L-2015-160, WCAP-17939-NP, Revision 0, Analysis of Capsule 97 Degrees from the Florida Power & Light Company St. Lucie, Unit 2, Reactor Vessel Radiation Surveillance Program, Part 3 of 3
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{{#Wiki_filter:Westinghouse Non-Proprietary Class 3 C-41 Westinghouse Non-Proprietary Class 3 CAl CAPSULE 830 IS PLATE M-605-1 (TRANSVERSE) CVGth 6.0; Hypabol Tanment Cw Pmted n M2-12014 1:18 PM A=38.8B=371&C=84.S9TD = 82."!D=6.0O Cmhielhia Coefflient =i0937 Equaimo is A + B * [TaImCi(-ITY(C-DL))] Upper refL.E = 75-37 lawer ShefL.K [00 (F-xD) Temp-,35 mil= 75.60 F Plant SL Lwki2 Materik- S.AW3Bl Heat A-8490-2 Ofiengtmiom TL Capmk- 8y0Thx Fhxene so 70
~60
~4o
~30 20 10 0 =
-300 -200 -100 0 too 200 300 400 500 600 Temperature (* F)
CVna-h 6.0 1./0120M14 Page 1/2 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-42 Westinghouse Non-Proprietary Class 3 C-42 St. Lwae 2 PlaNtC Material SAS3BI Heat A-8490-2
-mTL Capswl* &P Fhue'e CAPSULE 830 IS PLATE M-605-1 (TRANSVERSE)
Charpy V-Notch Data Tenpatur (*-F) h rL. E. Computed L E Diffvntia 1 12.0 10.4 1.61 47 23.0 23.3 -032 60 30.0 29A 1.60 79 39.0 36.1 2.92 113 41.0 50.9 -9.92 140 50.0 60.1 -10.09 157 87.0 644 60 217 65.0 72.4 38 252 77.0 74.0 297 300 78.0 74.9 3.07 350 75.0 75.2 -o023 401 70.0 753 -53,3 CVGaph 6.0 12/01f014 Page 2ý2 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-43 CAPSULE 830 IS PLATE M-605-1 (ERANSVERSE) CV 60. *Hypebc&Tangt Curve Pfiedon I12/M'2014 124FM A= 50.SO B 50.00 C= 115-59 TO = 169.5 D5=0.00 Cmu ficn oeffid=0937 Equatmi is A + B * [arb(r-OW(c+DT))] UPP" %effY-%Smr= 100.00 (Fxed) Iow-er ShlfShear = 0-00 Fixed Tempmiftwe at 50% Sear-- 169.60 Plait St I~izE2 Matenl: s* nBI Heat A-4490-2 tfinwem- IL Capvsle: 830 110 100 90 80 L. 70 S60
* -- -/ --
S50 1* 40 30 20 10
- L L J BI
-300 -200 -100 0 100 200 300 400 500 600 Temperature (I F)
CVGCnh 6.0 12101;2014 Page 1,2 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-44 Westinghouse Non-Proprietary Class 3 C-44 Plat St. Lade 2 MaNtnm: SA533BI Heat A-4090-2 (kiatmiuTL Capsue- 8w* Fli-CAPSULE 830 IS PLATE M-605-1 (TRANSVERSE) Chatpy V-Notch Data Temperture (IF)
*mt ear mCoputed %Shear Diferential 1 0.0 5.1 -5.14 47 5.0 10.7 -5.71 60 10.0 13.1 -3.06 78 30.0 17.0 12.98 113 30.0 273 2.68 140 30.0 37-5 -7.49 157 60.0 44.6 15.41 217 35.0 69.4 -34.44 252 100.0 30.6 1936 300 100.0 90.5 9.47 350 100.0 95.8 4-22 401 100.0 98.2 1.79 cvraph 6.o 12/011'2014 Page 2'2 WCAP-17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-45 Westinghouse Non-Proprietary Class 3 C-45 CAPSULE 830 SURVEILLANCE PROGRAM WELD METAL CVGrh6.0: Hyperbolic TwqpWwePxintedm 12/1 M0141:27 PM A=1.510 B= 4& C =65.83 10=4.33 D = 0.00 Coieatmfio Coeffwiet =0959 Equ~ualm .A + 9 r(C1'-WHJYC4D))l U4erSgff Et-*= 100-00 (Fixed) Lower Sb&F=egy=22O (Fiec) Te~mp-30A-DbS-34.70"F Tmp_435 fl-1w-26.800 F Terip50 A-03s5 ,5.8O0 F Plta: St. Lacie 2 Mzakiia SAW Heat 0637 ofeuf .w*x cvn&e. &33 Fklewe, 140 120 100 80 40 60 40 20 0 . 1 1 1 1 1 1 1 1 !
-300 -200 -100 0 100 200 300 400 Soo 600 Temperature (I F)
CVCut6.o 12I(012014 Page 1/2 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-46 Plmot St. Luc.k 2 MAiua: SAW Heat 83%37 CAPSUEio3NA CEk wOR F"D T CAPSULE 830 SURVEILLANCE PROGRAM WELD M1ETAL Charpy V-Notch Data TeImer2urem F) Input CIVN computed CVNVDiffeniawd
-40 22-0 26.9 4.93
-25 39.0 361 2.77
-13 31.0 44.7 -13.70
-5 62-0 50.6 1139 0 61.0 54-3 6.63 49 80.0 93.4 -3.44 78 870 92.6 -5.59 117 100.0 97.6 239 156 96.0 99.3 -3_26 217 97.0 99-9 -288 300 111.0 100.0 21.01 401 99.0 100.0 -1.00 CVGiph 6,0 12(0102014 Pae 2f!
WCAP-17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-47 Westinghouse Non-Proprietary Class 3 C-47 CAPSULE 83" SURVEILLANCE PROGRAM WELD METAL CVGrtuh 6_0: Hyperbolic TxmgemCuPintdon 12/1 M-14 1:M FM A=41A3 B=40.43 C=7i"TU =-3.71 D=&00 aon Cbeffit=00973 Equatin 's A +B FIm-zTW-T0y(C+DT))] Ul ISeefLE.
=S1.86 Laim ShefLf LE
= LiOO z Tewq. 5 i w- 16 W0F Pian&St. Lucie 2 MAtezial: SAW Heat 93637 Wuentafion: NA Tbewe 100 90 80
= 10 60 50 4,
30 20 10
-0 k
,300 -200 -400 0 100 200 300 400 500 600 Temperature (* F)
CVruph 6 o 12/01f2014 Pige in2 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-48 Plant St. Lacie 2 Mafiter SAW Heat 8&637 C.mfntfio=-A Cpsie.83' Fmme-CAPSULE 830 SURVEILLANCE PROGRAM WELD METAL Charpy V-Notch Data Tmpera ¢ F) Input L E. Compnud L E. Differea
-40 17.0 23.6 -663
-25 33.0 30.5 250
-13 28.0 36.6 4.56
-5 48.0 40.8 7-25 o 51.0 43,4 7.62 48 62.0 65-2 -3.17 78 71.0 73-3 -2.26 117 77,0 78.5 -152 156 78,0 80.6 -2.62 217 77.0 81.6 -4.60 300 880 818 6-17 401 86.0 81.9 4-14 CVGrph 60 1301i2014 Page 202 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-49 CAPSULE 830 SURVEILLANCE PROGRAM WELD METAL CVGrapi 6.0: Hyrbdkic Tangent Cumve PFia an t211/2014 137 PM A= 50.00 B = 50.00 C = 5.68 TO = 10.76D = 0.0 elation Coient= 0-974 Equaion is A + B
- 1TmbCr-'Y(C+iD))1 Upper Shef %.Shew--10000 (FRixed) Lower'Slf%Sr = 0.00 (iX4 Temperalre at 50. Sher= 10.80 Plant St. Lnde 2 MuleuiaL SAW Heat 81637 Orieitatim- Llc Cqpule W3 Thaene:
110 I00 90 80 so Lo 70 05
' 5 60 S40 30 20 ir_
10 a
-300 -200 -10 0 100 200 300 400 500 600 Temperature (* F)
CVGrpk6_0 12/0112014 Page i12 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-50 Pliat St Ick 2 albeia: SAW Heat 83637 OAeataim. NA Cqmkii&r
- e. 8 CAPSULE 830 SURVEILLANCE PROGRAM WELD METAL Charpy V-Notch Data TempmiUr (0F1 input %,%tair Campute "Shear Diffrenli
-40 10.0 13_1 -3.11
-25 40.0 20.9 19.12
-13 10.0 29.2 -19i1
- -5 40-0 35.7 4.27 0 40.0 40.1 -0.11 41 80.0 80.0 -0,02, 78 95.0 92.4 255 117 100.0 98.1 1.87 156 100.0 99_6 0.44 217 100.0 100.0 0.05 300 I00.0 10(10 0.00 401 10D.0 100.0 0.00 CVGrp6o0 12101 014 Page 2J2 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-51 C-5 1 Westinghouse Non-Proprietary Class 3 CAPSULE 830 HEAT AFFECTED ZONE CV~naph 6.0- Hypexbaic Tappent Curv Pfinted m L2/112014 1:39 PM A =60.60 B = 5&40S C= 13077 TO =-53-9 D =GOM ColnelalicnCoeffidalt=0.662 Equation is A+ B - nIm~((rTJY(C+IYI))] Upperx S ~nffi = 119-00 (Fixe4 Lcawu SfrWEnerif =22O~ixe&M Temp@M ft-ls=--51.500 F Tamp@35 fk-IPw=-3 1.40- F Teup00ft-gj=20.50 0 F Plant St. Lucie z MAtmiiak SA-S33BI Heat A-8490-2 Oiienlatim- NAL cvt& BY0 flue 160 140 120 I 100
'-p 80 60 U
40 20 0-
-300 -200 -100 0 100 200 300 400 500 600 Temperature (0 F)
CIVrhph 6-0 121/01/2014 Fige in-May 2015 WCAP- 17939-NP I17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-52 plant St.ucide 2 Maalexik SAW33BI Heat 14-9B4-OnenbrkioirN-A CPL8l30 W.FFTDO H e: CAPSULE 830 BEAT AFFECTED ZON"E Charpy V-Notch Data Teinerature(CY) b"u CYN Coampteo CVNK Differential
-40 26.0 32.9 -6.80
-12 17.0 403 -23.29 1 45.0 44.1 0-93 49 56.0 58.8 -2.79 60 113.0 627 5033 102.0 684 39-56 1t8 25.0 80.6 -5557 157 47.0 90.8 -43.78 217 137.0 102.5 34.46 250 100.0 1071 -7.06 300 145.0 Ill.8 33.18 401 92.0 116.6 -2455 CVGrah 6.0 12/0112014 Page 2/2 WCAP-17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-53 CAPSULE 830 HEAT AFFECTED ZONE CVGai 6.0: Hypnbolic Tangat Curme Phited m 12(112014 1:45 PM A = 36.45 B =35ý C =13283 TO =16.72.D = 0.00 Cxxclatin CoeffieA =0.735 Equafto is A+ BA ganr(r-T'oY(c+Di))i Lrpp, SIeff L.E = 71-91 .ower ShfILE. = 1.00 (b Teump435 milws 11300 F Plant St. Lucie 2 Material: SA-533BI Heat A-9490-2 OrAmalion NA C~psde. 93- Fhmxce: 100 90 80 000 70 60 50 40 1~. 0 4-i 30 20 10 J 1 . 1 1~LL 0.
