ML21230A366

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Xlpr Seminar_Applications_Code Case N-770
ML21230A366
Person / Time
Issue date: 08/18/2021
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NRC/RES/DE
To:
Homiack M
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Download: ML21230A366 (9)


Text

ASSESSMENT OF SMALL DIAMETER DISSIMILAR-METAL WELD INSPECTION INTERVALS USING XLPR xLPR User Group Meeting August 18, 2021 1

Key Research Question

  • With the updated Alloy 82/132/182 crack growth rates Excerpt from ASME Code Case N-770-6, Table 1 in EPRI report MRP-420, Rev. 1, is a change in the reinspection Item Parts Inspection Requirement interval warranted for PWR cold Unmitigated butt weld at leg dissimilar metal (DM) butt Cold Leg operating Visual exam once per interval welds from those that are B-1 temperature 274°C (525°F) and < 304°C Volumetric exam every currently established in ASME (580°F), less than NPS 14 second inspection period Code Case N-770? (DN 350) not to exceed 7 years Unmitigated butt weld at Visual exam once per

- Code Case N-770 was Cold Leg operating temperature 274°C interval developed using crack growth B-2 (525°F) and < 304°C Volumetric exam once per rates of Alloy 82/182 from (580°F), NPS 14 (DN 350) or interval MRP-115 larger 2

Methodology

  • Individual steps performed are as follows:
1. Cold leg DM butt welds and the various configurations from each Nuclear Steam Supply System (NSSS) plant type were reviewed and grouped by size
2. Additional input data were collected, including welding residual stresses, material properties, environmental conditions, and inspection detection capabilities
3. Probabilistic fracture mechanics (PFM) evaluations were performed using the recently released xLPR (Extremely Low Probability of Rupture) software
4. Deterministic fracture mechanics (DFM) evaluations were performed using average parameters to provide verification of the PFM analysis results 3

Component Grouping

  • A compilation of all the cold leg temperature DM butt weld components Westinghouse was developed for the U.S. operating
  • Auxiliary Head Adapter Nozzle - Small pressurized water reactor (PWR) fleet Diameter

- NSSS designs from Westinghouse, Combustion Engineering, and Babcock & Combustion Engineering Wilcox were considered

  • Charging Nozzle - Small Diameter

- All welds less than reactor coolant loop

  • Spray Nozzle - Small Diameter (RCL) size were grouped as either medium
  • Letdown/Drain Nozzle - Small Diameter or small
  • Safety Injection Nozzle - Medium
  • Medium > nominal pipe size (NPS) 8 (DN200) Diameter
  • Small < NPS 8 (DN200)

- The small size was further divided based on Babcock & Wilcox wall thickness

  • High Pressure Injection Nozzle - Small
  • Bounding geometry and stresses were Diameter determined for each grouping
  • Letdown/Drain Nozzle - Small Diameter
  • Core Flood Nozzle - Medium Diameter 4

PFM Methodology

  • The PFM evaluations were performed using the xLPR software
  • Probabilistic analysis considers three inservice inspection (ISI) scenarios

- Current 7-year interval using Code Case N-770 inspection criteria based on MRP-115 (baseline) and MRP-420, Rev. 1 crack growth rates

- Investigating 10-year interval with MRP-420 crack growth rates

- Also included mixed ISI cases representing two ISI intervals of 7 years followed by 10-year intervals Inspection Scenarios (at Years)

ISI 1 ISI 2 ISI 3 7, 14, 21, 28, 35, 42, 49 10, 20, 30, 40, 50 7, 14, 24, 34, 44 (every 7 years) (every 10 years) (two 7 years + every 10 years) 5

PFM Methodology (contd)

  • Operating temperatures, water chemistry, and operating loads were collected for operating plants
  • A pre-existing, single, primary water stress-corrosion cracking (PWSCC) flaw in the DM butt weld was assumed with no additional initiation during the evaluation period

- Consistent with the MRP-139 and ASME Code Case N-770 bases

  • Welding residual stresses included the effects of inside diameter weld repairs
  • The material properties required for flaw stability are obtained from the material library of xLPR V2.1
  • The probability of detection curves from MRP-262, Rev. 3 were used 6

PFM Methodology (contd)

  • From the PFM evaluations, probabilities of leak and rupture were calculated
  • The acceptance criterion adopted for this study: increase in failure probability per year must be less than 1x10-6

- Consistent with U.S. NRC Regulatory Guide 1.174 as discussed in the development of the proposed xLPR leak-before-break acceptance criteria 7

PFM Results

  • In total, 24 base cases were evaluated to compare the change in failure probability due to relaxing the inspection interval

- An additional 5 sensitivity studies were also evaluated

  • For the Medium DM butt weld, the changes in leak and rupture probabilities were either zero or negative, which indicates that the proposed 10-year inspection interval satisfies the acceptance criteria
  • For Small DM butt welds, the changes in leak and rupture probabilities demonstrated that the proposed 10-year inspection interval is acceptable if two 7-year inspections have been previously performed 8

Conclusions

  • The evaluation demonstrated that the failure probability increase for small and medium diameter DM butt welds was within the acceptance criteria when comparing the current requirements (7 years) and the proposed alternative inspection frequency (10 years)

- For Small DM butt welds the conclusion is conditional on two 7-year inspections have been previously performed

  • The work included bounding values that are intended to be generally representative of the fleet based on various configurations; however, the following areas need to be addressed to demonstrate plant-specific applicability

- Geometry and stress

- Welding residual stresses

- Environmental conditions (temperature and hydrogen addition)

- Also see PVP2021-62560 for a summary 9