L-06-038, Proposed Alternative to American Society of Mechanical Engineers Code Section XI Repair Requirements

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Proposed Alternative to American Society of Mechanical Engineers Code Section XI Repair Requirements
ML060960393
Person / Time
Site: Beaver Valley
Issue date: 03/31/2006
From: Lash J
FirstEnergy Nuclear Operating Co
To:
Document Control Desk, Office of Nuclear Reactor Regulation
References
BV2-PZR-01, L-06-038
Download: ML060960393 (23)


Text

FENOC' FirstEnergy Nuclear Operating Company James H. Lash 724-682-5234 Site Vice President Fax: 724 -643-8069 March 31, 2006 L-06-038 U. S. Nuclear Regulatory Commission Attention: Document Control Desk Washington, DC 20555-0001

Subject:

Beaver Valley Power Station, Unit No. 2 Docket No. 50-412, License No. NPF-73 Proposed Alternative to American Society of Mechanical Engineers Code Section XI Repair Requirements (Request No. BV2-PZR-01)

Pursuant to 10 CFR 50.55a(a)(3)(i), FirstEnergy Nuclear Operating Company (FENOC) hereby requests NRC approval to use the following alternative during the Beaver Valley Power Station (BVPS) Unit No. 2 maintenance and refueling outage scheduled for October 2006.

Application of structural weld overlays on pressurizer nozzle welds is planned due to increased inspection requirements and difficulties associated with application of ultrasonic inspection technology to the current weld geometry.

The ASME Code year of record for the current inservice inspection interval is the 1989 Edition, no addenda. Paragraph IWA-4000 of ASME Section XI contains requirements for welded repairs performed on ASME components. In lieu of these ASME Code requirements, this submittal is requesting approval to use an alternative weld repair.

Additionally, Supplement 11 of Appendix VIII of the 1995 Edition, 1996 Addenda of ASME Section XI, which is required to be implemented by I0CFR50.55a(g)(6)(ii)(C),

establishes requirements for nondestructive examination of weld overlays. In lieu of these requirements, this submittal is requesting approval to use the EPRI Performance Demonstration Initiative (PDI) alternative. The proposed weld overlay alternative provides. an acceptable level of quality and safety. The details of the 10 CFR 50.55a request are enclosed.

FENOC requests approval by September 2006 to support the BVPS Unit No. 2 maintenance and refueling outage, scheduled for early October 2006.

Beaver Valley Power Station, Unit No. 2 Proposzd Alternative to ASME Code Section XI Repair Requirements L-06-038 Page 2 The regulatory commitment contained in this submittal is listed in the attachment. If there are any questions concerning this matter, please contact Mr. Gregory A. Dunn, Manager, Fleet Licensing at 330-315-7243.

Sincerely, mes H. Lash

Enclosure:

10 CFR 50.55a Relief Request No. BV2-PZR Proposed Alternative in Accordance with 10 CFR 50.55a(a)(3)(i)

Attachment:

Commitment List C: Mr. T. G. Colburn, NRR Senior Project Manager Mr. P. C. Cataldo, NRC Senior Resident Inspector Mr. S. J. Collins, NRC Region I Administrator Mr. D. A. Allard, Director BRP/DEP Mr. L. E. Ryan (BRP/DEP)

ENCLOSURE

'10 CFR 50.55a AUTHORIZATION REQUEST No. BV2-PZR-01 Proposed Alternative In Accordance With 10 CFR 50.55a(a)(3)(i)

I 10 CFR 50.55A RELIEF REQUEST No. BV2-PZR-01 1.0 ASME CODE COMPONENTS AFFECTED Component Numbers: 2RCS-PRE21 (Pressurizer Vessel)

Nozzle-to-Safe End Safe End-to-Pipe Nozzle Weld ID Weld ID Safety 2RCS*PRE21-lO1A 2RCS-101-FO1 Safety 2RCS*PRE21-102B 2RCS-102-FO1 Safety 2RCS*PRE21-103C 2RCS-103-FO1 Relief 2RCS*PRE21-107Z 2RCS-107-FO1 Spray 2RCS*PRE21-202Z 2RCS-202-F01 Surge 2RCS*PRE21-84Z 2RCS-84-F03 Code Class: Class 1 Examination Categories: B-F Item Numnber: B5.40

Description:

Alternative Welded Repair for the Pressurizer Safety, Relief, Spray, and Surge Nozzle-to-safe end welds

References:

ASME Section XI, 1989 Edition, no addenda ASME Section XI, 1995 Edition, 1996 Addenda ASME Section XI, 2005 Addenda, Nonmandatory Appendix Q ASME Section XI, Code Case N-504-2 ASME Section XI, Code Case N-638-1 ASME Section XI, Code Case N-416-2 ASME Section III, 1971 Edition through Summer 1972 Addenda ASME Section III, 1971 Edition through Winter 1972 Addenda 2.0 APPLICABLE CODE EDITION AND ADDENDA ASME Section XI, 1989 Edition, no addenda ASME Section XI, 1995 Edition, 1996 Addenda (Appendix VIII, Supplement XI, as required by 10CFR50.55a(g)(6)(ii)(C))

3.0 APPLICABLE CODE REQUIREMENTS IWA-40(0 of ASME Section XI contains requirements for welded repairs performed on ASME components. The specific Code requirements from which relief is requested are as follows:

ASME Section XI, IWA-4120(a) states that "Repairs shall be performed in accordance with the Owner's Design Specification and the original Construction Code of the component or system."

ASME Section XI, IWA-4310 states that "Defects shall be removed or reduced in size in accordance with this Article."

ASME Section XI, IWA4533(b) states that "Thermocouples and recording instruments shall be used to monitor the preheat and interpass requirements and the 450 0F to 550°F heat treatment.

