SUMMARY

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-'builtdrawings 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

6~0 REFERENCES

[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,

Subject:

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,

Subject:

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,

Subject:

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~

dosimeters which accumulate fission tracks throughout the irradiation.

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

eliminate some of the tracks produced by isotropic incidence (exposures made with the source in contact with the SSTR material).

In the case of mica SSTRs, the track length is reduced if damage has been partially removed by annealing.

The outstanding problem in the application of SSTR-TMs in power reactors is the lack of calibration data.MCC will be initiating an extensive calibration program within the next few months.Calibration curves for SSTR-TMs are obtained by observing the annealing characteristics of SSTRs.Sets of quartz glass and mica SSTRs are prepared in the same way the SSTR-TMs were prepared for inclusion in the NMP-1 replacement surveillance capsule.Both isotopic and normally incident fission fragment irradiations are used.Subsets of these SSTRs are then heated in an oven at constant temperature for a given period of time.The oven must be well regulated so that stable temperatures are attained with an accuracy of at least+4 F.Upon withdrawal from the oven, the SSTRs are etched and subsequently scanned.Calibration data are generated by repeating this process at different oven mperatures for different time durations.

Preliminary calibration data for uartz glass and for mica have already been reported[Go79, RoBOJ.Both quartz glass and mica are used for SSTR-TMs in Capsules A'nd C'.The pre-irradiation preparation of quartz glass and mica SSTR-TMs is discussed separately in Sections A.2.2.1 and A.2.2.2.A.2.2.1 Pre aration of uartz Glass SSTR-TMs.The type of quartz glass chosen for SSTR-TM applications in reactor surveillance should possess a very low concentration of fissionable impurities.

Consequently, a high purity quartz glass, namely Supersil, has been used.Supersil quartz glass was supplied by Amersil Company, Inc., Hillside, New Jersey.The Supersil quartz glass was cut into a disk shape, 0.178 inches in diameter by 0.06 inches thick.Both surfaces of the disk were then mechani-cally polished to remove scratches and imperfections.

A final surface polish was obtained by etching in 49 percent HF at 70 F for 120 minutes.The polished Supersil quartz glass was then cleaned by rinsing in the following solutions in the order given: (1)Palm Olive Soap Solution, 2)distilled water, (3)double distilled water, (4)Ultrex BN nitric acid, , finally, (5)double distilled water.This cleaning process was used both A-7

,'ljl 4 Qd+(~n

~~~~~prior to irradiation with fission fragments and just prior to encapsulation for reactor surveillance.

A.2.2.2 Pre aration of Mica SSTR-TMs.The type of mica chosen for SSTR-TM applications in reactor surveillance should also possess a ve~low concentration of fissionable impurities.

To this end, mica from India, sup-plied by The Perfection Mica Company, has been used.The mica was first pre-annealed in an oven for about 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> at 1076 F.It was then pre-etched in 49 percent HF 70 F for about 18 hours2.083333e-4 days <br />0.005 hours <br />2.97619e-5 weeks <br />6.849e-6 months <br />.When placed under a microscope, resi-dual fission fragment tracks are seen.The mica with a low density of tracks was selected.It was then cleaved to thicknesses of about 0.003 inches.Disks, 0.178 inches in diameter, were punched from the freshly cleaved mica.Mica'STR-TMs were cleaned by the same procedure used for the quartz glass.This cleaning process is important just prior to encapsulation, in order to rid the mica of transuranium or other actinides that may produce undesirable fission fragment tracks while being exposed to neutrons in the ctor.A.2.2.3 SSTR-TM Fission Fra ment Irradiation.

Prior to use, the SSTR-TMs must be exposed to fission fragments.

A uniform source of 252Cf was.used for the irradiation.

Two types of, fission fragment exposure, isotropic and normally incident, were used.The isotropic exposure is performed by placing the'SSTR-'TM in firm contact with the spontaneous fission fragment source.Normally incident exposures were obtained in a vacuum chamber.There was approximately 2.2 inches between the SSTR-TM and the spontaneous fission fragment source.For the isotropic exposures, a 252Cf spontaneous fission fragment source having a diameter of 0.25 inches', on a stainless steel disk 0.75 inches in diameter, was used.The source had a very thin gold coating.On 1-29-86, this source had an activity that produced 9230 tracks per minute per square centimeter in mica placed in direct contact with it.A 252Cf source about 1/8 inch in diameter was used for exposures in the vacuum chamber.On 1-31-86, an exposure gave a track density for normal incidence of 60.1 tracks per minute per square centimeter.

The statistical accuracy of oth measurements is 2.7 percent.A-8

+1IF A.2.2.4 Fission Fra ment Irradiation of uartz Glass SSTR-TMs.-One side of the quartz glass SSTR-TM was irradiated isotropically with fission fragments and the other side was irradiated with normally incident fission fragments.

Estimated track densities for the isotropic and normal irradia-tions, respectively, are given in Table A-2.Two such quartz glass$STR-TMs were prepared for each capsule.Isotropic exposure data from the mica SSTR-TM are given in Table A-3.A third quartz glass SSTR-TM was prepared for each capsule as described earlier, but was not irradi'ated with fission fragments.

One surface of this third quartz glass SSTR-TM is used to assess fission fragment track background induced during the reactor surveillance irradiation.

The other surface was placed in firm contact with a 23BU deposit to form an SSTR neutron dosimeter for the'reactor surveillance irradiation.

This SSTR neutron dosi-meter will provide fission fragment tracks that are formed throughout the entire course of the surveillance irradiation.

Consequently, this type of SSTR-TM provides information on the time-temperature history of the surveil-~~~~~nce irradiation.

After being cleaned, the SSTR-TMs were loaded into capsules AB2 and CB2 as shown in Figures A-1 and A-2.A.3 Char V-Notch S ecimens The types-and number of Charpy specimens in the reinserted capsules were summarized in Table A-2.Niagara Mohawk decided to weld reconstitute the Charpy specimens prior to reencapsulation.

The specimens can be tested in this configuration or miniature Charpy specimens could be machined in the future when the capsules are withdrawn.

Battelle has developed a miniature Charpy test in which 16 miniature specimens can be machined from one conven-tional specimen.A total of 24 Charpy V-notch (CVN)specimens (12 base, 12 weld)were reconstituted for inclusion in Capsule C'.A total of six CVNs were recon-stituted for inclusion in Capsule A'.The specimens were stamped on the ends with the appropriate F.A.B.code designation.

The original F.A.B.code'dentification was used with an additional letter"A" or"B" to designate a onstituted specimen.The specimen identifications and locations within the packets are given in the Appendix A specimen inventory drawings.A-9

TABLE A-2.EXPOSURE DATA FOR SUPERSIL II QUARTZ GLASS+SSTR Label Isotro ic Time (min)Tracks/cm2 Normal Incidenae Time (min)Tracks/cm2 C*11 12 13 3C*21 22 23 20.6 30 30 0 21 30 30 0 1.2E5 2.4E5 2.4E5 0 1.2E5 2.4E5 2.4E5 0 1014 680 680 0 1014 680 680 0 4.45E4 4.1E4 4.1E4 0 4.45E4 4.1E4 4.1E4 0+'ll exposures made on 1-27-86, except for C and 3C, which were exposed on 4-1-87.*Control samples, not put into the reactor.These will be stored at or below room temperature, and etched along with the SSTR-TM when they are removed from the reactor.TABLE A-3;ISOTROPIC EXPOSURE DATA FROM MICA SSTR-TM+SSTR Label Exposure Time in Min.Predicted Tracks per cm2 Cl*11 12 13 C2*21'2 23 13.75 11 10 0 13.75 10 10 0 9.2E4 1.0E5 9.2E4 0 9.2E4 9.2E4 9.2E4 0+All exposed on 1-27-86 except for C1 and C2, which were exposed on 4-1-87.*Control samples, not placed in the reactor.These will be stored, at or below room temperature, and etched along with the SSTR-TM when they are removed from the reactor.

,II~4%18~-~

DISTR E D VICE f ISSION FRAGHCt4T XRRRD I R T'I OH.t!OtiE$50TROPXC NICR 12 b I SOTROP ZC t40NE MICR 13 b U-2 39'lt23 3 NONE HONK:QLlRRTZ QURRTZ I 2 b NORMRL I BOTROP 3C I SOTROP I C OORHFiI U-2 38 423 8 QURRTZ 13 t MICR SPRCER FIGURE A-1.ARRANGEMENT OF SOLID STATE TRACK RECORDER TEMPERATURE MONITORS IN CAPSULE AB2 (A t denotes that the ID is on the top surface of the mica or quartz glass, whereas a b denotes that the ID i s on the bottom surf ace.)

SSTR TD Nl CR 21 t FISSION F RRGHEHT IRRRDIRT I Ot4 NOAE IBOTROP1C I SOTROP I C NONE NI CR 29 b U-238+226 NONE HOME QURRTZ 2 I t QURRTZ 22 b NORgQ I SOTROP I C ISOTROPIC HO~PL QVRRTZ 23 t Ll-238 422$NONE NlCR SPRCER FIGURE A-2.ARRANGEMEHT OF SOLID STATE TRACK RECORDER TEMPERATURE MOHITORS IN CAPSULE CB2 (A t denotes that the ID is on the top surface of the mica or quartz glass, whereas a b denotes that the ID is on the bottom surface.)

A.4 Miniature and Conventional Tensile S ecimens The types and number of tensile specimens in Capsules A'nd-C'ere summarized in Table A-2.In cases where conventional tensile specimens were already tested, miniature specimens were machined from the broken halves.The Battelle proprietory specimen design is shown in Appendix A[Ma86].A total of two miniature tensile specimens (base)were included in Capsule A'nd eight miniature tensile specimens (four base, four weld)were included in Capsule C.The miniature tensile specimens were numbered consecutively from one to 10.The conventional tensile specimens retained their F.A.B.code designations.

The specimen identifications and locations are shown in the Appendix A inventory drawings.A.5 Ca sule Desi n and La out Surveillance capsule packet inventory drawings were prepared for the o reinsertion Capsules A'nd C'nd are given in Appendix A.The inven-ories include all specimens shown, in Table A-2 and the recommended dosimeters and temperature monitors.Packet fabrication drawings were also prepared that show specimen, dosimeter, temperature monitor, and spacer locations and dimen-sions in each capsule.GE fabricated the spacers, packets, baskets, and lead tubes.The drawings indicate the specimen F.A.B.code designations and the as-built photographs show specimen by specimen agreement with the fabrication drawings.The dosimetry was carefully oriented and spaced to avoid neutron field perturbations which would affect the data.The dosimetry was also located so that the axial flux profile can be measured.Good heat transfer is insured by tight specimen packing and a helium backfill in each packet.A.6 Archive Materials The length of these planned irradiations, namely Capsule"A" for 14 efpy and Capsule"C" for 24 efpy, make it mandatory that archive dosimetry nd TM materials be retained by Niagara Mohawk.Experimental results from wer reactor irradiations can sometimes by inconsistent or hard to resolve.

Cf

~~It is essential, therefore, that these archive materials be available as a contingency should problems arise with the experimental dosimetry results.With these materials, calibration experiments can be repeated and, if n'eces-sary, 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 Cap-sules A'nd C'ave been provided to Niagara Mohawk.Tables A-4 through A-7 summarize the supplied archive materials for RM neutron dosimeters, SSTR neutron dosimeters, MW-TMs and SSTR-TMs, respectively.

TABLE A-4.ARCHIVE RM AND HAFM NEUTRON DOSIMETRY MATERIALS Dosimeter aterial Type PO No.Batch Vendor Form guantity Fe RM 07448 26/17944 MRC 0.020D Wire 2 inches Ni RM"1" SE Roll 2 Semi Element 0.020D Wire 2 inches Cu RM, HAFM 19047 CPI 3054 Cominco Am.0.020D Wire 2 inches Co/Al RM 44451 SC Bar 26 Sigmund Cohn 0.020D Wire 2 inches Ti RM 19046 Cat 614 Reactor Exp.0.020D Wire 2 inches Al HAFm 19045 SE Roll 1 Semi Element 0.020D Wire 2 inches NOTES: (1)Archive samples of the vanadium encapsulated fissionable RM dosimeters are not provided;those included in Capsule Sets A and C are to be used for this purpose.(2)Samples of the Be, Fe, and Ni HAFM dosimeters are not provided;but are available for purchase from RI-RD.A-14 V PI TABLE A-5.ARCHIVE SSTR NEUTRON DOSIMETRY MATERIALS SSTR(1)Type ID Diameter Isotope SSTR De osit(2)Mass ID Total (pg)Density-(pg/cm2)Mica 219 Mica 231 Mica 199 0.168 0.168 0.168 235-U 238-U 237-Hp 219 231 199 0.826 7.65 10.39 8.81 81.6 110.8 (1)Three additional mica SSTRs of 0.168 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.TABLE A-6.ARCHIVE MW-TM MATERIALS Composition, WtX Melting Temperature Length Diameter (F)(in.)(in.)Source 80 Au, 20 Sn 536 97.5 Pb, 2.5 Ag 580 97.5 Pb, 1.5 Ag, 1.0 Sn 588 90 Pb, 5 Ag, 5 Sn 558 0.25 0.030 Indium Corp.of America 0.25 0.090 Babcock&Wilcox 0.25 0.084 Babcock&Wilcox 0.25 0.084 Babcock&Wilcox 98.8 Cd, 1.2 CU 498 0.25 0.083 Babcock&Wilcos A-15

TABLE A-7.ARCHIVE SSTR-TM MATERIALS Material guantity Description and Purposes India Ruby Muscovite Mica India Ruby Muscovite Mica 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.

Cl and C2 as described in Table 4-2.Needed as standards when mica SSTR-TMs are removed from the reactor.Supra II quartz Glass Supra II quartz Glass 3/8 in.thick squares about 40 mi ls thick.Representative materials used in SSTR-TMs.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.A-16

0 0464 6.942---Spocer r 3 rr v/4'i'o>>I II<x 2 ccti kt Iw r O444 IO 0.250 OO32 c~0 I/16 05000 Hole 2.125~-I/l6 I.3 DD Q 0 f 25 0 109 Cleoronce 2.000 Spocec 0.380$0 500$0.125 x45oChom 0.025'tcoronce g~AvChab><0"~+<t~fC CB+0.025 Cteoronce cp ui co 11 too Cteoconce g saoos 16 2 i.772 0 936 gol5 M<n 0.836 Cleoroncc 2.165 LOKI 0 0 ip ii o a m ip 0 0 242 0 0 0 ip~t cp I 1 I 1 I 1 1 I 1 I~I c I I I 1 I I 1 I I 1 I I I I I I 1 I 1 I 1 I I I I I I I I I I I 1 I I I I I I I I I I t O a O4OO 0 CL O 0 I I I I I I I I l 1 I I I I I I I I I 2 165.at00 2.082$oco 2.067 cn 0 I 2 005 43OIO 1.990 008300.I 635 Ooco 1.620~0084 i 44520CX o o-l.430 0.090 1402 foco-1.387~2570*O005 oo4o Q 00 0.08r/0 0 0 250 0.032 2.314-2 250 12.865 1 SE=DRAWING 004 0.028 ox 2.314 SEE DRAWING 003 I0002 ALL DIMENSIONS ARE IN INCHES~04 O Z Z ol Cot 20~IOI COA44 O~22 ta~i~2/i~err TASK COORO f3A MANAGER NOTFi Fnn 33rD f A SR Bv oa cvcc v 3 NOTES: l.The outside dimensions Df the basket contents have a minImuct 0.016 clearance for disassembly.

2.Charpy V notch shoItd flee the pressure vessel wall.3.Charpy packets.matt wire packets and lcnsilc'lccbcs arc sc)kd cs follows: 3-\.Exhaust air to (educe intecnal pressure to I lorr.Back lill with welding grade Ileticm al atmosphenc pressure and scat.3-2.Verily leak tigttnesc using mass spectrometer.

fhe cllowable leakage is to s atm cc.min.4.The original dosime!ry consisted of Fe, Cu, Ni wires.These wires~re rcinstalled at each location In the packets al shown lone Fe.one Cu, and one Ni al e ch lccation).

DATE oRAwccpv/RAFTIRO Arvo,/35 r//c SC.rc//Q c.~4 Attn, FROJCCT Ati'O.r'/.SFSCIAL Attn SIGNATURE DIV.-"".".":Battelle Cotombuc tabor 2 cocicc 505 King Avenue Columbus.Ohio 43201.2693 Telephone f614)424 6424 CAPSULE A'SSEMBLY DRAWING FOR NINE MILEI POINT UNIT 1 (RE-ENCAPSULATION)

RKV.Stgg COOS tOSNT NCX OCV NO.DWCA NO.I 79986 442 BCD-NMP-OOI 1 scam I: I" accr.N0938-2900 sNggy I o(I l:~k~A 1 t a,,\'rv 0 1~l)I 3 D Irradiated HAZ Unbroken and Reconstituted Base 0 0 Irradiated Weld 0 Tensile Tubes SPACER Melt Wires glk CfxB){)v~@>~e0 Cggb g@ggg,fc J12 J13 E71A E12 E31A EO1 ED2 t EO3 l JD1 (Beee)JLK JTA (Vreld)(KAZ)JUL (KAZ)598 F Advanced Dosimetry Original Dosimetry{Fe, Cu, Ni Wires)Advanced Dosimetry See Note1 J14 IB)f J15 J16 J17)IID)y BIDtr J1A J1B J1C J1D JTE E2E E2T E2UA E17 trio)r BZO)r E1AA E2Y E1CA E1D EBKA ED4 1l EOS E06 il ED7 I tyco)r B cQ)r EOAi EDB EOC EOO'EOE S P A C E R JD2 (Bere)1 JL2 (Bete)plveld)2 (Bere)JUJ (KAZ)588 F 580 F 558 F 536 F NOT A SCALE DRAWING 0 Z o O 1.REVIEW BOARD DATE., gC~/S 2.TASK COORO JfASK LEADER QA MANA(IFR Qx NOTE: t.The original dosimetry consisted ol Ff, Cu, Ni wires.These wires'are reinslailed at each location In the packets ss shown lone Fe, one, Cu, and onc Ni at each location).

I 2.The advanced dosimetry tubes musl lie Installed so that the liest character{A)In the tube Identification Is st the lowest elevalion as shown in the drawing.3.The capsule must be assembled exactly ss specliied due to neutronic snd other design SIGNATURE DRAWN SV~DRATTIND Areo Aeep.N~li 3 IEg~l 4 DIV DATE/3d/Z'6"..,.:Battelle-Columbul teboreloINI AZ Zjztr!JC Ri Oa-0 505 Kmt Avenue Columbus Otvo 4320)2693 Telephone (6 I 4)424.6424 CAPSULE A MECHANICAL BEHAVIOR SPECIMEN INVENTORY DRAWING FOR NINE MILE POINT UNIT 1 (RE-ENCAPSULATION)

RKV.NOTE: sn"r ss BvoACIAT CAT II~I~I IOIIN D~Ie~Ie 4 considerations I'Roeccv ATTD.se CIAL Tep.A(ALL 4a/f 4 SIZK COOK lOKNT.NCk OIV.NO.OWO.NO.C 79986 442 BCD-NMP-002 1 SCALE Aocr.N093B-2900 sKKKT I of I~vj 1 J+I F R I h f~JC I C V+

3.I/4-28UNF-2A Both ends 0.078 R D-D-D 0 0.250<petite 0 Qa>>"'~ca~~

~~~g(QfC 30'y)3 Po.oos Reduced Section l7 0.03I O.I87 0.073 0.350 0.073 0.3I7 I 0>0.010 SCALE IO:I.ALL DIMENSIONS ARE IN INCHES+0 20-0.0)s 0 Z cs~O SCALE 5: I ALL DIMENSIONS ARE IN INCHES B 1.D Stok BOARD DATE SIGNATURE oRAwsrov~DIV/35 DATE"'.".".Battelle Columbus tsborr tories 505 King Avenue Columbus.Oho 43201 2693 Telephone (614)424.6424~g~ac.2.TASK COORD ASK LEADER~adit S.OA f4AMABER 4'OTE: sort ngtgAs'c tsv 0A orrcv of reduced section.003)al ends of reduced 2 rms, s0.001.kOTESt 1.0~0.150 g0.001 Diameter at cente 2.0'~Actua'I-D" Diameter+I0.002-0 section, tapering to"D" at center.3.100%dimensional inspection require 4.Polish reduced section and radius to remainder as turned.5.All olher dimensions are to be within AFJ'o//-g/.A"" enopc'T Aeao clAL rro P C COtrg IDENT.ko.tSIV.NO.tSWG.NO.I REV 79986'42 BCD-NMP-003 1 N0958-2900 sttggT I of I MINIATURE TENSILE SPECIMEN FOR NINE MILE POINT UNIT i (CAPSULE A AND C RE-ENCAPSULATION)

CAT.Is~sot roau o~Ir rs 4

'V'\)ll'~Gw a 0 4 D I/32 X 450 CHAM TYP A~<<~~I/16 CUT 0.255 I.D.g+I/32 IE 0.005 to O.OIO Clearance with actual 10 of tensile lube I I0.444 10.Ref.)ALL DIMENSIONS ARE IN INCHES Source.General Electric 0rowing No.I07C3?97 DRAY/ING APPROVED BY: 1.D SIGN REVIEW BOARD DATE<tu!X 2.TAsK CDDRD ABK LEADER Ml:~4 3.OA MANAGER>@8 NOTE: ron RracAse ev oA c>>4.v CAT, A04 F 07 ROAR 0'ltd 0$4 3 Aeep,~u P/X/TC.As/&~'e/2 SliII/W eeolecv Aeep.RACCIA Aeep, SIGNATURE DIV DATE/35 4/iA/sb PRAFTIRC AA00 ,R<b I 0 KO I I Tetephene (6t4)424 6424 SIZC CDDC IDENT.ND.C 79986 DIV.ND.DWO.ND..442 BCD-NMP-004 scAcc 5": I ACCT.,N0938-2900 sNccT I of I CONVENTIONAL TENSILE SPECIMEN FILLER SLEEVE Rcv.~A 3 0aea 6 942=-=Spocer/l c/u sup~c(rc ca r c c~c r crA~o.soo D.aaa ID 0.250 c 0 032 D f/t6 f 0 0.025 Oe prance 0.250 0 5000 Note 2.I25~PI-'r" III"'.500 0125 Spacer 0380 q 0.500tu 00 O.I09Clearance 2 000 0 125 xas Cham/0.025 Cleoronce r 2.165 0 Ipp ggo QvQlh~e A~gfe QQf8 lt tOOCteara nce*aoos 02900 0.936 (0.015 Min.0836 (Clearance~c 0 ru 0 co 0 rd u 0 0 ccr a crr Io ra 0 0 I I I I I I I I I 340 c0002 2.082'8oto 1.990 (.893rpplp 0 I.878 I 701.80I i.eee-4 0.0830 a.08400 1672 1.77 0.250 I Ic 2'65'-oko I I I I I I I I I I I I 1 I I I I I I I I O'.a.327 8oo I.312 0.090<21a.o.olo)

OD.I 199~0.2570 f co.oos 0 03000 0.032 2 250--2.314--+0.028 SEE 2 314 NOTE 4 SEE DRAWiNG 003 12.865 Max, SEE ORawiNG ooa DRAWING APPROVED BY: 1.OE6lGM REVtEW BOARD DATE KXTE~, M~'YCK 2.TASK COORD.ASK LEADER 3.QA MANAGER~J~he basket.015 clearance the pressure ackets and s follows: e internal I k till with at atmosphecic sing mass wable leakage are 1.0'by NOTES: l.The outside dimensions oi contents have a cninimum for disassembly.