-300 -200 -100 0 100 200 300 400 50 600 Temperature (0 F)
CVGrap 6.0 12dU012014 Pig 11 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-54 Plat St Lucie 2 NMteiiaL SA.WSB1 Heat A-8490-2 Oficotatin INA caule: &3Y CAPSULE 830 HEAT AFFECTED ZONE Charpy V-Notch Data Temperitur F) Input L E. Computed L E. Diffeutiu
-40 24.0 222 1.83
-12 120 28.9 -16.90 1 34.0 32.3 1,2 48 42-0 447 -2.65 60 72.0 47.6 2439 78 72.0 51.7 20_26 118 26.0 592 ,3323ý 157 46.0 643 -1825 217 95.0 686 16.41 250 72.0 69.9 2.15 300 718.0 0.9 7.09 401 67.0 713 -469 CVGrah6_0 12/t,2014 Page 12 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-55 CAPSULE 830 HEAT AFFECTED ZONE CVGiuh 6.0: Hypabolic Tmgent Curve Pfixted an 12t1120141:51 PM A = 50.00 B = 5&00 C = 14&77 TO = 61.6 D =OAO Qarelation Cbeffwiria = 0-123 Equatim is A + B [Tn(r-TnY(C-D'))I LT~er Shelf %Shme= 100.o0 (F=ix4 Lawr helf..Shear= 0.00 Fixd Tawmatmhe at 50% Shear = 61.50 Flaint St. Luck 2 MAterija S.AS3BI Heat A-84U-2 OfientztioxE NA capiule: BY&luw 110 100 90 80
- 70 S60
- 50 C.4
' 40 30 20 0-0 10 0
-300 -200 -100 0 100 200 300 400 500 600 Temperature (I F)
CVGih 60 120112014 Page V2 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-56 Plant St.Lucie 2 Matnial: SA533BI Heat A-8490-2 Orientation: MA Capsule: 83*3 CAPSULE 830 HEAT AFFECTED ZONE Charpy V-Notch Data Tempwature (* F) Input %Shear Cmnputed %Shear DIfferential
-40 50 20.4 -1536
-12 10.0 27.1 -17.14 1 40-0 30.7 92-7 48 40.0 45.5 -5.49 60 90.0 495 40.49 78 75.0 55-5 19.46 11s 30.0 68-1 -38.14 157 60.0 78_3 -1832 217 100.0 89.0 ILO0 250 100.0 92.7 735 300 100.0 96.1 3.89 401 I00.0 99.0 1.03 CVGraph 6.0 12*0*2014 Page 2(2 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-57 CAPSULE 2630 IS PLATE M-605-1 (TRANSVERSE) CV"rph 6-0. Hyperboic Tangent Qave Printed-- 1211/2014 2:36PM A=40.60 B=3840 C =91-6 TO= 159.08 D= 0.00 Coeffient = 0.955
-tlation EquatiouisA+B
- T=aX(r--oY(C+4I)T]
Upper Sher Enery = 79.00 (Fmxe Lmw Sh*fEnfrg= 2120 (ixec Teap@30 fi4b=133.10" F Ternip35 fk--*445.60 F Temn50 114-lb V20F Plant St. Lucie 2 lfibmiaL- SA53-3BI Heat A-U90-2 Omuiecaiol TL Cýe: 200 Fu RumeE 100 90 80 70 W~ 60 50 40 30 20 10 0 L_
-300 -200 -100 0 100 200 300 400 500 600 Temperature (0 F)
CVGn4 6_0 12/0112014 PAge 1V2 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-58 Matwal: SA533B1. Piant St. Ladie ieat A-&190-2 Orientation- TL Capsule: 260* Fbmm CAPSULE 2630 IS PLATE M-605-1 (TRANSVERSE) Charpy V-Notch Data Temperatv, e (*F) input CvN Computed C". Differemtal 0 30 4.5 -1.54 40 11.0 7.6 3.44 72 16.0 12.2 3.75 100 19.0 18.8 0.16 125 36.0 27.0 9.01 150 41.0 36.8 4.18 160 23.0 41.0 -17.98 195 47.0 549 -7.88 225 80.0 64.2 15.78 250 66.0 69.7 -3.66 300 86.0 75.6 10.42 375 84.0 783 5.69 cvcrrph6.o 12101)n014 Page 2/)2. WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-59 CAPSULE 2630 IS PLATE M-605-1 (TRANSVERSE) CVGrCph 64. H1-t-ic Tangent Cuve Pnied an 12/112014 2.41 PM A =43.37B =4237 C=115.12 Tf= 177.75D= 0.00 Chmeiatio Coeficien = 0_96 Fmtiom is A + B* *mzoff-Toxc+ni) ULper Shelf LE. =85.74 Lower Shelf LE = 1.00 (Fixed) 35 Ten~j mils=54M0 F Plant St. Lucie 2 MateziaL SAS33BI Heat .A-84802 OricubfimniTL Capmde: 263* Fhsenrce: 100 90 70 0-60 1.. 50 40 30 20 10 030
-300 -200 400 0 100 200 300 400 500 600 Temperature (0 F) cvGrah 6.0 12/0112014 Page 1/2 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-60 Westinghouse Non-Proprietary Class 3 C-60 Plant St.LIAck MatciiaL SWS3BL Heat A-8490-2 Oaionbm TL Capsule: 263' Flhume. CAPSULE 2630 IS PLATE M-605-1 (TRANSVERSE) Charpy V-Notch Data Temnp ur ( F) Input L E. Coniputed L E Differendil 0 6.0 4.7 130 40 9.0 8.1 0.91 72 14.0 12.6 136 100 14.0 18.4 -4.44 125 34.0 212 8.79 150 40.0 334 6.65 160 22.0 36.9 -14.89 195 49.0 49.7 -0.67 225 65.0 59.8 5.15 250 62.0 66.9 -4.95 300 85.0 76.7 831 375 78.0 83.1 -5.07 CVGraph 60 12/01;2014 Fage 2Q WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-61 CAPSULE 2630 IS PLATE M-605-1 (TRANSVERSE) CVGrqa 6.0: Hyperbolic Tangent Cmve Pnmted on 12I/2014 2:43 PM A = 50. 0B=5.O0 C = 6.76 TO = 17516 D = 0.00 Correlatioa Coefficieut = 0-962 Equatim is A + B [franbM-TQY(C+DIf)j Upper S if f/Sber = 100.00 (Fxxo Lower P %/.Shear
= 0.00 (Fi-xed Temtpeature at 50% Shear= 17520 Planr -St.Lucie 2 Material: SA*_.3B1 Heat A-8490-2 Oriataionw IT capsule- W6O ht 1luence-110 t00 9o 80 lh 70 2 60 50 I-gq 40 30 20
[0-0-
-300 -200 -100 0 100 200 30W 400 500 600 Temperature (1 F) cVGxrah6.0 12/01/2014 PAPe 112 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-62 PlantSA Lucik Mabealw SAWBI1 Heat A-8-490-2 orimi 7 Capsule: 263- Flume: CAPSULE 2630 IS PLATE M-605-1 (TRANSVERSE) Charpy V-Notch Data TIemperaure ( F) Input %Shear Computed %Shear Differential 0 5.0 0V7 4.35 40 10.0 20 7-97 72 15,0 4.9 10.06 100 20.0 104 9_61 125 30.0 19.2 10.82 150 35.0 327 229 160 20-.0 39.3 -1930 195 50.0 63.9 -13.85 2_ 100.0 80.7 1932 250 100.0 89.5 10.47 300 100.0 973 2.71 375 100.0 99.7 032 C!%raph60 1-10112_014 Page 2-2 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-63 CAPSULE 2630 SURVEUILANCE PROGRAM WELD METAL CVGxao 6.0- Hypeebolic Tmigwi Curve Pfinted c 1211/20142:45 FM A=-53.60B=51A@ C =1OL.75T=26.J9D =D0G Cbae1afim Cbeffwieut=0966 Equiatim is A + B
- tgavI(CrJ0Y(C+DD)]
Ez Upper Shelfnm = 105.00 (Fized) LoerS1%ff Eaery= 220 (F=0e~ Thi)30 &Ft-Is24.W0 F TaiW35 ffta-rx-12.f F Temp@50 ft-1bsi 19ATO F Pbnt St Lucie 2 atieril: SAW Heat W3637
.xaNA CTRer 260- Fkenie.