Thermocouples may be attached by welding or by mechanical methods."

Enclosure to L-06-038 Page 2

.4SME Section XI, Appendix VIII, Supplement 11 (1995 Edition, 1996 Addenda) contains nondestructive examination requirements for structural weld overlays and is required to be implemented by 10CFR50.55a(g)(6)(ii)(C).

The applicable requirements of the Construction Code required by IWA-4120(a) from which relief is requested are as follows:

.4SME Section III, Subsection NB4453.1 states that "Unacceptable defects shall be removed by

rnechanical means or by thermal gouging processes."

ASME Section III, Subsection NB4641 states that "Components or items including materials that have been repaired by welding shall be postweld heat treated in accordance with the requirements of NB-4620."

4.0 'REASON FOR REQUEST Primary Water Stress Corrosion Cracking (PWSCC) of Alloy 600/82/182 components exposed to Pressurized Water Reactor (PWR) primary coolant has become a growing concern in the nuclear industry over the past decade. In particular, base metal and weld metal components exposed to elevated temperatures, like the pressurizer, have been shown to pose a heightened propensity to PWSCC. AIs a result, increased inspection requirements have been applied to these locations via several mechanisms, including 10CFR50.55a, the ASME Code, the recently issued NEI 03-08 Mandatory Guidance, "Primary System Piping Butt Weld Inspection & Evaluation Guideline (MRP-139)," and internal utility Alloy 600 program;.

Many of these requirements call for dramatically improved ultrasonic examination coverage (> 90%5 of the inner 1/3t of the dissimilar metal weld) and inspection frequencies far in excess of those required by the exist ng Inservice Inspection (ISI) program. In many cases, these examination coverage requirements are difficult or impossible to meet using current ultrasonic inspection technology due to the short length of the stainless steel safe end between the dissimilar metal and stainless steel welds and of the nozzle between the dissimilar metal weld and the nozzle transition.

Due to the combination of inspectability issues and a reduced ability to validate the integrity of these welds prior to the observation of leakage, FirstEnergy Nuclear Operating Company (FENOC) has concluded that the application of preemptive structural weld overlays to the susceptible pressurizer nozzle locations is the most appropriate course of action to ensure Reactor Coolant System (RCS) pressure boundary integrity and improve future inspectability.

Pursuant to 10CFR50.55a(a)(3)(i), an alternative is requested on the basis that the proposed alternative will provide an acceptable level of quality and safety. The Code of Construction (ASME Section III, Subsection NB-4453) does not allow unacceptable flaws to be reduced to an acceptable size through the application of a structural weld overlay. Furthermore, the Code (ASME Section III, Subsection NB-4641) requires that components that have been repaired by welding be post-weld heat treated in accordan e with Subsection NB4620 following the repair. IWA-4533(b) of ASME Section XI further requires that inprocess thermocouples be attached by welding or mechanical methods. Finally, Appendix VIII, Supplement 11 of the 1995 Edition, 1996 Addenda of ASME Section XI establishes nondestructive examination requirements for weld overlays. The proposed alternatives to these requirements, as discussed. in Section 5.0 of this request, provide an acceptable level of quality and safety utilizing processes better suited to in-service field applications.

Enclosure to L-06-038 Page 3 5.0 PROPOSED ALTERNATIVE AND BASIS FOR USE Proposed Alternative to ASME Section XI, 1WA-4120(a), IWA-4310. and ASME Section III, Subseclion NB-445 3 A preemptive full structural weld overlay is proposed for each Alloy 82/182 nozzle-to-safe end weld.

ASME Code Case N-504-2 allows a flaw to be reduced to an acceptable size through the deposition of weld reinforcement (weld overlay) on the outside surface of the pipe without flaw removal. In this case, the existence of (or lack of) any flaws is not known due to the inability to perform a qualified ultrasonic examination prior to application of the overlays. As such, assumptions are required to be made as to the size and location of flaws which may be present in the original dissimilar metal weld, as discussed below.

Figure 1: Generic Pressurizer Nozzle Configuration PZR CS Nozzle SS Clad Alloy Alloy SS SS SS 82/182 82M182 Safe-End Weld Pipe Weld Table 1: Beaver Valley Unit No. 2 Pressurizer Nozzle Material Identification Material Identification Nozzle Type NPS Alloy 82/182 Weld ID Nozzle N-SE Weld Safe End SE-P Weld Pipe Spray 4" 2RCS*PRE21-202Z SA-508, Ni-Cr-Fe SA-182, SS Field Scheduk:

Cl 2A Weld Type 316L Weld 160, SA-Metal, F- 312/376, Number 43 Type 316 Safety 6" 2RCS*PRE21-101A SA-508, Ni-Cr-Fe SA-182, SS Field Schedul:

Cl 2A Weld Type 316L Weld 160, SA-Metal, F- 312/376, Number 43 Type 316)

Safety 6" 2RCS*PRE21-102B SA-508, Ni-Cr-Fe SA-182, SS Field Schedule Cl 2A Weld Type 316L Weld 160, SA-Metal, F- 312/376, Number 43 Type 316 Safety 6" 2RCS*PRE21-103C SA-508, Ni-Cr-Fe SA-182, SS Field Schedule Cl 2A Weld Type 316L Weld 160, SA-Metal, F- 312/376, Number 43 Type 316

i, Enclosu:e to L-06-038 Page 4 Material Identification Nozzle Type NPS Alloy 82/182 Weld ID Nozzle N-SE Weld Safe End SE-P Weld Pipe Relief 6" 2RCS*PRE21-107Z SA-508, Ni-Cr-Fe SA-182, SS Field Schedule C1 2A Weld Type 316L Weld 160, SA.-

Metal, F- 312/376, Number 43 Type 316 Surge 14" 2RCS*PRE21-84Z SA-508, Ni-Cr-Fe SA-182, SS Field Schedule Cl 2A Weld Type 316L Weld 160, SA.-

Metal, F- 376, Type Number 43 304 Table 1 identifies the materials of construction for the pressurizer nozzle-to-pipe assemblies within the scope of this relief request. Figure 1 shows the generic configuration of the nozzle-to-pipe assemblies. In order that both the dissimilar metal nozzle-to-safe end weld and the stainless steel safe end-to-pipe weld are inspectable per the ASME Code post-overlay, the weld overlays will extend from the carbon steel nozzle to the stainless steel pipe.