2.Charpy V.notch should fac~vessel wall.3.Charpy packets, melt wire tensile tubes are sealed a 3-1.Exhaust air to reduc pressure to 1 tort.8 welding grade Neliu pressure and seal.3-2.Verify leak tightness spectrometer.

The ap is lp-s atm cc/min.4.Four plugs foc tensile lube 0.434 S 0.002 diameter.SIGNATURE D(V onAWNav ACCO I'gn aa'z DATE",,-Battelte Columbus tcbornor les 505 Kurt(Avenue Columbus.One 43201 2693 Tetentene (614)424 6424 CAPSULE C-ASSEMBLY DRAWING FOR NINE MILE POINT UNIT 1 (RE-ENCAPSULATION)

SCZE CODE CDENT.NO.Dtv.NO.DWP.NO.ALL DIMENSIONS ARE IN INCHES-c((0 ap 08-ccc, r~1~Ac revu 0~~c cc NOTE: FOR RctpasE av PA Pcrcv>nocccz Acco.sl'ccIAL ccu/i<("c REV.C 79986-<<Z BCD-NMP-OO5}s spnm I": I" Aopr.N0938-2900 sNEET I p(I I 1 1 c~Q t.~e C fg (~f":i I D D Reconstituted Weld Unirradiated Base Reconstituted 8 ase Tensile Tubes SPACER Melt Wires Advanced Dosimetry IBO EDKA EDLA EDMA EJTA JAEA JAMA ZBO NCOI NC21 NC02 NC22 NC03 NC23 CBO E1JA E1JB E1KA I)E1KB EASA EASB S P A C E R T01 (ease)P L U G 3 (esse)4 (ease)P L U'P L U G 7 (Weld)8 (Weld)598 F 588 F C Advanced Dosimetry See Note 1 J2CA Tf 1SO 8(SO J1LA J1MA NC04)f ZOO BCOO NC24 NCOS E42A T(COO BCSO,: E1MA'f E1UA I T02 (esse)T21 5 9 (8222)(8222)(Weld)6 10 (ease)(Weld)580 F 558 F J1PA J1TA J1JA NC25 NC06 NC26 E3TA E7EA See Note 1 J2C P L U G P L U G 536 F NOT A SCALE DRAWING 0 z ts 0 BY: 1.Qg@gf AEVIEW BOARD DATE 2L(~gc 2,~COOAO ASK LEADEA~i~c s.~ANAG('n~SPAZ/xseb..

~y4 NOTE: sent~..sc ov OA oN(v NOTEt l.All reconstituted specimen were prepared from broken weld or base metal ppecimens excepl tor J2CA and J2CB..These specimens were prepared from the weld and base metal portion of a broken HA2 specimen, J2C.~I 2.The advanced dosimetry tebes must be installed so that the first character (C)in the tube Identification is at the (owe'st elevation as shown in the drawing.3.The capsule must be assersbled exactly as specitied due to neutronic nd other design considerations.

SIGNATURE DIV DRAWN av~//Z5~*y 2/)Attn I/DATE>/I>//'b</cd M/gry G ft-Q Cu4 IA/g sir f(tC"".".'"-Battelle 6(5 King Avenue CorumbuL Ohio 4320)2693 Telephone (6)4)424 6424 trro/ccv Attp, srzc coos togrrr.No.Olv.No.owo.rKx 7 9 9862BCDNMP0061 Columbus lsborrroIN2 CAPSULE C'-'MECHANICAL BEHAVIOR SPECIMEN INVENTORY DRAWING FOR NINE MILE POINT UNIT1(RE-ENCAPSULATION)

REV.cA'I, I~I I 22 rouu 0'~2'22 3 CCIAL Attn, 2/2/~N0938-2900 srtggT I of I I I 1 P 0 Aa~,~r/V 4 4.I,>>'Rg-l1 v I APPENDIX B AS-BUILT PHOTOGRAPHS FOR CAPSULES A'ND C' e h,~11 g 1 jf I I iy

.~pa"~j.~~ZR~-,.t P~, pt+:aat~'$ca t'ai f t a~I"~ggM wm A Ia~Per~i It'I j>p CAPSULE~.aa I ty ta li Y f..A'I tc.)..CI'PSV!L st'IGURE 1.CAPSULE A'HARPY SPECIMENS E l)

FIGURE 2.CAPSULE A'HARPY SPECIMENS B-3 1I ,I~g'k FIGURE 3.CAPSULE A'ENSILE SPECIMENS B-4 0 r FIGURE 4.CAPSULE A'EMPERATURE MONITORS B-5 I!

FIGURE 5.CAPSULE C'HARPY SPECIMENS

%~iN 1~p>

FIGURE 6.CAPSULE C'HARPY SPECIMENS B-7 Wag~11 FIGURE 7.CAPSULE C'ENSILE SPECIMENS B-8

, p r<bA FIGURE 8.CAPSULE C'EMPERATURE MONITORS B-9

APPENDIX C DOSIMETRY DESCRIPTION FOR CAPSULES A'ND C'

TABLE 1 ADVANCED DOSIMETRY PROVIDED BY METROLOGY CONTROL CORPORATION (MC~)Radiometric (RM)Flux Monitors a.6 sets of non-fissionable Gd covered RMs;each set consists of one each of: Fe, Ni, Cu, Ti and Co/Al metal wires.b.6 sets of non-fissionable"bare" RMs;each set consists of one each of: Fe and Co/Al metal wires.c.2 sets of fissionable, vanadium encapsulated, Gd covered RMs;each set consists of one each of: U-235, U-238 and Np-237 oxide wires.d.2 sets, of fissionable, vanadium encapsulated,"bare" RMs;each set consists of one each of: U-235 oxide wire.Solid State Track Recorder (SSTR)Fluence Monitors e.2 sets of Gd covered SSTRs;each set consists of one each of: U-235, U-238 and Np-237, (fission deposits on solid state track recorder backing material with mica SSTRs).2 sets of"bare" SSTRs;each set consists of one each of: U-235, (fission deposit with mica SSTR).Helium Accumulation Fluence Monitors (HAFM/g.6 sets of non-fissionable, Gd covered HAFMs;each set consists of one each of Be (pieces wr apped in Al)*, Cu, Co/Al (or Al), Ni and Fe metal"wires.

h.6 sets of non-fissionable,"bare" HAFMs;each set consists of one each of Be (pieces wrapped in Al), Cu, Co/Al (or Al), Ni and Fe metal wires.Thermal Monitors TMs)i.2 sets of melt wire (MW)TMs;each MW-TM set consists of five melt wires, each of which is contained in a quartz capsule.*Material will be in the form of one or more small pieces of Be metal, wrapped in aluminum with a nomial effective package diameter of-20 to 40 mils and length of less than 0.25".C-2 kt 4 TABLE 1 (Cont'd)Solid State Track Recorder (SSTR)-THs j.2 sets of TMs;each set consists of 3 quartz and 2 mica pre-irradiated SSTRs wrapped in Al.Each set placed in a Gd cover (with other dosimeters) in a SS dosimetry capsule.Oosimetr Ca sule Fabrication k.6 bare and 12 Gadolimium lined stainless steel holders were loaded and assembled.

1.The SS capsules were back-filled with high purity (dry)Argon**prior to welding and were subsequently leak checked by immersion in near boiling water (that has been boiled to remove air bubbles).X-Rays of the loaded holders were also taken.QA and Oocumentation m.A QA data package including the"as-built" description and documentation of all dosimeters and encapsulation containers is provided in the Appendices.

• • Helium was not used because it could adversely (by absorption or diffusion) bias the interpretation of the HAFH monitor results.C-3

TABLE 2 NINE MILE POINT UNIT-1 OOSIMETRY MATERIALS (Total Weight Inc uding Dosimetry, Backing, and Encapsu ation Materials)

Material'238-U 237-Np 235-UAl Be Co Fe Gd Ni Stainless Steel Quartz"A" Capsule Series Wt (Grams)0.007 0.006 0.002&.61 0.020 0.0002 0.38 1.03<<7 7 1.59 0.16 0.06-8.7<<4.7"C" Capsule Series Wt (Grams)0.007 0.006 0.003 M.59 0.013 0.0002 0.37 1.00<<7.7 1.56 0.15 0.06-8.7<<4.7C-4

TABL CAPSULE LOADING SEQUENCE"A" SERIES (-14 EFPY EXPOSURE)(FROM BOTTOM OF SS OR Gd CAPSULE)Loaded SS Ca sule Al Wr a ed Dosimeters Location Top Mid AG1A AG1B AB1 AG2A AG2B ia.In.0.253 0.254 0.256 0.257 0.253 en t n.0.829 0.834 0.830 0.832 0.830 2.9025 2.9723'.7789 2.9552 3.0509 RI H1 H2 (R2)R3 H3 7 8 5 RM HAFM Fe Grad.HAFM RM RM HAFM SSTR 0.165 0.180 0.0.175 0.190 0.175 0.368 0.380 0.394 0.375 0.358 Fe Grad.Tyy>e 0>a.emnth t.m 251.82 231.65 256.42 287.55 255.85 AB2 Bottom AG3A AG3B AB3 0.253 0.254 0.253 0.256 0.829 0.834 0.834 0.834 1.9125 2.8947 3.0017 1.7750 A H4 5 R4 R5 H5 H6 ST-T HAFM SSTR RM RM HAFM Fe Grad.HAFM 0.180 0.195 0.180 0.175 0.376 0.012 0.372 0.355 0.177 0.368 250.83 225.8 248.5 258.25 1 No dosimeter materials are closer than 0.10" from outer SS capsule top.Therefore the top can be parted off up to 0.10 from top.Care must be'taken that no burrs exist nor the open end swaged as the inner capsules may not shake out.2)It is recommended the Gd capsules actually be cracked open (i.e., use"nut cracker" on lower end of capsule)the reason for this is that several of the dosimeter packets are quite a tight fit and possibly would be damaged in the attempt to pull them out of the capsule or to cut open the bottom and push them out.3)No Al material should be discarded without close observation as to whether it is simply spacer material of wrapped dosimeter material.Fe gradients are wrapped individually and though marked Fe could be mistaken for spacer material.Both bare spectral Co/Al and Fe/235-U are wrapped in Al and are unmarked and could therefore be mistaken for spacer material.

TABLE 4 TASK/ID: 85-WHSC-9010 Task 1/Nine Nile Point Unit 1 SS Capsule Number: AG1A RH Set ID: R1 HAFH Set ID: SSTR ID: SSTR-TH ID: Cover: Gd 81 Location: Set ID Haterial AG1A Gd II1 R1 Purchase Order Number Batch Number Haterial Desert tIon~Wt.m s Stain ess tee Outer Ca sule Gd Inner Ca sule Ti S acer Sample ID Elemental~tom.Comments Bottom Bottom Fe Ni Cu Co/Al 07448 19047.19046 44451 26/17944 SE Ro 2 CPI 3054 Cat 614 Sc ar 26~e u folded wire 2~U folded wire~U folded wire~U tl-folded wire ut-folded wire Ti S acer Al Shim S acer Gd Inner Ca sule Al Shim S acer arge e eat Sink S acer 53.436 47.967 61.994 38.266 9.259 251.82 0.165" OD 99.999X 99.999K 99.999K 99.917K 0.506K X 0'68" OL Al Wra ed Spectral Set Al Wra ed To SS Outer Ca sule 2902.48 0.253" OD X 0.830" OL To

TABLE 5 TASK/ID: 85-WHSC-9010 Task 1/Nine Mile Point Unit 1 SS Capsule Number: AG18 RH Set IO: HRFH Set IO: HI SSTR IO: SSTR-TH ID: Cover: Gd FIO LocetIon:~To Set ID AG1B Gd 810 H1 Material Be Purchase Order Number RI Batch Material Goober Descr1 tIon~Ht., m s Stain ess teel Outer Ca sule Gd Inner Ca sule Ti S acer RI-7*3 Metal Pcs Al Wra ed 4.25 Sample ID NM-BE-1 Elemental~Com.Comnents Bottom Bottom Fe Rl RI-RI-4*RI-11A*.8'ngle Fold Wire~~sm~ng e Fold Wire 62.695 125.384 rappe HAFM Set Cu 19047 EDL-CP I 3054 Fold Wire ng e 33.187 99.999K Al 19045 0-ng e SE Roll 2 Fold Wire Ti S acer 9.301 231.25 0.180" OD 99.999K X 0.380" OL Fe o Rx Lot 11.03'ta Disk Al Shim S acer Gd Inner Ca sule Al Shim S acer 82.26 92.772K Al Wrapped Gradient To*Batch No.given by RI for Boron analysis.Large T el eat Sink S acer SS Outer Ca sule 2972.30 0.254" 00 X 0.834" OL To et TABLE 6 TASK/ID: 85-WHSC-9010 Task 1/Nine Mile Point Unit 1 SS Capsule Number: AB1 RH Set 10: R2 HAFH Set ID: H2 SSTR 10: SSTR-TH ID: Cover: Bare Locatton:~To Set ID Material AB1 H-2 Purchase Order Number Batch Material Number Desert t ton~Nt.m a Stain ess tee Outer Ca sule Ti S acer Sample ID Elemental~Com.Comments Bottom Be RI RI-7*3 Metal Pcs Al Wra ed 2.75 NM-BE-3 Fe Cu RI Rl 19047 RI-4*Rl-11A*E L-CP I-3054.8 ingle Fold Wire Snge Fold Wire"Snge Fold Wire 64.514 124.704 30.008 99.999K Al rapped HAFM Set R2 Al Fe 19045 Rx Lot 11 eta Disk o d E-90.X." S ng e Se Roll 2 Fold Wire Ti S acer 9.068 256.42 0.178"OD 82.66 99.999K X 0.394"OL 99.772K Al Wra ed Co/Al 69-89-0885 SRM 953 9.095 Al S acer Shim arge T e eat Sink S acer SS Outer Ca sule 1778.90 0.256 OD 0.116K Al Wra ed X 0.830 OL To*Batch No.given by RI for Boron analysis.

TASK/ID: 85-WHSC-9010 Task 1/Nine Mile Point SS Capsule Number: AG2A RM Set ID: R3 HAFM Set ID: TABLE 7 SSTR ID: SSTR-TM IO: Cover: Gd I2 Location: Hid Set in AG2A Gd 82 R-3 Material Fe Ni Cu Co/Al 235-U 238-U 237-N Purchase Order Number 07448 19047 19046 44451 88705 77014 88705 Batch Number 26/17944 SE Roll CPI 3054 Cat 614 SC Bar 2 264C ES-Z 24HP-U Oescri tion Stain ess tee Outer Ca sule Gd Inner Ca sule Ti S acer u t-Folded Wire X.90" V Ca sule 1 Ca sule 5.'Ca sule Material~Mt.m a 49.149 46.011 60.330 39.602 9.998 1.903 7.561 6.612 Sample ID Elemental~Com.99.999%99.999%99.999%99.917%0.506%87.97%87.25%88.3%Comments Bottom Bottom A rapped RM S ectral Set Series 4 Series 8 Series 6 Ti S acer Al Shim S acer Gd Inner Ca sule Al'Shim S acer 287.55 0.19" OD X 0.375" OL To

TASK/ID: 854HSC-9010 Task 1/Nine Hi le Point SS Capsule Number: AG2A TABLE 7 (CONTtD)RH Set ID: R-3 HAFH Set ID: SSTR ID: SSTR-TH ID: Cover: Gd 82 Location: Hid Set ID Hateri al Purchase Order Number Batch Number Descri tion Lar ge e eat Sink S acer SS Outer Ca sule Haterial~Wt.m e 2955.22 Sample ID 0.257" OD Elemental~Cem.X 0.832" OL To Comments

TASK/ID: 85-WHSC-9010 Task 1/Nine Mile Point SS Capsule Number: AG2B TABLE 8 RH Set ID: HAFH Set IO: H3 SSTR ID:~7 8 5 SSTR-TH IO: Cover: Gd d3 Locatltoo:

Mid Set ID AG28 Gd 83 H-3 Material Purchase Order Number Batch Number Descri tion Stain ess tee Outer Ca sule Gd Inner Ca sule Ti S acer Material~Wt.m a Sample ID Elemental~Com.Comments Bottom Bottom Be Fe RI RI RI-7*Rl-4*3 Metal Pcs Al Wra ed.0.'ng e Fold Wire 3.32 NM-BE-8 62.351 Al rapped HAFM Set Ni Cu Mica 237-N Mica 238-U Mica 235-U RI 19047 19045 49096 49096 RI-11A*CPI-3054.8 ing e Fold Wire ng e Fold Wire ED-9 5.'nge Se Roll 2 Fold Wire Ti S acer Huscovite SSTR Label Down 24HP Oe osit Label Down Muscovite SSTR Label Down ES-Z De osit Label U Huscovite SSTR Label Down 314A Oe osit Label Down 123.889 31.868 8.945~255.85 0.175" 0 Table 12 203 Table 12 229 Table 12 217 99.999K 99.999K X 0.358" OL Al Wra ed TR Al Wra ed SSTR Al Wra ed*Batch No.given by RI for Boron analysis.

TASK/ID: 85-WHSC-9010 Task 1/Nine Mile Point TABLE 8 (CONT'D)SS Capsule Number: AG28 RH Set ID: HAFH Set ID: H3 SSTR ID: 7,8,5 SSTR-TH ID: Cover: Gd f3 Location: Mid Set ID Material Fe Purchase Order Number Batch Number Descri tion 0.16 x Lot 11 Disk Al Shim S acer Gd Inner Ca sule Al Shim S acer Large T eld eat Sink S acer Haterial~ltt.m e 81.38 Sampl e ID Elemental~Cem.99.772K Comments Al tfvrappe Gradient SS Outer Ca sule 3050.88 0.253"OD X 0.830"OL To 0

TABLE 9 TASK/10: 85-WHSC-9010 Task 1/Nine Mile Point Unit 1 SS Capsule Number: AB2 RN Set IO: R4 HAFN Set ID: H4 SSTR ID: 5 SSTR-TN ID: AB2 Cover: Bare Looattoo.r Set ID Material AB2 Purchase Order Number Batch Number Material Oescri tioo~Wt.m s Stain ess tee Outer Ca sule Sample ID Elemental~Com.Comments Bottom AB2 Mica uartz 238-U uartz uartz Mica 238-U Mica Mica uscovite Supersil ES-Z Supersil Su ersil 1uscovite ES-Z'luscovite tuscovite S acer Label U Label U Label Down Label U Label Down Label U Label Down Label U Ti S acer 13 Table 12 230 12 13 Table 12 233 12 Al Wra ed-T Monitors Be RI RI-7*3 Pcs Metal Al Wra ed 3.09 NH-BE-2 Fe Ni Cu RI RI RI-11A*RI-4*HEDL 19047 CPI 3054 0.30'X.87'ingle Fold Wire angl e Fold Wire>ng e Fold Wire 62.333 120.157 30.844 99.999ÃA Wrapped HAFH Set*Batch No.given by Rl for Boron analysis.