140 120 100 00,1 80 Q 60 40 20 01--
-300 -200 -100 0 100 200 300 400 W00 600 Temperature (0 F)
CVGah 6.0 12/0V12014 Page 1/2 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-64 Plant St. Liade 2 matmia SAW Hat 83637 OCAPnStUi63NA CapsIle -263 R fEDMET CAPSULE 2630 SURVEIULLAINCE, PROGRAM WETLD METAL Charpy V-Notch Data Temyeratne (cF) Input C.N- Compued C'N Diffential
-80 11) 13.5 -2.48
.40 21.0 24.1 -3.10
-0 36.0 31.6 439 0 48.0 40.5 7.49 50 601) 653 -5.27 72 68.0 751 -7.17 10 91.0 90.9 0.11 150 104.0 96.7 7.34 195 107.0 1014 5.61 250 111.0 1037 726 275 89.0 104.2 -1523 300 130-0 1045 25.47 CVG-aph 6.0 120112_014 Page 202 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietaxy Class 3 C-65 Westinghouse Non-Proprietary Class 3 C-65 CAPSULE 2630 SURVEILLANCE PROGRAM WELD METAL CVGrqh 6.0: Hypertol Tmagmt Cum-e PNiedon 12m1f2014 2:48 PM A=57A8R=558 C=--16.98 T0=4S2D=0.00 Camelaion Coeffmieat =02967 Equahio is A+ h
- IrWT-n~r-ThYc4{f))]
Uppe SfrffLE. = 114.16 lawe&lIof LE = LOD (Fixed Terip@35 mlls7- ~10' 1 F Plant St Iade 2 MaleriaL SA.W Heat 83637 Onleaiubi Capmule 2,63- Ehume.- 140 120 100
.~80-rlt 60
.16
-340 20-
-300 -200 -100 0 100 200 300 400 500 600 Temperature (0 F)
CVr60 121012014 PagelW May 2015 WCAP-WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-66 Plant StL Luck Ma2iiat: SAW Heat 83637 ntaueo NA 20.
!63C CAPSULE 2630 SURVEILLANCE PROGRA.M WELD METAL Charpy V-Notch Data 0
Tanpmrture F) Input LEF. Computed LEY Diffwredga
-SO 9.0 12-3 -3.35
-40 24-0 21.5 2.53
-20 29.0 27.8 1.16 0 40.0 35-5 4.55 50 52.0 58.4 -639 72 66.0 68.9 -2.88 120 91.0 8..5 2.53 150 103.0 972 5.76 195 i07.0 105.6 137 250 111.0 110.7 0.33 275 87.0 1119 -24.86 3_0 132.0 112.6 1935 CVGraph 6.0 12/012014 Page 2 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-67 CAPSULE 2630 SURVEILLANCE PROGRAM WELD METAL
-VC--hi 6.0 Hypebok Tuagaut Curve Pizdan 12/0'2014 2:51PM A=50.ooB=-*MC=trJsTo= 16.30D=.00 Cmeilatim Coefficent = 0-997 Equutiz is A + B' [Th(Cr-T0Y(C4YM)]
Upper Shf4"**-- 10000 (Fxed Low Sff '/.Shear= 0-00 Fie) T erxhue at 50%. Shen - 16340 Plaut St. Lude, MateriaL SAW Heat &33
- 0. 1 1- Ion N C4psule: 2W3 Fhmsm-I10 100 90 80 70 60 I*'
40 30 20 i0
-300
-300 -200 -100 0 100 200 300 400 500 600 Temperature (0 F)
CVGxph 6.0 12/0112014 Page i2 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-68 P tl SL
- Incie 2 Mateil SAW Heat 83637 Oriemtboa NA Q~vwfr. W"3 Funem:
CAPSULE 2630 SURVEILLA.NCE PROGRAM WELD METAL Charpy V-Notch Data Temperature(r F) Imput 4%Sear Cbwfuted %Shiear Differen&Ia
-80 15.0 IL.0 3.99
-40 25.0 22-9 2.24
-20 3010 313 -1.26 0 40.0 412 -1.25 50 65.0 675 -2.51 72 75-0 770 01 120 95.0 90.5 4.53 150 100-0 94.- 5-21 195 I00.0 98.0 2.03 50100.0 99-4 0.6"2 275 100.0 99.6 036 300 100.0 9919 021 CVGmph6,0 12/01!014 Tape 2.2 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-69 CAPSULE 2630 BEAT AFFECTED ZONE 1VGra* 6.0- Hyperboli Twnuipt QrwPfinxfdu l21/V2D14 53 PM A=66.10 B=63-OC = 163.76 TO= 15113S D=0.00 Cmiahtkui Codeffiet-O16 Equatmiuis A +B' [TaW'-1J(C-T0WVThI UP 1 e Sif FmRg = 130-00 (Fkd ~ low ShlfEmmV=y 220 CFixec) TarV30 ft-OIh6=46.4O F Temp@3 5 A-lBxt 6 421T F TmaI*5O ft-1br109.11V F Plant: St. Ludci. 2 Matefid- SAM313B Heat A-8490-2 OriembtatwNA Cqmk- 2&P~ 160 140 120 100 80 60 40 20 o
-200 -100 0 100 200 300 400 500 600 Temperature (0 F)
CVGz~h 6.0 1201OW014 Page I/2 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-70 Plant St. I.Ade I Mateial: SAO3BI Heat A-&go-.2 OfiietdadmINA Caps-e. w63° Fmnee: CAPSULE 2630 HEAT AFFECTED ZONE Charpy V-Notch Data Temperature (*F) Input CV'N Computed ON Diffrentlial
-40 32o 13.5 18.52 10 15.0 215 -6.54 60 13.0 33.8 -20.79 72 410 37.4 7.59 100 51.0 46.8 4.24 120 54.0 54.1 -0,08 150 83.0 656 17.36 180 70.0 772 -7.23 250 119.0 100_6 18.43 250 49.0 100.6 -51.57 300 144-0 112.1 31.86 375 12-6.0 122.2 3.80 CV~n~h 6 -0 12N12014 Par 2f-WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-71 CAPSULE 12630 HEAT AFFECTED ZONTE CVGraph60: Hy&ixeJic TmigatCuiw Pfinweouj 121120142-56PM A= 41205 B =4LO15C-=17287T=10652D =0.00 xica~anCUOeýc=i4909 Equaftu is A +B * [rm*l(C-D+D'l)1] UppezSI%1fLE_=9310 LoavmSheIfLE. -1.00 fFnweD~ Tamp@j35 =Is-- 76,60- F plant St. Lad!2 MatuWa1 SAS33BI Hmeat A4t2 Odentatio1 MA CaqA&: 263' Thww.e: 100 90 80 70 pan 60 s0 40 30 20 10 0 1_
-300 -200 -100 0 100 200 300 400 500 600 Temperature (0 F)
CVGraph 6_0 12/01/2014 Pw w WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-72 iplant St. LAU*eI maL SA555BI Hemt A-Orientwiiox N.1 AU 26 6*Ae CDZO CAPSULE. 2630 HEAT AFFECTED ZONE Charpy V-Notch Data Temperatrt (IF) hiput L E. Cmputed L E. DifferetW
-40 26.0 13.7 1227 10 15.0 21.2 25 60 13.0 313 -18.26 72 42.0 34.0 8.04 100 43.0 40.5 2.50 120 47.0 452 1.75 150 60.0 522 7.93 10 56.0 58.5 52 250 54.0 70.0 -15.99 250 78.0 7.0 9.01 40 83.0 752 7,81 375 77.0 79.6 - i58 cvGraph 6,0 12,0112014 Pagp20 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-73 Westinghouse Non-Proprietary Class 3 C-73 CAPSULE 2630 HEAT AFFECTED ZONE CVG7cr 60 Hypmbo&p Tangent Curve Pfintedm 12112014 2-5 PM A= W5 B--=50.00 C=139.62TO=101.67D=0.00 Cmeatiocmoueficient=V0950 Equtinim is A + B * [Tab(r-lITC+DI!))j Upper Sbhef-/%ew = 100.00 (F=4 i) bW& SlWfi.Sh= 0&00 (FizD Tenmer-afte at 50% Shearm= 101-70 Plant StLucie I Material: SA533BL Beat A-849W2 OfielataimD NA CV9Av.e 26PI Fbaazcre 110 100 90 80 Iýv 7, 09 4-0 rw Q 50 46 40 30-20-0
-300 -200 -100 0 too 200 300 400 500 600 Temperature (I F)
Cv~h& 6-0 1210Lr2014 Par 1/2 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-74 Plant Sr. Lucie 2 Maten[ SAk533B1 Heat A-84904 Oriktiuf. NA CAPSUeL 2637 ZNhE: CAPSULE 2630 HEAT AFFECTED ZONE Charpy V-Notch Data Temprture (0 F) Input %Shear Computed %War Diffemztial
