Background

Scope IV Results V Conclusions VI References 10

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Proprietary Information LIST OF TABLES Number Title ~Pa e

'Nickel Content for Coiled Wire Electrode Weld Deposits Weld Seams and Consumables Using [Adcom] Heat ¹A8746 12 Copper Analysis Results for Weld Wire Heat ¹A8746 13 Weld Deposit Copper Content for [Adcom] Wire Heats Weld Seams and Consumables Using [Reid Avery] Heat ¹34B009 15

'opper Content Analysis Results for Weld Wire Heat ¹34B009 16 Weld Deposit Nickel Content with Cold Nickel Feed 17 Nickel Content for Heat ¹34B009 with Cold Nickel Feed and Linde 1092 Flux 18 Best Estimate Copper and Nickel Content for Vessel Welds 19

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Proprietary Information I. INTRODUCTION This report presents the results of a task undertaken for the Combustion Engineering Owners Group (CEOG) to provide the basis for the copper and nickel content of reactor pressure vessel welds made using two specific heats of weld wire. These heats are common to beltline welds in several reactor vessels fabricated by ABB/CE in Chattanooga, Tennessee. The as<eposited welds were not always analyzed explicitly for copper or nickel during fabrication because the significance of those chemical elements to irradiation embrittlement was not then recognized. Subsequent efforts to.estimate the as-deposited weld chemistry from limited data sometimes have resulted in different values for the same weld consumables. The purpose of this evaluation is to utilize a broad set of chemical analysis results in conjunction with information from material specifications to establish a consistent and viable basis for the as-deposited weld chemical content for four specific reactor pressure vessels involving two heats of weld wire.

II. BACKGROUND Submittals were made in December 1991 to the Nuclear Regulatory Commission (NRC) in response to 10 CFR 50.61, "Fracture Toughness Requirements for Protection Against Pressurized Thermal Shock (PTS) Events" (Federal Register, v.5694, page 22304, May 15, 1991). The NRC expressed concern regarding the consistency and credibility of data used as the basis for PTS submittals, especially with respect to chemical content. Two or more licensees have reported different copper or nickel contents for reactor vessel welds for which an identical heat of weld wire was used. These differences arose in part because of the way multiple analyses were handled, the type of estimation methods used by licensees, or the degree to which data traceability was established.

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Proprietary Information The PTS submittal of one CEOG licensee was questioned by the NRC regarding the copper and nickel content of a vessel beltline weld formed using weld wire heat number A8746. This same weld wire heat was also used for two other CEOG licensees'essel beltline welds. The same copper content (a single measurement, not an average) was reported by all three licensees, but different nickel contents were reported. An initial response to the question was prepared based on a review of fabrication records, procedures and specifications as described in the results section.

This report builds upon that initial review using chemical analysis data representative of weld wire specifications and weld procedures employed by ABB/CE.

NRC guidance for determination of copper and nickel content is contained in 10 CFR 50.61, "Fracture Toughness Requirements for Protection Against Pressurized Thermal Shock Events". Four alternatives are available to obtain bestmtimate copper and nickel values for the plate or forging, or for weld samples made with the weld wire heat number that matches the critical vessel weld as follows:

(1) The mean of the measured values, or, if these values are not available, (2) the upper limiting values in the material specifications to which the vessel was built, or if not available, (3) conservative estimates (mean plus one standard deviation) based on generic data from reactor vessels fabricated in the same time period to the same material specifications, ifjustification is provided.

(4) If none of the first 3 alternatives are available, 0.35% copper and 1.0% nickel must be assumed.

The preceding guidance was employed in this evaluation.

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Proprietary Information III~ SCOPE The objective of this evaluation is to provide best estimate values of copper and nickel content for weld deposits produced using the following materials:

[Adcom HiMnMo] weld wire heat A8746 and Linde 124 fiux

2. [Reid Avery HiMnMo] weld wire heat 34B009 and Linde 124 or 1092 flux

3. [Reid Avery HiMnMo] weld wire heat 34B009 with Ni-200 cold wire feed and Linde 1092 flux The preceding materials were used to fabricate reactor vessel beltline welds in Calvert Cliffs Unit 2, St. Lucie Unit 1, Millstone Unit"1, and Millstone Unit 2. The .

guidelines contained in 10 CFR 50.61 are followed to provide those best estimates.

The approach taken is to review ABB/CE welding procedures and specifications, to collect chemical analysis results specific to the three weld materials noted, and to collect chemical analysis results for comparable and contrasting weld materials. This information is then evaluated to determine the best estimate value for:

the nickel content of [HIMnMo] wire weld deposits, specifically heats

¹A8746 and 34B009,

2. the copper content of [Adcom] wire weld deposits, specifically heat

¹A8746

3. the copper content of [Reid Avery] heat ¹34B009.weld deposits, and the nickel content of [Reid Avery] heat ¹34B009 plus Ni-200 cold wire feed weld deposits.

In this evaluation, chemical analysis results were obtained from weld deposits fabricated using Linde 0091, 1092, 124 and 80 fluxes. The toughness properties of welds made using Linde 0091, 1092 and 124 fluxes have been previously shown to be

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Proprietary Information comparable'". [Flux type is known to affect certain chemical elements, but nickel and copper contents in the weld deposit have not been found to be substantially affected by fiux'ype for Linde 0091, 1092 and 124 for a given heat of weld wire"'.] There is insufficient information from ABB/CE fabrication records to draw similar conclusions regarding Linde 80 flux welds. Therefore, copper and nickel analysis results from Linde 80 flux welds will be considered for information only.

