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Report Number NMEL-90001 Final Report entitled Nine Mile Point Unit 1 Surveillance Capsule Program to Niagara Mohawk Power Corporation January 4, 1991 by Dr.M.P.Manahan Battelle 505 King Avenue Columbus, Ohio 43201 Penn State University Nuclear Engineering Dept.231 Sackett Building University Park, PA 16802 Battelle does not engage in research for advertising, sales promotion, or endorsement

'of our clients'nterests including raising investment capital or recommending investment decisions, or other publicity purposes, or for any use in litigation.

Battelle endeavors at all times to produce work of the highest quality, consistent with our contract commit-ments.However, because of the research and/or experi-mental nature of this work the client undertakes the sole responsibility for the consequences of any use, misuse, or inability to use, any information, appara-tus, process or result obtained from Battelle, and Battelle, its employees, officers, or Trustees have no legal liability for the accuracy, adequacy, or efficacy thereo'f.

TABLE OF CONTENTS Pacae  

..........~...........1 1.1 Historical Perspective

..............2 F 1.1 1.1.2 Revised Surveillance Program Description

.6 Materials Mix-Up Concern.~..~..~..10 1.2 Detailed=Work Scope....~...~.~..~..15 1.2.1 Re-evaluate Data and Write New Surveillance Program Description

............15..1.2.2 Determine Initial RT~~of Beltline Materials 16"-1:2:3 Encapsulate Archive Dosimetry and Temperature Monitor Materials.....~~171.3 Applicable Documents MATERIAL MIX-UP ANALYSIS 2.1 Chemistry Analysis 2.2 Tensile Data Analysis 2.3 Charpy Data Analysis 2.4 Hardness Data Analysis 2.5 Conclusions Concerning Materials Mix-up 2.6 Surveillance Capsules A'nd C'aterials

===2.7 Limiting===

Plate Adjustment Methodology 17 22 22 35 40 48 48 49 56 3.0 BELTLINE MATERIAL INITIAL RT~~DETERMINATION

===4.0 ARCHIVE===

DOSIMETRY AND THERMAL MONITOR ENCAPSULATION 5.0

===5.1 Benefits===

to Niagara Mohawk 59 61 66 67 5.1.1 5.1.2 5.1.3 5.1.4 5.1.5 PLEX Surveillance Material Mix-Up Resolution Limiting Beltline Material RT~~of Beltline Materials Significant Economic Benefits in~~~~~Hydro-test 67 68 69 69 705.2 Future Direction REFERENCES 71 73

.vl APPENDICES Pacae APPENDIX A DESCRIPTION OF CAPSULES A'ND C'....A-2 A.l Dosimetry A.2 Temperature Monitors A-3 A-5 A.2.1 A.2.2 Melt Wire Temperature Monitors Solid State Track Recorder-Temperature Monitors A-5 A-6 A.2.2.1 A.2.2.2 A.2.2'A.2.2.4 Preparation of Quartz Glass SSTR-TMs Preparation of Mica SSTR-TMs SSTR-TM Fission Fragment Irradiation Fission Fragment Irradiation of Quartz Glass SSTR-TMs A-7 A-8 A-9 A.3 Charpy V-Notch Specimens A.4 Miniature and Conventional Tensile Specimens A.5 Capsule Design and Layout A.6 Archive Materials A-9 A-13 A-13 A-13 APPENDIX B APPENDIX C APPENDIX D AS-BUILT PHOTOGRAPHS OF ADVANCED DOSIMETRY FOR CAPSULES A'ND C'-1 AS-BUILT PHOTOGRAPHS FOR CAPSULES A'ND C''-1 DOSIMETRY DESCRIPTION FOR CAPSULES A'ND C'.C-1 APPENDIX E APPENDIX F CHEMICAL ANALYSIS DATA FOR NINE MILE POINT UNlT 1 o~~~~~~~~~~~~~~~F-1 PHOTOGRAPHS OF MELTWIRE TEMPERATURE MONITORS'-1 F.l F.2 F.3 Plate Data Weld Data Supplementary Base Metal Chemical Analysis F-2 F-11 F-14 3.v

H-4 H-17 H-21 H.2 Irradiated Surveillance Specimen Data.H-33 H.2.1 H.2.2 H.2.3 1984 Irradiated 300 Degree Charpy D ata.1985 Irradiated 30 Degree Charpy D ata.1990 (current study)Irradiated Base from HAZ for the 300 Degree Capsule 0 H-34 H-39 H-42 APPENDIX I APPENDIX J APPENDIX K HARDNESS DATA DROP WEIGHT DATA FLUX AND FLUENCE DATA K-1 APPENDIX L K.1 30 Degree Capsule Data K.2 300 Degree Capsule Data NINE MILE POINT UNIT 1 RTq~~DETERMINATION K-2 K-5 U I LIST OF FIGURES Pacae FIGURE 1-1 NINE MILE POINT CORE MIDPLANE SHOWING THE LOCATION OF THE 30 DEGREEi 120 DEGREEi AND 300-DEGREE SURVEILLANCE CAPSULES.......4 FIGURE 1-2 DRAWING SHOWING THE PLACEMENT OF THE SIX BELTLINE PLATES FOR NMP-1..........14 FIGURE 2-1 FIGURE 2-2 FIGURE 2-3 FIGURE 2-4 FIGURE 2-5 COMPARISON OF CHEMICAL ANALYSIS OF COPPER..27 COMPARISON OF CHEMICAL ANALYSIS OF NICKEL..28 COMPARISON OF CHEMICAL ANALYSIS OF PHOSPHORUS

LIST OF TABLES TABLE 1-1 SURVEILLANCE CAPSULE MECHANICAL BEHAVIOR SPECIMEN ZNVENTORY FOR NINE MILE POINT Pacae UNIT 1 o~~~~~~~~~~~~~~~~~~3 TABLE 1-2 CURRENT SURVEILLANCE CAPSULES AFTER REINSERTION FOR NINE MILE POINT-UNIT 1...5 TABLE 1-3 NINE MILE POINT UNXT 1 LEAD FACTORS AND REVISED WITHDRAWAL SCHEDULE..~.....9 TABLE 1-4 NMP-1 BELTLINE SURVEILLANCE PROGRAM TRACEABILITY 19 TABLE 2-1 TABLE 2-2 TABLE 2-3 LUKEN'S MEASURED CHEMISTRY OF BELTLINE PLATES FOR NMP-1 26

OF CHEMICAL ANALYSIS TEST MATRIX...24 CHEMICAL ANALYSIS SPECIMEN IDENTIFICATIONS

..25 TABLE 2-4 ABLE 2-5 TABLE 2-6 TABLE 2-7 TABLE 2-8 TABLE 2-9 TABLE 2-10 TABLE 2-11 TABLE 2-12 TABLE 3-1 BASE METAL ROOM TEMPERATURE TENSILE PROPERTIES 38 CHANGE IN YIELD STRENGTH ANALYSIS......39'

OF CHARPY IMPACT PROPERTIES FOR IRRADIATED MATERIALS FROM THE NiNE MILE POINT UNIT 1 REACTOR............~...44 SURVEILLANCE CAPSULE B MATERIAL COMPOSITIONS

OF 1964 BASELINE CHARPY IMPACT INDICES (L-T ORIENTATION)

..........42

OF CHARPY IMPACT PROPERTIES FOR UNIRRADIATED BASE METAL PLATE G-8-3/G-8-4

..43 TABLE 4-1 ARCHIVE RM AND HAFM NEUTRON DOSIMETRY MATERIALS e~~~~~~~~~~~~~~62 0

LIST OF TABLES continued TABLE 4-2 TABLE 4-3 TABLE 4-4 ARCHIVE SSTR NEUTRON DOSIMETRY MATERIALS...63 ARCHIVE MW-TM MATERIALS...........64 ARCHIVE SSTR-TM MATERIALS..........65  

0 INTRODUCTION The primary purpose of the analyses reported herein is to resolve questions raised concerning a mix-up of the base metal materials used in the Nine Mile Point Unit 1 (NMP-1)surveillance program.As described in Section 2.0, it,has been conclusively demonstrated that a material mix-up did occur during fabrication of the surveillance capsule specimens.

Conclusions concerning the actual materials used in the surveillance program are presented in Section 2.5.Since some of these materials were included in the re-encapsulation capsules A'nd C', a re-evaluation of the specimen inventories for the re-encapsulation capsules and the remaining B capsule was conducted.

These esults are pxesented in Section 2.6.Since the surveillance program is based on materials which are not limiting from an embrittlement perspective, it was necessary to develop an adjustment methodology so that the surveillance data can be used in P-T analysis.This methodology is described in Section 2.7.In addition to the material mix-up analysis, additional Charpy tests were conducted to determine the RT>>T of plate G-8-3.These results are provided in Section 3.0.In Section 4.0, the capsule A'nd C'rchive dosimetry and thermal monitor storage plan is presented.

PW I~'hg p any of the earlier documents are in error and should only be used in the future with caution.This report contains all of the data and information needed to evaluate future surveillance capsules and prepare Pressure-Temperature (P-T)operating curves.1.1 Historical Pers ective Three surveillance capsules were installed in the NMP-1 reactor in 1969 prior to initial operation.

[ST84]and[MA85a]contain the results of tests performed on the contents of these capsules.The number and type of mechanical behavior specimens, as well as the capsule identification and location within the reactor vessel, are summarized in Table 1-1.Figure 1-1 shows the location of the surveillance capsules.Prior to the material mix-up analysis, the base metal Charpy 30 ft-lb index shift (BT3Q)of 114'F for plate G-8-3 was thought to be larger than the shift predicted by Regulatory Guide 1.99 (Revision 2)[RG1.99(2)]

by a statistically significant amount.Since plant life extension is being considered, Niagara Mohawk decided to reinsert two capsules (A'nd C').The prime is used to designate the new capsule in the same azimuthal location as the original capsules.The radial location of the new capsules is slightly closer to the core than the original capsules to increase the neutron flux.The mechanical behavior specimens which were included in the new capsules are summarized in Table 1-2.