-40 20.0 11.6- &39 10 25.0 21.2 3.80 60 20.0 35.5 -15.50 72 45.0 395 5.47 100 50.0 49.4 0.60 120 50.0 56.5 -6.53 150 75.0 66.6 .35 180 800 75.4 456 250 100.0 89.3 10.67 250 70.0 893 -1933 300 100.0 94.5 551 375 100.0 9&0 195 CVGaph 6.0 1210V2014 PapeY2 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-75 CAPSULE 2630 STANDARD REFERENCE MATERIAL CVGrUFJ.0: llpe*booic Tangent OCW Phitedon 121/12014 3-0t PM A=44,101B=41.90 C=89.08 TO=188.20D=0.00 Coneklti Coeffica =0.974 Equati i +B * [!T'r-T0W+DT1))j Upo -tpuAe.if F 96.00 (Fixed) Lowe Shelf Ener =2-20 (H-ieo) Ternp*30 fl4bs=157.100 F TenqY@3S ft-lba=468_600 F Tmai450 ft-lbw=200.900 F Plant St. Luck 2 Mlaterial:- SA53SB11 Heat EBSTf-Ollff Orionbica'L OCqmke 2630 Fhvaaar i00 9o 80 f-)
.0 I
60 50 40 U 30 20 10 00
-300 -200 -100 0 100 200 300 400 500 600 Temperature (0 F) cvGrph6.0 12/01f2014 PAP in WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-76 Westinghouse Non-Proprietary Class 3 C-76 Pla& SLI Wile Ma2a SAS3W
& 3B1 Heat H MST-Oay Orieztakia LT caps& w. H°ec CAPSULE 2630 STANDARD REFERENCE MATERIAL Charpy V-Notch Data 0
Tempeature I F) Input clVN Computed C%'N Differential
-4O 3.0 2,7 030 50 7.0 58 1.20 100 12.0 12.4 -0.36 125 23.0 l&5 4.47 150 40.0 27.2 12.84 160 27-0 31.3 -1_26 195 33.0 473 -1429 195 45.0 473 29 250 75.0 69.3 5.75 300 89b 797 930 375 93.0 84.8 825 cvGuph 6.0 12)OV2014 Page 212 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-77 CAPSULE 2630 STANDARD REFERENCE MATERIAL CVGraph 6.0: Hyperxbd Tamut Cumne Pated an 12/(120143,03 PM A= 44.19 B = 43.19 C = 110.5 TO =207.15,D=0.00 CQmlatioun Cbefie*t 0=90 Eqiwftx is A + B * [frTf-anDY(C+DTh1] Upper SHlLE = 87.37 Lower Sei..LE.= 1.00 (FixeO Temp,,35 nmLs413300 F Fit St. La& 2 MateriaL: S-A533BI Hear HSST-0L1Y Ofieigation LT C~ars&~ 2630 100 80 70 01-60 50 I-s 40 30 20 10 0 0
.300
=
-ZOO
= =-100
-100 0I 0
100 100 200 200 0 300 400 400 5 500 600 600 Temperature (° F) CVGnph 6-0 12/01t2014 Page V2 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-78 Phat St Icki2 MiateikL SA,"3BI Heat HSST-OIMY OnkentamirLT CpsunL- 263- fluxee CAPSULE 2630 STANDARD REFERENCE MATERIAL Charpy V-Notch Data Ttupram (!) Input LIE. Computed L E Diffnintial
-40 1.0 2-0 -0A9 50 7.0 5.8 1.25 100 11.0 11.9 -0.87 125 18.0 16.9 1.06 150 33.0 23.7 9.34 160 29_0 26.8 1.19 195 34.0 39.5 -5.46 195 29.0 39.5 -1046 250 670 60.1 68.6 300 77.0 73.8 3-20 375 80.0 83,4 -3.42 C~3arph 6.0 1YI2IC014 Pape12 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-79 CAPSULE 2630 STANDARD REFERENCE MATERIAL CVGih 60- Hyebolic Tangent Cnve Printed on 1211Of014 3:05 *M A =5&00 B = 5000 C =76-99 TO = 190.04 D = 0.00 Canelatioa Coefficient =0-973 Equation i A + B
- nTw1-T1DY(C+IDT))]
Upper Sdf %eSbeu= 100-00 (Fixed) Lower Sx-Hf-/.Sben==0-00 (Fixed) Tempn"ature at 50% Sher= 190.10 Plant St.L :I 2 Material: S.33B1 Heat IJ ;ST-0IMY Orientaion: LT Capsulec 203° Fmeme: 110 100 I 90 80 _ _ _ _ _ __ _ _ _ 1W 70 00 60 iO50
.,40 I - - - LCI J -! L 30 20 10 0
00 -200 -100 0 100 200 300 400 500 600 Temperature (0 F) cVoraph 6.0 12/01V2014 Pge1/2 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-80 Plant St. Lude 2 Material" S.A5331B1 Heat: HSST-0LMY Onieunmn- LT Capsule. 2635 CAPSULE 2630 STANDARD REFERENCE MATERIAL Charpy V-Notch Data Temperature (I F) Input %Shear Computed %Sheax' Differential
-40 0.0 0.2 25 50 5.0 2-5 100 15.0 837 6.30 125 10.0 15.5 4.53 150 35.0 26&0 8.99 160 30.0 313 -134 195 50.0 5312 23 195 35.0 532 -1823 250 100.0 82.7 1728 300 100.0 94.6 536 375 1o0.0 992 0.79 CVGrph6 0 11D12014 Page 1)2 WCAP-17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-81 CAPSULE 970 IS PILATE M-605-1 (LONGn-UDI.NAL) CV6TapJ 6.0: Hyperbolic Tangent Cwvtue Pnnted on 12/grA014 9-09 AM A=5510NIOB=51.90 C=116.%6TO= 1&4.60D= (LOO Correlation Coeffuient= 0-99 Equation is A +B *[TaiX(T-TY(C+DTh]j Upper Sh~lf~nmgy = 102.00 (F=4ed Iiow Sik1f Enffff = 220 (Fizd) Tenip@iJQ fl-lbs-12433F TaxpW5 AMba=1379GVF Temprx450 ftlb-l-173_30' F Plait St. Luck 2 Matmmil: SA:-d3BI Heat.A-849M2 OrienibiomnLT Capsole:. 970lum 125 100 q~75 - 25-0
-300 -200 -100 0 100 200 300 400 5"0 600 Temperature (I F)
CV~mph 6.0 1210&2014 Page 112 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-82 Westinghouse Non-Proprietary Class 3 C-82 Plau t.SLuci eat A-8490-2 Orientaiiom L r cQuk 97" Fluwe: CAPSULE 970 IS PLATE M-605-1 (LONGITUDIN-AL) Charpy V-Notch Data Temupraetux (mF) Iawt C'V-N Computed CN-" Differefnial 70 19.0 153 3.73 95 35.0 21.0 14.00 110 28.0 253 2-71 120 43.0 28-5 14.47 140 24.0 35.9 -11.85 150 2&.0 39.9 41.89 170 67.0 485 18.47 200 41.0 620 2lD2 200 42.0 62-0 -20.02 260 111_0 95.1 25.85 300 100.0 95.1 491 375 113.0 104.1 9-93 cVoGrap 60 12/08r2014 Pae 2J2 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-83 CAPSULE 970 IS PLATE M-605-1 (LONGITUDINAL) CVGrnh 6.0- Hypmo Tmgai Cunve Printed on L2/&1-014 9:15 AM A = -3.40 B= 52.40 C = 162.40 TO = 20735 D = 0.00 Cmehiboi Coefficiet = 0-901 Eqpm-a is A+ t ff fF-T0(C+D¶))l uprShelffLE = 1052S0 Lowe Shelf L-E = 00 (Fized Temp@35 ni,1s4Z0' F Plant St. Lucie 2 M~alesLa SA533B1 Heat A-8490-2 OQienwiloniZT Capsule: Or Tbueace: 120 100 0 80 as 60-S40-20 0 =
-300 -200 -100 0 100 200 300 400 500 600 Temperature (0 F)
CQh6.0 12/08/214 Page 1/2 WCAP-17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-84 Westinghouse Non-Proprietary Class 3 C-84 Plant St.lmdi MatajmaL: SMS313B1 eat A--890-2 Orientatioll L] Capsule: i97, Fluence CAPSULE 970 IS PLATE M-605-1 (LONGITUDINAL) Charpy V-Notch Data Tempera*mr (OF) Input L E. Computed L E. Differential 70 15.0 173 -230 95 30.0 220 &.00 110 27.0 25.3 1-72 120 360. 27.7 8.35 140 25.0 32.1 -7,83 150 29.0 35,6 -6.63 170 59.0 416 17.44 200 32.0 51.0 -19.03 200 380 510 -13.03 260 89.0 69.8 19.18 300 82.0 804 1_58 375 $9.0 94.0 -5.00 CGraph 6.0 120*0014 Par M WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-85 CAPSULE 970 IS PLATE M-605-1 (LONGITUDINAL) CVC 6. Hyperbolic Tamn t Cum- Pnnted on 1213/"4 9-49 AM A=S5O B= 50.0O C=11016T0 = 18044 D=0.00 CunatVinaaCoeffldiet = 0.934 Equation is A +B * [T-rC1(r-ToY(C+DT))] Uppe Self 1/.Shew = 100.00 (ixed) Lower Sbef %Sheui 0.00 (Fixed) Texpwtwe at 5V0 Sear = 18050 Plnt. SL. Laide 2 MatezWi: SAMMIB Heg A-4900-2 Oiientaliozr LT cujsule- 970 Fluence-110 100 90 80
,- 70 60 coo 1...