IV. RESULTS

1. Welding Procedures and Specifications ABB/CE fabricated many reactor pressure vessels using automatic submerged

. arc welding. [Type Mil-B4 electrode wire specifications (see MIL-E-18193A, Military Specification, "Electrodes, Welding, Carbon Steel and Alloy Steel, Base, Coiled," July 23, 1957) were used as the basis for ABB/CE procurement of the filler wire. In this report, the terminology "wire type" is used to represent the broad classification of weld filler material: Mil-B4 of Mil-B4 Modified (Mil-B4 Mod). The terminology "specification" is used to represent I

the specific classification of weld filler material: HIMnM, MnMoNi, MnMo, or Low Cu-P. The terminology "supplier designation" is used to represent the specific compositional classification of wire provided by the supplier to meet the CE specification: HiMnMo, MnMoNi or Low Cu-P. ABB/CE purchase specifications in place between 1965 and 1971 called for several groups of coiled electrodes differentiated by the manganese (Mn), molybdenum (Mo) and nickel (Ni) content: k

~Wire T e Mil-B4 Mod S~

ABB/CE HiMnMo Specified Nickel Content Supplier

~Desi nation HiMnMo Mil-B4 Mod MnMoNi 0.90 to 1.10% MnMoNi Mil-B4 MnMo HiMnMo Mil-B4 Mod MnMoNi 0.65 to 0.85% MnMoNi Mil-B4 Low Cu-P Low Cu-P

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Proprietary Information Only'n the case of the wire designation MnMoNi was any nickel required (specified by CE) to be included in the wire. Note also that Mil-B4 Modified was originally specified by CE as either HiMnMo or MnMoNi. In subsequent specifications, Mil-B4 Modified referred only to MnMoNi wires with nominally 0.75% or 1.00% nickel, and Mil-B4 referred only to HiMnMo, MnMo, or Low Cu-P wires which all had no nickel specified.

The suppliers of coiled wire electrodes typically used the designations as indicated above on their certiftcations. Supplier certifications and weld material release reports (generated by ABB/CE upon receipt of the wire) included nickel content only for the MnMoNi wires, i.e., the nickel was determined only where it was specified. Weld material certification tests (weld deposits) and actual vessel weld deposit analyses generally included an analysis for nickel only when MnMoNi wires were utilized or when the vessel equipment specification called for a nickel analysis, Nickel was not intentionally added to a heat because of the extra expense to the wire supplier.

Therefore, the nickel content for a HiMnMo or a MnMo wire is expected to be low (significantly less than 0.75%).]

2. Observed Nickel Content of [HiMnMo and MnMoNi] Coiled Wire Electrode Weld Deposits

[The nickel content of welds deposited using HiMnMo heats "¹A8746 and

¹34B009 is not available from ABB/CE weld deposit analysis records.

However, nickel content was determined for other HiMnMo heats and for many MnMoNi heats. [Note: welds fabricated using a Ni-200 cold wire addition are not included in the discussion which follows.] A search was "

performed of ABB/CE weld receipt and weld deposit analysis records for the years 1965 to 1971, and a list was compiled of each analysis that included nickel content. For each analysis with a reported value of nickel, the supplier

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Proprietary Information designation and wire supplier is noted as shown in Table I; multiple analyses on a single heat are grouped together. The mean and standard deviations described below are based on the average nickel for each heat, whereas the ranges reflect all reported nickel values within each set of wires.

The MnMoNi wires fall within two ranges of nickel, 0.59 to 0.82% Ni and 0.89 to 1.10% Ni. The corresponding mean and standard deviation are:

mean = 0.706% Ni, o' 0.051% Ni mean = 0.990% Ni, u = 0.069% Ni These correspond well to the two specification levels of 0.75% and 1.00% Ni discussed in the previous section.

For the HiMnMo wires, nickel content is in the range of 0.01 to 0.16%. The mean nickel value for the 16 heats is 0.058% with a standard deviation of 0.037% Ni, It is clear from the HIMnMo data that nickel was not intentionally added to the original heats from which the electrode wires were drawn. Therefore, for the HiMnMo heats ¹A8746 and ¹348009, a conservative best estimate (mean plus one standard deviation) of the nickel in the weld deposit is 0.10% Ni.]

3. Copper Content of Weld Deposits Using Wire Heat ¹A8746

[Weld wire heat ¹A8746, a HiMnMo coiled electrode supplied by Adcom, was used to fabricate the weld seams described in Table 2. In each case, the submerged arc welding was performed using Linde 124 flux.

Two separate weld deposit chemical analyses were performed which involved heat ¹A8746 as described in Table 3. Only one of the analyses relates directly to the four weld deposits listed in Table 2. Each of the vessel welds were

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Proprietary Information deposited using Linde 124 flux, whereas only one of the chemical analyses reflected a Linde 124 flux weld. Therefore, the Linde 80 weld deposit analysis can only be used for information.

The Linde 124 flux weld deposit analysis resulted in a copper content of 0,12% using Adcom weld wire heat A8746. In order to judge the viability of the 0.12% copper value, a compilation was made of weld deposit copper contents of other Adcom heats which is given in Table 4. Treating each copper analysis as independent (i.e., assuming that each reflects results from a unique coil), the mean copper content is 0.20%, the standard deviation is 0.036%, and the range is 0.12 to 0.27%. The data include seven different heats or combinations of heats, four different types of flux, two different wire specifications, and a 29 month time period over which wire was procured and analyses were performed. Therefore, the 0.036% standard deviation for copper reflects heat-to-heat and coil-to-coil variations as well as the influence t

of weld flux and the time dependence of the copper coating process on weld deposit copper content. In other words, since the standard deviation represents many Adcom wire heats and other factors, the 0.036% copper (one standard deviation) should conservatively represent the copper variability of welds deposited using a single heat of Adcom wire, heat PA&746.