Core Pe rl p her y Stainless Steel Shroud Reactor Pressure Vessel 00 30 Degree Capsule Stainless Steel Liner 300 Degree Capsule 270 I I I I 90 t20 Degree Capsule t80 NOT A SCALE DRAWING FIGURE 1-1 NINE MILE POINT CORE MIDPLANE SHOWING THE LOCATION OF THE 30 DEGREE r 1 2 0 DEGREE r AND 3 0 0 DEGREE SURVEILLANCE CAP SULES

TABLE 1-2 CURRENT SURVEILLANCE CAPSULES AFTER REINSERTION FOR NINE MILE POINT-UNIT 1 Capsule Ca sule Contents"'harpy Tensile A'Base-0 2 Base-0 6 Base-R 2 Base-M 12 Weld-0 2 Weld-0 12 HAZ-0 3 HAZ-0 10 Base 8 Weld 9 HAZ 9 APED 3 Base 2 Weld 3 HAZ 2 APED C'2 Base-R 4 Base-M 12 Weld-R 4 Weld-M 12 Base-U 3 Base-U (1)0=Original irradiated (untested) specimen.M=Miniature tensile specimens machined from broken ends of tested specimen.R=Reconstituted Charpy specimen.U=Unirradiated specimen.

====1.1.1 REVISED====

~~A detailed description of the original surveillance program was given in reference[ST84].Three surveillance capsules, each containing Charpy and tensile specimens, as well as dosimetry wires[iron (Fe), copper (Cu), and nickel (Ni)], were installed in the NMP-1 pressure vessel prior to initial startup.As of the date of this report, two capsules have been removed as described earlier[ST84, MA85a].The full contents from the C capsule, 24 Charpy specimens and 6 tensile specimens, were tested at Battelle in 1983 to determine tensile properties and reactor vessel base metal, weld metal, and heat affected zone (HAZ)Charpy impact nil-ductility transition temperatures (NDTT)[ST84].Six Charpy base metal~~specimens from the A capsule were also tested at Battelle to confirm the 30-ft-lb shift of the base metal observed in the C capsule specimens[MA85a].In addition, one base metal tensile specimen from the A capsule was tested in order to further benchmark the correlation between change in yield strength and shifts in the 30 ft-lb temperature.

MPR Associates, Inc.reviewed the NMP-1 data, and recommended to Niagara Mohawk that two capsules be reinserted during the 1986 refueling outage[NE85].Battelle provided neutron transport data to MPR for calculation of the desired radial position of the reinserted capsules[MA85b].A description of the revised surveillance program is provided in

~<<4>>, V~<<p'is QJl~+I l4,.g I, 0 reference[MA85c]and is summarized below.Charpy and tensile base metal, weld metal and HAZ specimens from the A capsule were returned to the reactor vessel in a new capsule which was installed at the A location (30 degrees azimuth), during the 1986 refueling outage.The six Charpy base metal specimens from the A capsule which were tested, were reconstituted prior to reinsertion.

One tensile base metal specimen from the original A capsule was tested and machined into two miniature specimens and inserted in the new capsule.In addition, five temperature monitors were installed in the reinsertion capsule to determine the maximum specimen temperatures experienced during reactor operation.

The radial position of the reinsertion capsule relative to the reactor vessel wall was modified to increase the neutron flux at the capsule location by a factor of 1.97 over the maximum flux at the reactor vessel shell at the 1/4 T location.This lead factor will make up for the time the specimens were out of the reactor and allow the specimens to reach the anticipated end of life fluence at the time the 1/4 T position reaches 24 EFPY.It is recognized that there may be a neutron flux effect which could result in different mechanical behavior for the reinserted samples as compared with regions of the vessel irradiated at a lower flux.However, the practical constraint of achieving timely data requires a higher flux at the reinsertion capsules than at the vessel.It is anticipated that future research will either confirm or negate the damage rate

If necessary, a mechanistic damage model should provide adequate correlation between the surveillance data and the vessel.Twelve reconstituted full-sized Charpy base metal and weld metal specimens and miniature tensile specimens machined from the broken tensile base metal and weld metal specimens from the C capsule were reinserted in the NMP-1 reactor vessel in a second new capsule at the C location (300 degrees azimuth).In addition, twelve unirradiated Charpy base metal specimens and three unirradiated tensile base metal specimens were installed in'the reinserti'on capsule.The unirradiated specimens were machined from the NMP-1 reactor vessel archive plate material (G-8-3)which was used in the original weld and HAZ surveillance specimen fabrication.

No HAZ specimens were included in this capsule since the observed shift for the HAZ specimens tested to date is negligible, and the HAZ shift is expected to be bracketed by the base metal and weld metal shifts.The C'einsertion capsule also contains five temperature monitors.The same lead factor was used for the C'apsule as was used for the A'apsule.The revised withdrawal schedule and the exposure for each mechanical behavior specimen set is summarized in Table 1-3.At one-half of original design vessel life (16 efpy), the original B capsule will be withdrawn and the specimens tested.These data will provide information on the current tensile properties and Charpy shift of the reactor vessel base metal, weld metal, and

TABLE 1-3 NINE MILE POINT UNIT 1 LEAD FACTORS AND'"REVISED WITHDRAWAL SCHEDULE~Ca sule C'ead Factor to 1 4 T Position 1.97 0.99 1.97 Capsule Exposure at Withdrawal EFPY 24 16 32,

Due to the 1.97 lead factor on this capsule, the exposure of the A'apsule specimens will be approximately equal to the vessel 1/4 T at end of life.Results of mechanical behavior tests for the A'apsule contents will provide information on end-of-life tensile properties and Charpy shift of reactor vessel base metal, weld metal, and HAZ.At end of vessel life (32 efpy), the reinsertion C'apsule will be withdrawn.

lates.In addition, Y.Soong of Niagara Mohawk analyzed the reference[CE65]drawing and produced the drawings shown in Figures 1-2 and 2-7.A total of five nozzle cuts were made in the beltline region: two from plate G-8-1, two from plate G-8-3 (one of these was at the G-8-3/G-8-4 interface), and one from plate G-8-4.Therefore, the surveillance material had to come from these dropouts.In order to confirm the hypothesis that the base metal Charpys are from G-8-1, chemistry and mechanical behavior tests and analyses were performed.

The detailed scope of work is described in Section 1.2.13

.2 Detailed Work Sco e A detailed description of the work undertaken in the present study is given below.1.2.1 Re-evaluate Data and Write New Surveillance Pro ram As a result of the findings described above, much of the Reference[ST84, NA85a, and MA87]data are in error and the current P-T curves are overly conservative.

Also, many of the surveillance program reference documents are in error or are misleading.

To attempt to rectify this situation, a new surveillance program description has been written and included herein.This report supercedes all previous documents and ontains all of the information necessary to conduct the program in the future.Zn addition, several analyses were conducted to correct and update existing data.These include: (1)Fit all unirradiated beltline Charpy data using the Weibull model.(2)Clearly indicate which materials are G-8-1 and G-8-3.For specimens which are currently being irradiated, those for which there is some uncertainty regarding the material composition have been identified.

(3)Correlate tensile, Charpy, hardness, and chemistry data to demonstrate that base metal specimens were cut from Plate G-8-1 and weld and HAZ specimens were cut from G-8-3.(4)Develop a correlation factor which relates data on Plates G-8-3 and G-8-1 with Plate G-307-4.15

Several of the unirradiated Charpy specimens which were machined at GE and tested at Battelle were remachined prior to testing.The tensile specimens may exhibit bending during testing.There is experimental evidence that the GE machined specimens were not within ASTM specifications.

During the test, evidence of bending which results in significant uncertainty in the yield strength determination was observed.(6)Test reconstituted Charpy specimens from 300'apsule HAZ specimens to establish the Plate G-8-3 bTpp.Reconstitution and testing of 6 HAZ base metal halves (Plate G-8-3)was performed.

In addition, chemical analyses were performed on the base metal taken from a HAZ specimen to verify that the material is G-8-3.These Charpy tests provide surveillance data on Plate G-8-3.Perform tensile and hardness measurements on plates G-8-3 and G-8-1.Unirradiated tensile tests were rerun with more accurately machined specimens cut from plate G-8-3.In addition, miniature tensile specimens machined from the base portion of weld Charpy specimens were tested.These data were needed to develop the tensile correlation.

Hardness measurements were made on both plate materials for the same purpose as the tensile data.1.2.2 Determine Initial RT~of Beltline Materials The initial RT>>~for the beltline plates and welds were not determined in accordance with current ASME requirements.

he initial RTNqq.In the case of plate G-8-3, unirradiated

~~Charpy and drop weight tests were performed to establish the RT~~in strict conformance with the ASME code.A total of 18 unirradiated Charpy specimens oriented normal to the rolling direction were tested in the current study.For the remainder of the beltline materials, an analytical technique was used to conservatively calculate the RT>>~.The results are provided in Section 3.0 and Appendix L.1.2.3 Enca sulate Archive Dosimetr and Tem erature Monitor Materials As discussed in Reference[MA87], the archive dosimetry and temperature monitor materials should be carefully stored until apsules A'nd C're pulled, tested, and analyzed.Ne recommend storage in evacuated quartz tubes.This work was done to ensure adequate protection from humidity and the encapsulated materials should be stored in a temperature controlled environment.

1.3 A licable Documents As mentioned earlier, this report serves as the new baseline beltline pressure vessel materials document and supersedes all previous reports'll of the relevant data needed to conduct the surveillance program have been extracted from earlier reports and included in this report.In cases where the material composition I is different than previously thought, the correct composition is indicated and the change noted.The data tables in the appendices 17 ir J have been correctly changed and footnoted to indicate these~))changes.Examination of any of"the earlier references must be done with caution.In order to provide traceability, a comprehensive listing of'the references which pertain to the beltline surveillance program are given in Table 1-4.Comments pertaining to the material mix-up have been provided as appropriate.