C6 4o 40 30 20 10 00
-300 -200 -100 0 100 200 300 400 500 600 Temperature (0 F)
CVcV 6-0 12/08t2014 Pwin WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-86 Plant St. U16 2 Maenil: SA533BI I- eat A-8490-2 Ofienuadon: Ll " Cvsuke. 97r Fhwen CAPSULE 970 IS PLATE M-605-1 (LONGITUDINAL) Charpy V-Notch Data Tcmperuturt ( IF) Input *%*a Computed %Shear Difffrenmal 70 2010 11.9 8.13 95 25.0 17.5 7.51 110 25.0 21.8 3.23 120 3X.0 2510 4.98 140 25.0 32.4 -743 150 30.0 36.5 -6.53 170 60.0 45-3 14.72 m00 45.0 58,8 -13,79 200 40.0 598 -18.79 26D 100.0 80.9 19.09 300 100.0 89.8 10.24 375 100.0 97. 2.84 cVGmph6-o 1M2/08/014 Page 2,2 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-87 CAPSULE 970 IS PLATE M-605-1 (TRANSVERSE)
"VGrh6.0: Hyperbac Tan=Vt Curve Pijted an 12AM2014 9:22 AM A=40100B=37.90 C=114.35 T0=189.17 D=0.00 CoekatiwiCoen aut = 0910 Equafim is A +B - *n(r1-T0Y(C-{YO)j Utrpw Shef rB = 79-00 (Fixed) Low SefEmV = 2O(Fixe Temu ,30ft4bs=15&00c F Ta@35 fi-Ib=173_700 F Teiq@50 ft-lbw=219W0 F Plant St. LuiE 2 MatderiaL SV5,33B1 Heat A-&g0-2 Ocenatio- TL Capmde FhwweL 100 80 60 1-40 20 o F - - I I I I f I I l I 1 1
-300 -200 -100 0 100 200 300 400 500 600 Temperature (0 F)
CVGraph 60 12/08/2014 Page 1/2 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-88 Plant St. Lace MateiaL- S&S33BI Eeat A-8490-2 OrieniawTL n Cvsl97v Flumme CAPSULE 970 IS PLATE -M-605-1 (TRANSVERSE) Charpy V-Notch Data Temp*mtue (IF) bput CVN- CCmputed CV-N Differential "7 l.0 10,6 7.41 95 16.0 144 156 120 27.0 19.6 738 140 a.0 24.7 -2.74 150 37.0 27.6 9.40 170 36.0 33.2 2.19 200 25.0 43-7 -18.69 2m 29.0 43.7 -14.68 230 54.0 53.1 091 270 80.0 632 1623 300 78.0 68.5 9.54 375 77.0 75.2 1.83 CVGmph 6.0 12/W2014 Pae 2*2 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-89 Westinghouse Non-Proprietary Class 3 C-89 CAPSULE 97" IS PLATE M-605--1 (T7RANSVERSE) CVGr~h 6.0- Hypbahc Tan~it Oarv Pzmfed on 12AXM214 9-43 AM A =40-30 B = 39.30 C -146M2 TO =215A D= ILO CwewiouCceffkzent=0916 Equaim is A+B - fjanl((T-1Y(C4IYI))J Upper SheffLF =79-59 Lower~belf E = 1.00 (Fixed Tempq-35 niilsl-96 F Piant St. Lucie i Mate:W: SAS3BBL Heat A4U90-2 Orientatiom TL CpSUIEc 97' Fluate 100 80 60 I-.. 40 "!0 20 ; , i "-.Q i ,0 0
-.300 -200 -100 0 100 200 300 400 500 600 Temperature (0 F)
CVGrh6-0 12/012014 Page 1/2 May 2015 WCAP- 17939-NP WCAP-17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-90 Plant St.Luck i ,fMatezL SA,533BI Heat A..&90-22 Ofiaftatim TL Cqxlde: 97- F'oeme CAPSULE 970 IS PLATE M-605-1 (TANSVERSE) Charpy V-Notch Data Temtratmre (1 ) InputL E. ComputedL L Diffemetial 70 14.0 10-5 3-53 95 10 13-7 -1170 120 240 17.7 625 140 22.0 21.6 038 150 34.0 23.1 1024 170 37.0 28.4 8.60 200 230 36.1 06 20 23.0 36,1 -13.06 230 47T0 4441 294 270 60.0 54.2 5.4 300 650 606 437 375 68.0 71.5 -3.52 CVGraph 60 12M0gt2014 Page I22 WCAP-17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-91 CAPSULE 970 IS PLATE, M-605-1 (TRANSVERSE) CVGraph 6.0: Hyperbok Tangodt CmePidiem an 1,X014 9-45 AM A=-0.OO B =54O C= 1W.82 TO =1g7.21 D= 0.00 Eqation is A+B * ['rwb(C-T¶Y(C+DT))1 Ua5er Shelf hS ea = 100.00D ) Lowe Shelf%1Slwr = 0,00 (Fied) Tempnmtire at 50% Shen= 18730 Flu&t St. Ladie 2 MateiaL- SAS33B1 Heat A.490-2 Oritnutaio TL Capsule. 9rk~ Fhmnm 11o 100 90 80 70 ri~ 60 so I.' 40 30 20 to 0I-
-300 -200 -100 0 100 200 300 400 500 600 Temperature (0 F) cv~raph 6.0 12/0&2014 Par LI2 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C -92 Plant SL Ldk .ManmWal:SA533BI Heat A-8490-2 o TCse- 97" FlHume: CAPSULE 970 IS PLATE M-605-1 (TRANSVERSE) Charpy V-Notch Data Tflrmnpatur IF) input %Shear Cmued %She2r Differntial 70 15.0 9-7 535 95 20.0 14.7 531 1-20 25b 21.7 3.29 140. 25.0 28-9 -3.89 150 45.0 33,0 12.04 170 45.0 419 3.14 200 35.0 56.1 -21.07 0045.0 561 -11.07 230 701 693 0.65 270 100.0 82.9 17.09 300 1001) W9.6 10-41 375 IQO.0 973 2.70 CVGraphi 6.0 12/09_M014 Page 2/2 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-93 Westinghouse Non-Proprietary Class 3 C-93 CAPSULE 970 SURVEILLANCE PROGRAM WELD METAL CVCh6.0. Ho*,pebc Tmint Cuve Pfixio 12/90214 9.51 AM A = 4&60 B = 46.40,C= 9215 TO = "A1D = LOG Caffehaim Co ff=ieial 0-951 Equationis A+B* frznI((-T0OWC+DI')] Upper s1qIf Eimu= 95ý00 (FmeOd) sbrelEfng = 210 (Fimx Tm 3i* f t-,b-25.
- 70AF Temap 35 l-ft --14.40 F
- Taip50 ft-bs 16.20F F Plat St. Lmcie 2 mate*ial: SAW Heat 83637 Or ntabiom NA Capsule: 97
- Fkua ne:
120 100 :_ _
.... .. .. 0 0* -..9....- ,, ;r W
600 40 20
-300 -200 -100 0 100 200 300 400 500 60(
Temperature (01?) CVGrph6.0 12A0W214 Pag V2 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C -94 Plant S. Laud 2 MaNmal: SAW Hft 367 oAPSULE11%k Casule- PR FkLnceT CAPSULE 970 SURVEILLANCE PROGRAM WELD METAL Charpy V-Notch Data Te- eatu-r F) input c(N Com0, ted CN ifffermial
-60 17.0 17.9 -0.39
-40 25.0 24.4 0.64
-30 22.0 282 -623
-25 24.0 30.3 -631 2_0 45.0 32.5 12.52 0 49.0 41.9 7.10 20 49.0 51.9 -2.91 70 61.0 74.0 -12.98 120 93.0 86.6 6.35 170 113.0 92.0 21-00 250 82.0 94i5 -12.46 300 93.0 94., -1.'2 CVGraph 6.0 12l/2014 Page 202 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-95 CAPSULE 970 SURVEILLANCE PROGRAM WELD METAL CVGnph 6.0: Hyperbolic Tangent Cwve Pfmled am12/&2014 10:04 AM A = 41-12 B = 40.22 C = 8&46 TD = 1L76 D = &.00 Qxxauebft Coefflickw = 0967 Equatliuis A + B * [Tw (Cr-TQY(C+DI))J Upper SheffLE =91.45 Lowa %&fL.__ 1.00*Fied Teazp35 mils- -2 00"'F Plant St. lIne2 Maateri: SAW Hwt 83637 Oneutahmu NA Capsl*e: 97* nume: 100 0 0 o ------ 0 60 40 260 0. . * -
;4/0 2 0 0 f l
-300 -200 -100 0 100 200 300 400 500 600 Temperature (I F)
CVGrh6,0 12/&2014 Pag1e2 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-96 Westinghouse Non-Proprietary Class 3 C-96 amt St Lucie 2 Mae"a: WSAW Heat 83637 Ono NA capk. ie97g nRu CAPSULE 970 SURVEILLANCE PROGRAM WELD METAL Charpy V-Notch Data Temperature (, 1) InputL E. Cmnputed L E. Differeaffid
-60 14.0 14.3 -026
-40 21.0 20. 0.95
-;0 15.0 215 53
-25 25.0, 25A -0441
-20 36.0 27A 8.63 0 45.0 35-9 9.09 20 35-0 45.0 -9496 70 60.0 64,4 -4.44 120 94D0 75.0 &.96 170 84-0 793 4.74 250720 11 -9.08 300 82.0 813 0.67 CVGrap 6-0 12/08_2014 Page2f2 WCAP- 17939-NP May 2015 Revision 0