Comparison of the data from Table 3 and Table 4 indicates that the range of available measurements specific to heat PA8746, 0. 12 to 0.17% copper, is within the range of the seven different Adcom supplied heats and combinations of heats. Furthermore, the mean of the two A8746 analyses, 0.145% Cu, is within one standard deviation of the single Linde 124 weld deposit analysis (0.036% plus 0.12% equals 0.156% Cu). Therefore, a conservative best

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Proprietary Information estimate of the copper content of the welds described in Table 2 is 0.16%

based on the heat-specific measurement and the standard deviation for generic Adcom wire heat data.]

4. Copper Content of Weld Deposits Using Wire Heat ¹348009

[Weld wire heat ¹348009, a HiMnMo coiled electrode supplied by Reid Avery, was used to fabricate the weld seams described in Table 5, The submerged arc welding was performed using either Linde 124 or Linde 1092 flux.

Nine chemical analyses involving heat ¹348009 are described in Table 6. The first two entries are laboratory experiment results and, therefore, are not representative of production weld deposits. Four entries are analysis results from samples extracted from a H.B. Robinson Unit 2 (HBR-2) reactor vessel head weld. Three entries are analysis results for the Millstone Unit 1 (MP-1) surveillance weld performed for EPRI and General Electric. The seven representative measurements were from welds deposited using Linde 1092 flux, and the two experimental analysis results were from welds deposited using Linde 1092 or Linde 124.

The Linde 1092 flux weld deposit analyses resulted in a mean copper content of 0.19%. This mean of measured values is directly applicable to the Millstone Unit 1 weld described in Table 5. Given that the weld flux does not affect the copper content significantly (see Section III), the 0.19% mean copper is also applicable to the St. Lucie Unit 1 weld described in Table 5 which was deposited using Linde 124 flux.]

5. Nickel Content of Weld Deposits Using Wire Heat ¹348009 and a Cold Nickel Wire Feed

[The Millstone Unit 1 weld described in Table 5 was fabricated using a cold nickel

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Proprietary Information wire feed in addition to the electrode wire heat ¹34B009. Therefore, the nickel 4

content of that weld would be greater than normal for a HiMnMo wire weld deposit without the nickel feed wire (as discussed in Section IV.2).

Table 7 presents 24 sets of data on the nickel content of welds deposited using RACO-3 (Reid Avery) wires, Ni-200 wire (cold nickel feed) and Linde 1092 flux.

Only two different wire heats, singly or in tandem, were used. The mean nickel content is 1.065% and the range is 0.72% to 1.21% Ni.

Table 8 presents nickel content associated with the Table 6 data in which heat

¹34B009 was used with Ni-200 wire and Linde 1092 flux. All but two of the nickel contents specific to heat ¹34B009 are within the range of the data from Table 7. The average of the three MP-1 surveillance weld values is 0.94% Ni, and the range is 0.81 to 1.03% Ni. The average of the MP-1 and the two in-range HBR-2 values is 0.88% Ni, and the range is 0.75 to 1.03% Ni for the welds deposited with heat

¹34B009. The 0.88% Ni represents the mean of measured values for weld deposits formed using heat ¹34B009 with a cold nickel wire feed. However, given the higher mean of the generic data (Table 7), a more conservative estimate of the heat-specific weld nickel content is 1.03%, the upper bound of the data from Table 8.]

V. CONCLUSIONS PVelds deposited by Combustion Engineering using HiMnMo coiled wire electrodes yield a mean nickel content of 0.058% with a standard deviation of 0.037%.

Therefore, a conservative estimate (mean plus one standard deviation) of nickel content in such welds is 0.10% Ni.]

2. [Welds deposited using Adcom Heat ¹A8746 (HiMnMo) and Linde 124 flux are conservatively estimated to contain 0.16% Cu and 0.10% Ni.]

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Proprietary Information

[The welds deposited using Reid Avery Heat ¹34B009 (HiMnMo) with Linde 124 or Linde 1092 flux are estimated to contain 0.19% Cu based on the mean of measured values, and conservative estimates of nickel content are 1.03% Ni with a Ni-200 wire addition and 0.10% Ni without a Ni-200 wire addition.]

These best estimate chemical contents are summarized in Table 9 for the welds described in Tables 2 and 5.

VL REFERENCES

1. "Evaluation of Pressurized Thermal Shock Effects due to Small Break LOCA's with Loss of Feedwater for the Combustion Engineering NSSS," Combustion Engineering Report CEN-189, December 1981.

2. "Application of Reactor Vessel Surveillance Data for Embrittlement Management,"

Combustion Engineering Owners Group Report CEN-405-P (Draft Revision 2),

December 1992.

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Proprietary Information TABLE 1 Nickel Content for Coiled Wire Electrode Weld Deposits Supplier Wire Nickel

~Desi nation ~Sn lier ~Content e HiMnMo Page 0.03, 0.05 HiMnMo Page 0.02, 0.02 HiMnMo Page 0.01, 0.03, 0.03 HiMnMo Page 0.03, 0.03, 0.04, 0.04, 0.05, 0.07, 0.11 HiMnMo Page 0.02, 0.03, 0.03, 0.03, 0.03, 0.04, 0.04, 0.05 HiMnMo Page 0.02, 0.03, 0.03, 0.03 (Not Reported) Page 0.03, 0.03 HiMnMo (Not Reported) 0.05 HiMnMo Page 0.06 HiMnMo Reid Avery 0.08, 0.09 HiMnMo Reid Avery 0.07, 0.08, 0.12 HiMnMo Reid Avery 0.16, 0.16 HiMnMo Reid Avery 0.04 HiMnMo Reid Avery 0.03, 0.06, 0.07 HiMnMo Reid Avery 0.10, 0.11 HiMnMo Reid Avery 0.05, 0,05, 0.06 MnMoNi Adcom 0.74 MnMoNi Adcom 0.73, 0.74 MnMoNi Page 0.64, 0.68, 0.68, 0.70, 0.71 MnMoNi Adcom 0.59, 0.61, 0.72, 0.72 MnMoNi Reid Avery . 0.59, 0.60, 0.62, 0,64, 0.64 MnMoNi Reid Avery 0.64, 0.64, 0.64, 0.66 MnMoNi Adcom 0.73 MnMoNi (Not Reported) 0.69 MnMoNi Reid Avery 0.73, 0.74 MnMoNi Reid Avery 0.69, 0.72, 0.72, 0.73, 0.74, 0.76, 0.81 MnMoNi Reid Avery 0.75, 0.78, 0.79, 0.80, 0.82 MnMoNi Adcom 1.00, 1.01 MnMoNi Adcom 1.02, 1.03, 1.03, 1.04, 1.04, 1.05, 1.05, 1.05, 1.08 MnMoNi Adcom 0.96, 1.00(4), 1.02(2), 1.06(2), 1.10 MnMoNi (Not Reported) 0.89