The weld overlay will be designed consistent with the requirements of ASME Code Case N-504-2, "Alternative Rules for Repair of Classes 1, 2, and 3 Austenitic Stainless Steel Piping," with the modifications noted in Table 2. The weld overlay will extend around the full circumference of the nozzle-to-safe end weld location as required by Code Case N-504-2. The specific thickness and length will be calculated according to the guidance provided in Code Case N-504-2.

The design of each overlay will assume that a 3600 circumferential through-wall flaw is present in the original Alloy 82/182 weld. Fatigue crack growth evaluations will be performed for the dissimilar metal butt welds to demonstrate that the weld overlay thickness is sized adequately to satisfy the requirements in the flaw evaluation procedures of IWB-3640. The initial flaw size assumed in the fatigue crack growth calculations will be consistent with the post-overlay ultrasonic examination requirements (i.e. a minimum of the outer 25% of the original Alloy 82/182 weld will be inspectable post-overlay). If the crack growth analysis shows that fatigue crack growth will not grow a flaw to the design basis depth for the normal ASME Code,Section XI inspection interval, then the existing Code interval will be used for subsequent inservice inspections. If the crack growth analysis shows that the assumed crack will grow to the allowable flaw size, then the inservice inspection interval will be established based on this time.

Preservice inspections will be performed in accordance with Code Case N-504-2, Nonmandatory Appendix Q, Subarticle Q-4200, and ASME Section XI, 1995 Edition, 1996 Addenda, Appendix VIII, Supplem.nt 11, as modified by this request.

Code Ca:;e N-504-2 is approved for use for austenitic stainless steel material in Regulatory Guide 1.147, Revision 14, provided that it is used with Nonmandatory Appendix Q of the 2005 Addenda of ASMIE Section XI. An alternate application for nickel-based and carbon materials is proposed due to the configuration of the subject welds, and the lack of an approved code case for these applications. The methodology of Code Case N-504-2 shall be followed with the modifications detailed in Table 2.

Details regarding the in-process, pre-service, and inservice examinations that will be applied to the proposed weld overlays are shown in Table 3. These examinations meet all of the requirements of the applicable Codes, as modified by this request.

The above proposed alternative will be implemented during the Beaver Valley Power Station Unit No. 2 2R12 Refueling Outage (Fall 2006) and provides an acceptable level of quality and safety.

'Enclosure to L-06-038 Page 5 Proposel Alternative to ASME Section XI, IWA-4120(a) and ASME Section III, Subsection NB-4641.

Application of the structural weld overlays will require welding to the carbon steel nozzle material. The Code of Construction does not permit welding to the carbon steel nozzle without pre-heat or post-weld heat treatment. In lieu of these requirements, the requirements of ASME Code Case N-638-1, "Similar and Dissimilar Metal Welding Using Ambient Temperature Machine GTAW Temper Bead Technique,"

will be met, with the modification detailed in Table 4.

The ambient temperature temper bead welding technique permits applications of the structural wveld overlay without the need for elevated preheat or post-weld heat treatment required by ASME Section III.

The technique has been qualified and will be performed using the methodology described in ASME C'ode Case N-638-1. Welding will commence when the base materials exhibit a minimum preheat of 50 degrees Fahrenheit. The interpass temperature during weld installation will not be permitted to exceed a maximumn value of 350 degrees Fahrenheit. During the welding, heat input will be precisely controlled to conform to the welding procedure specification.

The above proposed alternative will be implemented during the Beaver Valley Power Station Unit No. 2 2RI2 Refueling Outage (Fall 2006) and provides an acceptable level of quality and safety.

Proposed Alternative to ASME Section XI, IWA-4533(b)

IWA45:33(b) requires that inprocess thermocouples and recording instruments be attached by welding or mechanical means. In lieu of attached thermocouples and recording instruments, process temperatures will be monitored with non-attached devices, such as contact pyrometers, which will enable manual recording of process temperatures. Instruments used will be calibrated in accordance with approved calibration and control program requirements.

The above proposed alternative will be implemented during the Beaver Valley Power Station Unit ND. 2 2R12 Refueling Outage (Fall 2006) and provides an acceptable level of quality and safety.

Proposed Alternative to ASME Section XI, Appendix VIII. Supplement 11 Appendi x VIII of Section XI cannot be used for nondestructive examination of a structural weld overlay repair. Relief is requested to use the Performance Demonstration Initiative (PDI) program implementation of Appendix VIII. A detailed comparison of Appendix VIII and PDI requirements is summarized below.

Relief is requested to allow closer spacing of flaws provided they do not interfere with detection or discrimination. The specimens used to date for qualification to the Tri-party (NRCIBWROG/EPRI) agreement have a flaw population density greater than allowed by current Code requirements. These samples have been used successfully for all previous qualifications under the Tri-party agreerrent program. To facilitate their use and provide continuity from the Tri-party agreement program to Supplement 11, the PDI program has merged the Tri-party test specimens into their weld overlay program. Specific details regarding the PDI program's alternative to the requirements of Supplement 11 are contained in Table 5.