TABLE 1-4 NMP-1 BELTLINE VEILLANCE PROGRAM TRACEABILITY Reference Title Affected By Material Comments[BU85]Fast Neutron Axial Pressure Vessel Calculations for Nine Mile Point Unit No.1 No Vessel Flux Analysis[CE65][HO65a]Combustion Engineering Drawing, Inspection Revision No.1, Material Identification for Niagara Mohawk RV, Drawing E 231-582-1, 9/20/65 Surveillance Test Program for Niagara Mohawk Reactor Vessel No Yes Believed to be the latest as-built drawing.Shows the beltline plate and weld positions and the nozzle cutouts.Specified base Charpys to be cut from plates G-8-3 and G-8-4.Specimens actually taken from G-8-1.[HO65b]Fabrication Test Program for Niagara Mohawk-213" BWR General Electric Co.Unirradiated Charpy and tensile data on plate G-38.[LE64][LU64]Welding Material Qualification to Requirements of NAV ships 250-1500-1 Lukens Test Certificates, From Lukens Steel Company to Combustion Engineering No No Weld Wire Qualification Data Lukens Test Certificates 19

TABLE 1-4 NMP-1 BELTLINE SURVE NCE PROGRAM TRACEABILITY continued Reference Title Affected By Material Mixu Comments[LU85][MA85a][MA85b]Copper Content of Reactor Vessel Plates Examination and Evaluation of the Nine Mile Point-Unit 1 30 Degree Azimuthal Surveillance Capsule Radial Flux Profiles for Nine Mile Point Unit 1 No Yes No Data on Cu content of beltline pl'ates not reported in[LU64]30 Degree Capsule Analysis Radial flux profile data[MA87]Surveillance Capsules A'nd C'or Nine Mile Point Unit 1 Yes Re-Encapsulation Report[NMFS][NMTS][ST64]NMPU-1 Final Safety Analysis Report Minimum Reactor Vessel Temperature for Pressurization Mechanical Test Report from W.A.Stone Metallurgical R&D Department Yes Yes No FSAR must be updated P-T curves must be updated Unirradiated Charpy and tensile data on beltline plates 20

TABLE 1-4 NMP-1 BELTLINE SURVE NCE PROGRAM TRACEABILITY continued Reference Title Affected By Material Comments[ST84]300 Degree Capsule Examination, Testing, and Evaluation of Irradiated Pressure Vessel Surveillance Specimens From the Nine Mile Point Nuclear Power Station Yes 300 Degree Capsule Analysis 21 1l Q4S4 IW p 0 MATERIAL MIX-UP ANALYSIS This section contains the data supporting the conclusion that a material mix-up in the NMP-1 surveillance program did occur.A conclusive demonstration was made using the reference[MA87]chemistry data.These data are reviewed in Section F 1.In addition, the mechanical behavior trends were examined to confirm the chemistry data, and these findings are discussed in Sections 2.2-2.4.Conclusions concerning the mix-up, the impact on the material inventories, and a discussion of the limiting plate adjustment methodology are given in Sections 2.5-2.7.2.1 Chemistr Anal sis As described in reference[MA87], the method of Inductively Coupled Argon Plasma (ICAP)Spectrometry was the primary chemical analysis method used.In addition to the ICAP measurements, the atomic absorption (AA)method was performed to determine the Cu and Ni content of the samples as an independent check.The test matrix is summarized in Table 2-1.As stated in[MA87], the primary goals of the chemical analysis task were: to determine whether the differences in the reference[ST84]and[MA85a]measurements are due to the XRF technique; to determine whether the unirradiated plate chemistry matches the Lukens data;and to determine whether there are any observable chemistry differences between the Charpy base metal 22  

pecimens fabricated from the nozzle dropout (30-degree and 300-degree base metal specimens) and the specimens fabricated from other regions in the G-8-3 and G-8-4 plates (HAZ specimens and unirradiated plate).23  

TABLE 2-1.

OF MICAL ANALYSIS TEST MATRIX Number of Measurements Method Unirradiated Material BCL WMAL 30'apsule Base Material WMAL 300'apsule 300'apsule HAZ Specimen Base Material Base Material WMAL WMAL ICPS (')AA (Cu, Ni)Standard Reference Material (NBS)3 3 1 dup~~1 dup 1 1 1 1 1 dup.1 dup.1 dup.Colormetric (P)Leco Combustion (C)Combustion Titrimetric (S)Gravimetric (Si)(1)BCL measured Cu, Ni, P, Mo, Cr, Mn WMAL measured Cu, Ni, P, Mo, Cr, Mn, Co, V, Ti (2)dup=duplicate analysis 24 sI<<If)jap" l$I w" 4~i i At least three ICAP measurements per sample were made so that the uncertainty could be quantified.

The WNAL measu'rements examined all of the elements on the Lukens record.In addition, one AA backup measurement per specimen type and one backup colormetric measurement for P content were made.Four specimen categories were analyzed and the specimen identifications are summarized in Table 2-2.Chemistry data from the Lukens test certificates

[LU64]and the Lukens measured Cu content from reference[LU85)is shown in Table 2-3.The results of the chemical analyses are provided in Appendix F and in"Figures-'2-1

'through 2-6.TABLE 2-2.CHEMICAL ANALYSIS SPECIMEN IDENTIFICATIONS Base From Base Base From Base Base From Plate G-8-3 30 Degree,.Capsule 300 Degree Capsule HAZ Unirradiated ElA Elc EBK E2U E31 E42 E7E ElM E1U E3T JlL JAM JAE JlT J1P D25 D21 D01 25  

G-307-5 0.20 0.27 0.48 0.53 0.018 0.019 1.45 1.23 0.45 0.52 P2091 P2112 P2130 G-307-10 G-8-1 G-8-3/G-8-4 0.22 0.23 0.18 0.51 0.51 0.56 0.018 0.021 0.012 1.43 1.34 1.16 0'0 0'5 0.47 (1)Limiting plate from a radiation damage perspective.

COPPER ICAP AA ICAP AA 0.200 O K I-G 0.150 lCAP AA lCAP AA ICAP AA 0.100 (WMAL~(W MAL~(Base from base Base from base Base from HAZ Vnirradiated Unirradiated test test 30 degree 300 degree 300 degree archive plate archive plate certificate certificate G-8-3/G-8-4 6-8-1 WMAL-Westinghouse Waltz Mill Analytical Laboratories BCD-Battelle Columbus Division FIGURE 2-1.COMPARISON OF CHEMICAL ANALYSIS OF COPPER 27

NICK L 0.700 ICAP AA-ICAP AA ICAP AA 0.600 I-z V K G 0.500 ICAP AA ICAP AA 0 0.400 Lukens Lukens (WMAL){WMAL)(WMAL){WMAL)(BCD)test test Base from base Base from base Base from HAZ Unirradiated Unirradiated certificate certificate 30 degree 300 degree 300 degree archive plate archive plate 6-8-3/6-8-4 6-8-0 WMAL-Westinghouse Waltz Mill Analytical Laboratories BCD-Battelle Columbus Division FIGURE 2-2.COMPARISON OF CHEMICAL ANALYSIS OF NICKEL 28

PHOSPHORUS 0.040 I-z 0.030 O (9 0.020 0.010 (WMAL)(WMAl)(WMAL)(WMAL)Base from base Base from base Base from HAZ Unirradiated 30 degree 300 degree 300 degree archive plate 0 Lukens Lukens test test certificate certificate G-8-3/G-8-4 G-8-1 WMAL-Westinghouse Waltz Mill Analytical Laboratories BCD-Battelle Columbus Division FIGURE 2-3.COMPARISON OF CHEMICAL ANALYSIS OF PHOSPHORUS 29

oo MANGANESE 1.400 O K (9 1.200 0 1.000 (WMAL)(WMAL)(WMAL)(WMAL)(BCD)Basefrombase Basefrombase BasefromHAZUnirradiated Unirradiated test test 30 degree 300 degree 300 degree archive plate archive plate certificate certificate G-8-3/G-8-4 G-8-1 WMAL-Westinghouse Waltz Mill Analytical Laboratories BCD-Battelle Columbus Division FIGURE 2-4.COMPARISON OF CHEMICAL ANALYSIS OF MANGANESE 30

'I MOLYBDENUM 0.500 l-z o 0.450 K I-z (9 0 0.400 (WMAL)(WMAL)(WMAL)(WMAL)(BCD)Lukens Basefrombase BasefrombaseBasefromHAZ Unirradiated Unirradiated test 30 degree 300 degree 300 degree archive plate archive plate certificate 6-8-3/G-8-4 WMAL-Westinghouse Waltz Mill Analytical Laboratories BCD-Battelle Columbus Division Lukens test certificate G-8-1 FIGURE 2-5.COMPARISON OF CHEMICAL ANALYSIS OF MOLYBDENUM 31

0.130 0.120 I-Z 0.310 0.100 U 0.090 0.080 0.070 (W MAL)(WMAL)(WMAL)(WMAL)(BCD)Base from base Base from base Base from HAZ Unirradiated Unirradiated 30 degree 300 degree 300 degree archive plate archive plate WMAL-Westinghouse Waltz Mill Analytical Laboratories BCD-Battelle Columbus Division FIGURE 2-6.COMPARISON OF CHEMICAL ANALYSIS OF CHROME 32 t

As discussed in Section.1.1, nozzle drop out material was available from plates G-8-1, G-8-3, and G-8-4.Plates-G-8-3 and G-8-4 are from the same heat, have identical composition, and therefore behave the same from a radiation damage viewpoint.,Examination of Figures 2-1 through 2-6 indicates that the chemistry of the base metal Charpy specimens closely matches that of the plate G-8-1 Luken's ladel analysis, whereas the chemistry of the base material from the Charpy HAZ specimens'closely matches the.unirradiated archive G-8-3 plates and the Lukens G-8-3 ladel analysis.However, this observation is not consistent with reference"[H065a]which specified that all of the base metal material should be prepared from plates G-8-3 and G-8-4.A plausible explanation is that between the time the[H065a]pecification was written and the time the specimens were fabricated, a decision was made to fabricate the base metal Charpy specimens using the G-8-1 material because the Cu content is higher in the G-8-1 material and closer to the highest Cu plate in the beltline region (G-307-4).