0 TABLE 9 (Cont'd)TASK/ID: 85-WHSC-9010 Task 1/Nine Hile Point Unit 1 SS Capsule Number: AB2 RH Set ID: R4 HAFH Set ID: H4 SSTR ID: 5 SSTR-TH ID: AB2 Cover: Bare Location: Hid Set ID Haterial Al SE Roll 1 19045 Purchase Order (Batch Number)Number (NH)ii904 Descri tion)*0..Sin-le Fold Wire Ti S acer Haterial~Wt.m e 8.783 Sample ID 250.83 0.180"OD Elemental~Com.99.999K X 0.376"OL Comments Al Wrappere HAFH Set Hi ca 1uscovite SSTR Label Down Table 12 Al Wra ed R4 235-U Fe 235-U Co/Al 49096 88205 69-89-0885 314A x Lot 11 264C SRR 953 De osit Label U.164"X0.031'ta Disk.035.90 V Ca sule Fo Wire Al Shim S acer arge e eat Sink S acer 81.9 1.207 9.123 214 99.772K Al Wra ed Series 2 0.116K Al Wra ed SS Outer Ca sule 1912.45 0.253"OD X 0.829"OL To

TABLE 10 TASK/ID: 85-WHSC-9010 Task 1/Nine Hile Point Unit 1 SS Capsule Number: AG3A RH Set ID: R5-HAFH Set ID: SSTR ID: SSTR-TH ID: Cover: Gd 84 Location: Bottom Set ID Haterial AG3A Gd 83 R5 Purchase Order Number Batch Number Oesort tion State ess tee Outer Ca sule Gd Inner Ca sule Ti S acer At u Haterial~Nt., m s Sample ID Elemental~Com.Comments Bottom Bottom Fe Cu Co/Al 07448 19047 19046 44451 26/17944 Se Roll CPI 3054 Cat 614 Sc Bar 26 Folded Wire ut-Folded Wire~U Folded Wire~\t~u Folded Wire u Folded Wire Ti S acer Al Shim S acer Gd Inner Ca sule Al Shim S acer 54.735 46.351 62.060 41.232 9.933 225.8 0.180" OD 99.999K 99.999K 99.999K 99.917K 0.506K X 0.372" OL r appe S ectral Set.Al Wra ed To arge e eat Sink S acer SS Outer Ca sule 2894.73 0.254" OD X 0.834" OL To

TABLE 11 TASK/ID: 85-WHSC-9010 Task 1/Nine Mile Point Unit 1 SS Capsule Number: AG3B RM Set ID: HAFH Set ID: H5 SSTR ID: SSTR-TH ID: Cover: Gd$14 Location: Bottom Set ID AG3B Gd 814 H5 Materi al Be Purchase Order Number RI Rl Batch Number RI-7*RI-4*.0.Single Fold Wire 63.053 Hateri al Decent t1on~Mt.m e Stain ess tee Outer Ca sule Gd Inner Ca sule Ti S acer 3 Pcs Metal Al Wra ed 3.55 Sample ID NH-BE 12 Elemental~Com.Comments Bottom Bottom A rappe HAFH Set Cu Al Fe RI 19047 19045 R I-11A*L-CPI 3054-9 Se Roll Rx Lot 11 ng e Fold Wire ng e Fold Wire ng e Fold Wire Ti S acer eta Disk Al Shim S acer Gd Inner Container Al Shim S acer arge e eat Sink S acer 129.574 37.833 9.166 248.5 81.49 0.175" 0 99.999K 99.999K X 0.355" OL 99.772K A rapped Fe Gradient To*Batch No.given by RI for Boron analysis.SS Outer Ca sule 3001.65 0.253" 00 X 0.834" 00 I 1 TABLE 12 TASK/ID: 85-WHSC-9010 TASK 1/Nine Hile Point Unit 1 SS Capsule Number: AB3 RH Set ID: R6 HAFH Set ID: H6 SSTR ID: SSTR-TH ID: Cover: Bare Location: Bottom Set ID Haterial AB3 H6 Be Fe Cu Purchase Order Number R2 R2 R2 19047 Batch Number RI-7*RI-11A" RI-4*E L-CPI-3054 Descri tion Stain ess tee Outer Ca sule Ti S acer 3 Hetal Pcs Al Wra ed ingle Fold Wire sng e Fold Wire ng e Fold Wire Haterial~Mt.m s 2.94 62.815 126.896 31.886 Sample ID NH-BE-9 Elemental~Com.99.999K Comments Bottom A rappe HAFH Set Al Fe Co/Al 19045 69-89-0885 SE Rol l x Lot 11 SRH 953>ng e Fold Wire Ti S acer eta Disk Wire Al Shim S acer Lar ge e d eat Sink S acer SS Outer Ca sule 9.016 258.25 81.32 8.863 1775.05 99.999K 0.177"00 X 0.368"OL 99.772K 0.116K 0.256"00 X 0.834"OL Al Wra ed Al Wra ed To*Batch No.given by RI for Boron analysis.

TABLE 13 SOLID STATE TRACK RECORDERS (SSTR)(")SS CAPSULE ID AB2 235-U A NO.(pg)ID 214 0.702 1 238-U 237-N DE IT MA DEPO I A T NO.(pg)ID NO.(pg)ID AB2B CG2B CB2 217 2 03 2 221 0.447 5 216 1-21 8 229 232 91.19 3 43.71 6 203 2.04 4 202 3.91 7 SOLID STATE TRACK RECORDER TEMPERATURE MONITORS (SSTR-TM)(")

CB2 225 23.39 226 12.09 238-U SS CAPSULE D OSIT DEPOSIT MA S lO K.AB2 230 33.45 233 68.53 T MATERIAL/I 0 quartz/13 Mica/13 quartz/23 Mica/23 1)All deposits are made on 0.168" Ni backing and have a deposit diameter of 0.136".The estimated uncertainties associated with the SSTR mass values are within+5%(1a).C-18

HAFM DOSIMET TS SS Capsule ID AG1B AB1 AG2B AB2 AG3B AB3 CG1B CB1 CG2B CB2 CG3B Al Capsule ID H-1 H-2 H-3 H-5 H-7 H-8 H-9 H-10 H-11 Be(1 2)Lot RI-7~m 4.25 2.75 3.32 3.09 3.55 2.94 2.25 2.02 2.16 1.90 2.32 125.384 124.704 123.889 120.157 129.574 126.896 121.639 120.041 62.695 64.514 62.351 62.333 63.053 62.815 61.938 60.452 114.982 58.747 119.615 59.479 121.077 61.289 Ni(2,3)Fe(2,3)Lot RI-4 Lot RI-11A~m m Cu(2 3)Lot HEDL-3054 m 33.189 30.008 31.868 30.844 37.833 31.886 30.743 30.597 28.795 33.123 30.358 Al(2,3)Lot HEDL-19045 m 9.301 9.068 8.945 8.783.9.166 9.016 8.708 8.454 8.430 8.495 8.594 CB3 H-12 2.13 120.439 61.109 30.848 8.535 Wire Diameter B Content (ppm)8.9.0.04" 0.004 0.03" 0.0046 0.02"<0.0002 0.02" 0.075 1)Each Be sample consists of 3 small pieces of metal weighed and wrapped in a single Al foil package by RI.2)gA analysis for Boron content of the various HAFM materials may be found in NUREG 3746 Vol.1-HEDL-TME 84-20, Semi-Annual Pro ress Re ort, October 83-March 84, (November 1984)pp.RI1 through RI9, 3)All wires are single folded with total length of&.87".

TABLE 15 QUARTZ ENCAPSULATED MELT WIRE (MW)TEMPERATURE MONITORS (TM)~Ca sule Melt Temp.oF Wire Dia.(in.).Wire Length (in.Wire Wt.~(m)Quartz Dia.Quartz Length (in.)(in.536 558 580 588.598 536 558 580 588 598 0.030 0.090 0.084 0.084 0.083 0.030 0.090 0.084 0.084 0.083 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 172.5 563.0 505.2 497.0 524.0 174.0 541.6 509.6 525.2 502;0 0.235 ,0.235 0.235 0.235 0.235 0.235 0.235 0.235 0.235 0.235 1.387 1.430 1.620 1.990 2.067 1.199 1.312 1.686 1.878 2.135

TABLE 16 CAPSULE LOADING SEQUENCE"C" SERIES (-24 EFPY EXPOSURE)(From Bottom of SS or Gd Capsule)Al Capsule-" Ial Top Hid CG1A CG18 CB1 CG2A CG2B 0.254'.252 0.255 0.255 0.254 0.832 0.832 0.831 0.836 0.830 2.8753 2.9847 1.7688 2.9598 3.9016 R7 H7 H8 R8 R9 H9 7 8 5 RM HAFM Fe Grad.MAFH RH RH SSTR-TH HAFH SSTR 0.180 0.180 0.180 0.180 0.180 0.387 0.362 0.368 0.380 0.357 233.35 255.28 247.25 280.9 234.1 Bottom CB2 CG3A CG3B CB3 0.254 0.833 0.255 0.833 0.255-0.836 1.0617 2.8687 1.7624 CB2 H10 5 R10 R11 H11 H12 R12 Fe Grad.SSTR-TH HAFH SSTR RH RH HAFH Fe Grad.HAFH RH 0.178 0.193 0.180 0.175 0.180 0.380 0.014 0.392 0.341 0.372 248.23 222.0 249.35 245.55 o os meter mater a s are closer than 0.10" from outer SS capsule top.Therefore, the top can be parted off up to 0.10" from top.Care must be taken that no burrs exist nor the open end swaged or the inner capsules may not shake out.2)It is recommended the Gd capsules actually be cracked open (i.e., use"nut cracker" on lower end of capsule).The reason for this is that several of the dosimeter pockets are quite a tight fit and possibly would be damaged in the attempt to pull them out of the capsule or to cut open the bottom and push them out.3)No Al material should be discarded without close observation as to whether it is simply spacer material or wrapped dosimetry material.Fe gradients are wrapped individually and though marked, Fe could be mistaken for spacer material.Both bare spectral Co/Al and Fe 235-U are wrapped'n Al and are unmarked and could therefore be mistaken for spacer material.

TABLE 17 TASK/ID: 85-WHSC-9010 Task 1/Nine Mile Point Unit 1 SS Capsule Number: CG1A RN Set ID: RT NAFM Set ID: SSTR ID: SSTR-TM ID: Cover: Gd 55 LocatIon:~To Set ID CG1A GD 85 Rj Material Purchase Order Number Batch Material Number Descrd tIon~Wt.m s Stain ess tee Outer Ca sule Gd Inner Ca sule Ti S acer Sample ID Elemental~Com.Comments Bottom Bottom Fe Ni Cu Co/Al 07448 so 1 sl 19047 19046 44451 26/17944 Sf Roll CPI 3054 Cat 614 Sc Bar 2 ut-Folded Wire.02"X-1.5 ul t-Folded Wire~u t Folded Wire 2'X>>.Ultl-Folded Wire.2'-.ut-Folded Wire 51.216 45.727 60.127 34.087 9.374 99.999K 99.999%99.999K 99.917K A rappe S ectral Set 0.506K Al Wra ed Ti S acer Al S acer Shim Gd Ca sule a Al S acer Shim Large T eld eat Sink S acer 233.35 0.180"OD X 0.387"OL To SS Outer Ca sule 2875.25 0.254"ODX0.8330L To 0 0 TABLE 18 TASK/ID: 85-WHSC-9010 Task 1/Nine Hile Point Unit 1 SS Capsule Number: CG1B RH Set ID: HAFH Set 10: H-I SSTR IO: SSTR-TH IO: Cover: Gd F12 Locatson:~To Set ID Haterial CG18 Gd 12 H7 Purchase Order Number Batch Hateri al Number Oescrs tson~Nt.m s Stasn ess tee Outer Ca sule Gd Inner Ca sule'i S acer Sample IO Elemental~Com.Comments Bottom Bottom Be Ni Fe RI RI Rl RI-7*RI-4 R I-11A*eta rappe in Al sng e Fold Wire.3.nge Fold Wire 2.25 NH-BE-7 121.639 61.938 rappe HAFH Set Cu Al 19047 19045 ng e Fold Wire SE Roll CPI 3054 Fold Wire DL-0.." sng e 30;743 30.597 99.999K 99.999K Ti S acer 255.20 0.180"ODX 0.362"OL x Lot 11.16'X.1'ta Disk Al Shim S acer Gd Inner Ca sule Al Shim S acer arge e eat Sink S acer 80.59 99.772K A rappe Gradient To*Batch No.given by RI for Boron analysis.SS Outer Ca sule 2984.72 0.252"ODX0.833"OL To f9 TABLE 19 TASK/ID: 85-WHSC-9010 Task 1/Nine Mile Point Unit 1 SS Capsule Number: CB1 RH Set ID:~RB HAFH Set ID: H-8 SSTR ID: SSTR-TH ID: Cover: Bare Locatton:~To Set IO H-8 Material Purchase Order Number Batch Number~baser)t3on SS Outer Ca sule Ti S acer Hater 1 al~Wt.m s Sample ID Elemental~tom.Comments Be Ni Fe Cu RI RI RI 19047 RI-7*RI-4*RI-11 A*ot CPI-3054.04 0.8 Single Fold Wire.8 S ng e Fold Wire 120;041 60.452 ng e Fold Wire 30.597 3 Pcs Metal Al Wra ed 2.02 NM-BE-11 A Wrapped HAFH Set RB Al Fe Co/Al 19045 69-89-0885 Lot HEOL-190 SE Roll 1 x Lot 11 SRH 953 4.2.in-le Fold Wire Ti S acer.6.1 eta Disk lng e Fold Wire Al Shim S acer arge T>e eat Sink S acer 8.454 247.25 81.00 8.562 0.180"ODX0.368"OL 99.772K 0.116K In ividua y Al Wra ed RH nmar ed Outer apsu e Ta 1768.79 0.255"ODX 0.831"OL" Batch No.given by RI for Boron analysis.

TABLE 20 TASK/ID: 85-WHSC-9010 Task 1/Nine Mile Point Unit 1 SS Capsule Number: CG2A RM Set ID: R9 HAFM Set ID: SSTR ID: SSTR-TM ID: Cover: Gd IG Locatton: Wid Set ID Material CG2A Gd 86 R-9 Purchase Order Number Batch Material Womber Oescrt t ton~Wt.m s Stain ess teel Outer Ca sule Gd Inner Ca sule Ti S acer Sample ID Elemental~Com.Comments Bottom Bottom Fe Ni Cu 07448 19047 19046 26/17944 SE Roll CPI 3054 Cat 614~U't 1-Folded Wire~U Folded Wire s e u't Folded Wire v~u Folded Wire 47.155 44.984 60.013 33.717 99.999K 99.999K 99.999K 99.917K A rappe S ectral Set Co/Al 44451 SC Bar 2 u ti-Folded Wire 8.583 0.506K Al Wra ed 235-U 238-U 237-N 88705 77014 88705 264C ES-Z 24HP-U Ca sule 0..5 V Ca sule Ca sule Ti S acer Al Shim S acer Gd Inner Ca sule 1.775 7.552 6.555 280.9 0.180"ODX 87.97K 87.75K 88.3X 0.380"OL Series 3 Series B Series 6 To 4'h.li TABLE 20 (Cont'd)TASK/ID: 85-WHSC-9010 Task 1/Nine Mile Point Unit 1 SS Capsule Number: CG2A'RH Set ID: RD HAFH Set ID SSTR ID: SSTR-TH ID: Cover: Gd 96 Location: Hid Set IO Material Purchase Order Number Batch Number~Deecri tion Al Shim S acer arge e eat Sink S acer SS Outer Ca sule Material~Mt., m e 2959.85 Sample ID 0.255"ODX Elemental~Com.0.836"OL To Comments

TASK/ID: 85-WHSC-9010 Task 1/Nine Mile Point SS Capsule Number: CG28 RH Set ID: HAFH Set ID: H-9 TABLE 21 SSTR ID:~7G.S SSTR-TM ID: Cover: Gd d7 LocatIoo: MId Set ID Material CG2B Gd 87 H9 Purchase Order Number Batch Number Descri tion Stain ess tee Outer Ca sule Gd Inner Ca sule Ti S acer Hater)al~Wt.m a Sample ID Elemental~Com.Comments Bottom Bottom Be Ni Fe Cu-Al RI RI RI 19047 19045 RI-7*RI-4*RI-11A*0-CPI 3054 EO-SE Roll 1 3 Pcs Metal Al Wra ed ng e Fold Wire-.8 ng e Fold Wire ng e Fold Wire ng e Fold Wire 2.16 NH-BE-6 114.982 58.747 28.795 8.430 99.999K 99.999K A rapped HAFH Set Ti S acer 234.1 0.180"ODX 0.357"OL Mica 237-N Mica 238-U Mica 235-U 49096 49096 Muscovite SSTR Label Down 24HP De osit Label U Huscovite SSTR Label.Down 2718 De osit Label U Muscovite SSTR Label Down 314A De osit Label U ee Tab e 20 Table 12 202 ee a e 20 Table 12 232 ee a e 20 Table 12 221 A rapped SSTR rappe SSTR A rapped SSTR*Batch No.given by RI for Boron analysis.

I' TABLE 21 (Conttd)TASK/ID: 85-WHSC-9010 Task 1/Nine Hile Point Unit 1 SS Capsule Number: CG2B RH Set ID: HAFH Set ID: H-9 SSTR ID:~7 8 5 SSTR-TH ID: v Cover: GD d7 Locattoo: Mtd R9 Fe Set ID Hater ial Purchase Order Number Batch Number Descri tion 0.16.etal x Lot 11 Disk Al Shim S acer I Gd Inner Ca sule Hateri al~Mt.m a 81.21 Sample ID Elemental~Com.99.772K Comments Al Wrapped Gradient To O I 00 Al Shim S acer Large 1 e eat Sink S acer SS Outer Ca sule 3061.69 0.254"ODX 0.829"OL To

~a TABLE 22 TASK/ID: 85-WHSC-9010 Task 1/Nine Mile Point Unit 1 SS Capsule Number: CB2 RH Set ID: 'R1D WRFH Set ID: 111D SSTR ID: 5 SSTR-TH ID: CB2 Cover: Bare Location: Hid Set ID Material CB2 Purchase Order Number Batch Material Dumber Descri tion~Wt.m s Stain ess tee Outer Ca sule Sample ID Elemental~Com.Comments Bottom CB2 H10 Hica uartz 3 238-U uartz uartz Mica 238-U Mica Mica Be RI uscovite Supersil ESZ Supersil Supersil uscovite ESZ uscovite uscovite Rl 7*S acer Label Down Label U Label Down Label U Label Down Label U Label Down Label U Ti S acer cs eta rapped In Al Table 12 225 12 13 Table 12 226 12 1.90 NM-BE-10 Al rapped SSTR-TH on tors Fe Ni Cu RI Rl 19047 RI-11A*RI-4*>ng e Fold Wire.0.>ng e Fold Wire HEOL 05*;20in-CPI 3054 le Fold Wire 59.479 119.615 33.123 99.999 Al Wra ed HAF Set

TABLE 22 (Cont'd)TASK/ID: 85-WHSC-9010 Task 1/Nine Hile Point Unit 1 SS Capsule Number: CB2 RN Set ID: R10 HAFN Set ID: HIO SSTR ID: 5 SSTR-TN ID: CB2 Cover: Bare Location: Nid Set ID Haterial Al Purchase Order Batch Number Number callw SE Roll 1 19045 Descri tion*0.0.ingle Fold Wire Haterial~Wt., m a 8.495 Sampl e ID Elemental~Com.99.999K Comments 5 Hica SSTR 235-U 49096 314A Ti S acer SSTR Label Down De osit Label U 248.23 Table 12 0.118" ODX0.380"OL 216 Al Wra ed TR Set R10 Fe 235-U 88705 Rx Lot 11 264C 0.16 X.031 eta Disk o Ca sule 81.73 1.187 87.97K Al Wra ed Pac age Series 5 Co/Al 69-89-0885 SRH 953 o d Wire Al Shim S acer 8.158 0.116K Al Wra ed arge e eat Sink S acer SS Outer Ca sule 1901.65 0.254"ODX 0.833"OL To*Batch No.given by Rl for Boron analysis.

TABLE 23 TASK/ID: 85-WHSC-9010 Task 1/Nine-Mile Point Unit 1 SS Capsule Number: CG3A RN Set ID: R11 HAFN Set IO: SSTR ID: SSTR-TN IO: Cover: Gd IO Location: Bottom Set ID CG3A Gd 89 R11 Material Fe Cu Co/Al Purchase Order Number 07448 19047 19046 44451 Batch Number 26/17944 Se Roll CPI 3054 Cat 614 SC Bar 2 Descri tion Stain ess tee Outer Ca sule Gd Inner Ca sule Ti S acer u t Fold Wire~U Fold Wire~02'~5 u tl-Fold Wire ut-Fold Wire.u tl" Fold Wire Material~NI., m e 52.113 52.643 60.402 39.413 9.695 Sample ID El cmental~Com.99.999K 99.999K 99.999K 99.917K 0.506K Comments Bottom Bottom A rappe S ectral Set Al Wra ed Ti S acer Al S acer Shim Gd Inner Ca sule Al S acer Shim Large Ti eld eat Sink S acer SS Outer Ca sule 222.0 2868.72 0.180"ODX0.3920L 0.255"ODX0.8330L To To

TABLE 24 TASK/ID: 85-WHSC-9010 Task 1/Nine Mile Point Unit 1 SS Capsule Number: CG3B RM Set ID: HAFM Set ID: H11 SSTR ID: SSTR-TM ID: Cover: GD 813 Location: Bottom Set ID Material CG3B Gd 13 H-11 Be Purchase Order Number Rl Batch Number RI-7*Material Oescrt t1oo~Wt.m s Stain ess tee Outer Ca sule Gd Inner Ca sule Ti S acer 3 Pcs Metal Al Wra ed 2.32 Sample ID NM-BE-5 Elemental~Com.Comments Bottom Bottom Fe Ni Cu Al Fe RI RI 19047 19045 Rl-11A*RI-4 CPI-3054 D-Se Roll x Lot 110'ingle Fold Wire X.nge Fold Wire.8'ing e Fold Wire sng e Fold Wire Ti S acer"X.031 eta Disk Al Shim S acer Gd Inner Ca sule Al Shim S acer Large T eld eat Sink S acer SS Ca sule 61.289 121.077 30.358 8.594 249.35 81.82 2989.80 99.999K 99.999K 0.175"ODX0.341"OL 99.772K 0.253"ODX0.830"OL A rappe HAFM Set rappe Gradient To To 0 0 TABLE 25 TASK/ID: 85-WHSC-9010 Task 1/Nine Hile Point Unit 1 SS Capsule Number: CB3 RH Set ID: R12-HAFH Set ID: H12 SSTR ID: SSTR-TH ID: Cover: Bare Location: Bottom Set ID CB3 H-12 Haterial Be Purchase Order Number Rl Batch Haterial number Descri tion~Wt.m s Stain ess tee Outer Ca sule Ti S acer RI-7*3 PCS Metal Al Wra ed 2.13 Sample ID NH-BE-4 Elemental~Com.Comments Bottom Fe Ni Cu RI Rl RI-11A*RI-4 19047 CPI 3054 E&.8'ingle Fold Wire sng e Fold Wire.0 0 X.87'sng e Fold Mire ng e 61.109 120.439 30.848 99.999K rappe HAFH Set Al 19045 SE Roll Fold Wire 8.535 99.999K Fe Co/Al Rx Lot 11 69-89-0885 SRH 953 Ti S acer eta Disk.020Ž.wo-Fold Mire Al S acer Shim arge>e eat Sink S acer 245.55 81.8 8.766 0.180"ODX0.372"OL 99.772K 0.116K Al Wra ed Al Wra ed SS Outer Ca sule 1762.44 0.255"ODX0.836"OL To*Batch No.given by RI for Boron analysis.