  • Enclosure to L-06-038 Page 6 6.0 DURATION OF THE PROPOSED ALTERNATIVE Use of the proposed alternative is requested for the Beaver Valley Power Station Unit No. 2, second. In-Service inspection (ISI) interval. The resulting repairs are requested for the design life of the repains, as determined by the required evaluation in Paragraph (g) of Code Case N-504-2 and the corresponding requirements in Nonmandatory Appendix Q.

The installed weld overlay will be added to the Beaver Valley Power Station Unit No. 2 ISI Pla:l in accordance with Subarticle Q-4300 of Nonmandatory Appendix Q for at least one inservice examination to be completed within the next two refueling outages following installation.

7.0 PRECEDENT FENOC is not aware of any precedent for the proposed alternative in which the existence of, or lack of, flaws in the dissimilar metal weld is not known. However, requests have been approved for repairs of known flaws in similar PWR locations at Three Mile Island Nuclear Station, Unit No. 1; D.C. Cook Nuclear Plant, Unit No. 1; and Millstone Power Station, Unit No. 3. Use of the Performance Demonstration Initiative (PDI) program for the inspection has also been authorized by the NRC for Calvert Cliffs Nuclear Power Plant, Unit No. 2; Donald C. Cook Nuclear Plant, Unit No. 1; and Millsione Power Station, Unit No. 3. Reference to NRC letters authorizing the alternatives is provided below.

> Three Mile Island Nuclear Station, Unit No. 1 l)ocket No. 50-289, TAC No. MC1201, dated July 21, 2004 Authorized relief from flaw removal, heat treatment, nondestructive examination requirements and weld overlay of nozzle-to-safe end weld.

> Calvert Cliffs Nuclear Power Plant, Unit No. 2 D)ocket No. 50-318, TAC Nos. MC6219 and MC6220, dated July 20, 2005 Authorized use of a weld overlay to repair welds and the Performance Demonstration Initiative (PDI) program for the inspection as alternatives to the ASME Code requirements.

> Donald C. Cook Nuclear Plant, Unit No. I Docket No. 50-315, TAC No. MC6751, dated June 27, 2005 Authorized use of PDI Program for weld overlay qualifications in lieu of Supplement 11 to Appendix VIII of Section XI of the Code

> Millstone Power Station, Unit No. 3 I)ocket No. 50423, TAC No. MC8609, dated January 20, 2006 Authorized use of a weld overlay for repair and the Performance Demonstration Initiative (PD])

rrogram for inspection as alternatives to the ASME Code requirements.

Enclosure to L-06-038 Page 7 Table 2: Modifications to Code Case N-504-2 Code Case N-504-2 Section Modification and Basis Reply: It is the opinion of the Committee that, in lieu of the Modification: Code Case N-504-2 will be used for the weld overlay of requirements of IWA-4120 in Editions and Addenda up to and the ferritic (P3) nozzle material, nickel alloy (F43/P43) weld material, including the 1989 Edition with the 1990 Addenda, in IWA-4170(b) in and austenitic stainless steel base (P8, safe end and pipe) and weld the 1989 Edition with the 1991 Addenda up to and including the 1995 materials.

Edition, and in IWA-4410 in the 1995 Edition with the 1995 Addenda and later Editions and Addenda, defects in austenitic stainless steel Basis: Code Case N-504-2 is accepted for use in the current NRC piping may be reduced to a flaw of acceptable size in accordance with Regulatory Guide 1.147 Rev. 14, and has been used extensively in IWB-3640 from the 1983 Edition with the Winter 1985 Addenda, or BWR primary system piping. More recently, N-504-2 has been applied later Editions and Addenda, by deposition of weld reinforcement (weld to PWR applications, with modifications, for the weld overlay repair of overlay) on the outside surface of the pipe, provided the following dissimilar metal welds with known flaws. Industry operating requirements are met. experience in the area has shown that PWSCC in Alloy 82/182 will arrest at the interface with stainless steel base metal, ferritic base metal, or Alloy 52/52M/152 weld metal. The 3600 full structural weld overlay will control growth in any PWSCC crack and maintain weld integrity.

The weld overlay will also induce compressive stress in the weld, thus potentially impeding growth of any reasonably shallow cracks.

Furthermore, the overlay will be sized to meet all structural requirements without considering the existing 82/182 weld.

Paragraph(b): Reinforcement weld metal shall be low carbon (0.035% Modification: A nickel alloy, specifically Alloy 52/52M, will be used as max.) austenitic stainless steel applied 360 deg. around the the reinforcement weld metal in lieu of austenitic stainless steel filler circumference of the pipe, and shall be deposited in accordance with a material.

qualified welding procedure specification identified in the Repair Program. Basis: The weld metal used will be ERNiCrFe-7A (Alloy 52M, UNS N06054) or ERNiCrFe-7 (Alloy 52 UNS N06052). This weld metal is assigned F43 by ASME per Code Case 2142-2. The requirements of ASME Section III, NB-2400 will be applied to all filler material.

The chromium content of Alloys 52 and 52M is 28-3 1.5%. Alloy 52M contains higher Niobium content (0.5- 1 %) than Alloy 52, which improves the welpability of the material and pins the grain boundaries, thus pfevetItilig s1paFiULIU1 between the grains and hot tearing during weld puddle soli 4ification.

'I1 Enclosure to L-06-038 Page 8 Table 2: Modifications to Code Case N-504-2 (Continued)

Code Case N-504-2 Section Modification and Basis These filler materials are selected for their improved resistance to PWSCC. Alloys 52, 52M and 152 all contain about 30% chromium (roughly twice that of Alloy 82/182), imparting excellent corrosion resistance. The existing Alloy 82/182 weld and the Alloy 52/52M overlay are austenitic and have ductile properties and toughness similar to austenitic stainless steel piping welds at PWR operating temperature.

