07/06/2017 - TMRE Public Meeting Slides

ML17207A067
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Site:	Nuclear Energy Institute
Issue date:	07/06/2017
From:	Montgomery B Nuclear Energy Institute
To:	Office of Nuclear Reactor Regulation
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ML17207A063	List: ML17181A307 ML17207A067
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NEI 17-02, Rev 0
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NEI 17-02 Bruce Montgomery TORNADO Director, Strategic Planning NEI MISSILE RISK EVALUATOR July 6, 2017 (TMRE)

GUIDANCE DOCUMENT

Agenda

• Overview of TMRE Development

• Overview of TMRE Pilot Plants, Plans, and Schedules

• TMRE Guidance Document Presentation 2

Overview TMRE Development

• TMRE development began Fall 2015.

• Since October 2015 NRC and industry held 6 public meetings to discuss methodology.

• November 2016 NEI began development of industry guidance on TMRE application.

• NEI 17-02, Revision 0, provided to NRC June 23, 2017.

• Three plants will pilot the TMRE methodology prior to broader implementation.

• NEI 17-02 will be included in/attached to each pilot LAR.

3

Overview TMRE Methodology

• Risk-informed methodology.

• Calculates SSC failure likelihood due to missile impact.

• Examines impact of failure using existing plant internal events PRA.

• Internal events PRA modified to account for effects from a tornado.

• Results compared to thresholds defined as delta-CDF and delta-LERF.

• License amendments pursuant to R.G 1.174.

4

Overview of TMRE Pilot Plants

• Three plants volunteered to pilot the TMRE risk-informed methodology o Shearon Harris Nuclear Power Plant - Duke Energy

• Single Unit 3-loop W PWR - CP 1978; OL 1987 o Vogtle Electric Generating Plant- Southern Nuclear Operating Company

• Dual Unit 4-loop W PWRs - CPs 1976; OL 1987/89

- Two additional W AP1000 reactors under construction o Grand Gulf Nuclear Station - Entergy Nuclear

• Single Unit BWR 6 - CP 1974; OL 1984 5

TMRE Technical Advisory Group

• NEI established the industry TMRE Technical Advisory Group (TAG) o Membership - Utility, Contractor, EPRI, Pilot Plant and NEI Representatives o Purpose

• Oversees content of NEI 17-02

• Ensure each pilot applies the TMRE model to address site specific considerations

• Ensure consistency of TMRE model application across the pilots o TAG meets weekly 6

TMRE Pilot Timeline

• Harris and Vogtle TMRE Pilot LAR Target Schedules o Pre-Submittal Meetings - August 1 o TMRE Pilot LAR submittal - August 31

• Grand Gulf TMRE Pilot LAR Target Schedule o Pre-Submittal Meeting - October 6 o TMRE Pilot LAR submittal - October 20

• Following issuance of any necessary RAIs regarding the third pilot LAR review o Incorporate pilot LAR lessons learned into NEI 17-02 o Updated NEI 17-02 will be submitted for NRC review and approval - Anticipated 2nd Quarter 2018 7

Bruce Montgomery Director, Strategic Planning NEI 17-02 NEI Overview

Table of Contents

• Section 1: Introduction

• Section 2: Compliance with Tornado-generated Missile Design and Licensing Basis

• Section 3: Overview of TMRE Methodology

• Section 4: Identify Nonconforming and Vulnerable SSCs

• Section 5: Perform Plant TMRE Walkdown

• Section 6: Determine Site Tornado Hazard 9 Frequency

Table of Contents (cont.)

• Section 7: Evaluate Target and Missile Characteristics

• Section 8: Develop TMRE PRA Model

• Section 9: Quantify Risk, Perform Sensitivity Studies, and Compare to Thresholds

• Section 10: License Amendment Request 10

Alex Gilbreath PRA Engineer, Southern Nuclear TMRE Tornado Hazard Frequency

=

Background===

• The initiating event for the TMRE is a tornado strike.

• Initiating event frequencies are site-specific.

• In general, higher intensity means lower frequency.

• Multiple intensity scales

• Climatology data is readily available in NUREG/CR-4461, Rev. 2.

12

Hazard Frequency Calculation

• Develop the site-specific hazard curve.

• Use Fujita (F-Scale) wind speed data from the NUREG to plot a hazard curve.

• Determine the site-specific frequency that corresponds to the beginning and end of each range.

• Calculate the initiating event frequency for each tornado intensity range 13

Example Hazard Frequency Calculation

• The end result is a plant-specific initiating event frequency for each F-scale tornado.