Also, as shown in Figure 2-7, one of the G-8-3 nozzle dropouts fell on the axial weld line.lt is possible that concern over including weld and HAZ material in the base metal Charpy specimens may have influenced the decision to machine the base metal specimens from plate G-8-1.33 I)k

2 Tensile Data Anal sis The irradiated and unirradiated baseline tensile data are provided in Appendix G.Also miniature tensile specimens were machined from the base metal portion of the weld specimens.

These data are provided in Appendix G as well.Prior to the preparation of the[MA87]report, GE machined and sent tensile specimens to Battelle to measure the archive plate G-8-3 unirradiated properties (T03, T22, T23)and for use in the C'apsule (T01, T02, T21).There is experimental evidence that the GE machined specimens were not within ASTM specifications.

-During the test, evidence of bending was observed which would result in significant uncertainty in the yield strength determination.

As a result, these tests were iscarded (T01, T22, T23)were rerun using specimens machined at Battelle (TN1, TN2, TN3).These data are presented in Appendix G~3.Care should be exercised when specimens T01, T02, and T21 from capsule C're tested since these specimens were machined in the same batch at G.E.as the specimens which exhibited bending during testing.An analysis was performed to determine the material from 1 which the surveillance program tensile specimens were machined.Unfortunately, there is no irradiated base metal tensile specimen material available at present for chemical analysis.Therefore, the composition of the original base metal tensile specimens is unknown and must be determined in the future when the surveillance capsules are withdrawn.

The only tensile specimens35

vailable for testing at present are the HAZ tensile specimens JUD and JTU.The base metal portion of JUD was analyzed and the results are given in Appendix F.As suspected, the chemistry of this material matches that of plate G-8-3.Therefore, it is likely that all of the HAZ tensile specimens were prepared using plate G-8-3 material.The weld specimens are composed entirely of weld metal.A summary of the room temperature tensile behavior data is given in Table 2-4.Several valuable insights can be gained by examining these data:~'he"TN-1 data (plate G-8-3 tested in 1990)is consistent with the 1964 CE data for the same plate.~The plate G-8-1 and G-8-3 unirradiated tensile properties are essentially identical.

As discussed in reference[OD85], the uncertainty in the average yield strength change (boy)for the LWR data base is about 3-3.5 ksi, with individual uncertainties as high as 10 ksi.Therefore, for the same heat of material, we would expect that values with+3-5 ksi would indicate similar material behavior.~Based on chemical analysis, it is believed that all HAZ and weld CVNs were fabricated using plate G-8-3.Therefore, specimen EJD is most likely irradiated G-8-3 material.

'I

~Assuming EJD represents irradiated G-8-3 material, and JJA was prepared from G-8-1 material, we would expect the change in yield strength to be larger for the JJA specimen.These assumptions are consistent with the)data given in Table 2-4.A comparison of the bT30 using the reference[OD85]yield strength correlation and the RG1.99(2)model is shown in Table 2-5.~Based on these observations, a plausible interpretation of the tensile data is that the HAZ and weld (entirely-weld metal)tensile specimens were fabricated using plate G-8-3 and the base specimens were fabricated using plate G-8-1 material.This interpretation is consistent with the way in which the Charpy specimens were fabricated.

This hypothesis must be verified in the future by chemical analysis when the capsules are withdrawn.

TABLE 2-4.BASE METAL ROOM PERATURE TENSILE PROPERTIES Unirradiated RT Pro erties Irradiated RT Pro erties Plate Identification Yield Strength~ksi Ultimate Tensile Reduction Strength In Area Ultimate Yield Tensile Reduction Strength Strength In Area~ksi~ksi G-8-1 (CE 1964)G-8-3 (CE 1964)66.6 65.0 87.5 86.2 66'65.4 TN-1 (Battelle 1990)(plate G-8-3)JJAt" (300'apsule 7.98 EFPY)67.4 (upper)87.2 65.4 (lower)62.5 79.2 99.7 65.7 JDE (30'apsule 5.8 EFPY)E JD<'>(Base from 300'apsule weld CVN)76.1 71.1 96.8 93.3 66.1 65.1 (1)The composition of JJA and JDE are unknown and must be determined in the future when the surveillance capsule is withdrawn.

It is currently thought that these specimens were machined from G-8-1 material.(2)The composition of EJD was not measured but it is believed that all HAZ and weld CVNs were fabricated using plate G-8-3.38

TABLE 2-5.CHANGE IN YIELD STRENGTH ANALYSIS Irradiated Specimen Identification Material Identification Ni Cu Com osition"',Cry ksi Yield RGl.99 (2)Strength Model Model JJA 0.23 0'1 12.6 92 44 EJD G-8-3"'.18 0.56 6.1 41 37 (1)Lukens ladel analysis.(2)These are the postulated materials used to fabricate the specimens.

The actual composition must be confirmed by chemical analysis.(3)Both specimens are from the 300'apsule with a fluence of 4.78 x 10" n/cm'.39 if,HI ft pjpp

.3 Cha Data Anal sis Appendix H contains all of the Charpy data generated to date.The unirradiated 1964 data for the beltline plates (L-T orientation) was fit using the SAM McFRAC code[MC89].The plots are given in Appendix H.1 and the indices are summarized in Table 2-6.Additional tests were conducted on plate G-8-3 using specimens with both the L-T and T-L orientation.

The L-T to T-L orientation change results in an average upward shift of 24'F of the Charpy curve at the 30 ft-lb level.These data are summarized in Table 2-7.One concern raised by the data presented in Table 2-7 is the relatively low USE exhibited by plate G-8-3 tested in the T-L rientation.

Analyses should be conducted in the future to~~determine the radiation damage effects on the USE decrement.

The irradiated base metal data from the 300 and 30 degree capsules and the weld and HAZ data from the 300 degree capsule were fit using the McFRAC code, and the results are presented in Appendix H.2.As described earlier, it is believed that the base metal specimens were machined from plate G-8-1.In order to further confirm this hypothesis, six specimens were reconstituted using base metal from the 300 degree capsule HAZ Charpy specimens.

These data are also presented in Appendix H.2.It is believed that these specimens were prepared using plate G-8-3 material.The irradiated material Charpy indices and 30 ft-lb shifts 40

re summarized in Table 2-8.Plots showing the effect of irradiation on the Charpy shift are shown in Figures 2-8 through 2-10.Flux and fluence data are provided in Appendix K.These data confirm the hypothesis concerning the material mix-up.As shown in Table 2-8, the measured shift for the G-8-1 material is higher at the higher fluence.Also, the G-8-3 shift is consistent with the lower Cu content.The measured BT~~s for the G-8-3 and G-8-1 materials are within the RG1.99(2)two sigma confidence band.Overall, the Charpy data confirm the chemistry data trends"'which show that the surveillance capsule base metal specimens came from plate G-8-1 and the HAZ and weld specimens were fabricated using G-8-3 base metal.41 It, TABLE 2-6.

OF 1964 BASELINE CHARPY IMPACT INDICES (L-T Orientation)

Plate Identification 30 ft-lb 50 ft-lb Transition Temperature Transition Temperature Upper Shelf Energy~F~F~ft-1b G-307-10 G-307-4 G-307-3 G-8-3/G-8-4 G-8-1-3.9-0.5-14.0-26.5 7.9 33.9 54.9 33'14.4 49.9 99.0<" 81.5 103.2 99.5 86.7~'>>(1)Insufficient data to determine the temperature dependence of the upper shelf.The USE was taken to be the average of the highest temperature test.These data were judged to be upper shelf based on the performance of other materials.

42  

TABLE 2-7.

OF CHARPY IMPACT PROPERTIES FOR UNIRRADIATED BASE METAL PLATE G-8-3/G-8-4 Orientation Remarks 30 ft-lb 50 ft-lb Upper Transition Transition Shelf Temperature Temperature Energy (F)'F)(ft-lb)'-T'(1987)'Archive (1987)-21 108 L-T (1964)C.E.Data (1964)-26.5 T-L (1990)Archive (1990)-0.2 14.4 46.5 99.5 68.3 43 4

ABLE 2-8.

OF CHARPY IMPACT PROP S FOR IRRADIATED MATERIALS FROM THE NI MILE POINT 1 REACTOR Material Fluence (E>1.0 mev)(n/cm2)30 ft-lb Transition Temperature (F)RG 1.99 (2)SHIFT 50 ft-lb Upper Transition Shelf Temperature Energy (F)(ft-lb)G-8-1 G-8-1(>>(300'ase)Change 4.78 z 10~7 4.78 x 10" 7.9 87.2 79.3 44.0 49.9 132.8 82.9 86.7(2)94 6'(2)G-8-1(')(30'ase)Change 3.60 x 10" 3.60 x 1 0>>55.1 37.6 1 00 50.1 G-8-3 G-8-3(')(300'apsule)

Change 4.78 z 10" 4.78 x 10"-26.5-15.3 11.2 37.2 14.4 22.0 7.6 99.5-100.0(')(1)Base material from the 300 and 30 degree capsules believed to be G-8-1 material based on chemistry and mechanical property trends.Base from weld or HAZ believed to be G-8-3 material.(2)The uncertainty in the pre-and post-irradiation USE data is high.Therefore, no conclusion can be drawn at this time concerning the USE decrement.