Furthermore, these filler materials are suitable for welding over the ferritic nozzle, Alloy 82/182 weld, and the austenitic stainless steel pipe, welds, and safe ends.

Paragraph(e): The weld reinforcement shall consist of a minimum of Modification: Delta ferrite (FN) measurements will not be performed two weld layers having as-deposited delta ferrite content of at least 7.5 when using Alloy 52/52M/152 weld metal.

FN. The first layer of weld metal with delta ferrite content of least 7.5 FN shall constitute the first layer of the weld reinforcement design Basis: Welds composed of Alloy 52/52M/152 are 100% austenitic and thickness. Alternatively, first layers of at least 5 FN may be acceptable contain no delta ferrite due to the high nickel (approximately 60%)

based on evaluation. content. The Alloy 52/52M filler material selected for these repairs is fully austenitic and is, therefore, exempt from delta ferrite content requirements. Alternatively, deposit chromium content provides a suitable alternate basis for first layer deposit acceptance in PWSCC-resistant structural weld overlays. N-504-2 does not identify first-layer acceptance criteria for fully austenitic deposits, however, draft ASME Code Case N-740 (and its accompanying technical justification) identify 24% chromium as an acceptable measure of first-layer deposit acceptability in PWR applications. For structural weld overlay repairs, verification of first layer acceptability will be accomplished using draft N-740 methodology. To accomplish this, first layer overlay deposit chemistry will be verified either by field chemistry measurements or by prior mockup demonstration using comparable welding parameters.

When first-layer surface chemistry meets or exceeds 24% chromium, this initial layer will be credited toward structural overlay deposit thickness. When first-layer surface chemistry chromium is less than 24% chromium, the first layer will be considered sacrificial and will not be credited toward structural overlay deposit thickness.

.4 Enclosure to L-06-038 Page 9 Table 2: Modifications to Code Case N-504-2 (Continued)

Code Case N-504-2 Section Modification and Basis Paragraph (Ih): The completed repair shall be pressure tested in Modification: In lieu of a hydrostatic test, a system pressure test will be accordance with IWA-5000. If the flaw penetrated the original pressure performed in accordance with approved Code Case N-416-2.

boundary prior to welding, or if any evidence of the flaw penetrating the pressure boundary is observed during the welding operation, a system Basis: Because the proposed relief is for the application of preemptive hydrostatic test shall be performed in accordance with IWA-5000. If the weld overlays, it is not anticipated that any flaws will have penetrated system pressure boundary has not been penetrated, a system leakage, the pressure boundary prior to welding. This being the case, Code Case inservice, or functional test shall be performed in accordance with N-504-2, Paragraph (h) would only require a system pressure test in IWA-5000. accordance with IWA-5000, and the use of Code Case N-416-2 would not be required.

Conservatively, if it is assumed that a flaw has penetrated the pressure boundary, Code Case N-504-2 requires a system hydrostatic test in accordance with IWA-5000. In this case, a system pressure test and an ultrasonic examination of the weld overlay are proposed, in accordance with the Second Interval ISI Program and ASME Code Case N-416-2.

This alternative requirement is sufficient to demonstrate that the overlay is of adequate quality to ensure the pressure boundary integrity.

Enclosure to L-06-038 Page 10 Table 3: Weld Overlav Examination Reauirements IN-PROCESS EXAMINATIONS Examination Description Method Technique Reference Acceptance Standards Safe end, welds, nozzle, and Surface Liquid Penetrant N-504-2 and Q-2000 N-504-2, Paragraph (c), Q-pipe pre-overlay surface 2000 preparation Initial layers of weld metal Surface Liquid Penetrant N-504-2 and Q-2000 N-504-2, Paragraph (d), Q-not associated with the 2000 structural weld overlay Thickness measurement for Volumetric UT-0L N-504-2 and Q-2000 Per weld overlay design final deposited weld requirements and Q-3000 reinforcement PRE-SERVICE EXAMINATION REQUIREMENTS Examination Description Method Technique Reference Acceptance Standards Completed weld overlay for Volumetric UT-00 L per PDI-qualified N-504-2 and Q-4100 Per weld overlay design complete bonding and procedure requirements, Q-3000, and minimum thickness Q4100 Examination of the Surface Liquid Penetrant N-504-2 and Q-4100 N-504-2, Paragraph (i) completed weld overlay and examination of a band at least 0.50 inches outward from the toe of the weld overlay around the entire circumference of the nozzle and pipe Completed weld overlay and Volumetric UT angle beam per PDI- N-504-2 and Q-4200 N-504-2, Paragraph (i) and the outer 25 percent of the qualified procedure Q4200 original nozzle, safe end and weld thickness at least 0.5-inch beyond the toes of the original weld and butter

11 Enclosure to L-06-038 Page 11 Table 3: Weld Overlay Examination Requirements (Continued)

INSERVICE EXAMINATION REQUIREMENTS Examination Description Method Technique Reference Acceptance Standards Weld overlay and outer 25 Volumetric UT angle beam per PDI ASME Section XI, IWB-35 14-2 and Q-percent of the original procedure Appendix VIII and Q4300 4300(c), re-examination nozzle, safe end and weld frequency and follow-up thickness at least 0.5-inch actions per Q4300(d), (e),

beyond the toes of the and (f) and Q-43 10.

original weld and butter within the next two refueling outages.

Surface examination of the Surface Liquid Penetrant ASME Section XI N-504-2, Paragraph (i) complete weld overlay surface

Enclosure to L-06-038 IV)

Page 12

  • I Table 4: Modifications to Code Case N-638-1 Code Case N-638-1 Section Modification and Basis Paragraph1.0(a): The maximum area of an individual weld based on _

Modification:The weld overlay area may exceed 100 sq. in. in some the finished surface shall be 100 sq. in., and the depth of the weld shall cases. The one-half base metal thickness limitation applies only to not be greater than one-half of the ferritic base metal thickness. excavations and repairs, and is not applicable to weld overlays described in this Relief Request.