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Proprietary Information TABLE 2 Weld Seams and Consumables Using [Adcom Heat] PA8746

[(HiMnMo)]

Weld Procedure Reactor Vessel Weld Seam No ote 1 Weld Flux T e ~Sufi Calvert Cliffs Unit 2 2-203 A,B,C Linde 124 SAA-4-0 St. Lucie Unit 1 2-203 A,B,C (Note 2) Linde 124 SAA-4-0 Millstone Unit 2 2-203 A,B,C Linde 124 SAA-4-0 3-203 A,B,C Linde 124 SAA-MA-501-2 Note 1: All of the weld seams listed were deposited without a cold nickel wire feed.

Note 2; Weld wire heat ¹34B009[(Reid Averyi]was also used with heat ¹A8746 to deposit the weld seams in a single are process.

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Proprietary Information TABLE 3 Copper Content Analysis Results for Weld Wire Heat ¹A8746 KAdcom HiMnMo)]

of Anal sis Date Flux /Lot No. ~Co euro Weld Deposit 8/19/69 Linde 80/¹8651 0.17 Weld Deposit . 8/27/69 Linde 124/¹3878 0.12

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Proprietary Information TABLE 4 Weld Deposit Copper Content for [Adcom] Wire Heats Supplier Flux 'Copper

~Desi nation ~Te ~Content o HiMnMo Linde 124 0. 12 (Note A)

HiMnMo Linde 80 0.17 (Note A)

MnMoNi Linde 0091 0.16 MnMoNi Linde 1092 0.16, 0.20 MnMoNi Linde 1092 0.18, 0.19, 0.20(2), 0.21(2), 0.22(2), 0.24, 0.25 MnMoNi Linde 1092 0.22 MnMoNi Linde 1092 0.22 (Note B)

MnMoNi Linde 1092 0.27 (Note B)

Note A - From Table 3 Note B - Combination of two Adcom heats in weld deposit

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Proprietary Information TABLE 5 Weld Seams and Consumables Using [Reid Avery] Heat ¹34B009

[(HiMnMo)]

Weld Procedure eactor Vessel Weld Seam No. Weld Flux T S N St. Lucie Unit 1 2-203 A, B, C (Note 1) Linde 124 SAAMO Millstone Unit 1 3-073 (Note 2) Linde 1092 SAA-33-J(1)

Note 1: Weld wire heat ¹A8746 [(Adcom)] was also used with heat ¹34B009 to deposit the weld seams in a single arc process. A cold nickel wire feed was not used.

Note 2: The weld process included the addition of a cold nickel wire feed.

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Proprietary Information TABLE 6 Copper Content Analysis Results for Weld Wire Heat 434B009 T~IA I I Tl ~T C~C Source Weld Deposit Linde 1092 0.15 CE Lab Experiment Weld Deposit Linde 124 0.17 CE Lab Experiment Weld Deposit Linde 1092 0.180 HBR-2 Head Sample Weld Deposit Linde 1092 0.182 HBR-2 Head Sample Weld Deposit Linde 1092 0.183 HBR-2 Head Sample Weld Deposit Linde 1092 0.202 HBR-2 Head Sample Weld Deposit Linde 1092 0.18 MP-1 Surveillance Weld (EPRI)

Weld Deposit Linde 1092 0.19 MP-1 Surveillance Weld (EPRI) II Weld Deposit Linde 1092 0.18 MP-1 Surveillance Weld (GE Report NEDC-30299)

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Proprietary Information TABLE 7 Weld Deposit Nickel Content with Cold Nickel Feed Source Nickel Content o Mixed Reid Avery Heats, Linde 1092 1.06, 1.03, 1.15, 1.16, 1.15, 1.08, flux and Ni-200 wire 1.03, 1.06, 1.06, 1.04, 1.10, 1.01, 1.04, 1.15, 1.07 Single Reid Avery Heat, Linde 1092 0.99, I. 12, 0.92, 0.94 (Note 1),

fiux and Ni-200 wire 1.115 (Note 2), 1.05, 1.20, 0.97 Note 1: Average of 20 analyses from single weld, with a range of 0.72 to 1.08% Ni.

Note 2: Average of 2 analyses from one surveillance program weld (1.02 and 1.21% Ni).