(3)Insufficient data to determine the USE.44  

NINE MILE POINT UNIT 1 PLATE Q-8-1 SHIFT AT 5,6X10+a1?(H/Clio+2) 120 100 I I-LL 80 Q 60 40 Q 20 A~(+w UNIR RADIATED EXP.DATA IRRADIATED EXP.DATA WEIBULL FIT TRANSITION HYPERBOLIC TANGENT FIT WEIBULL FIT TRANSITION HYPERBOLIC TANGENT FIT-100-50 0 50'I 00'I 50 200 250 TEST TEMPERATURE (F)Figure 2-8 Effect of Irradiation on Plate G-8-1 After a Fast Fluence of 3.6 x 10'/cm 45

NINE MILE POINT UNIT I PLATE C-8-1 SHIFT AT 4.8X10+a17(N/CMae2)

EXP.DATA 120 100 Cl I I-LL 80 CI 60 IRRADIATED EXP.DATA WEIBULL FIT TRANSITION WEIBULL FIT UPPER SHELF 40 V 20 HYPERBOLIC TANGENT FIT QfEIBULL FIT TRANSITION 0 HYPERBOLIC

-50 0 50 100 150 200 250 300 350 TANGENT FIT TEST TEMPERATURE (F)Figure 2-9 Effect of Irradiation on Plate G-8-1 After a Fast Fluence of 4.78 x 10" n/cm'6

NINE MILE PQINT UNIT 1 e'NIRRADIATED PLATE Q-S-S SHIFT AT 4.8X100017(N/Cllao2)

EXP.DATA 120 IRRADIATED EXP.DATA 100 I I-LL 80 60 gj e WEIBULL FIT TRANSITION WEIBULL FIT UPPER SHELF 40 V 20 0 g.'g<HYPERBOLIC TANGENT FIT oaooooooooooooooo Q(EIBUU FIT TRANSITION 0-100-50 0 50 100'I50 200 250 TEST TEMPERATURE (F)-.----HYPERBOLIC TANGENT FIT Figure 2-10 Effect of irradiation on Plate G-8-3 After a Fast Fluence of 4.78 x 10" n/cm'7 "i ill 4

===2.4 HARDNESS===

DATA ANALYSIS N Rockwell B and C hardness tests were performed on the unirradiated plate G-8-3 material and Charpy specimens from the 300 degree capsule.These data are provided in Appendix I.The Rockwell C tests were performed in, addition to the Rockwell B tests because the data fell high on the Rockwell B scale.Future r tests on more highly irradiated material may require the use of the Rockwell C scale.The broken Charpy specimens were indented after fracture testing.Specimens which exhibited little plastic deformation during Charpy testing were chosen so that the specimen was properly supported in the hardness test machine.The specimens were tested on the surface containing the notch and on the surfaces normal to the notch.A slight orientation effect was observed.Overall, the orientation effect s not significant.

The G-8-3 unirradiated material exhibited an average Rockwell C hardness of 10'and Rockwell B hardness of 89.9.The G-8-3 specimens irradiated to 4.78 x 10'/cm had an average Rockwell C hardness of 13.5 compared to an average of ,.15.0 for the G-8-1 material, and an average Rockwell B hardness, of 91.8 for the G-8-3 material compared to 92.5 for the G-8-1 material.Therefore, the hardness data confirms the material mix-up hypothesis.

==2.5 CONCLUSION==

S CONCERNING MATERIAL MIX-UP Based on a careful examination of all of the NMP-1 surveillance data, the following conclusions have been made:~A material mix-up did occur in the NMP-1 surveillance program.This conclusion is based on definitive 48

chemical analysis data and further substantiated by examining the mechanical behavior trends.The base metal Charpy specimens were prepared from plate G-8-1 material and the HAZ and weld specimens were prepared using G-8-3 material.The HAZ tensile specimens were prepared using G-8-3 plate material.It is likely that the weld (entirely weld)tensile specimens were produced using the G-8-3 material.Based on the mechanical behavior trend, it is likely that the base metal tensile specimens were prepared from G-8-1 material.Additional analyses will be needed in the future to confirm the tensile materials.

-base metal from Charpy weld for the 30'nd 300'apsules,-base, base from weld, and base from HAZ for Charpys in the 120'apsule, all tensile base metal specimens.

TABLE 2-9.SURVEILLANCE CAPSULE B MATERIAL COMPOSITIONS~i Specimen" Identification All Base Metal Specimens All Weld Specimens All HAZ Specimens Specimen~Te Charpy Tensile Charpy Tensile Charpy Tensile Base Metal Plate Material G-8-1 G-8-1 G-8-3 n/a G-8-3 G-8-3 I'1)These materials should be confirmed by chemical analysis when the capsule is pulled.50

TABLE 2-10.SURVEILLANCE CAPSULE A'ATERIAL COMPOSITIONS S ecimen Identification S ecimen T e Base Metal Plate MaterialE71A E12 E31A E2E E2T E2UA E17 E1AA E2Y E1CA E1D EBKA ED1 ED2 ED3 ED4 ED5 ED6 ED7 EDA EDB EDC Reconstituted Charpy Base Charpy Base Reconstituted Charpy Base Charpy Base Charpy Base Reconstituted Charpy Base Charpy Base Reconstituted Charpy Base Charpy Base Reconstituted Charpy Base Charpy Base Reconstituted Charpy Base Charpy Weld Charpy Weld Charpy Weld Charpy Weld Charpy Weld Charpy Weld Charpy Weld Charpy Weld Chazpy Weld Charpy Weld 51 G-8-1 G-8-1 G-8-1 G-8-1 G-8-1 G-8-1 G-8-1 G-8-1 G-8-1 G-8-1 G-8-1 G-8-1 G-8-3 G-8-3 G-8-3 G-8-3 G-8-3 G-8-3 G-8-3 G-8-3 G-8-3 G-8-3 E

S ecimen Identification S ecimen T e Base Metal Plate Material EDD EDE J12 J13 J14 J15 J17 J1A J1B J1C J1D J1E JD1 JD2 JLK JL2 JTA JUL Charpy Weld Charpy Weld Charpy HAZ Charpy HAZ Charpy HAZ Charpy HAZ Charpy HAZ Charpy HAZ Charpy HAZ Charpy HAZ Charpy HAZ Charpy HAZ Charpy HAZ Charpy HAZ Tensile Base Tensile Base Tensile Base Tensile Base Tensile Weld Tensile Weld Tensile HAZ Tensile HAZ Tensile HAZ G-8-3 G-8-3 G-8-3 G-8-3 G-8-3 G-8-3 G-8-3 G-8-3 G-8-3 G-8-3 G-8-3 G-8-3 G-8-3 G-8-3 G-8-1 G-8-1 G-8-1 G-8-1 n/a n/a G-8-3 G-8-3 G-8-3 (1)The base metal tensile and base from Charpy weld should be confirmed by chemical analysis when the capsule is pulled.52

TABLE 2-11.SURVEILLANCE CAPSULE C'ATERIAL COMPOSITIONS S ecimen Identification S ecimen T e Base Metal Plate Material NC01 NC21 NC02 NC22 NC03 NC23 NC04 NC24 NC05 NC25 NC06 NC26 El JA El JB E1KA E1KB EA5A EA5B E42A E1MA Charpy Base Charpy Base Charpy Base Charpy Base Charpy Base Charpy Base Charpy Base Charpy Base Charpy Base Charpy Base Charpy Base Charpy Base Reconstituted Charpy Base Reconstituted Charpy Base Reconstituted Charpy Base Reconstituted Charpy Base Reconstituted Charpy Base Reconstituted Charpy Base Reconstituted Charpy Base Reconstituted Charpy Base G-8-3 G-8-3 G-8-3 G-8-3 G-8-3 G-8-3 G-8-3 G-8-3 G-8-3 G-8-3 G-8-3 G-8-3 G-8-1 G-8-1 G-8-1 G-8-1 G-8-1 G-8-1 G-8-1 G-8-1 53 "J

TABLE 2-11.'SURVEILLANCE CAPSULE C'ATERIAL COMPOSITIONS (Continued)

S ecimen Identification E1UA E3TA E7EA J2CB EDKA S ecimen T e Reconstituted Charpy Base Reconstituted Charpy Base Reconstituted Charpy Base Reconstituted Charpy Base Reconstituted Weld Base Metal Plate Material G-8-1 G-8-1 G-8-1 G-8-3 n/a,, EDLA EDMA E JTA JAEA J1MA J1PA J1TA Jl JA T01 Reconstituted Weld Reconstituted Weld Reconstituted Weld Reconstituted Weld Reconstituted Weld Reconstituted Weld Reconstituted Weld Reconstituted Weld Reconstituted Weld Reconstituted Weld Reconstituted Weld Tensile Base 54 n/a n/a n/a n/a n/a n/a n/a n/a n/a n/a n/a G-8-3 P l TABLE 2-11.SURVEILLANCE CAPSULE C'ATERIAL COMPOSITIONS (Continued)

S ecimen Identification S ecimen T e Base Metal Plate Material T02 T21 10 Tensile Base Tensile Base Tensile Base Tensile Base Tensile Base Tensile Base Tensile Weld Tensile Weld Tensile Weld Tensile Weld G-8-3 G-8-3 G-8-1 G-8-1 G-8-1 G-8-1 n/a n/a n/a n/a (1)The base metal tensile and base from Charpy weld should be confirmed by chemical analyses when the capsule is pulled.55

The limiting plate, from a radiation damage perspective, is that plate with the highest copper and nickel content.As shown in Table 2-3, the plate G-307-4 has the chemistry which results in the largest RG 1~99(2)chemistry factor.As with many plants in operation today, the surveillance material is not the limiting material.Therefore, in order to be able to use the surveillance data in P-T curve calculations, we are recommending the use of a"correction factor" which adjusts for the chemistry differences.