Basis: Extensive experience exists in both BWR and PWR weld overlays applied in excess of the 100 sq. in. limitation. Additionally, industry studies into the qualification of overlays in excess of 100 sq.

in. have shown no issues with shrinkage stress, weld contraction stresses, etc.

Weld shrinkage caused by application of the overlays will be measured and evaluated for any system impacts, as required by Code Case N-504-2, Paragraph (g)(3).

Enclosure to L-06-038 Page 13 Table 5: PDT Program Alternative to Appendix VIII, Supplement 11 SUPPLEMENT 11 - QUALIFICATION REQUIREMENTS PDI PROGRAM:

FOR FULL STRUCTURAL OVERLAID WROUGHT The Proposed Alternative to AUSTENITIC PIPING WELDS Supplement 11 Requirements 1.0 SPECIMEN REQUIREMENTS 1.1 General. The specimen set shall conform to the following requirements.

(b) The specimen set shall consist of at least three specimens having Alternative: (b) The specimen set shall include specimens with different nominal pipe diameters and overlay thicknesses. They shall overlays not thicker than 0.1 in. more than the minimum thickness, nor include the minimum and maximum nominal pipe diameters for which thinner than 0.25 in. of the maximum nominal overlay thickness for the examination procedure is applicable. Pipe diameters within a range which the examination procedure is applicable.

of 0.9 to 1.5 times a nominal diameter shall be considered equivalent. If the procedure is applicable to pipe diameters of 24 in. or larger, the Basis: To avoid confitsion, tihe overlay thickness tolerance contained in specimen set must include at least one specimen 24 in. or larger but tire last sentence was rewvorded and the phrase "and the remainder need not include the maximum diameter. The specimen set must shall be alternativeflaws " was added to tihe next to last sentence in include at least one specimen with overlay thickness within -0.1 in. to paragraph1.1(d)(1).

+0.25 in. of the maximum nominal overlay thickness for which the procedure is applicable.

(d) Flaw Conditions (1) Base rietalflawvs. All flaws must be cracks in or near the butt weld Alternative: (1) ... must be in or... intentional overlay fabrication flaws heat-affected zone, open to the inside surface, and extending at least shall not interfere with ultrasonic detection or characterization of the 75% through the base metal wall. Flaws may extend 100% through the base metal flaws. Specimens containing intergranular stress corrosion base metal and into the overlay material; in this case, intentional cracking shall be used when available. At least 70% of the flaws in the overlay fabrication flaws shall not interfere with ultrasonic detection or detection and sizing tests shall be cracks and the remainder shall be characterization of the cracking. Specimens containing IGSCC shall be alternative flaws. Alternative flaw mechanisms, if used, shall provide used when available. crack-like reflective characteristics and shall be limited by the following:

(a) The use of alternative flaws shall be limited to when the implantation of cracks produces spurious reflectors that are uncharacteristic of actual flaws.

(b) Flaws shall be semi elliptical with a tip width of less than or equal to 0.002 inches.

I ________ I _ _______

Enclosure to L-06-038 Page 14 Table 5: PDI Pro2ram Alternative to AvDendix VIII. Suonlement 11 (Continmied)

SUPPLEMENT 11 - Qualification Requirements PDI PROGRAM:

for Full Structural Overlaid Wrought The Proposed Alternative to Austenitic Piping Welds Supplement 11 Requirements Basis: This paragraphrequires that all base metalflaws be cracks.

Iniplantinga crack requires excavation of the base materialon at least one side of theflaw. While this may be satisfactoryforferritic materials, it does not produce a useable axialflaw in austenitic materials because the sound beam, which nonnally passes only through base material, nust now travel through weld materialon at least one side, producing an unrealisticflawresponse. To resolve this issue, the PDIprogram revised this paragraphto allow iuse of alternativeflaw mechanisms under controlledconditions. Forexample, alternative flaws shall be limited to when implantationof cracksprecludes obtainingan effective ultrasonicresponse,flaws shall be semi elliptical with a tip width of less than or equal to 0.002 inches, and at least 70%

of the flaws in the detection and sizing test shall be cracks and the remaindershall be alternativeflaws.

To avoid confusion, the overlay thickness tolerance containedin paragraph1. I(b) last sentence, was reworded and the phrase "and the remaindershall be alternativeflaws" was addedto the next to last sentence.

Paragraph1.I(d)(1) includes the statement that intentionaloverlay fabricationflawsshall not interfere with Ultrasonicdetection or characterizationof the base mnetalflawvs.

Enclosure to L-06-038 Page 15 Table 5: PDI Program Alternative to Appendix VIII, Supplement 11 (Continued)

SUPPLEMENT 11 - Qualification Requirements PDI PROGRAM:

for Full Structural Overlaid Wrought The Proposed Alternative to Austenitic Piping Welds Supplement 11 Requirements (e) Detection Specimens (1) At least 20% but less than 40% of the flaws shall be oriented within Alternative: (1) At least 20% but less than 40% of the base metal

+/-200 of the pipe axial direction. The remainder shall be oriented flaws shall be oriented within +/-200 of the pipe axial direction. The circumferentially. Flaws shall not be open to any surface to which the remainder shall be oriented circumferentially. Flaws shall not be open candidate has physical or visual access. The rules of IWA-3300 shall be to any surface to which the candidate has physical or visual access.

used to determine whether closely spaced flaws should be treated as single or multiple flaws. Basis: The requirementfor axially oriented overlayfabricationflaws was excludedfrom the PDI Programas an improbable scenario. Weld overlays are typically applied uising automated GTA W techniques with thefiller metal applied in a circumferentialdirection. Because resultant fabrication induced discontinuitieswould also be expected to have major dimensions oriented in the circumferentialdirection axial overlayfabricationflawsare unrealistic.