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Proprietary Information TABLE 8 Nickel Content for Heat 0'34B009 with Cold Nickel Feed and Linde 1092 Flux Nickel Content Source 0.75 HBR-2 Head Sample 0.32 HBR-2 Head Sample 0.84 HBR-2 Head Sample 0.43 HBR-2 Head Sample

" 0.81 MP-1 Surveillance Weld (EPRI) 0.98 MP;1 Surveillance Weld (EPRI) 1.03 MP-1 Surveillance Weld (GE Report NEDC-30299)

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Proprietary Information TABLE 9 Best Estimate Copper and, Nickel Content for Vessel Welds

~Content e Reactor Vessel Weld Seam No. Cu Ni Calvert Cliffs Unit 2 2-203 A,B,C 0.16" 0.10 St. Lucie Unit 1 2-203 A B Ctt) 0.16 0.10 2-203 A,B,Ct') 0.19 0.10 Millstone Unit 2 2-203 A,B,C 0.16 0.10 3-203 A,B,C 0.16 0.10 Millstone'nit 1 3-073 0.19 1.03 Notes e

(1) Chemical content contribution from wire heat PA8746 (2) Chemical content contribution from wire heat 034B009

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Docket No. 50-335 and 50-389 ~

Generic Letter 92%1 Revision 1 FPL Letter L-93-286 Enclosure 1 10 CFR 2.7SO INFORMATION September 28, 1993 EXEMPT FROM DISCLOSURE F-MECH-93-050 .

Cobol ol I MECH-93-015 Mr. R. Scott Boggs Florida Power & Light Company P.O. Box 1400 Juno Beach, FL 33408-0420

Subject:

Upper Shelf Energy Information Pertaining to the St. Lucie Unit 1 and ~

Unit 2 Reactor Vessel Welds.

Appendices: A) Certified Material Test Reports Pertinent to St. Lucie Unit 2 Attachments: "Atypical Weld Material In Reactor Pressure Vessel Welds; Information Requested by Nuclear Regulatory Commission Inspection & Enforcement Bulletin No. 78-12", Prepared By Combustion Engineering Inc., dated June 8, 1979.

Dear Mr. Boggs:

The purpose of this report is to provide upper shelf energy (USE) information on beltline welds for Florida Power and Light Company (FP&L), St. Lucie Units 1 and 2 reactor vessels. This information is required by FP&L in order to respond to a NRC request for additional information associated with Generic Letter 92-01 (Ref 1) as described in References 2 and 3.

Additionally, two copies of the Combustion Engineering Document "Atypical Weld Material In Reactor Pressure Vessel Welds" are included as requested in Reference 3.

Please recognize that this letter report, including Appendix A, contains proprietary information and is not to be transmitted or reproduced without specific written approval from Combustion Engineering, Inc. The Attachment "Atypical Weld Material In Reactor Pressure Vessels", is not proprietary because it was publicly released in the past.

1.0 St. Lucie Unit 1:

1.1 Barrack round The St. Lucie Unit 1 reactor vessel intermediate shell longitudinal seam welds (2-203 A,B,C) were fabricated using wire heat numbers A8746 and 34B009 and Linde 124 Flux lots 3878 and 3688 respectively based upon input provided by FP&L and repeated in Reference 2. The initial Charpy upper shelf energy (USE) for this weld was not ABB Combustion Engineering Nuclear Power Combustion Engineering, tnc. 1000 Prospect Hitl Road Telephone (203) 688 1911 Post Otfice Box 500 Fax (203) 285-9512 Windsor, Connecticut 060954500 Tetex 99297 COMBEN WSOR

PROPRIETARY INFORMATION COMBUSTION ENGINEERING, INC.

Mr. Scott Boggs F-MECH-93-050 September 28, 1993 I MECH-93-015 Page 2 of 10 determined at the time of manufacture, nor is such data known to be available from other sources (e.g., surveillance program welds) for the aforementioned welding consumables.

The NRC has stated that an acceptable approach for satisfaction of 10CFR50, Appendix G requirements for initial USE is to use the average value from similarly fabricated welds (Ref 1); in this case, from USE measurements on submerged arc welds produced using MIL-B4 wire and Linde 124 Flux.

1.2 ~Sco e This report provides a basis for the initial upper shelf energy for weld wire heat numbers A8746 and 34B009 fabricated with Linde 124 flux using USE data from welds fabricated with Linde 124 flux.

1,3 Procedure Weld material certifications (WMC) (Ref 4) at the ABB Combustion Engineering facility in Chattanooga, Tennessee were searched to obtain Charpy impact test data specific to Linde 124 flux welds. The WMCs were compiled and the initial USE determined from the Charpy impact data in accordance with the definitions provided in ASTM E185-82 (Ref 5). The primary definitions necessary to establish the upper shelf energy are provided as follows:

1.3.1 Upper Shelf Energy is defined as the average energy value for all Charpy specimens (normally three) whose test temperature is above the upper end of the transition region. For specimens tested in sets of three at each test temperature, the set having the highest average may be regarded as defining the upper shelf energy (Ref 5),

1.3.2 Charpy Transition Curve is defined as a graphic presentation of Charpy data, including absorbed energy, lateral expansion and fracture appearance, extending over a range including the lower shelf energy (<5% shear), transition region and the upper shelf energy () 95% shear) (Ref 5).

1.3.3 Transition Region is defined as the region on the transition temperature curve in which toughness increases rapidly with rising temperature. In terms of fracture appearance, it is characterized by a rapid change from a primarily cleavage (crystalline) fracture mode to primarily shear fracture mode (Ref 5).

Charpy test data for each weld wire heat and flux lot combination showing a fracture appearance of 95% shear or greater were compiled. The Charpy tests tended to be conducted in sets of three over a range of test temperatures. This allowed each set of

PROPRIETARY INFORMATION COMBUSTION ENGINEERING, INC.

Mr. Scott Boggs F-MECH-93-950 September 28, 1993 L-MECH-93-015 Page 3 of 10 three tests to be averaged to determine the USE at a given temperature. The highest averaged USE for each weld wire heat and flux lot combination was taken to be the initial USE for the material and used to determine the best estimate (mean) and standard deviation for welds fabricated using Linde 124 flux. This best estimate can then be used as input for projecting USE after irradiation.