TABLE 26 NINE MILE POINT UNIT 1 DOSIMETRY gA INFORMATION Activation RH/HAFH Dosimeter Materials Batch/Dosimeter Form Lot No.PO No.Target Isotopic~lento e Abundance (at~om ractson)Vendor Element w/o Vendor HEOL Boron Diameter~Wt m or Thickness Al M Wire SE Roll 1 19045 27 Be Metal RI 7 Rockwell 9 Co/Al H Wire'RM 953 89095 59 H Wire SC Bar 26 44451 59 1.000 1.000 1.000 1.000 Semi.Ele.NBS Sigmund Cohn 99.999 0.116 5 0.117 0.506 1.48 8.9 1.23 0.020" D 0.020" D 0.020" D CU H Wire CPI 3054 19047 63 0.6917(1)Comico-Am.

99.999~30ppb Co 0.0002'.020" D Fe H Wire H Wire H Disc RI 11A 26/17944 Rx 110 Rockwell 56 07448 54 54 0.9172(30) 0.058(1)0.058(1)Materials Res.Reactor Exp.99.999 99.772 0.0046 0.015 0.030" 0 0.020" T 0 031st T Ni H Wire H Wire RI 4 SE Roll 2 Rockwell 58 II 1 II 58 H Wire Rx 139W 19046 46 0.6827(1)0.6827(1)0.080(1)Semi.Ele.99.999 Reactor Exp.99.917 0.004 0.015 0.040" D 0.020" D 0.020" D A)Values for natural isotopic abundances are from"Isotopic Composition of the Elements 1983", Pure&Appl.Chem.", Vol.56.pp 676-694 (1984).Error assignments in the last digits of the values are given in parenthesis

[1.e., 0.9172 (30)is 0.9172 k 0.0030].B)These reported Boron content values along with a discussion of the analytical techniques may be formed in NUREG/CR-3746, Vol.1, HEDL-THE 84-20,"LWR Pressure Vessel Surveillance Dosimetry Improvement Program Semi-Annual Progress Report, October 1983-March 1984, (November 1984), pp RI-2/9, (1984).

TABLE 26 (Con't)FISSIOHABLE RH t SSTR OOSIHETER HATERIAL Batch Hire ttesfeeter tie.tete~Dte.Ie.Anal.Element PO Ho.Lab p w/o Ana)tlcal Lab Results Isoto lc w/o Capsule Mal I 235-U 264C Ox)de Hire 0.0186 88705 ORHL 8.68 87.97~0.0005 HEDL-87.37 IOHS~0.0037 IIEOL 88.00 Titr.0.034 99.89 0.0294 99.901 0.025 0.022 0.053 0.043 0.007 235-U 314A Oxide 49096 ORML ORHL 9.62 87.25 LLNL-87.61 HEOL-87.87 238-U 2718 Oxide 49096 ORHL 238-U ES-ZOxide Mire 0.0175 77014 (0.001 0.036 99.940 0.011 0.013 (0.0001 (0.0001 0.0012%0.0001 99.999<0;0028~0.0035~0.0039 4).0032 99.987~=0~0001 (0.0001 0.0006 (0.0001 99.999 SSTR SSTR 0.007 237-Hp 24HP-U Oxide Hire 0.173 24HP Ox lde 88705 ORHL 8.14 88.3 ORHL 235<0.0005 236 237 238 239~99.999 (Only Isotope Detected)(0.0005<<99.99 S0.003 S0.003 V SSTR 0.007 0 0 APPENDIX 0 AS-BUILT PHOTOGRAPHS OF ADVANCED DOSIMETRY FOR CAPSULES A'nd C'

r r pe~yr~'pal+Pi.r~g r~l)" l""'"'""N~l'r gj'rll-:-'.j~"-"l pl~r"'l" m~rior'BP~r Sr~~~r~r*~r p,rr, r 4j g~k FIGURE 1.Stainless Steel.-(SS),'-'.Encapsul ated.Dosimetry Sets.D-2 0

0.060 0.100 0.030 0.030~FILLET WELD (TYP)SS END CAP Ti DISC (0.001 THICK)WELD HEAT SINK SPACER CRUMPLED AI FOIL FILLER PLUG Gd CAP~~~%aC~~I'~SLIP FIT 0.830 0.510'r'.f P~~~~h~~t 1~\DOSIMETER SPACE 0.040 I 0.060 o.ooo~~4o'~Gd LINER BODY 0.220 OD x 0.020 WALL SS CONTAINER BODY 0.250 OD x 0.010 WALL SS END CAP NOTE: ALL DIMENSIONS ARE INCHES HEDL 8704.034.2 FIGURE 2.Stainless Steel Container and Gadolinium Liner Design.D-3

4)

CAPSULE'C'SET'..CAPSULE A SET CG1A, AG1A AGIB CB1.-CG2A'CG2B CB2 P~[j j AB2 CG3A AG3A CG38" AG3B CB3 BEAM INTENSITY OPTIMIZED BEAM INTENSITY OPTIMIZED'TO SHOW INDIVIDUAL

~TO SHOW SS WELDS AND DOSIMETERS IN THE.SIX INDIVIDUAL DOSIMETERS IN Gd CAPSULES THE THREE BARE.CAPSULES HEDL8603-208 FIGURE 3.Radiographs of Encapsulated Dosimeters.

D-4

~'1q , 4.~C~I+(A~i wc:.-"~~<+ta 4+~'~+4~~g~">>;'>>~4'~",...'-;

'.,;,Cp4 gh~'94:4'Ye ym FIGURE 4.Dosimetry Capsules AGlA, AG2A, AG3A, CG1A, CG2A and CG3A.>leg 8602722-10 D-5 4 I 11, C 4 1 4~l'Sp I r r>'~y~~@PE.r~.r, Prr IV~, g,y'q4<)gf4rr'r~&C'$~,OUTER SS CAPSULE~rPPi'ger:

lt fr r r r S L e r>~.'+A~.,""Qg r"'.Irr~bMm5Ipr')AP,~, Pkg" ra,.4<I,~49+@" P.gal%.'>;,LI,:.'Wk<j%+e"'rP$'A r~.y<~(<<r e~~E~A4~rd.~~44~W~

~~P'~k 4'~'m~~~.r 4k 4*X2;'Vrr.r-~>>~~kf"-~rrITp

<<yA+'~P,*%%%f g Q r r rNQ+gg~~g~~)~Q~Qt j/f r, 4)fggg'Pg rr..,, A....'.'IE,dj,.MMr@~~';';

~%'--.'--~4[5)', y>~Q),,..Gd I,'NNER CAPSULE ,/~>@g~1Yfgr.'"I

',:FAA+@yp: 1t.4~~<WR-..444AhLeVp~">p

,.L.A-.y~r'

.'-'M+",<I<'$r.

~q~'"+@'~~I~'~re!~>:<i,,':rrI TOP:;)TI WELO HEAT SINK p: L'kp 1NR4PPED H4l IVl SET"..,:..'ORE 5.Dosimetry Capsules AGlB, AG38, CGlB and CG3B.Neg 8602722-7 D-6

WRAPPED Fe GRADIENT:f kga+<<p$>P'..~.*,,","~'.~I,~.4~<4~:.)~g>~Q.<P~

':,",;4"~jj."i'jjlI~gj@hlgi:.:,j::::j'i WRAPPED:237-Np SSTR Fi'IQt',aA'Chi~4>>

X.A~wi','>>!,','::WRAPPED HAFM SET>';;ij'j-,'t->',"Q'-~:,!~~~

Dosimetry Capsules AG28 and CG2B.Neg 8602722-8 D-7 4~L lg'I*a 6 l ,6!i~~a~~t$1 a.<~>~>>h%i9a p4.<<$)'4 W v:$w~<<%~p@yijg,+p$p$+y'r,++/i,g'P Q g)%%a~~g'lv,.<<+IL W<<<<ew<>>"<<44~~PPPA+,Gg~<<@!~ggyp+~;;~'.:.,,q p),.~.p:~.SS OUTER CAPSULE"e:.P.,".f'~O.,<<4Ž<p'.=--()+~~>p~<~rhf g<'~'"+Q-"~!"--(~<<4"'<<"'g'~p>~~l,'.'8'<4 4~p<~-k~~~~$"e'~"~4%"'4'~<<~'~:

+'~"4'~~~"~g~%@A<<<<~A~>~

~/~~4!p+'4~" g P>~v~'$>>j':jhow wQ g'~~g>>wf'Y H*4<<>>wr">>>PYp)<'~~5'-gY,+g gg>>sw$<dq<<:w+4K+$

~+A/g<p~i<<~$

~<<<cg,~<~Q~w,;~~<>>ivg~w<pj-~K~,y Yz-~y~~'~Yc.

d~,&)M<<p4<<~tr~g)

K gfg~q~p~8<<<<.!~--"':-~-'~-'-.'-:

"<-'c WRAPPED Co/Al RM i,',",,f h FIGURE 7.Dosimetry Capsules ABl, AB3, CBl and CB3.Neg 8602722-9 D-8 I~C.C~4 t., I!~0 ct ot

<<!<<<<<<.;:"'g~g"-'yF~

"."-4y3";:

"<~!".","'.'j"'.~'.".'-'-'>~~'j~" ,-.'-'>-.-';"::.'>

WRAPPED SSTR-'TIVI SET fM"."g."'-",p+;".'-4~v<<.'&4~<

IGURE 8.Dosimetry Capsules AB2 and CB2.Neg 8602722-12 D-9 J-'I-C

~,>hah$.~~>a<~+w~~&OW@8~

FIGURE 9.Bare RM Spectra1 Set.and Gradient RM.Neg 8602722-2

~, C'p 1 p))~t,

.'~a(i,A+g'"~~'y"pk~~."",;",'p,~x.~,".~g,-"j'm~+*4~~&'.s,j~zq-".Vjp'pg FIGURE 10.Bare RH Spectral Set with 235-U.Neg 8602722-6

'A'I I lE s s s s s ,aS, a~~~s%~a%'s s s FIGURE 11;Gd-Covered RM Spectral Set.Neg 8602722-4 0 t I~, f)g)a'p(g!)t gg~"~II>(~<"r ly II 1"1 FIGURE 12.Gd-Covered RM Spectral Set with Fissionable Oosimeters.

Neg 8602722-3 II'I~~~gal y r k,)kj,'r.,~.<<j'r;;, TOP h,: T;BPAOBBB+'<g BOTTOM.4",~,;-:~QPr,i5:,cbrit..<j

'h>>'hr r h r r~~~~p FIGURE 13.KAFM Dosimetry Set.Neg 8602722-5 P 1>ll I 4 WRAPPED 235-u'-k~Ppg~': i:" A~e@~w'~,"bA~w'.~-y'k wg4ggjg<<~~~~<$p~pQ>>FIGURE 14.SSTR Dosimeters.

Neg 8602722-1

>.S 4, g.,lt p4~h f yl I k 8

~.8'.Hi+"'*'.OUTER'Al.WRAPPlNG W/I C.h(MICA SPACER'-,~~'j+~,;4/'.'"'QUARTZ SSTR-TM, r4y~@ggg,~gy P~gg,p, p$~'IGURE-'15.'STR TM Temperature Monitor-Sets.Neg 8602722-13

.

APPENDIX E PHOTOGRAPHS OF MELTWIRE TEMPERATURE MONITORS w ll 1 il l~

QUARTZ CAPSULE~QUARTZ CAPSUI.E BACK-FILLED WITH APPROXIMATELY ONE ATOMOSPHERE OF HEUUM O.Z3"4I237" SPECIFIED LENGTHS TYPICAL MELTWIRE 668 F+c Qg+F z I'CAPSULE A MEI TWIRE SET CAPSULE C MELTWIRE SET 1N Ol NN IN I FIGURE 1.quartz Encapsulated Melt Wire Temperature Monitors (TM).

IL lg A j

.K~+-;e~p f,:@"'j;~.,--;g'~-:~k~"-~+$>~'~<,m,y,~g~c~'~"v:y',-~~.~<<,P'.'q~jP,*,~'~%"~~,'fi P, MQ.4q,,P'@'g.A~+0,/'*FIGURE z quartz Encapsulated Melt Wires.Typical of both Capsules A and C.Ne9 8602722-11 E-3

APPENDIX F CHEMICAL ANALYSIS DATA FOR NINE MILE POINT UNIT 1 0

F.1 PLATE DATA The plate chemistry data were taken from References

[LU64],[ST84],[MA85a], and[MA87].F-2

'I CHEMICAL AHALYSIS RESULTS (WMAL)FOR NINE MILE POINT UNIT 1.MODIFIED A382B MATERIAL[MA87]BASE FROM BASE 38 DEGREE CAPSULE (1)E1A(A)Elh(B)E1C EBK E2U E31 STANDARD RELATIVE MEAN DEVIATION DEVIATION, X Fe Cu Ni Cu(2)Hi (2)P Mn Co Mo V Cr Ti C(3)S(4)Si(6)MATRIX 8.244 8.512 8.241 8.468 8.841 1.377 e.sle 8.433<8.885 8.186 8.881 8.286 8.822 8.226 8.839 1.361 e.sle 8.435<e.ees 8.186 8.881 8.842 1.369 8.818 8.421<8.885 8.186<8.881 8.841 1.362 8.811 8.466<8.885 8.186<8.881 8.839 1.344 8.818 8.432<8.885 8.186<e.eel 8.839 1.368 8.818 8.436<8.885 8.189<8.881 8.226 8.226 MATRIX MATRIX MATRIX MATRIX MATRIX 8.243 8.243 8.258 8.248 8.246 8.514 8.5ee 8.55e s.sle 8.519 8.883 8.817 8.885~8.825 8.881 8.814 8.815 1.366 8.244 3.386 8.518 2.875 8.241 5.288 8.468 3.389 8.848 1.855 1.369 4.816 8.818 3.454 8.436<8.885 8.912 8.186<8.881 8.286 8.822 8.226 NOTES: (1)ALL MEASUREMEHTS BY ICAP UNLESS OTHERWISE HOTED (2)BY ATOMIC ABSORPTION (3)BY LECO COMBUSTIOH (4)BY TITRIMETRIC COMBUSTIOH (5)BY GRAVIMETRY

CHEMICAL AHALYSIS RESI.TS (WMAL)FOR HIHE MILE POINT UNIT 1.MODIFIED A382B MATERIAL[14AB7]BASE FROM BASE 388 DEGREE CAPSI.E (1)E42(A)E42(B)ETE EILl E1U E3T E3T(R)STANDARD RELATIVE MEAN DEVIATIOH DEVIATION, X Fe Cu Hi Cu(2)Ki (2)P Mn Co Mo V Cr Ti C(3)S(4)Si(5)MATRIX MATRIX MATRIX 6.233 8.23S 8.258 8.479 8.617 8.639 8.238 e.473 8.833 8.848 8.845 1.324 1.334 1.378 8.818 8.818 8.818 8.48S 8.428 8.462<S.SSS<e.eeS<S.SSS 8.185 8.18S 8.189 8.681 8.681<8.861 8.218 8.823 8.22S 8.22S 8.226 8.839 1.337 8.818 e.4es<e.ess 8.166<8.881 8.834 8.843 8.845 1.362 1.394 1.377 8.818 8.811 8.818 8.41S 8.452 8.445<e.sss<B.ees<B.ess 8.183 8.113 8.116 8.881<8.881<8.881 MATRIX MATRIX MATRIX MATRIX 8.243 8.241 8.24S 8.247 8.432 6.4SS 8.543 8.522.B.ess 8.827 8.865 8.817 8.884 8.825 s.ese 8.822 2.871 8.243 5.339 8.518 2.161 8.238 3.694 8.473 9.947 8.841 1.869 1.368 3.726 8.818 6.17S 8.431<e.ees 3.495 8.169<8.681 8.218 8.823 8.22S HOTES: (1)ALL L!EASURHlENTS BY ICAP UNLESS OTHERlISE KOTED (2)BY ATOMIC ABSORPTIOH (3)BY LECO COMBUSTIOH (4)BY TITRIMETRIC COMBUSTIOH (5)BY GRAVIMETRY k

CHEMICAL ANALYSIS RESIA.TS (WMAL)FOR HIHE MILE POIHT UHIT 1.MODIFIED A3828 MATERIAL[MA87]UHIRRADIATED ARCHIVE PLATE (1)025(A)025(B)D21 Dbl STANDARD RELATIVE MEAN DEV IATIOH DEVIATION,X Fe Cu Ni Cu(2)Ni (2)P Co V Cr Ti C(3)S(4)Si(5)MATRIX 5.173 b.562 8.178 8.573 b.b23 1.14d 8.518 d.4dd<S.SSS d.563<$.881 8.249 S.bid$.153 MATRIX 8.188 8.569 8.177 S.SSS$.823 1.168$.$1$$.477<$.885$.886<$.881 8.523 1.143$.51$$.491<S.bsS$.864<$.881$.818 1.151$.811$.469<S.SSS S.d64<$.$81$.163$.153 MATRIX MATRIX b.17d$.175$.52S$.5$4 8.883 1.673 8.17S 8.8LT 2.819 8.599 8.883 1.698 8.178 8.822 3.663 8.578 8.882 11.494 8.822 5.517 1.471 1.155 S.SSS 4.876 b.slb d.dll 2.231 8.47d S.SSS S.SSS<S.SSS 8.881 1.494 8.864<d.ssl 8.249 S.eld 5.163 XOTES: (1)ALL MEASUREMEIITS BY ICAP tRLESS OTHERSISE NOTED (2)BY ATOMIC ABSORPTIOX (3)BY LEO COMSSTION (4)BY TITRIMETRIC COSSTIOH (5)BY CRAVIMETRY 0

CHEMICAL ANALYSIS RESULTS (WMAL)FOR NINE MILE POINT UHIT 1.MODIFIED A382B MATERIAL fMA87]BASE FROM HAZ 368 DECREE CAPSULE (1)JIL(A)JIL(B)JAM JAE JIT JIP STANDARD RELATIVE MEAN DEVIATION DEVIATION,X Fe MATRIX MATRIX Cu 8.172 8.173 Hi 8.681 8.626 Cu(2).8.165 Ni(2)8.564 P 6.823 8.626 Mn 1.142 1.163 Co 8.818 8.811 Mo 8.456 8.463 V<8.665<8.665 Cr 8.884 8.665 Ti<8.881<8.861 C(3)8.227 S(4)8.818 Si(S)8.168 8.168 8.822 1.135 S.811 6.561<8.865 8.892<8.861 8.823 1.152 8.811 8.495<6.665 8.864<8.881 8.821 1.149 8.811 8.466<S.SBS 8.863<8.861 8.822 1.854 8.818 8.461<8.685 6.677<8.681 8.168 MATRIX MATRIX MATRIX MATRIX 8.173 8.174 8.173 8.164 8.654 8.644 8.639 8.598 8.684 8.825 8.864 8.819 8.862 S.B48 8.881 8.816 8.685 2.174 4.842 2.424 3.369 7.543 3.497 4.641 3.213 5.694 8.171 8.626 8.165 8.564 8.823 1.133 8.811 8.464<8.665 8.864<8.881 8.227 8.818 8.168 NOTES: (1)ALL MEASUREMENTS BY ICAP UNLESS OTHERWISE NOTED (2)BY ATOMIC ABSORPTION (3)BY LEO COMBUSTION (4)BY TITRIMEfRIC COMBUSTION (5)BY GRAVIMETRY

ICAP CHEMICAL AHALYSIS REPORT (KL)FOR HIHE MILE POINT UHIT 1.IMA87)UHIRRADIATED ARCHIVE PLATE (1)D25(A)D25(B)D21 Del STANDARD RELATIVE MEAH DEVIATION DEVIATION, X LNTRIX LNTRIX LNTRIX 8.1ae 8.Ds 8.1ee d.ee3 e.sss d.s7s 8.184 8.182 8.184 e.se4 d.s7s e.s78 1.198 1.118 1.148 Fe Cu Hi Cu(2)Ni (2)Mn Co Mo$.497 8.496$.493 V Cr 8.122 8.117$.118 Ti C(3)S(4)Si(6)LNTRIX 8.182 8.885 8.685 8.828 8.182 8.883$.678 8.822 1.128 8.838$.492 8.882$.121$.882 2.967 8.181 3.384 8.588 1.839 8.183 3.881 8.579 3.122 1.148 8.449 8.494 1.992 e.128 HOTES: (1)ALL MEASUREMEHTS BY ICAP MESS OTHERNISE NOTED (2)BY ATOMIC ABSORPTION (3)BY LECO COMSSTION (4)BY TITRIMETRIC COLRXSTION (6)BY CRAVIMETRY

EDAX CHEMICAL ANALYSIS RESU TS (BCL)FOR NINE MILE POIHT UNIT 1.MODIFIED 382B MATERIAL[MABSa)BASE FROM BASE 38 DECREE CAPSll.E EIA(A)E71 EIC(182)EBK(lk2)E2U E31 STANDARD RELATIVE MEAN DEVIATION DEVIATION, 8 Fe Cu Hi P Mn Co Mo Y Cr Ti C S Si MATRIX MATRIX MATRIX MATRIX MATRIX MATRIX 8.338 8.268 8.328 8.268 8.288 8.668 8.588 8.525 8.528 8.618.8.858 8.868 8.876 8.838 8.878 8.825 8.356 8.298 8.839 6.925 8.563 8.818 31.383 8.857

EDAX CHEMICAL AHALYSIS RESU TS (BCL)FOR HIHE MILE POIHT UHIT 1.MODIFIED 3828 MATERIAL LST84 j BASE FROM BASE 388 DECREE CAPSUL=E42(A)E42(B)ETE EIM ElU(112)E3T EOT(R)=TANOARO RELET I YE UCAH OEYIATIOH DEVIATI OH, X Fe Cu Hi P Mn Co Mo Y Cr Ti C S Si MATRIX MATRIX MATRIX MATRIX MATRIX MATRIX MATRIX 8.228 8.238 8.228 8.215 8.258 8.238 8.488 e.458 8.458 8.4vs e.458 8.458 8.822 8.821 8.821 8.819 8.824 8.827 8.813 8.813 8.883 5.518 8.228 2.T13 8.463 12.559 8.822

1964 LUKENS DATA FROM TEST CERTIFICATE()

ELEMENT Fe Cu Ni P Mn Mo C S.Si G-8-3 G-8-4 MATRIX 0.18 0.56 0.012 1.16 0.47 0.20 0.027 0.17 G-8-1 MATRIX 0.23 0.51 0.021 1.34 0.45 0.19 0.028 0.21 G-307-3 MATRIX 0.20 0.48 0.018 1.45 0.45 0.18 0.034 0.26 G-307-4 MATRIX 0.27 0.53 0.019 1.25 0.52 0.20 0.030 0.21 G-307-10 MATRIX 0.22 0.51 0.018 1.43 0.51 0.20 0.026 0.26 (1)Based on discussions with Lukens, data from ladel analysis by atomic absorption.