TABLE 2-12.SURVEILLANCE DATA ADJUSTMENT FACTORS Adjustment Factor"'o Obtain Plate G-307-4 Material E uivalent Data Fluence~ncm'easured Shift F Equivalent Plate G-307-4 Shift F G-8-1 G-8-1 G-8-3 FF (19.9)+hT3 FF (19.9)+b,T FF (43.7)+bT3 4.78 x 10>>3.6Q x 10~7 4.78 x 10" 79~3 55.1 11.2 85.0 60'23.7 (1)FF=f''~', f=fast fluence-.10'n/cm')57

TABLE 3-1 Beltline Material RT>>~Data for Nine Mile Point Unit 1 Plate G-8-3/G-8-4 G-8-1 G-307-3 G-307-4 G-307-10 RTggg (T L)OF 3 ll)36 28 40 20 a, OF Plate N5214/5G13F 86054B/4E5F 1248/4K13F 1248/4M2F RTgpg oF-50-50-50-50 Gz oF 17 17 17 17 (1)Measured in accordance with ASME code.58

MATERIAL INITIAL RT T DETERMINATION An analysis was performed to establish best estimate values for the RT>>T and 6, terms used in Regulatory Guide 1.99 (Rev.2)calculations for the Nine Mile Point Unit 1 (NMP1)beltline plate and weld materials.

With the exception of plate G-8-3, sufficient data are not available to determine the RT>>T in strict conformance with the current ASME code rules.In the case of the weld metals, only three unirradiated Charpy tests were conducted at 10'F~Charpy transition behavior data are available for the plate materials, however, there are no drop weight data (for all of the beltline materials except for plate G-8-3/G-8-4).

The methodology used is described in detail in Appendix L.The results of these calculations are presented in Table 3-1.not be determined in accordance with the current ASME code As described in reference[MA87], the plate G-8-3 RT>>, could requirements because the Charpy specimens tested at that time had an L-T orientation.

Therefore, Charpy (Appendix H)and drop weight (Appendix J)tests were performed to firmly establish the initial RT>>T for plate G-8-3.Specimens machined from plate G-8-3 with the T-L orientation were tested as part of the current work.These data are presented in Appendices H.1.2 and H.1.3 and the results are summarized in Table 2-7.The L-T to T-L orientation change results'n an upward shift of the Charpy curve of 21 F.This is consistent with data in the literature

plate G-8-3 is-25 F.Three Charpy specimens with the T-L~~~orientation exhibited 50 ft.-lbs.of absorbed energy at 57 F.Therefore, the RT>>~for plate G-8-3 is-3 F.60

.0 ARCHIVE'OSIMETRY AND THERMAL MONITOR ENCAPSULATION In surveillance capsule irradiations, it is prudent to store dosimetry and temperature monitor materials in case it is necessary to resolve conflicts in the data obtained.With these materials, calibration experiments can be repeated;and, if necessary, neutron benchmark irradiations can be conducted.

Should definitive follow-on experiments of this type be needed, the availability of these archive materials can be a crucial factor in the success of the dosimetry analysis.To this end, archive materials, identical to those used in Capsules A'nd C', have been provided to Niagara Mohawk.Tables 4-1 through 4-4 summarize the supplied archive materials for RM neutron d osimeters, SSTR neutron dosimeters, MW-TMs and SSTR-TMs, espectively.

These materials were sealed inside an evacuated quartz tube and sent to Niagara Mohawk[MA89].61

TABLE 4-1.ARCHIVE RM AND HAFM NEUTRON DOSIMETRY MATERIALS Dosimeter Material Type PO No.Batch Vendor Form Quantity Fe Ni 07448 26/17944 MRC 0.020D Wire SE Roll 2 Semi Element 0'20D Wire 2 inches 2 inches Cu RM, HAFM 19047 CPI 3054 Cominco Am.0'20D Wire-2 inches Co/Al Al 19046 Cat 614 Reactor Exp.0.020D Wire 19045 SE Roll 1 Semi Element 0.020D Wire 44451 SC Bar 26 Sigmund Cohn 0.020D Wire 2 inches 2 inches 2 inches NOTES (2)Archive samples of the vanadium encapsulated fissionable RM dosimeters are not provided;those included in Capsule Sets A'nd C're to be used for this purpose.Samples of the Be, Fe, and Ni HAFM dosimeters are not provided.62

TABLE 4-2.ARCHIVE SSTR NEUTRON DOSIMETRY MATERIALS TYpe SSTR<i>ID Diameter Isotope ID SSTR De osit''Total (pg)Mass Density (pg/cm')Mica Mica Mica 219 231 199 0.168 0.168 0.168 235-U 238-U 237-Np 219 231 199 0.826 7.65 10.39 8.81 81.6 110.8 (1)Three additional mica SSTRs of 0'68 inch diameter have been supplied as control samples to be stored along with the archive SSTR dosimeters 219, 231, and 199.These control SSTRs are unnumbered and are not in contact with any deposit.(2)The outer aluminum foil of the archive SSTR packages are marked.as follows: U-235 is labeled 5;NP-237 is labeled 7;U-238 is labeled 8.63

TABLE 4-3.ARCHIVE-MW-TM MATERIALS Composition, Wt%Melting Temperature Length Diameter (F)(in.)(in.)Source 80 Au, 20 Sn 90 Pb, 5 Ag, 5 Sn 97.5 Pb, 2.5 Ag 97.5 Pb, 1.5 Ag, 1.0 Sn 98.8 Cd, 1.2 CU 536 558 580 588 498 0.25 0.25 0.25 0.25 0.25 0.030 0.090 0.084 0.084 0'83 Indium Corp.of America Babcock&Wilcox Babcock&Wilcox Babcock&Wilcox Babcock&Wilcox.64

TABLE 4-4.ARCHIVE SSTR-TM MATERIALS K Material Quantity Description and Purposes India Ruby Muscovite Mica India Ruby Muscovite Mica upra II Quartz Glass Pre-annealed and pre-etched disks 15/16 in.in diameter and about 0.004 in.thick.Representative material for SSTR-TM and SSTR dosimetry.

C1 and C2 as described in Table 4-2.Needed as standards when mica SSTR-TMs are removed from the reactor.3/8 in.thick squares about 40 mils thick.Representative materials used in SSTR-TMs~Supra II Quartz Glass C and 3C are 3/8 in.squares about 40 mils thick.They are described in Table 4-2.Needed as standards when the Supra II quartz glass is removed from the reactor.65 J<<.~  

.0  

AND CONCLUSIONS Based on careful examination of all data available, it has been concluded that a materials mix-up has occurred in the NMP-1 surveillance program.For the capsules which have been pulled to date, it has been conclusively demonstrated that the base metal Charpy specimens were fabricated from plate G-8-1, and not plate G-8-3 as originally specified.

The base metal portion of Charpy weld and HAZ specimens is composed of plate G-8-3 material.Future chemical analysis of capsule B materials and all base metal tensile specimens are needed to determine the composition

" of thesematerials.

It is likely that the base metal tensile specimens were fabricated from plate G-8-1, and the same approach to specimen fabrication for capsule B was used as that used for apsules A and C.As a result of these findings, this report was prepared and is intended to serve as the new baseline surveillance document for NMP-1.All of the data needed to conduct.the surveillance program is contained herein.Should future analysis require examination of earlier reports, these studies should be conducted with caution since the earlier reports are known to contain errors related to the material mixup.In response to these findings, it is recommended that new P-T curves be prepared.The current P-T curves are overly conservative since the measured shift was determined using G-8-1 irradiated material and G-8-3 unirradiated material.The actual measured shifts, which have been corrected to account for the 66 Sgp C Ill.-s+hl~"

aterial mix-up, are consistent with the[RG 1.99 (2)]model.Therefore, it is recommended that Niagara Mohawk prepare new P-T curves to replace the current overly conservative curves.5.1 Benefits to Nia ara Mohawk A substantial amount of work has been performed under the NMP-1 surveillance program since removal of the A and C capsules.Capsule A was removed in 1979 after a vessel exposure of 5.8 effective full power years (efpy)and capsule C was removed in 1982 after a vessel exposure of 8 efpy.The culmination of this" work is reported"herein and has resulted in the firm re-establishment of the NMP-1 surveillance program.A brief summary of the past problems, resolution of the problems, and the enefits of this work to Niagara Mohawk are presented below.5.1.1 PLEX Surveillance The capsule C (at 300 azimuth)analysis showed a base metal BT3Q of 114 F at a fast fluence of 4.78 x 10"n/cm.In order to confirm this finding, the 30 degree capsule was analyzed and a base betal bT>>of 90 F=was measured at a fast fluence of 3.6 x 10'/cm.These data exceeded the RG 1.99(2)prediction by over 3 standard deviations.

In response to the concern raised by these findings, a surveillance capsule re-insertion program was undertaken.

Two new capsules containing both irradiated and unirradiated (from archive)specimens were re-inserted.

These are the first J ,t l apsules ever designed specifically to generate plant life extension data.These capsules are advanced BWR capsules and contain advanced dosimetry, temperature monitors, and innovative mechanical test specimens.

The benefit to Niagara Mohawk will be end-of-license and life extension data'hese data can be used in plant specific damage models to yield accurate estimates of the K,~curve shift for P-T calculations.