1.4 Results Charpy impact energy data was assessed for 68 different weld wire heat / flux lot combinations to determine the initial upper shelf energy in accordance with ASTM E185-82 definitions (Ref 5). 67 USE values represented the average of three Charpy impact specimens usually tested at a single temperature. The remaining one USE value comes

'from an average of two Charpy specimens tested at 100'F. This USE value was judged to be adequate for the purposes of this analysis and would not significantly alter the results if omitted. All fracture specimens have a fracture appearance showing no less than 95% shear.

The average upper shelf energy for the Linde 124 flux welds is [102.3 ft-lbs with a standard deviation of 9.4 ft-lbs.] The data ranges from [82.7 ft-lb to 125.7 ft-lb.] This represents an average of 68 different weld wire heat / Linde 124 flux lot combinations presented in Table 1.

Table 1: Initial Upper Shelf Energy Values for Linde 124 Welds.

Count Wire Heat / Flux Lot Initial USE ft-lb 1 30502 / 0342 104.3 2 3P7150 / 0662 97.0 3P7150 / 1061 86.0 3P7246 / 0662 97.3 3P7246 / 0951 108.0 3P7246 / 1061 103.7 7 3P7317 / 0281 94.0 3P7317 / 0662 98.3 3P7317 / 0951 102.7 10 3P7317 / 1061 103.0 3P7802 / 0171 109.7

\~

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Mr. Scott Boggs F-MECH-93-950 September 28, 1993 L-MECH-93-015 Page 4 of 10 Count Wire Heat / Flux Lot Initial USE ft-Ib 12 3P7802 / 0281 104.7 13 3P8013 / 0281 93.7 14 3P8013 / 0871 110.0 15 CU3P8013 / 0281 104.7 16 4P6524 /0951 106.3 17 4P7656 / 0951 88.0 18 4P7656 / 1061 91.3 19 4P7869 / 0171 107.7 20 4P7869 / 0281 104.7 21 4P7869 / 0871 93.7 22 4P7869 / 1061 97.3 23 4P7927 / 0662 115.7 4P7927 / 1061 116.3 25 4P8632 / 0281 109.3 26 SP7388 / 0662 107.7 27 SP8866 / 0171 91.3i 28 SP8866 / 1061 107.7 SP9028 / 0281 96.7 30 651A708 / 0281 94.0 31 651A708 / 0871 96.3 32 90071 / 0951 112.7 33 83637 / 0951 116.7 34 83646 / 1061 106.0 35 83653 / 1061 106.7 36 87005 / 1061 90.3 37 89408 / 0751 '110.7 38 89476 / 1061 100.0 39 89827 / 0951 118.3

0~ 4, >>e l H1 1t

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Mr. Scott Boggs F-MECH-93-950 September 28, 1993 L-MECH-93-015 Page 5 of 10 Count Wire Heat/ Flux Lot Initial USE ft-lb 40 89828 / 0281 96.0 41 89828 / 0951 109.3 42 89828 / 1061 104.3 43 89833 / 0871 113.3 89833 / 0951 105.3 45 89833 / 1061 95.7 46 90067 / 0951 124.3 47 90069 / 0951 125.7 48 90069 / 1061 97.6 49 90077 / 0951 115.7 50 90077 / 1061 112.3 51 90128 / 0951 99.3 52 90132 / 0951 115.0 53 90144 / 1061 93.0 54 90146 / 1061 96.7 55 90149 / 1061 94.0, 56 90154 / 0951 102.3 57 90157 / 1061 98.0 58 90159 / 0951 112.7 59 90209 / 1061 100.7 60 90211 / 1061 82.7 61 91762 / 0662 88.0 62 91762 / 1061 100.3 63 E56906 / 0662 89.3 F69025 / 0171 91.0 65 69025 / 1061 88.6 66 LP2P8374 / 0597 98.3 67 LPSP9744 / 0281 109.0

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Mr. Scott Boggs F-MECH-93-950 September 28, 1993 L-MECH-93-015 Page 6 of 10 Count Wire Heat/ Flux Lot Initial USE ft-lb 68 PSP73Sg /0342$ 97.7 Average USE: 102.3 (ft-Ib)

Standard Deviation: 9.4 (ft-ib) 2.0 St. Lucie Unit 2:

2.1 ~Back round The St. Lucie Unit 2 reactor vessel beltline welds were fabricated using the consumable presented in Table 2 based upon input provided by FP8rL and repeated in Reference 2.

The basis for the initial upper shelf energy for these welds was weld material certification tests performed at the time of vessel manufacture (Ref 4).

Table 2: Beltline Weld Wire Consumable used in St. Lucie Unit 2 Seam No. Wire Heat No. Flux Type Flux Lot No.

101-124 A,B,C 83642 Linde 0091 3536 101-124 C (Repair) 83637 Linde 0091 1122 101-142 A,B,C 83637 Linde 0091 1122 101-171 83637 Linde 124 0951 101-171 3P7317 Linde 124 0951 2.2 ~Sco e Weld material certification test reports (WMCs) for the following weld wire heat and flux lots are provided: Wire heat 83642, Linde 0091 flux lot 3536; wire heat 83637, Linde 0091 flux lot 1122; wire heat 83637, Linde 124 flux lot 0951; and wire heat 3P7317, Linde 124 flux lot 0951. Upper shelf energy values for the aforementioned wire/flux combinations will be determined if sufficient information is presented in the WMC.