F.2 WELD DATA The weld chemistry data were taken from references

[LE64],[CE90], and[ST84].

REACTOR VESSEL BELTLINE WELD INFORMATION Number Weld Seam Location Weld Wire Type Weld Flux Type and Heat No.and Lot No.Detailed Weld Procedure 2-564 A/C 2-564 D/F 3-564 Surveillance Capsule Weld Lower-Intermediate Shell Longitudinal Lower Shell Longitudinal Seams Lower Intermediate to Lower Shell Girth All Three Capsules RACO 3/86054 RACO 3/1248 E8018/HACD E8018/JBGD RACO 3/86054 E8018/HACD E8018/JBGD RACO 3/1248 E8018/DBDE E8018/IOGE RACO 3/W5214 Arcos Arcos N/A N/A Arcos N/A N/A Arcos N/A N/A Arcos B-5/4E5F B-5/4K13F B-5/4E5F B-5/4M2F B-5/5G13F SAA-33-A (3)SAA-33-A (3)MA-33-A (7)MA-33-A (7)SAA-33-A (3)MA-33-A (7)MA-33-A (7)SAA-33-A (3)MA-33-A (7)MA,-33-A (7)SAA-33-A (3)Reference[CE90]

Weld Seam Weld Wire Heat Flux Lot BELTLINE WELD CHEMISTRY DATA Si Mo Ni Cu 2-564 A/C 2-564 D/F 3-564 86054/4E5F 1248/4K13F 86054/4E5F 1248/4M2F.12.11.12.10 1.64 1.71 1.64 1.26.015.005.015.015.020.017.020.020.34.51.38.56.34.51.22.57 Surveillance Capsule Weld 5214/5G13F

.14 1.58.018.013 (~023).25.51 (2)(2)(.18)(.09)(1)Data in parenthesis were measured using irradiated material and reported in[ST84].(2)Reference[CE90]recommends the use of significantly higher values based on examination of generic.data Reference[CE90]

'T It F.3 SUPPLEMENTARY BASE METAL CHEMICAL ANALYSIS The base portion of the HAZ tensile specimen, JUD, from the'300 degree capsule was analyzed.Also, the base portion of the HAZ Charpy specimen, JlM, from the 300 degree capsule was also analyzed.The objective was to show that the chemistries of the base from HAZ are similar and match the G-8-3 Lukens data.The attached data support this theory.F-14

BASE METAL CHEMISTRY ANALYSIS FOR IRRADIATED SPECIMENS Concentration in Wei ht Percent Element JlM (Base from JUD (Base from Fe Co Cr CQ Mn Mo Ni BALANCE 0.011 0.075 0.183 1.044 0.472 0.642<0.010<0.010 BALANCE 0.013 0.092 0.168 1.129 0.474 0.579 0.026<0.010

APPENDIX G TENSILE DATA

The unirradiated weld properties are given in references

[LE64]and[CE90].The unirradiated plate properties are given in[ST64].Irradiated properties are reported in Battelle reports[ST84],[MA85a], and[NA87].The G-8-3 archive plate data and irradiated HAZ base metal miniature tensile data were measured as part of the current work.G-2

G.l BASELINE TENSILE DATA G-3

TABLE G-1 UNIRRADIATED WELD TENSILE DATA~T e Heat No.Flux Lot No.Yield Strength Ultimate Tensile Elongation Reduction Psi Stren th Psi In 2"%Of Area%RAC03 86054 4E5F 75, 500 90, 000 27.5 69.9 RAC03 1248 RAC03 1248 Surveillance Capsule Weld W5214 4K13F 4M2F 5G13F 66, 800 63, 000 65, 000 84, 100 80, 000 84, 000 26.0 27.5 27.5 64.9 64.3 67.0 (1)Data taken from[LE64]and[CE90].The test records do not indicate the test temperature.

Therefore, RT is assumed.

TABLE G-2 UNIRRADIATED BASE METAL DATA Plate Code Heat No.Yield Strength Psi Ultimate Tensile Stren th Psi Elongation Reduction In 2"%Of Area%G-307-3 G-307-10 A G-307-4 I G-8-1 G-8-3 G-8-4 P2074-2 P2091-2 P2076-1 P2112-1 P2130-1 P2130-2 62,000 69,400 69,400 66, 600 65, 000 59, 300 82, 000 92, 900 89,900 87,500 86, 200 85,500 28.0 25.0 27.0 27.0 26.0 29.0 69.0 67.0 66.2 66.0 65.4 68.0 (1)Data taken from[ST64]The test records do not indicate the test temperature.

Therefore, RT is assumed.

G.2 IRRADIATED SURVEILLANCE SPECIMEN DATA

TABLE G-3 TENSILE PROPERTIES FOR THE IRRADIATED MATERIALS FROM THE NINE MILE POINT 300-DEGREE SURVEILLANCE CAPSULE~~Test Specimen Material"'emp.'>

No.Type (F)Yield Stren th si Ultimate Fracture Fracture Reduction Stress in Area Elon ation (psi)(percent)Uniform ercent'~'otal JJA JDB JLB JL7 JUD JTU Base Base Weld Weld RT 79, 170 550 69, 410 RT 73, 680 550 67, 760 RT 63, 720 550 59, 960 99, 700 92, 890 90, 240 84, 690 85, 060 81,500 66, 060 68, 090 59, 450 59,180 54,880 56, 910 192, 300 161, 800 186, 300 157, 600 181,200 145, 100 65.7 58.0 68.1 62'69.7 60.8 12.5 8.9 13.0 10.5 7.5 7.1 27.7 19.7 23.2 20.9 19~8 18.4 (2)(3)(4)Data taken from[ST84].The weld and HAZ specimens were most likely fabricated using plate G-8-3 material.The composition of the base tensile specimens is not known at present.Room temperature (RT)is approximately 75'.The elongation is for a 1-inch gauge length.The composition of the surveillance tensile specimens is not known.Chemical analyses are recommended in the future.

TABLE G-4 TENSILE PROPERTIES FOR THE IRRADIATED BASE METAL FROM THE NINE MILE POINT 30-DEGREE SURVEILLANCE CAPSULE Test Specimen Material'" Temp.+'o.Type (F)Yield Fracture Reduction Stren th si Stress in Area Elon ation Ultimate Fracture (psi)(percent)Uniform ercent'~'otal JDE Base RT 76, 078 96, 817 65, 708 193, 939 66.1 12.0 24.1 (1)(2)(3)(4)Data taken from[MA87].The composition of the base tensile specimens is not known at present.Room temperature (RT)is approximately 75'.The elongation is for a 1-inch gauge length.The composition of the surveillance tensile specimens is not known.Chemical analyses are recommended in the future.

G.3 ARCHIVE PLATE G-8-3 DATA The axial extensometer slipped off specimen TN-2 during testing.As-a result, the stress/strain curve could not be accurately plotted and the uniform strain could not be determined.

G-9

TABLE G-5.TENSILE PROPERTIES FOR THE ARCHIVE PLATE G-8-3 Hatl Test Fracture Spec.Type Temp.Load (F)(lbs)Engineer>ng Strength (kss)Yield Ultimate Fracture.2X or upper loMer True Fracture Bridgman Stress Correction (ksi)(ksi)Red.In Elongatton Area Uni form Total (X)(X)(X)tn-1 Base tn-3 Base tn-2(1)Base 78 13281.67.4 65.4 87.2 66.8 178.3 152.5 250 11719.64.7 61.9 80.4 58.5 156.5 133.8 550 12842.57.9-.--86.3 64.1 148.3 129.7 62.5 13.8 45.2 62.6 10.1 33.3 56.8 38 5 The elongation is for a(n)1.0 inch gage length (1)The uniform elongation could not be determined because extensometer slipped during test

UNIRRADIATED ARCHIVE PLATE Q-8-3 SPECIMEN: TN-'t TESTED AT 78 F't 00 50 IMQIRIIHIEKI%9MQ S7RKSS+IMANIIIMtLIM 87IRK88 FINA,CVUIRK 87MSS 0.00 0.1 0 0.20 0.30 0.40 0.50 STRAIN (IN/IN)

UNIRRAOIATED ARCHIVE PLATE G-8-3 SPECIMEN: TN-1 TESTED AT 78 F 200 100 r<r r rr r rr r r r/IKMQIR0HIKIKIR0HQ 87IRIK88 7IRUIK 87IRIK88 SIRIISCIMAH COIRIRIKC7ION 65lAXOMUIM 87IRIK88 iFIRA,C7INIRIK 87IRIK88 0.00 0.20 0.40 0.60 0.80'I.OO 1.20 STRAIN (IN/IN)G-12 1'Y" C k~h h4 7."<~

ggcj)p4 28~v]iQ it~i A FIGURE G-1 POST-TEST PHOTOGRAPHS OF THE UNIRRADIATED BASE METAL ARCHIVE PLATE G-8-3 TENSILE SPECIMEN TN-1 SHOWING BOTH THE REDUCED AREA AND FRACTURE SURFACE G-13 I}'g4 4 1 F I GURE G-2 POST-TEST PHOTOGRAPHS OF THE UNZRRADZATED BASE METAL ARCHIVE PLATE G-8-3 TENSILE SPECIMEN TN-2 SHOWING BOTH THE REDUCED AREA AND FRACTURE SURFACE

UNIRRADIATED ARCHIVE PLATE Q-8-3 SPECIMEN: TN-3 TESTED AT 250 F IBQHIIIHIEIRIRIIM 87IRKSS+MAMIMUM 87IRKSS tF(M CVURIK 87(RIESS 0.00 0.1 0 0.20 0.30 0.40 0.50 STRAIN (IN/IN}G-15

UNIRRADIATEO ARCHIVE PLATE G-8-3 SPECIMEN: TN-3 TESTED AT 250 F 200'f 00 r r rr r r r I/Qg3IIDDQIgg(g CIRIMCYIIM IMANOMIUIM SYIMSS ISA,C'rUIRIB SYM88 0.0 0 0.20 0.40 0.6 0 O.S 0 t.0 0 1.20 STRAIN (IN/IN) k~,k'd bl.1~v tl>i~

FIGURE G-3 POST-TEST PHOTOGRAPHS OF THE UNIRRADIATED BASE METAL ARCHIVE PLATE G-8-3 TENSILE SPECIMEN TN-3 SHOWING BOTH THE REDUCED AREA AND FRACTURE SURFACE

6.4 MINIATURE BASE METAL SPECIMEN DATA (BASE METAL TAKEN FROM 300 DEGREE CAPSULE WELD CHARPY SPECIMENS)

Based on analysis of base metal taken from HAZ specimens, it is likely that these specimens were prepared from plate G-8-3 G-18

TABLE G-6.TENSILE PROPERTIES FOR IRRADIATED BASE METAL TAKEN FROM WELD HAZ SPECIHENS (Based on HAZ Base Metal Analysis, the HateTial is Host Likely G-8-3)Spec.Type Temp.Load (F)(lbs).2X or upper lover Engineering Strength (ksi)Hatl Test Fracture Yield Ultimate Fracture Red.True in Elongation Area Uniform Total Fracture Bridgman Stress Correction (ksi)(ksi)(X)(X)(X)ejd Base 78 1079.ejt Base 250 1001.edt Base 550 1138.71 1 66.8 66.3 62 8 93.3 86.6 90.0 61.9 58.2 66.1 177.4 150.4 157.3 134.3 150.8 132.2 65.1 63.0 56.2 10.5 31.5 8.7 29.4 26.6 31.5 The elongation is for a(n).102 inch gage length

BASE METAL FROM WELD CVN SPECIMEN: E JD TESTED AT 7 8 F'f 00 50 IRMQRIIIMIKIRRIMQ SYIRIKSS+MANIISlUM SY(RlKM PIMC'rUM 8YlMSS 0.00 0.1 0 0.20 0.30 0.40 0.50 STRAIN (IN/IN)G-20

BASE METAL FROM WELD CVN SPECIMEN: E JD TESTED AT 7 S F 200 100 rr rr r rr r rr rr r p'KIMCIROHKKIROHQ SVIRKS8 VIRUK SVIRKSS SIRODOLIAH CIRIRKCVIOII OIANOMUM SVIRKSS IFIM CVUIRK SVIRKSS 0.00 0.20 0.40 0.80 0.80'I.00 1.20 STRAIN (IN/IN) 0 J':,24 28 p pvp 24 28 FIGURE G-4 POST-TEST PHOTOGRAPHS OF IRRADIATED BASE METAL TENSILE SPECIMEN EJD SHOWING BOTH THE REDUCED AREA AND FRACTURE SURFACE G-22

BASE METAL FROM WELD CVN SPECIMEN: E JT TESTED AT 260 F 100 IEIMIIIIHIMRIM 87MSS+MAMMUH 87MSS lF IRACVUIM 87IRKSS 0.00 0.1 0 0.20 0.30 0.40 0.50 STRAIN (IN/IN)G-23

BASE NIETAL FROM WELD CVN-SPECIMEN: E JT TESTED AT 250 F 200 100 rr rrr rr r p KHQIRIIHKKIR0HQ 87IRK88 7IRVK 87IRK88 QIRIIpDQIUQ,Ig CIRIRKCVIOIM MANIIIMUIM 87IRK88 IFIRACVUIRIF.

87IRK88 0.00 0.20 0.40 0.60 0.80'!.00'I.20 STRAIN (IN/IN)G-24 p'lp l' y<~f rry!'!r~r'r.,.;*!i+r r',*~4 8 1r.--24 28 Q$D lA'0 J AW AC)~rr~i'-.*~g~;gpss;.~lpl ,jig jj ZB FIGURE G-6POST-TEST PHOTOGRAPHS OF IRRADIATED BASE METAL TENSILE SPECIMEN EJT SHOWING BOTH THE REDUCED AREA AND FRACTURE SURFACE G-25

BASE METAL EROM WELD CVN SPECIMEN EDT TESTED AT 550 F sac IKMQIRIIMEIMIIIMQ 87MSS+lMAMSIUM 8YÃtK88 lFiM C'rUIRlK SYIMSS 0.0 0 0.20 0.40 0.80 0.80 1.00 STRAIN (IN/IN)G-26

BASE METAL FROM WELD CVN SPECIMEN: EDT TESTED AT 550 F 200 100 r r/I KMRRIIHIKKIR!IMQ 87IRIK88 7IRUIK 87IM88 SIRISCHAH COIRMC7IIOM MANRilUM 87IRKSS IFIM CVUilK 87IR 888 0.00 0.20 0.40 0.80 0.80'f.00 1.20 STRAIN (IN/IN)G-27 I qa~,

-yS 24 28 32 F~4>4 3>~0 g8 56 FIGURE G-5 POST-TEST PHOTOGRAPHS OF IRRADIATED BASE METAL TENSILE SPECIMEN EDT SHOWING BOTH THE REDUCED AREA AND FRACTURE SURFACE

APPENDIX H CHARPY DATA

~-

The unirradiated weld properties are given in reference[LE64].The G-8-3 archive plate data for the T-L orientation were measured as part of the current work and the L-T orientation data was originally reported in Reference[MA87].The unirradiated plate properties are given in[ST64].Irradiated properties are reported in Battelle reports[ST84],[MA85a], and[MA87].H-2

H.1 UNIRRADIATED DATA H-3

H.1.1 1964 UNIRRADIATED BASELINE CHARPY DATA

TABLE H-1.UNIRRADIATED WELD CHARPY DATA~Te Heat No.Flux Lot No.+10'F Zm act Values~Auexa e RAC03 RAC03 RAC03 86054b 1248 1248 4E5F 4K13F 4M2F 66.0, 64', 65.0 55.0, 51.0, 57'53', 57.0, 65.0 65.2 54.4 58'Surveillance Capsule W5214 5G13F 61, 52, 58 57.0 Data taken from[LE64]and[CE90]

TABLE H-2.UNIRRADIATED PLATE G-8-3 CHARPY DATA~~Test Tem erature F-80-40+10 60 110 160 212 Im act Ener ft-lb 9.0, 6.0 32.0, 17.0 50.0, 37.0, 47.5 77.0, 63'90', 99.0 100.0, 96.0 87', 78.5 Avera e ft-1b 7.5 24.5 44.8 70.0 94.5 98.0 82.7 Data taken from reference[ST64]

~" 4l TABLE H-3.UNIRRADIATED PLATE G-8-4 CHARPY DATA Test Tem erature'F-40+10 40 60 110 160 212 Im act Ener ft-lb 23.5, 26.0 46.0, 61.0, 42'58.0, 64.0 72.5, 74'98', 98.0 100.5, 100'106.0, 106.0 Aveia e ft-1b 24.7 49.6 61.0 73.5 98.0 100.2 106.0 Data taken from reference[ST64]H-7

NINE MILE POINT UNIT I~UNIRRADIATED BASE METAL 083/Q84 (1 2)EXPERIMENTAL DATA 120 100 I IL 80 g+Jf j 0 WEIBVLL FIT TRANSITION WEIBVLL FIT UPPER SHELF HYPERBOLIC TANGENT FIT 60 40 V X-20 J J 0 0 (~/4-100-50 0 50'I 00 150 200 250 TEST TEMPERATURE (F)CONFIDENCE LIMIT (95%)CONFIDENCE LIMIT (95%)CONFIDENCE LIMIT (95%)CONFIDENCE LIMIT (95%)H-8 l C V'+Jul TABLE H-4.UNIRRADIATED PLATE G-8-1 CHARPY DATA*"*'Test Tem erature'F-40+10 40 60 110 212 43.5, 47.0, 45.0 58.0, 55.0 80.0, 70.0, 70.0 82.0, 95.0, 83.0 Im act Ener ft-1b 13.0 33.0, 33.5, 25.0 Avera e ft-1b 13.0 30.5 44'53.3 73~3.86.7'-" Data.taken f rom ref erence[ST64]H-9

NINE MILE POINT UNIT UNIRRADIATED BASE METAL Q-8-1 (1,2)DATA 120 WElBULL FIT TRANSITION 100 I l tL 80 HYPERBOLIC TANGENT FIT 60 40 V 20 k k A-100-50 0 50 100 150 200 250 TEST TEMPERAlVRE{F)CONFIDENCE LIMIT (9SX)CONFIDENCE LIMIT (95%)CONFIDENCE LIMIT (95%)CONFIDENCE LIMIT (95m)H-10

TABLE H-5.UNIRRADIATED PLATE G-307-3 CHARPY'DATA~>>

Test Tem erature'F-40+10 40 60+75 90 110 140 160 212 Im act Ener ft-lb 8.0 27.5, 37.5, 41.0 41.5, 52', 57.0 63.5 58.0 71.5 82.0 90.0 101.5 100.0, 106.5 Avera e ft-lb 8.0 35.3 50.2 63.5 58.0 71.5 82.0'90.0 101.5 103.3 Data taken from[ST64]