====5.1.2 Material====

Mix-U Resolution Measurement and careful study of the material chemistry data"and as-'built''drawings led to the discovery that a material mix-up had occurred in the NMP-1 surveillance program.The mechanical behavior trends were examined and found to confirm the chemistry ata.As a result, the plate G-8-3 (Cu=.18, Ni=.56)measured shift (hT>>), originally thought to be 114 F, was correctly established to be to 11 F at a fluence of 4.78 x 10 n/cm.Since the surveillance program is irradiating two plate materials (G-8-3 and G-8-1), the Charpy bT,~can be determined for plate G-8-1 (Cu=.23, Ni=.51)as well.For plate G-8-1, bT~,=79 F at a fluence of 4.78 x 10'/cm and ET3Q 55 F at a fluence of 3.6 x 10"n/cm.Therefore, the resolution of the material mix-up has resulted in three measured Charpy bT~,s instead of two, and the measured shifts are much lower than believed earlier.68

.1.3 Limitin Beltline Material~~As with many plants in operation today, the NMP-1 surveillance material is not the limiting beltline material~Based on the chemistry data and analysis of initial RT>>~for the beltline materials, plate G-307-4 is the limiting material.Therefore, in order to enable use of the surveillance data in P-T curve calculations, a correction factor which adjusts for the chemistry differences between G-307-4 and the surveillance materials (G-8-3 and G-8-1)has been developed.

This approach allows Niagara Mohawk to use plant-specific data to determine the"ART>>~'t'rend curve in accordance with the guidance provided in RG 1.99 (2).~1'RT of Beltline Materials The RT>>~of the beltline materials, with the exception of plate G-8-3, cannot be measured in conformance with the ASME code requirements.

A value of+10 F has been assumed.Should the NRC decide to question the assumption, Niagara Mohawk would be vulnerable.

However, a rigorous statistical method which is consistent with the intent of the ASME code was used to determine the RT>>~of all of the beltline materials.

Xn the case of the welds, it has been demonstrated that the+10 F assumption is overly conservative, and for the plates, the+10 F assumption is non-conservative.

Although the RT>>~for the limiting plate (G-307-4)was found to be 40 F, the analaysis enables identification of the actual limiting material~Following the RG 1.99(2)69 V'j.'~Jl, approach, the weld materials would have been limiting since the regulatory guide requires the use of.35%Cu and 1.0%Ni in cases where measured chemistry data are not available.

This chemistry assumption leads to a chemistry factor of 272 for the weld material as apposed to 174 for the limiting plate.Therefore, weld material would have been limiting and the ARTgT for the weld would have been larger than that for the plate if the RTND~analysis had not been done.5.1.5 Si nificant Economic Benefits in H dro-test'"The hydro-test temperature has been reduced significantly

(-20F)as evidenced by the new P-T curve which was developed using Charpy shift data appropriately corrected for the material mixup,[MA91].The technical specitication defines the cold shutdown condition as the reactor coolant temperature being less than (or equal to)212'F and the hot shutdown condition is defined by a temperature greater than 212'F.Hydro-test in the hot shutdown condition requiers longer time to warm up the water and, in addition, hot shutdown must be scheduled as a critical path activity.Hydrotesting in the hot shutdown condition requires that the ECCS system must be operational, the safety system surveillance must be complete and the primary containment must be isolated.In the hot shutdown condition, leak detection is more difficult and the inspection conditions are more severe for personnnel.

On the other hand, cold shutdown requires less time because the hydro-test can be done in parallel with other 70 I'h tf~

utage activities.

Saving one day or even one half day of outage time results in a significant economic benefit to NMP-1.5.2 Future Direction Niagara Mohawk should consider several actions for the future.The general direction should be to establish a strong plant specific surveill'ance program and avoid the use of overly conservative"generic" trend curves.If the NMP-1 and Oyster Creek data were shared, there would be sufficient data available to develop a plant specific trend curve.This approach can be'implemented within the guidelines of RG 1.99(2)since the regulatory guide allows the adjustment of the hRT>>~analytical model in cases where two or more credible surveillance data are vailable.Therefore, it is recommended that NMPC establish a cooperative program with GPU Nuclear as soon as possible.With regard to the surveillance capsules, the B capsule should be pulled as soon as possible and tested.Serious consideration should be given to re-inserting a capsule which contains advanced dosimetry, temperature monitors, irradiated and unirradiated mechanical property specimens, and unirradiated fracture toughness specimen blanks.Fracture toughness specimen blanks were recently placed in the Oyster Creek re-insertion capsule.It would be best if the new capsule B target fluences were compatible with the Oyster Creek fluences.In order to be certain of future regulatory acceptance, it is recommended that the limiting plate, adjustment factor be used 71 1

'n the next P-T curve update.It is essential that this approach be accepted by the NRC since it is important to establishing a plant-specific surveillance program.It is also suggested that work be undertaken to combine the NMP-1 and Oyster Creek surveillance programs and the existing data be used to establish a plant specific trend curve.It is likely that the current overly conservative model assumptions can be relaxed and future hydrotest and P-T operating windows opened.The NRC submittals should be coordinated and similarities of the two programs noted.A submittal which requests NRC approval for combining the data'ases shou'ld'be prepared in the near future.An overall plan for the combined program which optimizes the withdrawal schedule should be prepared.72 I

[APED][ASTM261][ASTM263][ASTM482][ASTM522][ASTM523][BU85]"Modified Surveillance Program for General Electric BWR Pressure Vessel Steels", General Electric Report APED-5490, April, 1967."Standard Method for Measuring Neutron Flux, Fluence, and Spectra by Radioactiviation Techniques", ASTM Designation E261-77, Annual Book of ASTM Standards, Part 45 (1982), pp 930-941."Standard Method for Determining Fast-Neutron Flux Density by Radioactivation of Iron", ASTM Designation E263-82, Annual Book of ASTM Standards, Part 45 (1982), pp 951-956'Standard Guide for Application of Neutron Transport Methods for Reactor Vessel Surveillance", ASTM Designation E482-82, Annual Book of ASTM Standards, Part 45 (1982), pp 1088-1092."Standard Method for Calibration of Germanium Detectors for Measurement of Gamma-Ray Emission of Radionuclides", ASTM Designation E522-78, Annual Book of ASTM Standards, Part 45 (1982), pp 1139-1144."Standard Method for Determining Fast-Neutron Flux Density by Radioactivation of Copper", ASTM Designation E523-82, Annual Book of ASTM Stnadrads, Part 45 (1982), pp 1145-1152.

Burns, L.S., Rogers, D.R.,"Fast Neutron Axial Pressure Vessel Calculations for Nine Mile Point Unit No.1", October 28, 1985'BUG75]BUGLE 80 Cou led 47 Neutron 20 Gamma-Ra P3 Cross Section Librar for LWR Shieldin Calculations, RSIC Library DLC-75.[CE65][CE90]Combustion Engineering Drawing, Inspection Revision No.1, Material Identification for Niagara Mohawk RV, Drawing E 231-582-1, 9/20/65."Niagara Mohawk Power Corporation Nine Mile Point Unit 1 Reactor Vessel Weld Materials", Report No.86390-MCC-001, ABB Combustion Engineering Nuclear Power Combustion Engineering, Znc., Windsor, Connecticut, June, 1990.73

[DOT75]RSIC Computer Code Collection, DOT 4.3 One-and Two-Dimensional Trans ort Code S stem, Radiation Shielding Information Center, Oak Ridge National Laboratory, Oak Ridge, Tennessee, November 17, 1975.[EP82]"Nuclear Reactor Vessel Surveillance Data Base", EPRI NP-2428, June 1982[GO79][HI69]Gold, R.,"Process for Measuring Temperature with Solid State Track Recorders", U.S.Letters Patent 4,167,109, September ll, 1979.Higgins, J.P.and Brandt, F.A.,"Mechanical Property Surveillance of General Electric BWR Vessels", General Electric Report NEDO-10115 (July, 1969).[HO65a]Howard, A.,"Surveillance Test Program for Niagara Mohawk Reactor Vessel", Combustion Engineering, Contract 164, Rev.2, 1965.[HO65b]'Howard,"D.A., Fabrication Test Program for Niagara Mohawk-213" BWR General Electric Company, DE A.Howard Combustion Engineering, December, 1965.[LE64][LO84]Lewis, S.R., Welding Material Qualification to Requirements of NAV Ships 250-1500-1, Metallurgical R&D, Combustion Engineering, Sept~1964-Feb.1965.Lowry, L.M., et al,"Examination, Testing, and Evaluation of Irradiated Pressure Vessel Surveillance Specimens from the Monticello Nuclear Generating Plant", Final Report from Battelle-Columbus to Northern States Power Company (March 15, 1984).[LO84]Private Communications, John Conway of Niagara Mohawk Power-Corporation to L.M.Lowry of Battelle's Columbus Laboratories, March 24, 1984 and May 2, 1984.[LU64][LU85]Lukens Test Certificates, from Lukens Steel Company to Combustion Engineering, May-July, 1964.Letter to Mr.Tom Caine from J.Fredric Longenecker,"Copper Content of Reactor Vessel Plates", October 9, 1985.[MA85a]Manahan, M.P., Failey, M.P., and Landow, M.P.,"Examination and Evaluation of the Nine Mile Point-Unit 1 30 Degree Azimuthal Surveillance Capsule, final report from Battelle to Niagara Mohawk Power Corporation, April 23, 1985.74 V  

[MA85b][MA85c]Letter to Mr.Ray Pasternak from Dr.Michael P.Manahan,"Radial Flux Profiles for Nine Mile Point Unit 1", June 24, 1985.Letter to J.A.Zwolinski from Mr.C.V.Mangan, Niagara Mohawk Power Corporation, 300 Erie Boulevard West, Syracuse, NY 13202,  

Docket No.50-220, DPR-63, December 10, 1985.[MA86]Manahan, M.P.et al, United States Patent 4,567,774,"Determining Mechanical Behavior of Solid Materials Using Miniature Specimens",[MA87]Manahan, M.P.,"Surveillance Capsules A'nd C'or Nine Mile Point-Unit 1", September 30, 1987, Draft Final Report to Niagara Mohawk.[MA89]Letter to Mr.Yang Soong, Niagara Mohawk Power Corporation, from Dr.Michael P.Manahan,  

Proposal/Agreement No.723-R-2326

'MA91]Manahan, M.P~,"Pressure Temperature Operating Curves for Nine Mile Point Unit 1," Final Report dated January, 1991.[MC89]"SAM McFRAC: Statistical Analysis Methodology for Mechanics of Fracture", PC Version Developed October, 1989.[NE85]Letter to Dr.Michael P.,Manahan from J.E.Nestell, MPR Associates, Inc., 1050 Connecticut Avenue, Washington, D.C.20036,  

Nine Mile Point Unit 1 (NMP-1)Reactor Vessel Surveillance Capsules, dated September 17, 1985.(Revised 11/27/85).