Westingbouse Non-Proprietary Class 3 C-97 Westinghouse Non-Proprietary Class 3 C-97 CAPSULE 970 SURVEILLANCE PROGRAM WELD METAL CVGaph 60. Hypboic Tangen Curve Prind ma12.'2014 10:16 AM A=50.001B 5M.O C=74.4 TO=8.73 D=0.00 Carnelatim Coedicient= 0.995 Equtm is A +B - [Tw*aa(-flY(C+DT))] Uer Shf %Mar= 100.00 (Fixed) Lowe -Sff/%Sw=0(0 0fired) Tempuerture at 504 She* = 8.90 plant St.Luci 2 MatriaL- Skw Heat 83637 OrkiatuicaL NA Capsu3le- 9r 110 100 9o 80
,. 70 U2 60
.50 S 40 30 20 10 0 L-
-300 -200 -100 0 100 200 300 400 500 600 Temperature (I F)
Cva-ph&6.0 12AM14 Pape 112 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-98 Westinghouse Non-Proprietary Class 3 C-98 Plant St Lucie 2 MatWal: SAW Heat 8&637 Ozientafin: NA Cjsue: 97' Fhniew CAPSULE 970 SURVEILLANCE PROGRAMNI WELD METAL Charpy V-Notch Data Temperatur* (I F) Input %Shear Compud %Shear Differential
-60 15-0 13.6 137
-40 25-0 21.3 3.74
-30 20.0 26.1 -6.10
-2 q25.0 28.8 -3.7S
-20 30.0 31.6 -1.61 0 50.0 44.2 5,84 20 60.0 573 2.49 70 W0.O 3.8 -3,94 120 95.0 952 21 170 98.0 98.7 -0,70 250 100.0 99.8 0.15 300 10o.o 100.0 0.04 CVGraph6.0 12/0W!014 Page2n2 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C -99 CAPSULE 970 HEAT AFFECTED ZONE CVGaph 60: Hyperbolic Tagent Cunve.Prin l12S2014 10:27AM A=47.60 B=45.40 C=435.21 TO=40.99 D=0.00 Couelaia Coefficient = D-07 E*zation is A + B
- UTab((r-TT- C+mD))
Upper Shelf Enmg = 9300 (Fixed) Lower Shef =2-0
=TEn Fi -*e0)
Tempr3M ft-lys'-137,00P F Teiiýý35 &M-lbs-.3000 F Tenoj50ft-Ihs64100 F Moat St.Lucie 2 MateriaL S.A:33B1 Heat A-3490-2 Orientaliol NA.4 Cqpsik 970 140 120 100 80 60 U 40 20 0 1 I 1t 1
-300 -200 -100 0 100 200 300 400 500 600 Temperature (0 F)
CVCraph 6.0 1-/0212014 Page V2 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-100 Westinghouse Non-Proprietary Class 3 C-100 Plant St. lude 2 _Material: S$-33B1 Heat A-8442 OrientasimonN Capsule: *'7' Flumee CAPSULE 970 HEAT AFFECTED ZO-NE Charpy V-Notch Data Temperm-m Y) Iput CrN Computed CYN Differnvu 50 106.0 48-5 57-46 70 17.0 50.6 -33.62 t0o 42.0 537 -11.72 120 34.0 55.8 -21.75 130 24.0 56.8 76 140 120.0 572 62-25 150 21.0 59.7 -37.74 170 22.0 607 -38,68 180 86.0 61.6 2437 250 12.0 67.9 55.13 300 59.0 71.8 -12.82 375 68.0 76.9 -8.90 CWcrAvh 6.0 12MV014 Page 2ý2 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-101 Westinghouse Non-Proprietary Class 3 C-i 01 CAPSULE 970 HEAT AFFECTED ZONE CV"4Guep6-0. Hypebolic Tangen Curve Prinkd n 122014 10:38 AM A=39.49 B=3&.49 C=300M TO= 116.0 D=0.00 Ccdation Coeffieut = 0-444 Equalic is A + B - [TInmflJ-YW(C+DT))] UpperiSbeLE = 77.97 Lower Shef LE_ = 1.00 CFired Tempg35 mlsn S1.60P F PlaitSL. Lm*i 2 MaeilS.AS3BI Heat A-8490-I Ozientwiioa NA Czpsule: 97' Rmeze: 90 80 70 60 ii' 0 50 IMO 40 30 20 10 0 L-
-300 -200 -100 0 100 200 300 400 500 600 Temperature (0 F)
CVGruph 6.0 12/U/2014 Page in-May2015 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C- 102 Westinghouse Non-Proprietary Class 3 C-102 Plait St. Lucie I Matezal: S1533B1 Hear A-890-2: Oxlltulioi "N's Capsde: 970 Flank CAPSULE 970 HEAT AFFECTED ZONE Charpy V-Notch Data Temperaturt (0 F) Inpu L E. Comptied L E Differentai 50 580 31.1 26.92 70 It0 33-6 -1555 100 37,0 37.3 -034 120 29.0 39.9 -10.90 130 22.0 412 -19.17 140 V_0 42.4 39-55 150 20.0 437 71 170 27.0 462 -1922 1S0 53.0 475 5.55 250 20.0 55.5 24.51 300 63.0 60.4 2-61 375 57.0 66.2 -9.24 CVGph 6 0 12*/2014 Papge 2r WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-103 CAPSULE 970 HEAT AFFECTED ZONE CVGr*oa 6.0-. Hyperbolic Tangnt Curve Pfinted an 12/gf2014 1040 AM A = 50.00 B =540.00 C = 17225 TO =92.39 D =0.00 Cozfreaticn Coefficient = 0343 Equation isA + B * [Tahnt(f-TVKy(C+DTM) Uppe Shelr Sbear= 100.00 (Fixed) Lower Shelf %Shear =0.00 (FMi Temzerabze at 50% Shear= 9240 Plant St. Lmce 2 Material: S&W33B1 Heat- A-34W0-2 Ouientuion- MAL Capsue:1ý FluAere. 110 100 90 80 L 70 rEn 60 S50
~40 30 20 10
-300 -200 -100 0 100 200 300 400 500 600 Temperature (* F)
CVGraph 6.0 12100014 Page 2 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 C-104 Westinghouse Non-Proprietary Class 3 C- 104 plant st. Lncie Mateial SAS3SB1 Heat A4-UW2 Orient~fi=onxA C¢,ule: 9
- mace:
CAPSULE 970 HEAT AFEECTED ZONE Charpy V-Notch Data Tempammtre f) Input m4Shear Compued %Skar Differental 50 60.0 38-0 ".02 70 30n0 43.6 -13.6 100 55.0 52-2 2."-0 1N0 50-0 57.9 92 130 5011 60.7 -10.71 140 95.0 63.4 31.57 150 4540 66.1 -21.07 170 45.0 711 -2X.05 18.0 ISO 73.4 11.62 250 100.0 86,1 1390 300 100-0 91-7 &30 375 100.0 96.3 3.66 CGjph 6.0 121W-014 Page 2 WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 D-1 APPENDIX D ST. LUCIE UNIT 2 SURVEILLANCE PROGRAM CREDIBILITY EVALUATION D.1 INTRODUCTION Regulatory Guide 1.99, Revision 2 [Ref, D- 1] describes general procedures acceptable to the NRC staff for calculating the effects of neutron radiation embrittlement of the low-alloy steels currently used for light-water-cooled reactor vessels. Positions 2.1 and 2.2 of Regulatory Guide 1.99, Revision 2, describe the method for calculating the adjusted, reference temperature and Charpy upper-shelf energy of reactor vessel beltline materials using surveillance capsule data. The methods of Positions 2.1 and 2.2 can only be applied when two or more credible surveillance data sets become available from the reactor in question. To date there have been three surveillance capsules removed and tested from the St. Lucie Unit 2 reactor vessel. To use these surveillance data sets, they must be shown to be credible. In accordance with Regulatory Guide 1.99, Revision 2, the credibility of the surveillance data will be judged based on five criteria. The purpose of this evaluation is to apply the credibility requirements of Regulatory Guide 1.99, Revision 2, to the St. Lucie Unit 2 reactor vessel surveillance data and determine if that surveillance data is credible. D.2 EVALUATION Criterion 1: Materials in the capsules should be those judged most likely to be controlling with regard to radiation embrittlement. The beltline region of the reactor vessel is defined in Appendix G to 10 CFR Part 50, "Fracture Toughness Requirements" [Ref. D-2], as follows:
"the region of the reactor vessel (shell material including welds, heat affected zones, and plates orforgings) that directly surrounds the effective height of the active core and adjacent regions of the reactor vessel that are predicted to experience sufficient neutron radiation damage to be considered in the selection of the most limiting materialwith regardto radiationdamage."
WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 D-2 The St. Lucie Unit 2 reactor vessel beltline region consists of the following materials:
- 1. Intermediate Shell Plates M-605-1, M-605-2, and M-605-3
- 2. Lower Shell Plates M-4116-1, M-4116-2, and M-4116-3
- 3. Intermediate Shell Axial Welds (Heat # 83642, Flux Type Linde 0091)
- 4. Intermediate Shell Axial Weld Repair (Heat # 83637, Flux Type Linde 0091)
- 5. Intermediate to Lower Shell Girth Weld (Heat # 83637 and 3P7317, Flux Type Linde 124)
- 6. Lower Shell Axial Welds (Heat # 83637, Flux Type Linde 0091)
Per WCAP-1 5040, Revision 1 [Ref. D-3], the St. Lucie Unit 2 surveillance program was developed to the requirements of ASTM El185-73. Intermediate shell plate M-605-1 had the highest initial RTNDT value and the second highest Cu wt. % value. This plate is also the same heat of material as the intermediate shell plate M-605-3; therefore, it is also representative of a second beltline plate. Intermediate shell plate M-605-2 has a higher wt. % Cu value; however, it has superior fracture toughness properties (Initial USE and RTNDT) as compared to plate M-605-1. Lastly, all three lower shell plates, while having less than or equivalent initial USE values, have lower initial RTNDT values and significantly better wt. % Cu values when compared to plate M-605-1. Hence, the intermediate shell plate M-605-1 was chosen as the most limiting plate material. The surveillance weld metal was selected as Heat # 83637, Flux Type Linde 124, Lot # 0951. The selection of this weld material was the general practice for Combustion Engineering surveillance programs because it was considered representative material, even though this material is not directly applicable to any of the reactor vessel beltline welds. The vessel welds fabricated using the same weld wire heat, 83637, are the intermediate shell axial weld repair, and the lower shell axial welds. However, these welds all used a different Flux Type: Linde 0091 for the reactor vessel and Linde 124 for the surveillance weld. The intermediate to lower shell girth weld seam used the same heat and flux type; however, this weld was made with a second weld wire, heat # 3P7317, making the surveillance weld only partially applicable to the vessel. Hence, weld wire Heat # 83637, Flux Type Linde 124 (flux lot # 0951) was utilized in the surveillance program. Based on the above discussion and the methodology in use at the time the program was developed, the St. Lucie Unit 2 surveillance material meets the intent of Criterion 1. Criterion 2: Scatter in the plots of Charpy energy versus temperature for the irradiated and unirradiated conditions should be small enough to permit the determination of the 30 ft-lb temperature and upper-shelf energy unambiguously. Based on engineering judgment, the scatter in the data presented in these plots is small enough to permit the determination of the 30 ft-lb temperature and the USE of the St. Lucie Unit 2 surveillance materials unambiguously. Hence, the St. Lucie Unit 2 surveillance program meets this criterion. WCAP-17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 D-3 Criterion 3: When there are two or more sets of surveillance data from one reactor, the scatter of ARTNDT values about a best-fit line drawn as described in Regulatory Position 2.1 should normally be less than 28 0 F for welds and 17°F for base metal. Even if the fluence range is large (two or more orders of magnitude), the scatter should not exceed twice those values. Even if the data fail this criterion for use in shift calculations, they may be credible for determining decrease in USE if the upper shelf can be clearly determined, following the definition given in ASTM E185-82 [Ref. D-4]. The functional form of the least-squares method as described in Regulatory Position 2.1 will be utilized to determine a best-fit line for this data and to determine if the scatter of these ARTNDT values about this line is less than 287F for welds and less than 177F for the plate. Following is the calculation of the best-fit line as described in Regulatory Position 2.1 of Regulatory Guide 1.99, Revision 2. In addition, the recommended NRC methods for determining credibility will be followed. The NRC methods were presented to industry at a meeting held by the NRC on February 12 and 13, 1998 [Ref. D-5]. At this meeting the NRC presented five cases. Of the five cases, Case 1 ("Surveillance data available from plant but no other source") most closely represents the situation for the St. Lucie Unit 2 surveillance plate and weld material. Furthermore, per ASTM E185-82, only transverse orientation base metal is required to be included in surveillance capsules. In addition, ASME Code requires that initial RTNDT and USE be determined via testing of Charpy V-notch specimens oriented in the transverse direction. Therefore, even though 10 CFR 50.61 states that "Surveillance program results means any data that demonstrates the embrittlement trends for the limiting beltline material, including but not limited to data from test reactors or from surveillance programs at other plants with or without surveillance program integrated per 10 CFR Part 50, Appendix H," ASTM E185-82 suggests inclusion of a greater quantity of Charpy V-notch test specimens, whenever possible (which was done for St. Lucie Unit 2). The longitudinal orientation Charpy V-Notch test results do demonstrate embrittlement trends for the limiting beltline plate material. Consistent with 10 CFR 50.61, the longitudinal and transverse orientation plate data are all considered in Tables D-1 and D-2. As an altemative presentation of the plate data, an interim chemistry factor and credibility conclusion is presented in Tables D-3 and D-4 using only the transverse orientation base metal Charpy V-notch test results. WCAP-17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 D-4 Case 1: Intermediate Shell Plate M-605-1 and Weld Heat # 83637 Following the NRC Case 1 guidelines, the St. Lucie Unit 2 surveillance plate and weld metal (Heat # 83637) will be evaluated using the St. Lucie Unit 2 data. This evaluation is contained in Table D-1. Note that when evaluating the credibility of the surveillance weld data, the measured ARTNTDT values for the surveillance weld metal do not include the adjustment ratio procedure of Regulatory Guide 1.99, Revision 2, Position 2.1, since this calculation is based on the actual surveillance weld metal measured shift values. In addition, only St. Lucie Unit 2 data is being considered; therefore, no temperature adjustment is required. Table D-1 Calculation of Interim Chemistry Factors for the Credibility Evaluation for St. Lucie Unit 2 Using All Available Surveillance Data Material Capsule Capsule Fluence FF F A FFT ______ _ (x10 19 n/cm 2, E> 1.0 MeV) (OF) (OF) Intermediate Shell Plate 830 0.140 0.488 45.1 21.99 0.238 M-605-1 (Longitudinal) 970 2.250 1.220 132.7 161.84 1.487 Intermediate 830 0.140 0.488 29.4 14.33 0.238 Shell Plate M-605-1 2630 1.000 1.000 102.7 102.70 1.000 (Transverse) 970 2.250 1.220 127.6 155.62 1.487 SUM: 456.48 4.450 CF M-605-1 (FF
- ARTNDT) + I(FF 2) = (456.48) + (4.450) = 102.6°F 830 0.140 0.488 15.8 7.70 0.238 Surveillance Weld Metal 2630 1.000 1.000 26.5 26.50 1.000 (Heat #83637) 970 2.250 1.220 24.8 30.25 1.487 SUM: 64.45 2.725 CF Su. Weld = X-(FF
- ARTNDT) +Y(FF 2 ) = (64.45) + (2.725) = 23.7°F WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 D-5 The scatter of ARTNDT values about the functional form of a best-fit line drawn as described in Regulatory Position 2.1 is presented in Table D-2. Table D-2 St. Lucie Unit 2 Surveillance Capsule Data Scatter about the Best-Fit Line Using All Available Surveillance Data CF Capsule Measured Predicted Scatter <17 0 F Material Capsule (Slopebt-li) Fluence 9 FF ARTNDT, ARTDJ ARTJIDT (Base Metal) ___________ _ (OF) (x 10 n/cm 2) (`F) (OF) (OF..) <281F (Weld) Intermediate Shell 830 102.6 0.140 0.488 45.1 50.0 4.9 Yes Plate M-605-1 (Longitudinal) 970 102.6 2.250 1.220 132.7 125.1 7.6 Yes 830 102.6 0.140 0.488 29.4 50.0 20.6 No Intermediate Shell Plate M-605-1 2630 102.6 1.000 1.000 102.7 102.6 0.1 Yes (Transverse) 102.6 2.250 1.220 127.6 125.1 2.5 Yes 830 23.7 0.140 0.488 15.8 11.6 4.2 Yes Surveillance Weld _ Metal 2630 23.7 1.000 1.000 26.5 23.7 2.8 Yes (Heat #83637) 23.7 2.250 1.220 24.8 28.9 4.1 Yes From a statistical point of view, +/- 1a would be expected to encompass 68% of the data. Table D-2 indicates that four of the five surveillance data points fall inside the +/- 1*a of 17°F scatter band for surveillance base metals; therefore, the plate data is deemed "credible" per the third criterion. Table D-2 indicates that three of the three surveillance data points fall inside the +/- la of 28°F scatter band for surveillance weld materials; therefore, the surveillance weld data is deemed "credible" per the third criterion. May 2015 WCAP- 17939-NP 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 D-6 Table D-3 Calculation of Interim Chemistry Factor for the Credibility Evaluation for St. Lucie Unit 2 Using Only Transverse Orientation Base Metal Surveillance Data Material Capsule Capsule Fluence AJTNDT Fl?*ARTNT FF
....... ....... . . , .... (x 10 19 n/cm 2 , E > 1.0 MeV ) (OF ) (OF ) __ _ _..
Intermediate 830 0.140 0.488 29.4 14.33 0.238 Shell M-605-lPlate 263o 1.000 1.000 102.7 102.70 1.000 (Transverse) 970 2.250 1.220 127.6 155.62 1.487 SUM: 272.65 2.725 CF M-605-1 TL Only - X(FF
- ARTNDT) + X(FF2 ) = (272.65) + (2.725) = 100.1 0F The scatter of ARTNTT values about the functional form of a best-fit line drawn as described in Regulatory Position 2.1 is presented in Table D-4 for only the transverse base metal data.