• ~4$'I>

NINE MILE POINT UNIT I~UNIRRADIATED BASE METAL Q-307-3 (1 I)~EXPERIMENTAL DATA 120 100 Ql t I I-LI 80 60 LLI 40 V 20 i/a/~k//e//4 t a 0-100-50 0 50 100 150 200 250 TEST TEMPERATURE (F)WEIBULL FiT TRANSITION HYPERBOLIC TANGENT FIT CONFIDENCE LIMIT (95%)CONFIDENCE LIMIT (95%)CONFIDENCE LIMIT (95%)CONFIDENCE LIMIT (95%)H-12

TABLE H-6.UNIRRADIATED PLATE G-307-4 CHARPY DATA~~Test Tem erature'F-40+10 60 110 212 Im act Ener ft-1b 13.0, 20.0, 12'37.0, 35.0, 38.0 50.0, 41.0, 61.0 82.0, 75.0, 84.5 80.0, 83.5, 80'Avera e ft-lb 15.0 36.6 50.6 80.5 81.0 Data taken from[ST64)

NINE MILE POINT UNIT 1~VNIRRADIATEP BASE METAL G 307 4 (1 1)EXPERIMENTAL DATA 120 100 IXI l I-LL 80 kkkk k Pkkkk kkkk WEIBULL FIT TRANSlTION WEIBULL FIT UPPER SHELF H YPERBOLlC TANGENT FIT 60 LLI 40 V 20 CL k k k k/k/k/k k k-'I 00-50 0 50'j 00 150 2'00 250 TEST TEMPERATURE (F)CONFlD ENCE LIMIT (95%)CONFIDENCE LlMIT (95%)CONFlD ENCE uMIT (95%)CONFIDENCE uMIT (95%)H-14

,'II%

TABLE H-7.UNIRRADIATED PLATE G-307-10 CHARPY DATA~i'.Test Tem erature'F-40+10 60 110 212 Im act Ener ft-lb 16.5, 12.5, 13.0 40.0, 33', 45.0 45.0, 56.5, 62.0 68.0, 80.0, 63.0, 97.0, 100', 100.0 Avera e ft-1b 13.3 39.3 54.3 70.3 99.0 Data taken from[ST64]H-15 r V4 NINE MILE POINT UNIT 1~UNIRRADIATED BASE METAL Q 307 1 0 (1 2)e EXPERIMENTAL DATA 120 WEIBULL FiY TRANSITION 100 I I-LL 80 60 ILI 40 V 20 g 4/J k o>r e r 0-100-50 0 50'I 00 150 200 250 TEST TEMPERATURE (F j HYPERBOLIC TANGENT FIT CONFIDENCE LIMIT (e5%)CONFIDENCE LIMIT (95%)CONFIDENCE uMIT (e5v)CONFIDENCE uMIT (e5v)H-16

H.1.2.UNIRRADIATED ARCHIVE PLATE G-8-3 DATA H-17 C,r LE H-8.CHARPY V-NOTCH IMPACT RESULTS OR UNIRRADIATED BASE METAL SPECIMENS PREPARED FROM PLATE G-8-3 (L-T orientation)

"'pecimen Identification Location Within Plate Test Impact Temperature Energy.(F)(ft-lb)Lateral Expansion (mils)Fracture Appearance

(%Shear)C28 C06 C27 C04 C24 C03 C22 C23 C02 C21 C01 C29 C07 C31 C09 C30 C08 1/4T 3/4T 1/4T 1/4T 3/4T 1/4T 1/4T 3/4T 1/4T 3/4T 1/4T 3/4T 1/4T 3/4T 1/4T 3/4T-80-80-40-40 10 10 35 35 35 60 60 110 110 160 160 212 212 8.4 9.2 14.5 24.0 85'55.0 51'107.0 67'104.5 97.5 108.0 105.5 108.0 113.0 109.5 110'12.4 10.2 18.2 29.6 50.8 44.4 43.8 77.4 53.4 68'82.0 73'79.0 78.0 83.8 82.4 81.4 5 5 10 10 50 25 40 100 50 65 70 100 100 100 100 100 100 Data taken from reference[MA87]

NINE MILE POINT DATA AND CURVES 8 Data Yatwe Wottwll fit TAlat t'tt OS Conttdonco t.tmtt~0 O O-l00-50 0 50 l00 l50 200 TEST TEMPERATURE (F)250 CVN IMPACT ENERGY VERSUS TEST TEMPERATURE FOR PLATE G-8-3 (L-T ORIENTATION)

H-19.

O COMPAR l SON PLOT DATA AND CURVES 0 plate~-5,$67 teet 0 plod~-b,$64 teet b pled~-4>$54 teet 0 0 LXI I o EO 4 cr 9 LJJ 0 0 h h 0 0 100-50 0 50 100 150 TEST TEMPERATURE (F)200 250 COMPARISON OF 1987 ARCHIVE PLATE G-8-3 DATA AND 1964 CVN IMPACT DATA ON PLATES G-8-3 and G-8-4 H-20

H.1.3.1990 Current Stud UNIRRADIATED ARCHIVE PLATE G-8-3 DATA T-L orientation H-21

LE H-9.CHARPY V-NOTCH IMPACT RESULTS OR'UNIRRADIATED BASE METAL SPECIMENS PREPARED FROM PLATE G-8-3 (T-L orientation)

Specimen Identification Location Within Plate Test Temperature (F)Impact Energy (ft-lb)Lateral Expansion (mils)Fracture Appearance

(%Shear)3N2 1N2 3N1 1N1 3N4 1N4 3N5 1N5 3N9'N8 1N8 3N7 1N7 1N9 3N6 1N6 3N3 1N3 3/4T 1/4T 3/4T 1/4T 3/4T 1/4T 3/4T 1/4T 3/4T 3/4T 1/4T 3/4T 1/4T 1/4T 3/4T 1/4T 3/4T 1/4T-80-80-40-40 10 10 35 35 57 57 57 79 79 79 110 110 212 212 7.3 9.0 11.0 12.2 33.9 41.0 41.0 45.5 60.1 53.1 57.2 53.0 51.2 68.3 69.0 73'68.0 64.0 5 4 6.4 9.4 11.2 28.6 34.4 37.4 39.4 52.0 48.2 51.4 48.6 46.6 62.0 59'61'61.2 58.8 8.1 6.5 20.5 15.3 34.4 37.6 56.0 61.1 83.5 81.0 74.9 95.6 73.3 81.0 100.0 100'100.0 100.0

NINE MILE POINT UNIT I~UNIRRADIATED g4$E METAL Q Q 3 (ff)(I 2)~EXPERIMENTAL DATA 100 CQ I f U 80 60 WEIBULL FIT TRANSITION HYPERBOLIC TANGENT FIT CONFIDENCE LIMIT (95%)40 0 20 0-100-50 0 50 100 150 200 250 TEST TEMP ERAT V RE (F)CONFIDENCE LIMIT (95%)CONFIDENCE LIMIT (95%)CONFIDENCE LIMIT (95%)H-23

~g<<4.'at 20 24 28 TESTED AT-800F l;)24 28 TESTED AT-80 F H-24

~lg V ,a TESTED AT-40"F I I l 1 io~~24 28 TESTED AT-40 F H-25

!tgg ll 24 28 TESTED AT 10 F g g I I I~24 28 TESTED AT 10 F H-26

\P)t'2'I~'lK I24 28 TESTED AT 35 F 8 u zO 24 2S TESTED AT 35 F H-27 Ci c TESTED AT 57'F j f a TESTED AT 57 F

$s 12 TESTED AT 57 F I a 8 12 z4 28 TESTED AT 79"F H-29

($ll~qfv>

I 8 24 28 TESTED AT 79 F i i (>>.g'))I;ggj~jpq4V TESTED AT 79 F H-30 p

TESTED AT 110 F 4 8>.3 24 28 TESTED AT 110 F I I~.>'4 i TESTED AT 2120'ESTED AT 212 F H-32

H.2.IRRADIATED SURVEILLANCE SPECIMEN DATA H-33

H.2.1.1984 IRRADIATED 300 DEGREE CHARPY DATA 0

TABLE H-10.CHARPY V-NOTCH IMPACT RESULTS FOR IRRADIATED BASE METAL SPECIMENS FROM THE NINE MILE POINT 300-DEGREE SURVEILLANCE CAPSULE Specimen Identification Test Temperature, F Impact Energy, ft-lb Lateral Expansion mils Fracture Appearance

%Shear E1U-RC E42 ElJ E1M E3T EA5 E1V E1M-RC E7E-RC E7E E3T-RC ElK-40 0 40 75 120 135 160 200 200 240 280 320 6.3'10 17.5 28 30 53 52.5 59 78 99 104 2.8 9.2 17.4 28.2 30 45.2 52.8 47.8 38 61.4 72.2 78.4 1 9 10 21 30 35 50 40 65 100 100 100 RC=Reconstituted (1)Data taken from Reference[ST84](2)Based on chemistry data, this material is believed to be plate G-8-1 material.

NINE MILE POINT UNIT 1 IBB4pI4TEp B4QE METAL 3 pp pEG g4p I q q t EXPERIMENT4L DATA 120 WEIBULL FIT TRANSITION 100 I I-L 80 Q 60 40 O X 20/4 WEIBULL FIT UPPER SHELF HYPERBOLIC TANGENT FIT CONFIDENCE LIMIT (95%)CONFIDENCE LIMIT (95%)CONFIDENCE LIMIT (95%)0 50 100 150 200 250 300 350 LIMIT (95%)TEST TEMPERATURE (P)H-36

TABLE H-11.CHARPY V-NOTCH IMPACT RESULTS FOR IRRADIATED WELD METAL SPECIMENS FROM THE NINE MILE POINT 300-DEGREE SURVEILLANCE CAPSULE Specimen Identification Test Temperature, F Impact Energy, ft-lb Lateral Expansion mil s Fracture Appearance

%Shear E JD-RC EDL EDT-RC EJD EDJ EJC EDK EDT EDJ-RC EDM EJC-RC EJT-120-100-80-40-20 0 40 75 125 160 240 280 33 28 33 59 61 76.5 110.5 100 116 112 7.2 3.4 30.4 25.2 30.4 52 54.8 63.2 84.6 66 78 85 3 7 17 22 27 42 64 68 100 100 100 100 RC=Reconstituted (1)Data taken from Reference[ST84]

>a l 1 Ph Il f>>,

NINE MILE POINT UNIT 1 RRADIATED~ELp 3pp DEGREE CAPSULE(q 2)EXPERIMENTAL DATA 150 125 I I LL.100 kk kkkk k*k j k kk Qkkkkk kk kk WEI BULL FIT TRANSITION WEIBULL FIT UPPER SHELF HYPERBOLIC TANGENT FIT 75 50 V*4 25-150/*k j*k k k k k k Ok Ok k k k k k k k k k k'I 50 CONFIDENCE LIMIT (95%)CONFIDENCE LIMIT (95%)CONFIDENCE LIMIT (95%)~CONFIDENCE LIMIT (95%)TEST TEMPERATURE (F)H-38 I I TABLE H-12.CHARPY V-NOTCH IMPACT RESULTS FOR IRRADIATED HAZ METAL SPECIMENS FROM THE NINE MILE POINT 300-DEGREE SURVEILLANCE CAPSULE Specimen Identification Test Temperature, F Impact Energy, ft-lb Lateral Expansion mils Fracture Appearance

%, Shear J2C J1L J1T J1M JlP Jl J-40 0 40 50 77 160 200 280 17.5 44 33 57.5 82 96 96.5 12.6 32.4 33.4 48 64~2 59.6 76 79.2 20 35 42 70 9'0 1 0 0 1 0 0 1 0 0 (1)Data taken from Reference[ST84]

100 90 70 50 40 30 20 LO-COO WO 0 50 LOO 150 200 250 300 350 Test Teaperstvre F CHARPY V-NOTCH IMPACT ENERGY VERSUS TEST TEMPERATURE FOR THE IRRADIATED HAZ METAL SPECIMENS FROM THE NINE MILE POINT 300-DEGREE SURVEILLANCE CAPSULE H-40

H.2.2.1985 IRRADIATED 30 DEGREE CHARPY DATA

TABLE H-13.

SUMMARY

OF CHARPY IMPACT DATA FOR IRRADIATED BASE MATERIALS FROM THE 30-DEGREE CAPSULE~i'~i Specimen Identification Type Specimen Test Temp, F Energy, ft-lb Lateral Expansion Total Mil Fracture Appearance

%Shear E1A E2U I c Elc E31 EBK E71 Base Base Base Base Base Base 85 125 45 100 60 72 47.0 68.0 27.7 50.5 24.0 25.0 43'55'25.4 42.4 25.4 25'40 50 30 40 25 30 (1)Date taken from reference[MA85a](2)Based on chemistry data, this material is believed to be plate G-8-1 material.

NINE MILE POINT UNIT 1 IRRADIATED BASE 30 DEG CAP (I, 1)120 CG 100 I I-L, 80 Q 60 40 O X 20 J A O 20 EXPERIMENTAL DATA WEIBULL FIT TRANSITION HYPERBOLIC TANGENT FIT CONFIDENCE LIMIT (95%)CONFIDENCE LIMIT (9 5%).-100-60 0 60 100 150 200 250 TEST TEMPERATURE (F)H-43

H.2.3.1990 current stud IRRADIATED BASE FROM HAZ FOR THE 300 DEGREE CAPSULE H-44

TABLE H-14.CHARPY V-NOTCH IMPACT RESULTS FOR IRRADIATED BASE METAL SPECIMENS PREPARED FROM HAZ SPECIMENS TAKEN FROM THE 300 DEGREE CAPSULE Specimen Identification Impact Test Energy Tem erature F~ft-lb Lateral Expansion~mile Fracture Appearance JlP J1J J1T J1M-50-50 35 150 23.0 8.2 42.0 25.7 57'114.3 17.0 3.0 32.6 20.6 44.4 85.8 11.5 11.0 29.1 27.0 39.4 100.0 (1)Based on chemistry data, this material is believed to be Plate G-8-3 material.

0 NINE MILE POINT UNIT RRAPIATEP BASE(HAZ)300 DEG CAP (1 2)EXPERIMENTAL DATA 120 100 Cl I I-0 80 Q 60 ao O X 20 J/fA-100-50 0 50 100 150 200 250 TEST TEMPERATURE (P}WEIBULL FIT TRANSITION HYPERBOLIC TANGENT FIT CONFIDENCE LIMIT (9 5%)CONFIDENCE LIMIT (95%)CONFIDENCE LIMIT (9 5%)CONFIDENCE LIMIT (95%)

V'c 1 1 4 8 ti.-vo ZO 24 28 32 TESTED AT-50"F ,>Qypgjjgf,lf t 4 8 iz 16 20 24 28 32 TESTED AT-50 F H-47 iL pj pi 32.64 4 l 12'lo-20 24 28 TESTED AT-5 F'~f8;4 8 32 12.~--~v z4 28 TESTED AT-5 F H-48 A+: Aw" ,'a'l'S Q 12 16 2~TESTED AT 35 F y pro f34'~viE 4 8 32 12 TESTED AT 150 F H-49

APPENDIX I HARDNESS DATA 0

TABLE I-1.ROCKWELL C HARDNESS DATA Specimen Identification Indentation"'urface Material"'verage Fluence (n/cm~)Rockwell'Hardness B Rockwell"'ardness C 3N3 3N3 1N8 1N8 JAE JAE JIT JIT EIM E42 RElU RElU side notch side notch side notch side notch notch (4)side notch 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 0 0 0 0 4.78x10'~4.78x10'~4.78x10" 4.78x10~'.78x10'~

4.78x10'~4.78x10'~4.78x10~'0.0 89.8 92.5 90 F 1 92.5 92.3 90.7 93.8 94.2 91.2 10.5 10.4 14.1 12.5 14.0 13.2 15.2 14.3 15.4 15.2 (2)"side" indicates the indentation was performed on the surfaces normal to the notch."notch" indicates the indentation was performed on the notched surface in the direction of crack propagation.

l base specimens from the 300'apsules are believed to be from plate G-8-1 and base specimens from HAZ or Weld are believed to be G-8-3 material.(3)the estimated uncertainty is+1.0 for the calibration.

(4)since the fracture surface was removed prior to hardness testing, the notch orientation could not be determined.

APPENDIX J DROP WEIGHT DATA Drop weight tests were con'ducted on archive plate G-8-3 using ASTM type P-2 specimens.

The NDT for plate G-8-3 is-25'F.

TABLE J-1.DROP WEIGH ST DATA FOR PLATE G-8-3 Specimen Identification Location Within Plate Test Temperature (F)Break D21 D22 D02 D04 D24 D01 D25 D26 D03 D23 D05 D06 D27 D28 D07 D08 1/4T 1/4T 3/4T 3/4T 1/4T 3/4T 1/4T 1/4T 3/4T 1/4T 3/4T 3/4T 1/4T 1/4T 3/4T 3/4T-70-50-40-35-35-30-30-30-30-30-25-25-20-20-20-20 Yes Yes Yes Yes Yes No No Test No Yes Yes Yes No No No No No*Specimen run at 320 ft-lb instead of 300 ft-lb.

APPENDIX K FLUX AND FLUENCE DATA

K.1 30 DEGREE CAPSULE DATA K-2

<ap K.1.1 Dosimetry Table K-1 contains the results of the analysis of the dosimetry wires from the 30-degree position surveillance capsule.The wire identifications, measured radionuclide activities (in dps-mg'), and wire compositions are tabulated.

The measured activities have been decay corrected to November 30, 1984.The composition of the Cu and Ni wires was taken from Reference[HI69].The percent Fe for the iron wire was taken from Reference[LO84].As indicated in Table K-l, the two Ni wires, Pl-Ni.l and P2-Ni.2, are listed for packet P1.This is because packet Pl contained two Ni wires but no Cu wire.Both Ni wires were anlayzed witht he results listed.For the Co-58 measurement on he Ni wires, no Co-58 activity was measured due to the long decay time following removal of the capsule from the reactor and the relatively short half-life of the isotope (70.8 days).The values which are listed in the table for Co-58 are upper limits for the-specific activity based on detection limits.K.1.2 Fluence Calculation To accurately determine the neutron flux at the capsule and in the pressure vessel wall, the neutron spectrum must be calculated.

The spectrum was calculated for the 300-degree capsule by analyzing the octant adjacent to the capsule, and the results were reported in Reference[ST84].An analysis was performed to determine if the assumption of octal symmetry for he 30-degree capsule is reasonable.

This assumption precludes the need to calculate the spectrum for the 30-degree capsule.K-3 Wt~~

Niagara Mohawk supplied bundle-cycle-exposure data for the core octant adjacent to the 30-degree capsule position.We compared the ratio of the bundle-cycle exposure to the core-average-cycle exposure for the appropriate geometrically symmetric bundles in the outer core region.Most of these ratios were within a few percent.Therefore, the assumption of octal symmetry is reasonable and results in a small error in the effective cross sections.Calculations of the flux and fluence were made using the DECAY code.The reactor power history was supplied in a private communication'C084].

The effective cross sections and nuclear constants were reported in Reference[ST84].The E>0.1 MeV and E>1'MeV full power flux and fluence calculated from initial startup to March, 1979, are given in Tables K-2 and K-3 respectively.

For each of the dosimeter wires, the average of the flux and fluence was determined by averaging over all the Fe and Cu wires.It was not possible to estimate the flux for the Ni dosimeters, since the Co-58 activity was not detectable because of the long decay time following removal of the capsule.The accuracy of the fluence values calculated is approximately

+5 percent accuracy, uncertainties in neutron spectrum and spectrum-averaged cross sections result in the larger variances in the computed flux and fluence values.K-4

TABLE K-1.MEASURED ACTIVITY OF THE 30-D GREE SURVEILLANCE CAPSULE DOSIMETRY WIRES Sample ID Nuclide Measured Activity*(dps-mg')Wire Composition Percent Pl-Ni.l Pl-Ni.2 P2-Ni P3-Ni Pl-Fe P2-Fe P3-Fe P2-CU P3-CU Co-58 Co-60 Co-58 Co-60 Co-58 Co-60 Co-58 Co-60 Mn-54 Mn-54 Mn-54 Co-60 Co-60<0.043 192+8<0'48 198+8<0.040 176+7<0.041 162 1.78+0.07 1.68+0.07 1~64+0 07 8.48+0.32 7.87+0.31 99.9271 Ni, 0'729 Co Commercially Pure Fe (99.865)99.999 CU*Decay corrected to November 30, 1984.

TABLE K-2.FLUX AND FLUENCE VALUES WITH ENERGY GREATER THAN 0.1 MeV AT THE NINE MILE POINT-UNIT 1 SURVEILLANCE CAPSULE (30-DEGREE AZIMUTHAL POSITION)Energy Dosimeter Material Full Power Flux (n/cm/sec)x 10 Fluence'n/cm

)x 10'.1 MeV Fe (P1-Fe)(P2-Fe)(P3-Fe)Average of Fe Cu (P2-Cu)(P3-CU)Average of Cu Average of Cu and Fe 3.8 3.6 3.5 3.6 3.3 3.1 3.2 3.4 6.9 6.6 6~4 6.6 6.1 5.7 5.9 6.3*Fluence based on 2117.8 equivalent full power days of operation.