Where fully applicable information is not available, the degree of applicability will be addressed as per the project proposal (Ref 2) ~

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Mr. Scott Boggs F-MECH-93-950 September 28, 1993 L-MECH-93-015 Page 7 of 10 2.3 Procedure Weld material certifications (WMC) at the ABB Combustion Engineering facility in Chattanooga, Tennessee were searched to obtain Charpy impact test data specific to the consumable presented in Table 2. The WMCs were compiled and the initial USE determined, when possible, from the Charpy impact data in accordance with the definitions provided in ASTM E185-82 (Ref 5) and presented in sections 1.3.1 - 1.3.3.

Where fully applicable information was not available in the WMC (e,g., where percent shear fracture was not reported) the degree of applicability to the Unit 2 weld seam USE is addressed.

2.4 Results Weld material certification (WMC) reports for the weld wire heat / flux lot number combinations presented in Table 2 were obtained from records in possession of Combustion Engineering. The WMCs pertaining to the Linde 124 welds contained enough information to fully determine the initial upper shelf energy values for the consumable used. The WMCs pertaining to the Linde 0091 welds did not contain sufficient information; however, enough information was available to determine a conservative (lower bound) upper shelf energy value relevant to the consumables used.

A copy of the WMCs for the consumables listed in Table 2 are provided in Appendix A, A description of the process used to determine the USE is described for each weld wire heat / flux lot combination as follows:

2.4.1 Wire Heat 83637, Flux Type Linde 124, Flux Lot No. 0951: The WMC pertaining to this combination of weld consumables contains a full array of Charpy tests over a range of temperatures. [The initial upper shelf energy was determined from a set of three Charpy specimens tested at 160'F. All three specimens show a fracture appearance of 100% shear failure and the initial upper shelf energy calculated to be 116.7 ft-lb.]

2.4.2 Wire Heat 3P7317, Flux Type Linde 124, Flux Lot No. 0951: The WMC pertaining to this combination of weld consumables contains a full array of Charpy tests over a range of temperatures. [The initial upper shelf energy was determined from a set of three Charpy specimens tested at 160'F. All three specimens show a fracture appearance of 100% shear failure and the initial upper shelf energy was calculated to be 102.7 ft-lb.]

2.4.3 Wire Heat 83642, Flux Type Linde 0091, Flux Lot No. 3536: The WMC pertaining to this combination of weld consumables contains limited Charpy tests at two test- temperatures and fracture appearance is not recorded. [An average

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Mr. Scott Boggs F-MECH-93-950 September 28, 1993 L-MECH-93-015 Page 8 of 10 Charpy energy at 10'F was calculated from three specimens to be 116.3 ft-lbs.]

This value does not represent an "official" upper shelf energy for these weld consumables because no measurement of the fracture appearance (i.e., % shear fracture) is available. However, this value suggests very good fracture toughness characteristics for the material at 10'F and, therefore, may be used as a lower bound approximation to the initial USE.

2.4.4 Wire Heat 83637, Flux Type Linde 0091, Flux Lot No. 1122: The WMC pertaining to this combination of weld consumables contains limited Charpy tests at 10'F and fracture appearance is not recorded. [An average Charpy energy was calculated from three specimens to be 136.3 ft-lb.] This value does not represent an official upper shelf energy for these weld consumables because no measurement of the fracture appearance (i.e., % shear failure) is available.

However, this value suggests very good fracture toughness characteristics for the material at 10'F and, therefore, may be used as a lower bound approximation to the initial USE.

3.0 CONCLUSION

S:

No information is available to determine the initial upper shelf energy specific to the weld consumables used in the St. Lucie Unit 1 reactor vessel 2-203 A,B,C weldments.

As an alternate approach, a best estimate value of initial USE was calculated using 68 welds fabricated with Linde 124 flux. The best estimate initial USE of these welds fabricated with MII B4 wire and Linde 124 flux was calculated to be [102.3 ft-lb with a standard deviation of 9.4 ft-lb.] This best estimate value can be used as input for projecting USE after irradiation.

Complete or partial information is available to determine the initial upper shelf energy specific to the consumable used in the St. Lucie Unit 2 beltline welds. Weld material certification reports for these materials are provided in Appendix A. Weld wire heat 3P7317 with Linde 124 flux lot 0951 has a calculated initial upper shelf energy value of

[102.7 ft-lb.] Weld wire heat 83637 with Linde 124 flux lot 0951 has a calculated initial upper shelf energy value of [116.7 ft-lb.] Weld wire heat 83637 with Linde 0091 flux lot 1122 has an average Charpy energy at 10'F of [136.3 ft-lb;] weld wire heat 83642 with Linde 0091 flux lot 3536 has an average Charpy energy at 10 F of [116.3 ft-lb.]

These average energies can be conservatively assumed to be a lower bound approximation of the initial upper shelf energy for the two Linde 0091 flux welds.

PROPRIETARY INFORMATION COMBUSTION ENGINEERING, INC.

Mr. Scott Boggs F-MECH-93-950 September 28, 1993 I MECH-93-015 Page 9 of 10 Ifyou have any questions or concerns regarding this information, please feel free to contact me at (203) 285-3794 or Steve Byrne at (203) 285-3469.

Sincerely, COMBUSTION ENGINEERING, INC Davi J. Woodilla Project Engineer Enclosure VERlFlCATION STATUS: COMPLETE

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Mr. Scott Boggs F-MECH-93-950 September 28, 1993 L-MECH-93-015 Page 10 of 10

References:

1. Letter from J. A. Norris (NRC) to J. H. Goldberg (FP&L), dated July 28, 1993, Docket No. 50-335, 50-389.

Subject:

St. Lucie Units 1 and 2 - Request for Additional Information - Generic Letter 92-01, Revision 1 (TAC NOS. M83505 and M83506).

2. ABB/CE Letter No. F-MECH-93-042, "St. Lucie Upper Shelf Energy Evaluation, Proposal No. 93-241-A6A," S. T. Byrne, dated August 27, 1993.