The requirementfor uising IWA-3300for proximityflaw evaluation was excluded, instead indicationswill be sized based on theirindividual merits.

(2) Specimens shall be divided into base and overlay grading units. Alternative: (2) Specimens shall be divided into base metal and Each specimen shall contain one or both types of grading units. overlay fabrication grading units. Each specimen shall contain one or both types of grading units. Flaws shall not interfere with ultrasonic detection or characterization of other flaws.

(a)(l) A base grading unit shall include at least 3 in. of the length of the Alternative: (a)(I) A base metal grading unit includes the overlay overlaid weld. The base grading unit includes the outer 25% of the material and the outer 25% of the original overlaid weld. The base overlaid weld and base metal on both sides. The base grading unit shall metal grading unit shall extend circumferentially for at least 1 in. and not include the inner 75% of the overlaid weld and base metal overlay shall start at the weld centerline and be wide enough in the axial material, or base metal-to-overlay interface. direction to encompass one half of the original weld crown and a minimum of 0.50" of the adjacent base material.

Basis: The phrase "ind hse m-eta! on hnth sides " twas inadvertently included in the description of a base mnetal gradingunit.

The PD! prograin intentionally excludes this requirementbecause some

Enclosure to L-06-038 Page 16 Table 5: PDT Pro2ram Alternative to Appendix VIII, Supplement 11 (Continued)

SUPPLEMENT 11 - Qualification Requirements PDI PROGRAM:

for Full Structural Overlaid Wrought The Proposed Alternative to Austenitic PiOine Welds Supplement 11 Requirements of the qualificationsamples includeflaws on both sides of the wveld. To avoid confitsion several instances of the tenn "cracks" or "cracking" vere changed to the term "flaws" because of the uise of alternative Flaw mechanisms.

Modified to require that a base metal gradingunit include at least I in.

of the length of the overlaid weld, ratherthan 3 inches.

(a)(2) When base metal cracking penetrates into the overlay material, Alternative: (a)(2) When base metal flaws penetrate into the the base grading unit shall include the overlay metal within 1 in. of the overlay material, the base metal grading unit shall not be used as part of crack location. This portion of the overlay material shall not be used as any overlay fabrication grading unit.

part of any overlay grading unit.

(a)(3) When a base grading unit is designed to be unflawed, at least 1 Alternative: (a)(3) Sufficient unflawed overlaid weld and base in. of unflawed overlaid weld and base metal shall exist on either side metal shall exist on all sides of the grading unit to preclude of the base grading unit. The segment of weld length used in one base interfering reflections from adjacent flaws.

grading unit shall not be used in another base grading unit. Base grading units need not be uniformly spaced around the specimen. Modified to require szfficient unflawved overlaid weld and base metal to exist on all sides of the gradingunit to preclude interfering reflectionsfrom adjacentflaws, ratherthan the I inch requirement.

(b)(1) An overlay grading unit shall include the overlay material and the Alternative: (b)(1) An overlay fabrication grading unit shall include base metal-to-overlay interface of at least 6 in2 . The overlay grading the overlay material and the base metal-to-overlay interface for a length unit shall be rectangular, with minimum dimensions of 2 in. of at least 1 in.

Modified to define an overlayfabricationgradingunit as including the overlay material and the base metal-to-overlay interfacefor a length of at least I in, ratherthan the 6 in2 requirement.

(b)(2) An overlay grading unit designed to be unflawed shall be Alternative: (b)(2) Overlay fabrication grading units designed to be surrounded by unflawed overlay material and unflawed base metal-to- unflawed shall be separated by unflawed overlay material and unflawed overlay interface for at least I in. around its entire perimeter. The base metal-to-overlay interface for at least 1 in. at both ends. Sufficient specific area used in one overlay grading unit shall not be used in unflawed overlaid weld and haiz m-ta! chnli exist nn both sidlps f the another overlay grading unit. Overlay grading units need not be spaced overlay fabrication grading unit to preclude interfering reflections from uniformly about the specimen. adjacent flaws. The specific area used in one overlay fabrication

Enclosure to L-06-038 Page 17 Table 5: PDI Program Alternative to Appendix VIII. Supplement 11 (Continued)

SUPPLEMENT 11 - Qualification Requirements PDI PROGRAM:

for Full Structural Overlaid Wrought The Proposed Alternative to Austenitic Piping Welds Supplement 11 Requirements grading unit shall not be used in another overlay fabrication grading unit. Overlay fabrication grading units need not be spaced uniformly about the specimen.

Basis: Paragraph1. I(e)(2)(b)(2) states that overlayfabrication grading units designed to be unflaawed shall be separatedby unflaved overlay material and unflaived base Ynetal-to-overlay interfacefor at least I in. at both ends, ratherthan around its entire perimeter.

(b)(3) Detection sets shall be selected from Table VIII-S2-l. The Alternative: ... base metal grading units, ten unflawed base metal minimum detection sample set is five flawed base grading units, ten grading units, five flawed overlay fabrication grading units, and ten unflawed base grading units, five flawed overlay grading units, and ten unflawed overlay fabrication grading units. For each type of grading unflawed overlay grading units. For each type of grading unit, the set unit, the set shall contain at least twice as many unflawed as flawed shall contain at least twice as many unflawed as flawed grading units. grading units. For initial procedure qualification, detection sets shall include the equivalent of three personnel qualification sets. To qualify new values of essential variables, at least one personnel qualification set is required.