Reference[Ma85a]

TABLE K-3.FLUX AND FLUENCE VALUES WITH ENERGY GREATER THAN 1.0 MeV AT THE NINE MILE-POINT-UNIT 1 SURVEILLANCE CAPSULE (30-DEGREE AZIMUTHAL POSITION)Energy Dosimeter Material Full Power Flux (n/cm'/sec) x 10'luence (n/cm~)x 10'~1.0 MeV Fe (P1-Fe)(P2-Fe)(P3-Fe)Average of Fe-Cu (P2-Cu)(P3-Cu)Average of Cu Average of Cu and Fe 2.2 2'2.0 2.1 1.9 1.8 1.9 2.0 4.0 3.8 3.7 3.8 3.5 3.3 3.4 3.6*Fluence based on 2117.8.equivalent full power days of operation.

Reference[Ma85a]

K.2 300 DEGREE CAPSULE DATA

'%ll

.2.1 Anal tical Method The determination of the neutron flux at the capsule, and subsequently in the pressure vessel wall, requires the completion of thre'e procedures.

First, the disintegration rate of the product isotope per unit mass of the flux monitor must be determined.

Second, in order to find a spectrum-averaged reaction cross section at the capsule location, the neutron energy spectrum must be calculated.

Third, the neutron flux at the capsule must be found by calculations involving the counting rate data, the spectrum-averaged cross sections, and the operating history of the reactor.The energy and spatial distribution of neutron flux in the reactor were calculated using the DOT 4.3 computer program'~~.OT solves the Boltzmann transport equation in two-dimensional geometry using the method of discrete ordinates.

Balance equations are solved for the density of particles moving along discrete directions in each cell of a two-dimensional spatial mesh.'nisotropic scattering is treated using a Legendre expansion of arbitrary order.The two-dimensional geometry that was used to model the Nine Mile Point-Unit 1 Reactor is shown in Figure K-1.As seen, there are 16 circumferential meshes and 66 radial meshes.The capsule includes circumferential meshes 6 and 7 and radial meshes 54 and 55.Third order scattering was used (P~)and 48 angular directions of neutron travel (24 positive and 24 negative)were used (S8 quadrature).

Neutron energies were divided into 47 roups with energies from 17.3 MeV to 10~eV.The 47 group K-9 k

structure is that of the RSIC Data Library DLC75/BUGLE 80 and neutron absorption, scattering, and fission cross sections used are those supplied by this librar'y.The core shroud is Type 304 stainless steel.The capsule is also modeled as a solid piece of Type 304 stainless steel.The reactor pressure vessel wall is SA302B steel.The reactor core was mocked up as homogenized fuel and water having the densities found in the operating reactor.The water in the core region has a density consistent with saturation conditions at the operating pressure of 1050 psia and a core-averaged steam volume fraction of 0.30~The water in'the downcomer has a density consistent with an inlet subcooling of 23 Btu/pound.

Finally, the fuel was a source of neutrons having a U-235 fission energy spectrum.The relative ower in the assemblies nearest the capsule, during he interval the capsule was in the reactor, is shown in Figure K-17'~~"'.

A plane view of the Nine Mile Point Reactor physical geometry at the core midplane is shown in Figure K-1 and because of symmetry includes only a 1/8th segment.The neutron spectrum at the capsule center, as calculated by DOT, is shown in Figure K-2.Also shown for comparison is the fission spectrum.The fission spectrum was normalized to contain one neutron/cm~/sec above 1.0 MeV.The neutron spectrum at the capsule center was normalized to contain the same flux as the fission spectrum at 1.0 MeV energy.As can be seen, the capsule spectrum is considerably harder than the fission spectrum.This is caused by neutron travel through water.K-10 di 0 280 15 13 300 Capsule 240 200 5)C V 160 E 0 u.56$6.95.99 1.02 1,08 1,09 1,19$3.49"'.93.93 1.06 1.05 1.12 1.15.39.79$0.93.85 1.04 1.04~50.99~53.88~52 V 4p Cg O~~a 4y Ng 4y 120 80 1.0 1,07 4~4~40 0 0 80 120 Distance From Core.Center (cm)240 280 FIGURE K-l.NINE MILE POINT CORE, INTERNAL VESSEL STRUCTURES, AND VESSEL WALL GEOMETRY USED IN THE DOT CALCULATION f'I 1.0 Fission Spectrum Neutron Spectrum at Capsule 10.1>102 g ul C E k 10'3 Le I L I L I I I I I I L~)I I I I Leans I I I I I Le w~~I I I I I I I I lcm mme 10 I 10'12 16 Neutron Energy (MeV)24 FZGURE K-2 COMPARZSON OF DOT SPECTRUM AT 300 DEGREE NZNE MILE POZNT SURVEILLANCE CAPSULE WZTH FZSSZON SPECTRUM K-12

Based upon the fluxes calculated by DOT at radial meshes 54 and 55 and circumfenential meshes 6 and 7 (the meshes used to represent the capsule and the region in which the flux monitors were placed), effective cross sections a~(E>0.1 MeV)and G~(E>1.0 MeV)defined as: cr(E>E,)0 (E)dE E, were calculated for iron, nickel, and copper.The results are shown in Table K-4.Other nuclear constants needed in the third step of the flux-finding procedure are given in Table K-5.In the third step, the full power flux at the capsule location is determined from the radioactivity induced in the monitor foils, the effective cross sections calculated for the monitor elements, and the power history of the reactor during capsule exposure.The fluence at the capsule is then calculated from the integrated power output of the reactor during the exposure interval using the following equation:)(E>E)=A/[Na(E>E)C]This equation was used to find fluxes based on the measured surveillance capsule activations.

The time intervals were taken as one month each and a time integrated relative power value for each month was used for the fractional power level values.Calculations of the flux and fluence were made with the DECAY code.The reactor power history was supplied in a private communication'

~'

TABLE K-4.CROSS-SECTIONS FOR THE IRRADIATED FLUX MONITORS CALCULATED FROM FLUXES AT CAPSULE CENTER OF THE NINE MILE POINT 300-DEGREE SURVEILLANCE CAPSULE Dosimeter Material E>0.1 MeV Cross-Sections Barns E>1.0 MeV Fe Cu Ni 1.01 x 10 1.77 x 10~1.28 x 10 i 1.76 x 10 i 3.09 x 10~2.23 x 10 i TABLE K-5.CONSTANTS USED'IIN DOSIMETRY CALCULATIONS FOR THE NINE MILE POINT 300-DEGREE SURVEILLANCE CAPSULE Reaction Target Percent Isotopic Abundance Percent Threshold Energy, MeV Product Half-Life~'Fe (n, p)~'Mn"Cu (n, a)"Co seNi (n, p)ssC 99.865 Fe 99.999 Cu 99.927 Ni 5.82 69.17 67.77 2.5 6.1 2.1 312.6 days 5.27 years 71.2 days K-14 0

