.70c 4.2281E-09 Zircaloy-2 cylindrical part of tank 47109.70c 3.9282E-09 6 2 4.3243E-02 4 -7 imp:n=1 $

29063.70c 1.9337E-07 Zircaloy-2 drain tube 29065.70c 8.6188E-08 7 3 5.3248E-05 -8 1 imp:n=1 $

82204.70c 3.6011E-10 air above solution 82206.70c 6.1990E-09 8 3 5.3248E-05 -9 6 5 10 imp:n=1 $

82207.70c 5.6846E-09 air around Zircaloy-2 tank 82208.70c 1.3478E-08 9 3 5.3248E-05 -10 5 7 imp:n=1 $

28058.70c 6.1995E-08 air around Zircaloy-2 tube 28060.70c 2.3701E-08 10 4 5.9544E-02 -11 9 12 imp:n=1 $

28061.70c 1.0261E-09 Al-alloy tank 28062.70c 3.2600E-09 11 4 5.9544E-02 -12 10 imp:n=1 $

28064.70c 8.2636E-10 Al-alloy tube 6000.70c 1.4791E-04 12 4 5.9544E-02 -13 11 imp:n=1 $

5010.70c Proprietary9.8103E-09 5011.70c Information 3.9488E-08 Al-alloy tank lip 13 2 4.3243E-02 -14 8 imp:n=1 $

mt6 be/o.10t o/be.10t al27.12t fe56.12t Zircaloy-2 tank lip c Graphite (mass density = 1.65 g/cc) 14 5 7.7673E-02 -15 8 imp:n=1 $

m7 6000.70c 8.2718E-02 Teflon gasket/tank lip 5010.70c 3.6580E-09 Proprietary Information 15 4 5.9544E-02 -16 17 19 21 imp:n=1 $

5011.70c 1.4724E-08 Al-alloy tank cover 1001.70c 1.6267E-05 16 4 5.9544E-02 -17 18 imp:n=1 $

11023.70c 8.2120E-07 Al-alloy center top tube (#1) 20040.70c 7.2103E-07 17 4 5.9544E-02 -19 20 imp:n=1 $

20042.70c 4.8123E-09 Al-alloy center top tube (#2) 20043.70c 1.0041E-09 18 4 5.9544E-02 -21 22 imp:n=1 $

20044.70c 1.5515E-08 Al-alloy center top tube (#3) 20046.70c 2.9751E-11 19 3 5.3248E-05 -18 imp:n=1 $

20048.70c 1.3909E-09 air in tube #1 62149.70c 1.1343E-10 20 3 5.3248E-05 -20 imp:n=1 $

22046.70c 8.3008E-09 air in tube #2 22047.70c 7.5745E-09 21 3 5.3248E-05 -22 imp:n=1 $

22048.70c 7.6575E-08 air in tube #3 22049.70c 5.7068E-09 30 6 1.4204E-01 -30 11 12 13 14 15 16 17 19 22050.70c 5.6030E-09 21 26054.70c 2.0995E-09 41 43 47 49 50 51 imp:n=1 26056.70c 3.2639E-08

$ BeO section #1 26057.70c 7.4729E-10 31 6 1.4204E-01 -31 30 12 17 19 21 26058.70c 9.9638E-11 41 43 47 49 imp:n=1 $

42092.70c 1.5537E-08 BeO section #2 42094.70c 9.6848E-09 32 6 1.4204E-01 -32 31 41 43 imp:n=1 $

42095.70c 1.6668E-08 BeO section #3 42096.70c 1.7464E-08 33 6 1.4204E-01 -33 17 19 21 imp:n=1 $

42097.70c 9.9989E-09 BeO top section #4 42098.70c 2.5264E-08 34 4 5.9544E-02 -34 17 19 21 imp:n=1 $

42100.70c 1.0083E-08 Al-alloy BeO cover 23000.70c 6.2418E-07 35 7 8.2737E-02 -35 12 17 19 21 30 31 32 33 17035.70c 7.4327E-08 34 17037.70c 2.3768E-08 41 43 44 45 47 49 50 51 52 53 imp:n=1 mt7 grph.10t fe56.12t

$ Graphite kcode 10000 1.0 50 600 40 3 5.3248E-05 -40 imp:n=1 $

ksrc 0 0 5 air, reflector channel #1 print 3DJHRI

>3URSULHWDU\,QIRUPDWLRQ:LWKKHOGIURPSXEOLFGLVFORVXUHXQGHU&)5 D @

6+,1(0HGLFDO7HFKQRORJLHV

16$756+1

5HY

41 4 5.9544E-02 -41 40 imp:n=1 $ 20 rcc 10 0 30.7 0 0 80 0.9 $