3. Florida Power and Light Company Purchase Order No. B93633-30016, dated August 31, 1993.

4. ABB/CE Letter No. MECH-93-1214, "Weld Material Certification Reports", S. T.

Byrne, dated October 14, 1993.

5. ASTM Designation E 185-82, "Standard Practice for Conducting Surveillance Tests for Light-Water Cooled Nuclear Power Reactor Vessels," Annual Book of ASTM Standards, Vol. 12.02, ASTM, Philadelphia, PA.

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Mr. Scott Boggs F-MECH-93-050 September 28, 1993 L-MECH-93-015 Page A1 of A10 APPENDIX A Certified Material Test Reports Pertinent to St. Lucie Unit 2

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Mr. Scott Boggs F-MECH-93-050 September 28, 1993 L-MECH-93-015 Page A2 of A10 Contents of Appendix A

~Pa e Title A4 Certified Material Test Report for Weld Wire Heat No. 83637 Linde Flux Type 124, Flux Lot No. 0951 A6 Certified Material Test Report for Wire Heat No. 3P7317, Linde Flux Type 124, Flux Lot No. 0951 A8 Certified Material Test Report for Weld Wire Heat No. 83642, Linde Flux Type 0091, Flux Lot No. 3536 A10 Certified Material Test Report for Weld Wire Heat No. 83637, Linde Flux Type 0091, Flux Lot No. 1122.

PROPRIETARY INFORMATION COMBUSTION ENGINEERING, INC.

Mr. Scott Boggs F-MECH-93-050 September 28, 1993 I MECH-93-015 Page A3 of A10 Certified Material Test Re ort for Weld Wire Heat No. 83637 Linde Flux e 124 Flux Lot No. 0951

Mr. Scott Boggs PROPRIETARY INFORMATION F-MECH-93-050 September 28, 1993 COMBUSTION ENGINEERING, INC. I MECH-93-015 Page A4 of A10

"~ PQQJFR SYSTEMS To J. McDowell Sub ject Welding Material Certlficatlon To Requirements of, ASME

'rom Metallurgical Laboratory

- Date

& Materials cc: R. E. Lorentz, Jr. Section III S. R. Lewis Job Number M-32255 Chattanooga S. A. Lewis Project Number 960009 B. Goins 4-22-76 The following test dat s for 3/16" dl eter bare 're, Type Low Cu-Phos, Heat No. 83637, Flux Type 124, Lot No. 09 (Test No. 1824).

A weld deposit was made using the above heat of wire and lot of flux.

Welding was done in accordance with SAA-SMA-511-0. The completed weldment was given a post weld heat treatment of 1150'F + 50'F for 40 hours4.62963e-4 days <br />0.0111 hours <br />6.613757e-5 weeks <br />1.522e-5 months <br /> and furnace cooled to 600 F.

IMPACT AND/OR F RACTUR E TESTS TYPE TEMP OF VALUE TEMP. 0F VALUES NOT CVN ~tJ bs ~her ilsLatEx Dro We laht

-80 21 21 -70 1 F -70 F

-80 26 18 -60 NF

-80 S~ 17 -50 2

1 NF

'40

-40

-40 52

40. '035 42 32

\

55 35 60 40~ +100 112/

6Fg

-108 9 80 72+ +100 100 84 ~

-1oi 94 70 +100 116'17 100/ 8&

+60 105 80 78 +160 .100 90

+60 106 80 ~ 75 +160 120 100 86

+60 108 80 77 +160 113 100 86 ALL'WELD METAL .505 TENSILE Lab Yie ld Streng th Ultimate Tensile Elongation Reduction of C;ode . KS[ Strenath KS 2 41n/ Area %

i'P 69.0 84.3 69.2 JMA:gb

PROPRIETARY INFORMATION COMBUSTION ENGINEERING, INC.

Mr. Scott Boggs F-MECH-93-050 September 28, 1993 L-MECH-93-015 Page AS of A10 Certified Material Test Re ort for Wire Heat No. 3P7317 Linde Flux T e 124 Flux Lot No. 0951

Mr. Scott Boggs PROPRIETARY INFORMATION F-MECH-93-050 September 28, 1993 COMBUSTION ENGINEERING, INC. L-MECH-93-015 pj444 '<<< 52> 3O +100 100< 100> 70

+20 72 60 48 +160 96 100 68

+20 75 . 60 S3~ +160 104 100 73

+20 77 60 51 +160 108 100 79

+60 97 100 66

+60 102 100 70

+60 99 100 68 WELD METAL . 505 TENSILE Lab Yield Strengt Ultimate Tensi Elongation Reduction of Code KS[ Streneth K. in 2 "% Area %

69.5 p 85.5 28.5 69.0 4-(r"J

'

'A'mold JMA:gb

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Mr. Scott Boggs F-MECH-93-050 September 28, 1993 L-MECH-93-015 Page A7 of A10 Certified Material Test Re ort for Weld Wire Heat No. 83642 Linde Flux e 0091 Flux Lot No. 3536

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PROPRIETARY INFORMATION COMBUSTION ENGINEERING, INC.

Mr. Scott Boggs F-MECH-93-050 September 28, 1993 L-MECH-93-015 Page A9 of A10 Certified Material Test Re ort for Weld Wire Heat No. 83637 Linde Flux e 0091 Flux Lot No. 1122.

Mr. Scott Boggs F-MECH-93-050 September 28, 1993 PROPRIETARY INFORMATION L-MECH-93-015 COMBUSTION ENGINEERING, INC. Page A10 of A10 ill I CM-Uf I IUD UUHVCEDl UIM!.)I..II'Est l

E-f CONIHUSYIQM DIVISIIGM PROPRf Sub ect From - Date Mr. P. C. Kiefer Welding Material Qualification Metallurgical Research and to Requirements of ASME Development Department