[NMFS][NMTS]Nine Mile Point Unit 1, Final Safety Analysis Report Nine Mile Point Unit 1, Technical Specifications, Section 3.2.2, Minimum Reactor Vessel Temperature for Pressurization, updated 1987.[OD85]Odette, G.R., Lombrozo, P.M., and Wullaert, R.A.,"Relationship Between Irradiation Hardening and Embrittlement of Pressure Vessel Steels," Effects of Radiation on Materials:

Twelfth International Syposi um, ASTM STP 870, F.A.Garner and J.S.Perrin, Eds., American Society for Testing and Materials, Philadelphia, 1985, pp.840-860.75  

[RO80]Roberts, J.H., Gold, R., and Ruddy, F.H.,"Thermal Annealing Studies in Muscovite and in Quartz", Proceedings of the Tenth International Conference on Soli d State Nuclear Track Detectors, Lyons, France, July 2-7, 1979, Pergamon Press, Oxford, (1980)177.[ST64]Stone, W.A., Mechanical Test Report (contract 164 Niagara Mohawk), from W.A.Stone Metallurgical R&D Department, Combustion Engineering, July-October, 1964.[ST84]Stahl, D., et al,"Examination, Testing, and Evaluation of Irradiated Pressure Vessel Surveillance Specimens from the Nine Mile Point Nuclear Power Station", Final Report from Battelle-Columbus to Niagara Mohawk Power Corporation (July 18, 1984).[ST84]Stahl, D., Manahan, M.P., Failey, M.P., Landow, M.P., Jung, R.G., and Lowry, L.M.,"300 Degree Capsule Examination, Testing and Evaluation of Irradiated Pressure Vessel Surveillance Specimens From the Nine Mile Point Nuclear Power Station", Niagara Mohawk Power Corporation, July 18, 1984.76  

APPENDICES  

APPENDIX A DESCRIPTION OF CAPSULES A'ND C'-2  

APPENDIX A.1 DESCRIPTION OF CAPSULES A'ND C'his appendix of the report describes the contents and layout-of Cap-sules A'nd C'.These capsules are considered to be advanced boiling water reactor (BWR)surveillance capsules since they contain mechanical behavior, temperature monitors, and dosimetry, which are not found in the currently used BWR capsules.The capsule inventory and assembly drawings are provided in Appendix A and the as-built photographs are provided in Appendix B.Details concerning the capsule design and fabrication of the contents are provided below.Battelle established a subcontract with Metrology Control Corpora-,.tion (MCC)to provide the radiometric monitors (RMs), helium accumulation fluence monitors (HAFMs), solid state track recorders (SSTRs), melt wires, and solid state track recorder-temperature monitors (SSTR-TMs).

MCC entered into a contract with Westinghouse Hanford Company (WHC)for U.S.Department of Energy (DOE)dosimetry services of the National Reactor Dosimetry Center RDC)at the Hanford Engineering Development Laboratory (HEDL)and the helium mass spectrometry laboratory at Rockwell International Rocketdyne Division (RI-RD)(Mc87a).All other work described in this report was performed by Battelle.Dosimetr In order to determine neutron exposure levels throughout the reactor vessel-geometry with a minimum uncertainty, it is necessary to employ a com-bination of rigorous analytical techniques and spectral dosimetry.

In parti-cular, neutron transport calculations coupled with advanced neutron monitor sets located in surveillance capsules provide an improved approach to the determination of both axial and azimuthal exposure gradients within the pres-sure vessel.It is felt that this approach is superior to the current dosi-metry practice in which only wires of Fe, Cu, and Ni are included.The design philosophy used for the dosimetry was to rely heavily on proven, time-tested technology which is why spectral RMs were used widely.owever, as a backup, recognizing that the technology will advance over the xt decade, we have included HAFMs and SSTRs.The SSTRs are integrating A-3 I~

Automated track counting is under development and counting methods will undoubtedly improve over the next few years.The HAFMs are wires composed of material with an appropriate (n, a)cross section.The helium accumulates in the material with increasing fluence and can be measured using any one of a variety of destructive chemical analysis techniques.

This section of the report gives a complete description of the advanced dosimetry fabricated for MCC by the NRDC at HEDL to provide two sets of dosimetry at three axial locations per set for Capsules A'nd C'.One set is to be exposed for-14 efpy years and the second set for-24 efpy years.This advanced dosimetry has been prepared by the NRDC at HEDL with the assis-tance of RI-RD.The advanced dosimetry services provided are delineated in Table 1 of Appendix C.Assistance was.also provided by the NRDC to MCC in the preparation of purchase order specifications for the acquisition and fabrica-tion of the outer stainless steel (SS)and inner Gadolinium (Gd)shield capsules as well as the subsequent gA of the fabricated parts.~~Capsule identification (etched on the outer SS surface)is as specified by Battelle.Anticipated fluence level exposures of-14 efpy and-24 efpy are denoted by A and C, respectively.*

-Bare and Gadolinium-covered dosimeters are designated by B and G, respectively; and the top, midplane, and bottom axial locations are indicated by 1, 2, and 3, respectively.

A fourth identifying letter (A or B)was used when all the dosimetry for a single location could not be loaded into'a single capsule;e.g., capsules AG1A and AG1B.As additional examples of the numbering system:.AG1B indicates an"A" fluence exposure-Gadolinium Covered-Top position-and second Capsule B with HAFM dosimetry; and CB3 would denote a"C" fluence exposure-Bare-Bottom axial location.In all instances, the first letter of the identifying number is located at the bottom end of the dosimetry capsule.The materials used and the 18 individual capsules are described in Appendix C.The dosi-metry holders and contents are shown in Appendix D.Each of the 18 capsules contains one or more of the following types of dosimeters:

(1)RMs, (2)HAFMs, (3)SSTRs, and (4)SSTR-TMs.Note: The Battelle designation for A and C are A'nd C', respectively.

A-4  

A.2 Tem erature Monitors Two different types of passive temperature monitors (TMs)were supplied to observe irradiation temperature.

A set of conventional melt wire (NW)TMs were used to cover the temperature range from 536 up to 598..F;These monitors are proven and time-tested and therefore are the primary source of temperature monitoring.

A detailed description of these MW-TNs is provided below.A second set of TMs were supplied which are based on the annealing properties of SSTRs.SSTR-TNs are a new and novel mean's of passively observ-ing irradiation temperature (Go79).A detailed description of these SSTR-TMs is provided in Section A.2.2 below.The advantage of these monitors is that'they"are"'potentially"capable of providing an estimate of the average tempera-ture in the capsule.They have not yet been proven for reactor irradiations and the same fission track counting problems are experienced as with SSTRs.However, these monitors were included as a backup to the melt wires since we~~ticipate that this technology will continue to develop over the next decade.A.2.1 Melt Wire Tem erature Monitors Eutectic materials with unique melting temperatures were included in Capsules A'nd C'.Composition and impurities greatly influence the melting'temperature;'therefore, the materials used consist of purities of 99.9 percent or greater, so that the measured melting temperature is within at least+6 F of the recognized melting temperatures.

The MWs were encapsulated in quartz tubing, evacuated and backfilled to approximately one atmosphere of helium pressure for optimum transfer of heat between the encapsulated NW and the outside environment.

The MW-TMs included in Capsules A'nd C're listed in Table A-1 and photographs are provided in Appendix E.The NW capsules were formed f'rom 0.24 inch outer diameter quartz tubing with 0.062 inch thick walls.To facilitate identification of these different NW temperature monitors, each MW was encapsulated in quartz tubing of a specific length as shown in Table A-l.After fabrication, the MW cap-sules were leak checked, pressure-tested and certified by con'ducting melt eriments.The certification test results indicated that all the MW ompositions melted within+2 F of the nominal value.A-5  

'U P I TABLE A-1.MW MATERIALS AND MELTING TEMPERATURES Composition, WtX Melting Temperature, F quartz Capsule Length, in.80 Au, 20 Sn 90 Pb, 5 Ag, 5 Sn 97.5 Pb, 2.5 Ag 97.5 Pb, 1.5 Ag, 1.0 Sn 98.8 Cd, 1.2 CU 536 558 580 588 598 1 1-1/4 1-1/2 1-3/4 2 A.2.2 Solid State Track Recorder-.Tem erature Monitors A number of limitations of MW-TMs can be overcome by using a new passive TM.This new passive TM provides for continuous monitoring of tem-rature with assigned uncertainties.

It represents a novel, patented appli-ion of SSTR techniques

[Go79].Since tracks are annealed in SSTRs at elevated temperatures, the degree of annealing can be used to measure the in-situ temperature.

Of equal importance is the nature of this SSTR-TM response, since it is based on track annealing and therefore, responds to the average time-temperature history that is experienced by the SSTR.Conse--quently, normal,.temperature excursions due to reactor operations are expected to make only small contributions to track annealing and the SSTR-TM will therefore furnish an accurate measurement of the in-situ temperature.

Fission fragments produce a narrow path of radiation damage in quartz glass, mica, and other SSTR materials.

When chemically etched, a hole is produced along the damage path which can be seen under a microscope; this hole is called the fission track.All or part of the damage can be annealed out by heating the SSTR.This annealing, when carried out before the etching process, drastically modifies the length and/or diameter of the track when etching occurs.The amount of annealing is a function of time and temperature

[Go79, Ro80].'n the case of quartz glass SSTRs, the annealing effect will reduce diameter of tracks produced by normally incident fragments, and will.A-6