(f) Sizing Specimen (1) The minimum number of flaws shall be ten. At least 30% of the Alternative: (1) The .... least 40% of the flaws shall be open to the flaws shall be overlay fabrication flaws. At least 40% of the flaws shall inside surface. Sizing sets shall contain a distribution of flaw be cracks open to the inside surface. dimensions to assess sizing capabilities. For initial procedure qualification, sizing sets shall include the equivalent of three personnel qualification sets. To qualify new values of essential variables, at least one personnel qualification set is required.

(3) Base metal cracking used for length sizing demonstrations shall be Alternative: (3) Base metal flaws used ... circumferentially.

oriented circumferentially.

(4) Depth sizing specimen sets shall include at least two distinct Alternative: (4) Depth sizing specimen sets shall include at least two locations where cracking in the base metal extends into the overlay distinct locations where a base metal flaw extends into the overlay material by at least 0.1 in. in the through-wall direction. mnterial hv nt least A.1 in. in the threu,,nh-..,Aq dirctirn.

_________________ I

Enclosure to L-06-038 Page 18 4

Table 5: PDI Program Alternative to Appendix VIII, Supplement 11 (Continued)

SUPPLEMENT 11 - Qualification Requirements PDI PROGRAM:

for Full Structural Overlaid Wrought The Proposed Alternative to Austenitic Piping Welds Supplement 11 Requirements 2.0 CONDUCT OF PERFORMANCE DEMONSTRATION The specimen inside surface and identification shall be concealed from Alternative: The specimen .... prohibited. The overlay fabrication flaw the candidate. All examinations shall be completed prior to grading the test and the base metal flaw test may be performed separately.

results and presenting the results to the candidate. Divulgence of particular specimen results or candidate viewing of unmasked specimens after the performance demonstration is prohibited.

2.1 Detection Test Flawed and unflawed grading units shall be randomly mixed. Although Alternative: Flawed.... (base metal or overlay fabrication) ... each the boundaries of specific grading units shall not be revealed to the specimen.

candidate, the candidate shall be made aware of the type or types of grading units (base or overlay) that are present for each specimen.

2.2 Length Sizing Test (d) For flaws in base grading units, the candidate shall estimate the Alternative: (d) For ... base metal grading ... base metal wall length of that part of the flaw that is in the outer 25% of the base wall thickness.

thickness.

2.3 Depth Sizing Test For the depth sizing test, 80% of the flaws shall be sized at a specific Alternative: (a) The depth sizing test may be conducted separately or location on the surface of the specimen identified to the candidate. For in conjunction with the detection test.

the remaining flaws, the regions of each specimen containing a flaw to (b) When the depth sizing test is conducted in conjunction with the be sized shall be identified to the candidate. The candidate shall detection test and the detected flaws do not satisfy the requirements of determine the maximum depth of the flaw in each region. 1.1(f0, additional specimens shall be provided to the candidate. The regions containing a flaw to be sized shall be identified to the candidate.

The candidate shall determine the maximum depth of the flaw in each region.

(c) For a separate depth sizing test, the regions of each specimen containing a flaw to be sized shall be identified to the candidate. The candidate shall determine the maximum depth of the flaw in each re'ion.

47

'F Enclosure to L-06-038 Page 19 Table 5: PDI Program Alternative to Appendix VIII, Supplement 11 (Continued)

SUPPLEMENT 11 - Qualification Requirements PDI PROGRAM:

for Full Structural Overlaid Wrought The Proposed Alternative to Austenitic Piping Welds Supplement 11 Requirements 3.0 ACCEPTANCE CRITERIA 3.1 Detection Acceptance Criteria Examination procedures, equipment, and personnel are qualified for Alternative: Examination procedures are qualified for detection when:

detection when the results of the performance demonstration satisfy the a. All flaws within the scope of the procedure are detected and the acceptance criteria of Table Vll-S2-1 for both detection and false calls.

The criteria shall be satisfied separately by the demonstration results for of Table VIf-S2-1 for false calls.

base grading units and for overlay grading units.

b. At least one successful personnel demonstration has been performed meeting the acceptance criteria defined in (c).
c. Examination equipment and personnel are qualified for detection when the results of the performance demonstration satisfy the acceptance criteria of Table Vill-S2-1 for both detection and false calls.
d. The criteria in (b) and (c) shall be satisfied separately by the demonstration results for base metal grading units and for overlay fabrication grading units.

3.2 Sizing Acceptance Criteria (a) The RMS error of the flaw length measurements, as compared to the Alternative: (a) The ... base metal flaws is ... position.

true flaw lengths, is less than or equal to 0.75 inch. The length of base metal cracking is measured at the 75% through-base-metal position.

(b) All extensions of base metal cracking into the overlay material by at Alternative: This requirement is omitted.

least 0.1 in. are reported as being intrusions into the overlay material.

Basis: The requirementforreporting all extensions of cracking into the overlay is omittedfrom the PDI Prograinbecause it is reduhndant to the RMS calculationsperformed in paragraph3.2(c) and its presence adds confusion and ambiguity to depth sizing as requiredby paragraph 3.2(c). This also makes the weld overlay programi consistent with the Supplement 2 depth sizing criteria.

ATTACHMENT to L-06-038 Commitment List The following list identifies those actions committed to by FirstEnergy Nuclear Operating Company (FENOC) for Beaver Valley Power Station (BVPS) Unit No. 2 in this document. Any other actions discussed in the submittal represent intended or planned actions by FENOC. They are described only as information and are not regulatory commitments. Please notify Mr. Gregory A. Dunn, Manager, Fleet Licensing at 330-315-7243 of any questions regarding this document or associated regulatory commitments.

Commitment Due Date The installed weld overlay will be added to the To be completed within the Beaver Valley Unit No. 2 Inservice Inspection Plan next two refueling outages in accordance with Subarticle Q-4300 of following installation.

Nonmandatory Appendix Q for at least one inservice examination.