Table D-4 St. Lucie Unit 2 Surveillance Capsule Data Scatter about the Best-Fit Line Using Only Transverse Orientation Base Metal Surveillance Data CIF Capsule Measured Predicted Scatter <1F Material Capsule (Slopeb, tf-it) Fluence 2) FF ARTNDT ARTNDT ARTNDT I(Base Metal) ___________ _____ (OF) (X 10,9 nicm) (OF) (0 1D (0 1F) 830 100.1 0.140 0.488 29.4 48.8 19.4 No Intermediate Shell Plate M-605-1 263° 100.1 1.000 1.000 102.7 100.1 2.6 Yes (Transverse) 100.1 2.250 1.220 127.6 122.1 5.5 Yes From a statistical point of view, +/- Icy would be expected to encompass 68% of the data. Table D-4 indicates that only one of the three surveillance data points falls outside the +/- 1ca of 17'F scatter band for surveillance base metals. With consideration of the three points, 67% of the data is within the 17'F scatter band. The one data point that falls outside of the scatter band is by 2.40 F, which is a small amount considering that the scatter band is 34°F (+/- 17°F). Furthermore, the two data points that are at fluence levels closer to the actual current vessel fluence and projected end of 40-year life fluence have very minimal scatter (2.6°F and 5.5°F). Since comparisons of the measured and predicted shifts for the two most recent data points have minimal scatter, it is reasonable to state that the transverse plate data only is deemed "credible" per the third criterion. WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 D-7 Criterion 4: The irradiation temperature of the Charpy specimens in the capsule should match the vessel wall temperature at the cladding/base metal interface within +/- 25'F. The surveillance materials are contained in capsules positioned near the reactor vessel inside wall so that the irradiation conditions (fluence, flux spectrum, temperature) of the test specimens resemble, as closely as possible, the irradiation conditions of the reactor vessel. The capsules are bisected by the midplane of the core and are placed in capsule holders positioned circumferentially about the core at locations near the regions of maximum flux. The location of the specimens with respect to the reactor vessel beltline provides assurance that the reactor vessel wall and the specimens experience equivalent operating conditions such that the temperatures will not differ by more than 25 0 F. Hence, Criterion 4 is met for the St. Lucie Unit 2 surveillance program. Criterion 5: The surveillance data for the correlation monitor material in the capsule should fall within the scatter band of the database for that material. The St. Lucie Unit 2 surveillance program does contain Standard Reference Material (SRM). The material was obtained from an A533 Grade B, Class 1 plate (HSST Plate 01). NUREG/CR-6413, ORNL/TM-13133 [Ref. D-6] contains a plot of Residual vs. Fast Fluence for the SRM (Figure 11 in the report). This Figure shows a 2cr uncertainty of 50'F. The data used for this plot is contained in Table 14 in the report. However, the NUREG Report does not consider the recalculated fluence and ARTNDT values for Capsule 2630. Thus, Table D-5 contains an updated calculation of Residual vs. Fast fluence, considering the recalculated capsule fluence and ARTNDT values for Capsule 2630. Table D-5 Calculation of Residual vs. Fast Fluence for St. Lucie Unit 2
- :* ~~Cap*sule f ::
CapulisxO' n/M2 F Measured Shift RG 1.99, Rev. 2 Residual C s (i .0 FF i (.3(2) Shift ('F) ) (Pf)(*) 2630 1.000 1.000 131.2 136.10 4.9 Notes for Table D-5: (a) Measured AT30 values for the SRM were taken from Section 5 of this report. (b) Per NUREG/CR-6413, ORNL/TM-13133, the Cu and Ni values for the SRM (ISST Plate 01) are 0.18 and 0.66, respectively. This equates to a chemistry factor value of 136.1*F based on Regulatory Guide 1.99, Revision 2, Position 1.1. The calculated shift is thus equal to CF
- FF.
(c) Residual = Absolute Value [Measured Shift - RG 1.99 Shift]. Table D-5 shows a 2a uncertainty of less than 50°F, which is the allowable scatter in NUREG/CR-6413, ORNL/TM-13133. Hence, Criterion 5 is met for the St. Lucie Unit 2 surveillance program. May 2015 WCAP- 17939-NP WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 D-8 D.3 CONCLUSION Based on the preceding responses to all five criteria of Regulatory Guide 1.99, Revision 2, Section B, the St. Lucie Unit 2 surveillance plate, with consideration of all surveillance data or considering only the transverse orientation Charpy data points, and weld data are both deemed credible. D.4 REFERENCES D-I Regulatory Guide 1.99, Revision 2, Radiation Embrittlement of Reactor Vessel Materials, U.S. Nuclear Regulatory Commission, May 1998. D-2 10 CFR 50, Appendix G, Fracture Toughness Requirements, Federal Register, Volume 60, No. 243, December 19, 1995. D-3 WCAP-15040, Revision 1, Analysis of Capsule 2630from the FloridaPower & Light Company St. Lucie Unit 2 Reactor Vessel RadiationSurveillance Program,February 2010. D-4 ASTM El185-82, Standard Practicefor Conducting Surveillance Tests for Light-Water Cooled Nuclear Power Reactor Vessels, ASTM, 1982. D-5 K. Wichman, M. Mitchell, and A. Hiser, USNRC, Generic Letter 92-01 and RPV Integrity Assessment Workshop Handouts, NRC/Industry Workshop on RPV Integrity Issues, February 12, 1998. D-6 NUREG/CR-6413; ORNL/TM-13133, Analysis of the IrradiationData for A302B and A533B Correlation Monitor Materials, J. A. Wang, Oak Ridge National Laboratory, Oak Ridge, TN, April 1996. May 2015 17939-NP WCAP- I17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 E-1 APPENDIX E ST. LUCIE UNIT 2 UPPER-SHELF ENERGY EVALUATION E.1 EVALUATION Per Regulatory Guide 1.99, Revision 2 [Ref. E-1], the Charpy upper-shelf energy (USE) is assumed to decrease as a function of fluence and copper content as indicated in Figure 2 of the Guide (Figure E- 1 of this appendix) when surveillance data is not used. Linear interpolation is permitted. In addition, if surveillance data is to be used, the decrease in upper-shelf energy may be obtained by plotting the reduced plant surveillance data on Figure 2 of the Guide (Figure E- 1 of this appendix) and fitting the data with a line drawn parallel to the existing lines as the upper bound of all the data. This line should be used in preference to the existing graph. The 55 EFPY (end-of-license) upper-shelf energy of the vessel materials can be predicted using the corresponding I/4T fluence projection, the copper content of the beltline materials and/or the results of the capsules tested to date using Figure 2 in Regulatory Guide 1.99, Revision 2. The maximum vessel clad/base metal interface fluence value was used to determine the corresponding 1/4T fluence value at 55 EFPY. The St. Lucie Unit 2 reactor vessel beltline region minimum thickness is 8.625 inches. Calculation of the 1/4T vessel fluence values at 55 EFPY for the beltline materials is shown as follows: Maximum Vessel Fluence @ 55 EFPY - 4.53 x 1019 n/cm 2 (E > 1.0 MeV) 1/4T Fluence @ 55 EFPY = 2 (4.53 x 1019 n/cm )
- e(-0.24 * (8.625 / 4))
= 2.700 x 1019 n/cm 2 (E > 1.0 MeV)
The following pages present the St. Lucie Unit 2 upper-shelf energy evaluation. Figure E-1, as indicated above, is used in making predictions in accordance with Regulatory Guide 1.99, Revision 2. Table E- 1 provides the predicted upper-shelf energy values for 55 EFPY (EOL). May 2015 17939-NP WCAP- 17939-NP May 2015 Revision 0
Westinghouse Non-Proprietaiy Class 3 E-2 Westinghouse Non-Proprietary Class 3 E-2 SLimiting Weld Percent USE Decrease- Limiting Plate Percent USE Decrease 13% from Capsule 83* 23% from Capsule 2634 I I (transverse-on pntlaion) I 100.0 I'a nSurveiltnce Material: IS Plate M-605-1
'10.0
'Surveillance Material WVeld Heat # 83637 I-0.
1 E0
!E 1,00E+17 1.00E'I 8 1.00E+19 !.O0E+20 Neutron Fluence, nlcm2 (E > I MeV)
Figure E-1 Regulatory Guide 1.99, Revision 2 Predicted Decrease in Upper-Shelf Energy as a Function of Copper and Fluence WCAP-17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 E-3 Westinghouse Non-Proprietary Class 3 E-3 Table E-1 Predicted Positions 1.2 and 2.2 Upper-Shelf Energy Values at 55 EFPY Position 1.2(a) Intermediate Shell Plate M-605-1 0.11 2.70 105 30 73.5 Intermediate Shell Plate M-605-2 0.13 2.70 113 30 79.1 Intermediate Shell Plate M-605-3 0.11 2.70 113 30 79.1 Lower Shell Plate M-4116-1 0.06 2.70 91 24 69.2 Lower Shell Plate M-4116-2 0.07 2.70 105 24 79.8 Lower Shell Plate M-4116-3 0.07 2.70 100 24 76.0 Intermediate to Lower Shell Girth Weld 0.07 2.70 96 30 67.2 Seam 101-171 Intermediate Shell Axial Weld Seams 0.05 2.70 116 24 88.2 101-124 A, B, C Intermediate Shell Axial Weld Seam 101-124 CREPAIR_____ 0.05 2.70 136 ______ 24 __ 103.4 Lower Shell Axial Weld Seams 101-142A,B,C 0.05 2.70 136 24 103.4 Position 2 .2(b) Intermediate Shell Plate M-605-1 0.11 2.70 176 29 74. Intermediate Shell Plate M-605-3 j0.11 2.70 11 980.2 Notes: (a) Calculated using the Cu wt. % value and 1/4T fluence value for each material and Regulatory Guide 1.99, Revision 2, Position 1.2. In calculating the Position 1.2 percent USE decreases, the copper weight percent values were conservatively rounded up to the next highest line for each plate and weld material. (b) Calculated using surveillance capsule measured percent decrease in USE from Table 5-10 and Regulatory Guide 1.99, Revision 2, Position 2.2; see Figure E-I. Consistent with Criterion I of Appendix D, the surveillance weld percent USE decrease was not applied to the reactor vessel weld materials because none of the actual reactor vessel welds directly match both the heat and flux type used for the surveillance weld material. May 2015 WCAP- I 7939-NP WCAP-17939-NP May 2015 Revision 0
Westinghouse Non-Proprietary Class 3 E-4 USE Conclusion As shown in Table E-1, all of the St. Lucie Unit 2 reactor vessel beltline materials are projected to remain above the USE screening criterion of 50 ft-lbs (per 10 CFR 50, Appendix G) at 55 EFPY. E.2 REFERENCES E-1 Regulatory Guide 1.99, Revision 2, Radiation Embrittlement of Reactor Vessel Materials, U.S. Nuclear Regulatory Commission, May 1998. May 2015 WCAP- 17939-NP WCAP- 17939-NP May 2015 Revision 0}}