K.2.2.Dosimetr Results~~~The surveillance capsule was located at the 300-degree azimuthal position at approximately the core midplane position and at 7/16-inch from the inner pressure vessel wall.This capsule was in the reactor for" 2913 equivalent full power days or about 7.98 equivalent full power years.The Nine Mile Point Nuclear Generating Plant design thermal output is 1850 MW.The neutron monitor wires from Charpy packets P7 and P8 wee counted to determine their specific activity.The recommended ASTM procedures

~~~"~~"'~'" As~"'~'were followed in determining the specific activity of the wires.Each dosimeter monitor consisted of an approximately 4-inch length of wire which was rolled into a small coil for counting.The count rate was determined for each wire~The fast flux and fluence calculated using the count rate therefore represented an average over the 4-inch length of that wire.The E>O.l MeV and E>1.0 MeV full power flux and fluence calculated from initial startup to March 1982 are given in Table K-6 and Table K-7., respectively, for each f the dosimeter wires along with the average of the flux and fluence derived from each wire and the average values for Fe, Cu, and Ni.In addition, the average values of the results for Fe and Cu are given.The Ni results were not used because the very short half life makes its results dependent on only the latest operating history.Using the average fluxes of 3.32 x 10 n/cm/sec for E>0.1 MeV and 1.90 x 10'/cm'/sec for E>1.0 MeV, the fluxes at full power at the inside of the pressure vessel wall, at 1/4 T and at k tf A4 3/4 T directly behind the capsule (300-degree orientation) and at the maximum position (285.66-degree orientation) were calculated.

The flux results are tabulated in Table K-8.The end of life (EOL)fluences were also calculated and tabulated in Table K-8 assuming a reactor pressure vessel lifetime of 40 years and the reactor operated at 80 percent of full power.The fine mesh and time integrated relative power values shown in Figure K-8 for each fuel assembly was used in the DOT 4.3 code to generate the values in Table K-8.A plot of neutron flux (E>1.0 MeV)as a function of azimuthal angle (in degrees)is shown in Figure K-3.The fluence values at the maximum position for inner vessel wall, 1/4 T and 3/4 T are plotted as a function of time in equivalent full power years (EFPY)for the Nine Mile Point pressure vessel~~in Figure K-4.The lead factor, ice., the ratio of the flux (E>1.0 MeV)at the surveillance capsule to the largest flux (E>1.0 MeV)received by the vessel wall at any azimuthal location, is approximately 0.68 (1.90 x 10'/2.80 x 10')at the vessel surface.This result indicates that the flux at the capsule actually lags the flux at certain vessel wall positions.

The lead factors at the pressure vessel 1/4 T and 3/4 T positions were calculated to be 0.99 (1.90 x 10/1.91 x 10)and 3.70 (1.90 x 10/5.14 x 10), respectively.

The accuracy of the fluence values generated is estimated to be+20 percent.Although specific activities of fluence monitor wires can be determined to+5 percent accuracies, uncertainties in neutron spectrum and spectrum averaged cross K-16 0

1010~Position of 300 Degree Capsule A N h 10>C X u C 0 z~h u inner gq~~'<<r 3/g y 108 270 290 300 310 Azimuthal Angle (degree)320 330 FIGURE K-3.CALCULATED FLUX AT PRESSURE VESSEL INNER WALL, 1/4 T THICKNESS AND 3/4 T THICKNESS AS A FUNCTION OF AZIMUTHAL ANGLE K-17

1018 g(4'1 1017 1016 0 10 15 20 Time (full power yean)25 30 FIGURE K-4.FLUENCE AT INNER WALL 1/4 T AND 3/4 T POSITION AS A FUNCTION OF TIME FOR THE NINE MILE POINT UNIT 1 REACTOR VESSEL p's sections result in the larger variances in the computed flux and fluence values.The rate of displacements per atom was also calculated using the cross sections for displacement available with the DETAN code.Table K-9 shows calculated values of displacements per atom per second at full power in the pressure vessel wall behind the capsule and in the pressure vessel wall at the angle of peak fluence in the wall.Table K-9 also shows calculated values of displacements per atom at these same positions in the wall for 7.98 effective full power years of operation (to time of'capsule removal)and for 32 effective full power years of operation.

K-l9 0

TABLE K-6.FLUX AND FLUENCE VALUES WITH ENERGY GREATER THAN 0.1 MeV AT THE NINE MILE POINT-UNIT 1 SURVEILLANCE CAPSULE (300-DEGREE AZIMUTHAL POSITION)Energy Dosimeter Material Full Power Flux (n/cm/sec)x 10'luence*(n/cm')x 10" O.l MeV Fe (P7)(P8)Average of Fe Cu (P7)(P8)Average of Cu Ni (P7)(P8)Average of Ni Average of Fe and Cu 3.549 3'10 3.380 3.253 3.253 3.253 3.230 3.117 3.174 3.32 8.933 8.078 8.506 8.188 8.188 8.188 8'30 7.844 7.987 8.35*Fluence based on 2913.1 equivalent full power days of operation.

a)P7 refers to bottom packet b)P9 refers to top packet Reference-[ST84]

0 TABLE K-7.FLUX AND FLUENCE VALUES WITH ENERGY GREATER THAN 1.0 MeV AT THE NINE MILE POINT-UNIT 1 SURVEILLANCE CAPSULE (300-DEGREE AZIMUTHAL POSITION)Energy Dosimeter Material Full Power Flux (n/cm/sec)x 10'luence (n/cm)x 10" 1.0 MeV Fe (P7)'P8)~Average of Fe CU (P7)(P8)Average of Cu Ni (P7)(P8)Average of Ni Average of Fe and Cu 2.033 1.839 1.936 1.864 1.864 1.864 1.851 1.786 1.819 1.90 5.118 4.629 4.874 4.691 4.691 4.691 4.659 4.494 4.577 4.78*Fluence based on 2913.1 equivalent full power days of operation.

a)P7 refers to bottom packet b)P9 refers to top packet Reference[ST84]

TABLE K-8.FLUX AND FLUENCE IN THE PRESSURE VESSEL WALL OF THE NINE MILE POINT-UNIT 1 REACTOR-BEHIND THE SURVEILLANCE CAPSULE (300-DEGREE)

AND AT THE AZIMUTHAL ANGLE OF MAXIMUM FLUX IN THE VESSEL WALL (285.66-DEGREE)

Full Power Flux in Vessel Wall Maximum (285.66')Behind Capsule (300')Fluence in Vessel Wall Energy Location Behind Capsule (300')Maximum (285.66')March 82 (1)(MeV)(n/cm'/sec x 10')(n/cm'/sec x 10')(n/cm x 10'EOL (2)March 82 (1)EOL (2)(n/cm x 10")(n/cm~x 10'(n/cm x 10")>0.1>O.l I>1.0>1.0>1.0 1/4T 3/4T Surface 1/4T 3/4T>0.1 Surface 3.19 2.85 1.31 1~51 1.02 0.281 5.56 5.01 2.26 2.80 1.91 0.514 8.03 7.17 3.30 3.80 2.57 0.707 3.22 2.88 1.32 1.52 1.03 0.284 1.40 1~26 0.569 0.705 0'81 0.129 5.61 5.08 2.28 2.83 1.93 0.51 (1)Fluence based on 7.98 effective full power years of operation.

• (2)Fluence based on 32 effective full power years of operation.

Reference[ST84]

g k TABLE K-9.ATOM DISPLACEMENTS IN THE PRESSURE VESSEL WALL OF THE NINE MILE POINT-UNIT 1 REACTOR Dis lacements er Atom Dis lacements er Atom er Second Behind Capsule Maximum (285.66')Location Behind Capsule Maximum (285~66')March 82 (1)EOL (2)March 82 (1)EOL (2)Surface 1/4T 3/4T 2.56x10~1.79x10 9 6.19x10" 4.82xlO~3.28xlO 9 1.10xlO 9 0.644 0.452 0.156 2.582 1.813 0.626 1.214 0.825 0.277 4.868 3'08 1.111 (1)Fluence based on 7.98 effective full power years of operation.

(2)Fluence based on 32 effective full power years of operation.

Reference[ST84]

APPENDIX L NINE MILE POINT VNIT 1 RT~DETERMINATION i,

FINAL REPORT entitled NINE MILE POINT UNIT 1 RT r DETERMINATION to , Niagara Mohawk Power Corporation 301 Plainfield Road Syracuse, NY 13212 by Dr.Michael P.Manahan, Sr.September 28, 1990 NPN Consultin~

213 Teaherry Circle State CO11egeg PA 16803 (814)234-8860 0

IMPORTANT NOTICE REGARDING CONTENTS OF THIS REPORT This document was prepared by Dr.Michael P.Manahan.The information contained in this report is believed by Dr.Manahan to be an accurate and true representation of the facts known, obtained or provided to Dr.Manahan at the time this report was prepared.Dr.Manahan does not make any representation or warranty (express or implied)as to the completeness, accuracy or usefulness of the information contained in this document or that such use of such information may not infringe privately owned rights;nor does he assume any responsibility for liability or damage of any kind which may result from such use of such information.

L-3 t ia>i COPYRIGHT NOTICE The Ropy methodo l ogy is the property of Dr.Manahan.Permission is hereby granted to Niagara Mohawk to use the results obtained using ,.this methodology, for the Nine Mile Point Unit 1 P-T curve analysis.Use of the methodology, other than for Nine Mile Point Unit 1, is forbidden without prior written approval.M.P.Manahan, 1990~~L-4 W4 TABLE OF CONTENTS

1.0 INTRODUCTION

1.1 Purpose 2.0 WELD MATERIAL ANALYSIS~~0~~7~~~8 2.1 Weld W5214/5G13F Analysis 2.1.1 cr, Analysis 2~1~2 Ropy Ana lysis 2.1.3 Summary of Findings 8 9 11 16 2.2 Beltline Weld Analysis 16-.'.3.0 PLATE MATERIAL ANALYSIS 3.1 Base Metal cr, 3.2 RTp~Analysis.

4.0 CONCLUSION

S 0~~~~~~~~~~19~~~19~~~19

28.0 REFERENCES

.

...................'...30

LIST OF FIGURES 2-1 2-2 Charpy Impact Energy Versus Test Temperature for Irradiated Weld Specimens from the Nine Mile Point Unit 1 300 Degree Capsule.............10 RT~~Analysis for Surveillance Capsule Weld Material W5214/5G13F

..................15 2-3 RT~~Analysis for Beltline Weld 86054B/4E5F

......18 3-1 Charpy Data Fit for Base Metal Plate G-8-3/G-8-4 22 3-2 3-3-3-6 Charpy Data Fit for Base.Plate G-8-3/G-8-4 (T-L)Charpy Data Fit for Base Plate G-8-1-5.Charpy Data Fit for Base Plate G-307-3 Charpy Data Fit for Base Plate G-307-4 Charpy Data Fit for Base Plate G-307-10 Metal Metal Metal Metal Metal~~23.24.25.26~27 L-6

LIST OF TABLES 2-1 Summary of RTQQ7 0,, and Charpy Indices for Weld W5214/5G13F

..................16 2-2 RT~~Data for Beltline Welds...............17 3-1 RT+~, 0'and Charpy Indices for Unzrradiated Beltline Plates..............21 L-7

1.0 INTRODUCTION

1.1 Pur ose An analysis was perf1ormed to establish best estimate values for the RT~~and a, term used in Regulatory Guide 1.99 (Rev.2)calculations for the Nine Mile Point Unit 1 (NMP1)beltline plate and weld materials.

Sufficient data are not available to determine the RTgp~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 was first described in{MA85]and was specifically designed to address ,the problem of RTz~determination in cases where there are not sufficient data available to satisfy the ASME code requirements.

The results of these analyses are presented in Sections 2.0 and 3.0 of this report.Conclusions and recommendations concerning the use of these data are provided in Section 4.0.L-8

2.0 WELD MATERIAL ANALYSIS The objective of the weld material analysis is to calculate a statistically meaningful o, for the beltline welds which can be used in the Margin term of the Regulatory Guide 1.99-Rev.2 (RG1.99(2))

model.Also, the initial RTpT of each of the beltline welds and the surveillance capsule material was calculated using Manahan's statistically based calculative procedure[MA85b].The only unirradiated fracture behavior data available for the weld materials is Charpy data at 10'F[MA90, BY90].Irradiated data for the surveillance capsule material, designated weld W5214/5G13F (wire heat no./flux lot no.), is also presented in Reference[MA90].Both the irradiated surveillance data and the unirradiated data for each weld were used to calculate o, and the RTpT of each beltline weld.As described in Reference[MA90], the base metal Charpy specimens were machined with their long axes rallel to the plate rolling direction.

Therefore, the crack plane is oriented transverse to the material grain (L-T orientation).

The weld specimen long axis was machined transverse to the weld direction.

Since there are no microstructural data available for the welds, it'has been assumed that the material is isotropic and no correction for grain orientation was made in the RTgpT analysis.Unl ike base metal pl ates, the weld material generally does not exhibit grain orientation effects and, therefore, the Charpy specimen orientation is not critical for weld.materials.

2.1 Weld W5214 5G13F Anal sis Weld W5214/5G13F is the surveillance capsule weld.Unfortunately, this weld was not made using the same wire or flux as the beltline welds.However, the weld materials were manufactured by the same suppliers for the beltline materials (RACO g3 wire, Arcos B5 flux)and the Cu and Ni content is representative of the beltline weld 1248/4M2F.

[BY90, MA90](Data on the Cu and Ni content of the other two beltline welds L-9

is not available.)

Therefore, it has been assumed that the capsule weld material is similar to the beltline welds in terms of its mechanical behavior trend.The irradiated Charpy data for the capsule weld material was analyzed using the SAM McFRAC code[McFRAC).The SAM McFRAC code has been QA verified in accordance with The Pennsylvania State University, Nuclear Quality Assurance Program.This code is based on a non-linear, least squares, regression analysis using the Weibull statistic.

The Weibull statistic has been shown to be the correct statistic for analysis of fracture data by considering the microstructural mechanisms involved in the fracture of ferritic, pressure vessel steels[MA85a].The confidence bands are measures of"the goodness of fit" and do not indicate the classical 954 statistical error spread.This uncertainty must be analyzed using conventional statistical methods.However, the McFRAC confidence intervals are used to measure confidence in the fit of a particular data set as well as the inherent scatter due to the fracture process.These error bands must be calculated, particularly, for sparse data sets, because in many cases the ability to fit sparse data drives the uncertainty.

The McFRAC analysis for the irradiated capsule weld is shown in Figure 2-1.The o, term is the uncertainty in the initial RTgpy determination.

Section III of the ASME code requires that, both drop weight tests, to determine the NDTT, and Charpy tests be performed.

The NDTT temperature deter-mined by following ASTM E-208 is the RT>>provided that, at 60'F above the NDTT, at least 50 ft-lbs.of energy and 35 mils lateral expansion are obtained in Charpy speci-mens with crack planes oriented in the weak direction.

The weak direction is transverse to the direction of maximum working (T-L orientation) for base metal.

e 10 NINE INILE POINT UNIT 5~IRRADIATED WELD 300 DEGREE CAPSULE{'I,2)

EXPERIMENTAL DATA 150 125 Cl I I-IL 100 C9 75 50 V 26 4 A j 4 J J 4 ja 4/gg Jk k WEIBULL FIT TRANSITION WEIBULL FIT UPPER SHELF--HYPERBOLIC TANGENT FIT CONFIDENCE LIMIT (95%)CONFIDENCE LIMIT (95%)CONFIDENCE LIMIT (95%)-'I 50 150 TEST TEMPERATURE (F)CONFIDENCE LIMIT (95%)FIGURE 2-1: CHARPY IMPACT ENERGY VERSUS TEST TEMPERATURE FOR IRRADIATED WELD SPECIMENS FROM THE NINE MILE POINT UNIT 1 300 DEGREE CAPSULE

11 Therefore, cr, should reflect the uncertainty in either the drop weight test or the Charpy test depending on which test ultimately determined the RTDz.As described below, Charpy data are used to determine the Ropy and there f ore, a, is determined by estimating the uncertainty in temperature at the 50 ft-lb.energy level.Based on examination of the confidence in the McFRAC fit at 50 ft-lb., cr,(fit)=14.0'F.Analysis of the statistical 954 confidence interval for the data yields cr,(experimental)

=12.5'F.Based on examination of the LWR data base, Odette[OD86]has shown for welds that, cr,(data base)=18.0'F.The uncertainty for weld W5214/5G13F is higher than that of the LWR data base because of the sparsity of data in the transition region.Additional testing would reduce o,(fit)and e,(experimental).

Therefore, the final o, was determined using a weighted average of plant specific and generic data conservatively assuming there were only ten data points in the data base analyzed by Odette, to yield cr,=17'F.This value for cr, is recommended for use in[RG1.99]Margin term calculations for all of the beltline weld materials.

Many operating power plants were built when current regulations concerning establishment of the initial RT~~were not in force.Zn many cases, insufficient drop weight and Charpy data are available to determine the RT~~in accordance with the current Section XII of the ASME code.Prior to 1972, the ASME code recpxired that the average of three Charpy specimens be at least 30 ft-lb.at a designated temperature, with no single impact energy less than 25 ft-lb.These are the rules which were used for the vessel.The NRC Branch Technical Position, MTEB 5-2, contains a procedure for estimating the RT~~based on generic data.However, this approach

12 is overly conservative for some materials and does not take advantage of the use of limited unirradiated nor irradiated data in the analysis.GE also has a generic model which is based on a transition region slope of.5 ft-lb./'F.

However, this model, like the NRC model, is generic and lacks statistical rigor.Neutron irradiation of pressure vessel materials causes: an increase in the 30 ft-lb.transition temperature 2)a lowering of the upper shelf 3).a decrease in the slope of the transition region[OD86]In addition, Odette has shown that the transition region occurs over an approximately constant interval of temperature.

Odette pointed out that this fact, in concert with a continuous decrease of upper shelf energy (USE), requires that the'transition region slope must decrease with irradiation.

The average value of the transition temperature range, 6T~, is about 200 F+45 F for welds.These data, along with Odette's yield strength model, can be used to provide an accurate estimate of the RTQ7 of the beltline weld materials assuming that the NDTT occurs at a lower temperature than the temperature at which three Charpy specimens would exhibit 50 ft-lbs.of energy minus 60.This assumption is accurate for most pressure vessel materials because the NDTT is expected to occur at or near the brittleness transition region near the onset of the lower shelf.Analysis of the LWR ASTM A533B data base substantiates this assumption.

In the 23 cases analyzed, the NDTT was less than or equal to the RT~~.In 15 out of 23 cases, the RT~~was determined from the Charpy data.The average difference between the actual RTgp~and the RTgp7 estimated using the Ref erence[MA8 5]approach I I 13 was 8'F for welds and 10'F for base metal.The average net deviation is about 4.3'F for plate and weld.A similar analysis was conducted for ASTM A302B data.In all of the 17 cases analyzed the NDTT was less than or equal to the RT~T.The RTgpT was determined from Charpy data in 13 of the 17 cases.The average between the ASME code determined RT~T and that determined using Reference[MA85]was 8', and the average net deviation was 4.4'F for the base metal.Given these facts and observations, the approach to RTgp7 determination is to determine a temperature, T50T (for T-L orientation), at which three Charpy specimens would be expected to yield greater than 50 ft-lbs of absorbed energy.The T50T is determined by analyzing the uncertainty in the Charpy data in the transition region.The Tzo~temperature is defined as the, temperature at which the mean Charpy curve minus 50 ft-lbs equals 20E.Once the T50~temperature is determined, the RTgp7 is taken to be T50~'minus 60'F.This basic approach was used for both plates and welds.In the weld analysis, additional steps were followed since full Charpy curves were not available for the unirradiated welds.The procedure used to calculate the RTN07 for the Oyster Creek welds is as follows:~Ste 1~Ste 2~Ste 3 Using Odette's yield strength model[OD86], calculate the unirradiated upper shelf energy (USE).Draw a horizontal line at the USE'evel and pass a line through the unirradiated data which intersects the USE'ine such that the transition region spans 2004F.Verify the reasonableness of the slope by comparison with the irradiated transition region slope.Estimate the 954 confidence band for energy at the 50 ft-lb.level.L-14 v

14~Ste 4 Using the results of Steps 2)and 3), determine the temperature at which 50 ft-lb.is achieved and subtract 60'F to obtain the Rior~Ste S (Optional)

Zf sufficient data exists, use the Odette yield strength model to calculate the transition temperature shift at the 30 ft-lb.level (6T>Q)and compare with the ST3Q obtained above and with the RG1.99(2)model prediction.

For weld 85214/5G13F, the unirradiated USE was calculated to be: USE'128 ft-lb.The results of the Step 2)graphical analyses are presented in Figure 2-2.As discussed in Reference[OD86], the entire irradiated Charpy curve can be predicted knowing only the change in yield strength due to irradiation and the unirradiated Charpy curve.This procedure was woxked in reverse using the irradiated Charpy curve and the change in yield strength.The measured slope of the irradiated Charpy curve is 0.539 ft-lb/'F which is in good agreement with the irradiated data as shown'n Figure 2-2.The calculated slope of the unirradiated transition region is 0.645 ft-lb/'F, which is slightly larger than the irradiated curve, as expected.The third step of the RTQT analysis calls for an assessment of the statistical 954 confidence band (2u)E for energy measurement at the 50 ft-lb.level.Two separate calculations were performed.

The first approach uses the 2'ariation in energy at the 50 ft-lb.level.This results in: 2aE(fit)=13.5 ft-lb.The second approach consists of an assessment of the 954 confidence in the experimental data.This approach yields: 2v~(experimental)

=12.0 ft-lb.The procedure defines 2@~as the larger of 20E (fit)and 2'~(experimental), with the lower bound being 10 ft-lb.Therefore, for weld W5214/5G13F:

2aE=10 ft-lb.

~e'I VI A.

15 126 I I-100 C9 76 K 4 L 4 Oa A A giikgi gal@r/ra re 4 300--TEST TEMPERATURE (F)NINE INILE POINT UNIT 1~VfELD 52 1 4/661 3F (SURVEILLANCE

%ELD)150 IRRADIATED DATA NEIBULL FIT TRANSITION NEIBULL FIT UPPER SHELF HYPERBOLIC TANGENT FIT CONFIDENCE LIMIT (85%)" CONFIDENCE LIMIT (95%)CONFIDENCE LIMIT (85%)CONFIDENCE LIMIT (95%)UNIRRAOIATED DATA UNIRRADIATED CHABPY CURVE F I GURE 2 2 RTg)7 ANALYSIS FOR SURVE I LLANCE CAPSULE WELD MATERIAL W5214/5G13F

'

16 Since the three data points for weld W5214/5G13F were over 50 ft-lb., the RT~z is taken to be: RT~~(weld W5214/5G13F)

=10'F-60 F=-50'F.In order to demonstrate the validity of the RT~~approach, the Reference[MA85)procedure was followed.In accordance with Step 4, three Charpy specimens with energies in excess of 50 ft-lb.would be expected at a test temperature of 20'F.Therefore, the RTz~using this approach would be-40'F, which is in close agreement and slightly conservative when compared with the measured Charpy data.2.1.3 Summar of Findin s Based on the statistical analysis presented above, a value of o>of 17'F is justified for the beltline welds.An initial RTgQ7 of-50 has been established for weld W5214/5G13F.

Also, unirradiated Charpy indices have been established for the capsule weld material.These data are summarized in Table 2-1..TABLE 2 1

SUMMARY

OF RT ()7~0)AND CHARPY INDICES FOR WELD W5214 5G13F Descri tion cr, RTvov 2G~T3Q unirradiated Upper Shelf Energy (unirradiated)

Best, Estimate Value 17 F-50 F 13.5 ft-lb.-32 F 128 ft-lb.2.2 Beltline Weld Anal sis The RT~~determination for the beltline weld 86054B/4E5F was made as described in Section 2.1 for weld W5214/5G13F L-17 0

17 because the data at+10 are well above 50 ft-lb.However, the calculated RTgQ7 using the[MA85]procedure is-53'F.Since there is a small difference (3'F)between the calculated and experimental value, the RT~~was taken to be-50'F.The data for weldS 1248/4M2F AND 1248/4K13F were above 50 ft-lb.at 1 0 F and theref ol e the Ropy was determined experimenta l 1 y for these materials as well.The results are presented in Table 2-2 and Figure 2-3.TABLE 2 2 RT ()~DATA FOR BELTLI NE WELDS Weld Identification RT or~F 86054B/4E5F 1248/4M2F'248/4K13F 50-50 E'I 18 NINE MILE POINT UNIT I NELD 860548/4ESF 150 125 I I 100 C V5 K 50+UNIRRRDIATED DATA UNIRRADIATED CHARPY CURVE 300 TEST TEMPERATURE (F)F FIGURE 2 3 RT~)~ANALYS I S FOR BELTLINE WELD 8 6 054 B/4E4F L-19 t'

19 3.0 PLATE MATERIAL ANALYSIS 1 In the case of the base metal plates, full unirradiated Charpy curves are available for each beltline plate.The surveillance capsule base metal'pecimens were fabricated from plate G-8-1[MA90).It is possible to calculate a o>for each plate as was done for the irradiated weld.However, a value of a,=0 is recommended for all the plates except G-8-3/G-8-4.

The o<for G-8-3/G-8-4 is taken as 2'F since experimental data was used and conventional ASME test practices followed.Justification of u,=0 for the remaining plates comes from the fact that Manahan's RTz~determination is generally conservative, the T)pg is taken to be a point where the ASME Charpy criterion is expected to be satisfied with high confidence, and the L-T to T-L orientation correction was taken to be 24 F which is 4 F higher than that recommended in Branch Technical Position MTEB 5-2.The value of cr,=2 was obtained by taking the Ropy found using Manahan's method, subtracting the ASME determined Ropy and dividing by 2 (rounding up).The resu l ts of the o', analysis are given in Table 3-1.The RTgpz was determined in a similar manner as described in Section 2.1.2, except that the temperature at which 50 ft-lb.of energy would be obtained in three Charpy specimens could be determined directly from the Charpy curves.First, the unirradiated data was-fit using the SAM McFRAC code.Then, the 954 confidence interval in energy (2cr<)was determined using the more conservative value of either the fit uncertainty at the 50 ft-lb level (2cr~(fit))

or the deviation of the data from the mean in the transition region (2v~(experimental)).

If both of these measures are less than 10 ft-lbs, then 10 ft-lb.was taken as the 2cr<value.Otherwise, the larger of 2az(fit)or 2vz(experimental) was used.The 10

20 ft-lb.uncertainty was judged to be a reasonable and conservative value based on observation of many data sets in the LWR data base.After 2a'~was determined, the temperature, T><<(L-T orientation), at which three Charpy specimens would exhibit 50 ft-lbs of absorbed energy was determined.

This temperature was taken to be the temperature at which the mean Charpy curve minus 50 ft-lbs.equals 2cr~.Once, the T><<temperature is determined, the RTzz (L-T)is taken to be T><<minus 60'F.The Charpy specimens tested for the plate materials had an L-T orientation.

The ASME code requires testing using the T-L orientation because it is the limiting orientation.

General Electric recommends adding 30'F to the RT~~obtained C using L-T specimens.

Similarly, Branch Technical Position MTEB 5-2 recommends adding 20 F.Analysis of the EPRI data base presented in'MA89]indicates that 30'F is appropriate.

Therefore, in the absence of material specific data, MPM Consulting recommends using 30'F.However, reference[MA90]reported an L-T to T-L Charpy curve transition of 24'F at the 30 ft-lb.level.Therefore, based on the material specific data, the L-T to T-L correction used herein was 24'F.The results of the analysis are summarized in Table 3-1 and the McFRAC fits are given in Figures 3-1 through 3-6.

I,kr TABLE 3-1: RT oT~<Tr AND CHARPY INDICES FOR UNIRRADIATED BELTLINE PLATES Descri tion Plate G-8-3 G-8-4 Plate G-8-1 Best Estimate Data Plate G-307-3 Plate G-307-4 Plate G-307-10<7)RT07 (1)RTNoT (2)2<TE T30 2 F-24 F(L-7)-3'F<7-L)11 ft-lb.-26OF<L-7)

O'(7-L)0 F 12 F(L-7)36 F(7-L)10 ft-lb.8 F OF 40F<<-7)F (7 L)11 ft-lb.-14 F 0 F 16 F (L-7)0 F-4 F (L-T)0 F-3 F 40 F (T-L)20 F (7-L)10 ft-lb.10 ft-lb.Upper Shelf Energy ('unirradiated) 96 ft-lb.<L-T) 88 ft-lb.68 f t-lb.(7-L)112 ft-lb.81ft-lb.115 ft-lb.L-T orientation.

P-T calculations require RT+7 to be determined for the T-L orientation.

'T-L orientation.

Obtained by adding 24'F to the L-T orientation data for all plates except G-8-3/G-8-4.

The value was determined experimentally.

(3)Fracture appearance data are not available for any beltline plates.Upper shelf data was identified by the shape of the curve fit.

he'r 22 NINE MILE POINT UNIT I~UNIRRADIATED BASE-METAL G&3/G&4 (0 2)~EXPERIMENTAL DATA 100 CQ I I-U 80 A e A L A+Jl S A A WEIBULL FIT TRANSITION WEIBULL FIT UPPER SHELF HYPER8OLIC TANGENT FIT A A A A A-'I 00-50 0 50'I 00'I 60 200 260 TEST TEMPERATURE (F j CONFIDENCE LIMIT (95%)CONFIDENCE LIMIT (95%)CONFIDENCE LIMIT (95%)CONFIDENCE LIMIT (95%)FIGURE 3-1: CHARPY DATA FIT FOR BASE METAL PLATE G-8-3/G-8-4 L-23

23 NINE MILE POINT UNIT I~UNIRRADIA rPD BASP METAL Q g 3 (QL)(I 2)EXPERIMENTAL DATA 120 100 IXt I I-80 Q eo 40 V 20 A-'IOO-60,0 50 100 160 200 260 TEST TEMPERATURE (F)WEIBULL FIY TRANSITION HYPERBOLIC TANGENT FIT CONFIDENCE LIMIT (95%)CONFIDENCE LIMIT (95%)CONFIDENCE LIMIT (95%)CONFIDENCE L'IMIT{95%)FIGURE 3-2: CHARPY DATA FIT FOR BASE METAL PLATE G-8-3/G-8-4 (T-L)L-24

24 NINE MILE POINT UNIT I~UNIRRADIATED BASE'ETAL G-8-'I (l,2)EXPERIMENTAL DATA CZ0 400 Ql I IL 80 C eO ILI 40 V zo-.'IOQ-50 0 50'I 00 160 200 260 TEST TEMPERATURE (F)WEIBULL FIY TRANSITION HYPERBOLIC TANGENT FIT CONFIDENCE uMn (95%)CONFIDENCE uMn (95%)CONFIDENCE LIMIT (95%)CONFIDENCE uMn'95%)Fj:GURE 3-3: CHARPY DATA FIT FOR BASE METAL PLATE G-8-1 L-25

'C NINE MILE POINT UNIT I~UNIRRADIATED BASE lNETAL G-30V-3 (1 a)~EXPERIMENTAL DATA'I 00 I I 80 C 60 40 V 20 L L SL l~I PA 0-100-50 0 50'I 00'I 50 200 260 TEST TEMPERATVRE (F j WEIBULL Fl'Y TRANSITION HYPERBOLIC TANGENT FIT CONFIDENCE LIMIT (95%)CONFIDENCE LIMIT (95%)CONFIDENCE LIMIT (95%)CONFlD ENCE LIMIT (95%)FIGURE 3-4: CHARPY DATA FIT FOR BASE METAL PLATE G-307-3

26 NINE INILE POINT UNIT 1~UNIRRADIATEP BASE METAL g 307 4 (1 1)~EXPERIMENTAL DATA 120 CQ 100 I I LL 80 40 V 20 L A C J L L AIL<WEIBULL FIT TRANSITION WEIBULL FIT UPPER SHELF HYPERBOLIC TANGENT FIT CONFIDENCE uMn.(95%)CONFIDENCE LIMn (e5%)CONFIDENCE uMn (95%)0 CONFIDENCE

-100-50 0 50 100 15Q 200 250 LIMIT (95%)TEST TEMPERATURE

{F)FXGURE 3-5: CHARPY DATA FIT FOR BASE METAL PLATE G-307-4 L-27 ll 0 27 NINE MILE POINT UNIT 1~UNIRRADIATED BASE METAL Q-307-10 (1,2)EXPERIMENTAL DATA 120 WEIBULL FIY TRANSITION 100 I I-80 C 60 gk 0~0 J'-100-50 0 50'I 00 150 200 250 TEST TEMPERATURE (F)HYPERBOLIC TANGENT FIT CONFIDENCE uMn (95%)CONFIDENCE LIMIT (95%)CONFIDENCE LIMIT (95%)CONFIDENCE uMn (95%)FIGURE 3-6: CHARPY DATA FIT FOR BASE METAL PLATE G-307-10 L-28

28

4.0 CONCLUSION

S The following RT~z results were obtained: Plate G-8-3/G-8-4 G-8-1'-307-3 G-307-4.G-3 07-.10 RT~pz (T L)oF 36 28 40 20 C)oF Weld W5214/5G13F 86054B/4E5F 1248/4K13F 1248/4M2F RTunz oF-50-50-50-50 0)oF 17 17 17 17 The data reported here was compared with the calculations re-*ported in, reference[MA90a].The surveillance welds for Oyster Creek and NMPl are identical.

Also, the beltline welds 1248/4M2F and 86054B/4E5F are the same fox the two plants.The RT+z results for the surveillance weld and weld 1248/4M2F were exactly the same for the two plants, and the RT+zs for weld 86054B/4E5F differed by only 8'F using the[MA85]procedure.

Thus, the agreement for the two independent calculations was quite good.The weld RT~zs are also consistent with the generic RT~z value of-56'F reported in[BY90].In addition to firmly establishing the RT~z for all of the beltline materials, a further benefit of this analysis has been the determination of the surveillance weld T>Q and USE.Up to the resent, the weld surveillance data has been of little value since 0

29 the 4T>0 and 4USE cannot be calculated.

However, the calculations reported herein have determined the unirradiated Tzo to be-32'F and the USE to be 128 ft-lb.In the future, consideration should be given to obtaining a cooperative agreement with GPU Nuclear to share surveillances data for NMP1 and Oyster Creek.These two units are of the same design and vintage and have several identical materials.

The two data bases can be combined to yield accurate plant-specific trend curves.Also, it would be desirable in the future to anneal the surveillance weld material and directly measure the Charpy properties of the material.These data could be used to verify the calculations and possibly reduce the uncertainty in the models.L-30

30

5.0 REFERENCES

[BY90]Byrne, S.T.,"Niagara Mohawk Power Corporation Nine Mile Point Unit 1 Reactor Vessel Weld Materials", Report No.86390 MCC 001 g 6/13/90~[MA87]Manahan, M.P., BCD-763-87-1,"Surveillance Capsules A'nd C'or Nine Mile Point Unit 1", Final Report from Battelle to Niagara Mohawk, September 30, 1987.[MA85]Manahan, M.P.,"Procedure for the Determination of Initial RT~~in Cases where Limited Baseline Data are Available", 11/85[MA85a]Manahan, M.P., Quayle, S.F., Rosenfield, A.R., and Shetty, D.K.,<<Statistical Analysis of Cleavage-Fracture Data", Invited paper, Conference Proceedin s of the International Conference and Exhibition on Fati ue, Corrosion Cracking, Fracture Mechanics, and Failure Analysis, Salt Lake City (December 2-6, 1985).[MA89]Manahan, M.P.,"A Statistically Based Procedure for Determination of RT~~When Limited Materials Data are Available", in preparation for The Journal of Nuclear Technology.

[MA90]Manahan, M.P., NMEL-90001,"Nine Mile Point.Unit 1 Surveillance Capsule Program", Final Report from Penn State/Battelle to Niagara Mohawk, December, 1990.[MA90a]Manahan, M.P.,"RT~~and cr, Analysis for the Oyster Creek Nuclear Generating Station Pressure Vessel Beltline Materials", Final Report to GPU Nuclear Corporation, April 11, 1990.

-[McFRAC)Manahan, M.P., et.al.,"Statistical Analysis Methodology for Mechanics of Fracture", Final Report to Battelle's Corporate Technology Development Office, 1984[OD86]Odette, G.R., Lombrazo, P.M.,"The Relation Between Irradiation-Hardening and Embrittlement of Pressure Vessel Steels", Proceedings of the 12th ASTM Symposium on the Effects of Irradiation on Materials, 1986[RG1.99]Regulatory Guide 1.99, Revision 2,"Radiation Embrittlement of Reactor Vessel Materials", May, 1988 L-32