Intensity Initiating Event Frequency F2 8.56E-05 F3 2.16E-05 F4 5.63E-06 F5 1.08E-06 F6 5.95E-08 14

Leo Shanley Manager, JENSEN HUGHES TMRE Missile Impact Parameter (MIP) and Missile Characteristics

Topics Covered

• Exposed Equipment Failure Probability (EEFP)

• Missile Impact Parameter (MIP) o Definition of MIP o MIP Values for Use in the EEFP

• Discuss TMRE Missile Inventories o Classifying Missiles o Missile Confirmatory Walkdowns 16 o Outage Impacts and Temporary Missiles

Exposed Equipment Failure Probability

• The Exposed Equipment Failure Probability (EEFP) is used to determine the conditional probability that an exposed SSC is hit and failed by a tornado missile, given a tornado of a certain magnitude EEFP =

MIP x # of Missiles x Target Exposed Area x Fragility

• The EEFP serves as the basic event failure probability for the tornado missile strike failure mode of exposed equipment (or targets) 17

Missile Impact Parameter (MIP)

• MIP can be thought of as a missile flux MIP = Probability of Missile Hit / ft2 / missile / tornado 18

Missile Impact Parameter (MIP)

• MIP values were derived using published TORMIS data (EPRI NP-768) o NEI 17-02, Appendix B provides the basis for the MIP values to use in the TMRE o NEI 17-02 MIP values apply generically to all sites

• Separate MIP values are provided for each F-Scale tornado from F2 to F6

• Separate MIP values are provided for Near Ground and Elevated targets 19

MIP Values from NEI 17-02 Tornado Elevated Near Ground Intensity Targets (>30) Targets (<30)

F2 5.8E-11 1.1E-10 F3 2.0E-10 3.6E-10 F4 3.4E-10 6.3E-10 F5 8.7E-10 1.6E-09 F6 1.3E-09 2.4E-09 20

Number of Missiles

• The number of missiles used in the EEFP calculation are provided in NEI 17-02

• Site verifies that the number of missiles is bounding

• Missile inventory is based on potential missiles within ~2500 of targets

• NEI 17-02 Section 5 provides details on missile inventory walkdowns 21

Number of Missiles from NEI 17-02 Tornado # of Missiles Intensity F2 155,000 F3 155,000 F4 205,000 F5 240,000 F6 240,000 22

Missile Inventory Walkdowns

• The missile inventory walkdown is a separate walkdown

• Guidance and examples are provided in Section 5 of NEI 17-02

• NEI 17-02 Table 5-2 provides list of 23 types of missiles (structural and nonstructural).

• Examples:

o Pipes, rebar, utility pole, wood beams and planks, pavers, concrete blocks, drums, gas cylinders, vehicles 23

Temporary Missiles

• Missile inventories will vary over time - do not need to be recalculated due to nominal changes.

• Construction o Additional structures evaluated to confirm TMRE missile inventory remains bounding o Sensitivity study to account for construction-related missiles 24

Leo Shanley Manager, JENSEN HUGHES TMRE Targets

Overview

• Describe the TMRE Vulnerable SSC Walkdown

• Describe Target Characteristics

• Target Area Calculations 26

TMRE Vulnerable SSC Walkdown

• Collect data to inform modifications to the PRA to develop the TMRE model

• Confirm vulnerability of SSCs from Discovery Walkdowns

• Identify additional vulnerabilities and targets

• Review PRA operator action access pathways

• Document details of targets (dimensions, elevation, shielding, robustness, and correlation) 27

High Wind Equipment List (HWEL)

• The HWEL is a list of SSCs that need to be considered vulnerable to tornado missiles (and/or tornado wind pressure) in the TMRE PRA

• The initial HWEL should contain o The list of vulnerable SSCs determined as part of the discovery activities o A list of potentially unprotected SSCs from the TMRE PRA

• The HWEL will be updated based on information and observations from the Vulnerable SSC 28 walkdowns

Operator Actions Outside Cat I Structures

• Identify PRA operator actions that are performed outside Category I structures or require transit outside Category I structures

• Review actions with an operator prior to the walkdown 29

Non-missile Related SSC Failure Modes

• Located inside non-Category I structures due to structural collapse from tornado winds

• Located inside non-Category I structures, such as the Turbine Building, due to tornado missiles

• Located outside, but near, non-Category I structures due to structural failure of the non-Category I structure 30

Example Targets Turbine-driven AFW pump steam exhaust stack 31

Example Targets Steam relief exhaust stacks 32

Example Targets Exposed Service Water piping 33

Missile Barriers Wall behind door limits exposure of SSCs to missiles going through the door 34

Missile Barriers

• Missile protection on the side of the EDG room

• Shielding should have been evaluated as part of the discovery walkdown 35

Target Areas

• Exposed area of each target must be determined for EEFP

• Targets inside Category I structures may be vulnerable to a non-rated opening o The effective area is the smaller of the opening or the target itself

• Target may be partially shielded, so that entire area of target is not exposed to missiles o Examples: Pipe or cable tray mounted on wall, tank in a corner 36

Leo Shanley Manager, JENSEN HUGHES TMRE Targets and Exposed Equipment Failure Probability

Overview

• Describe how robust targets are addressed in the EEFP

• Describe EEFP calculations and provide examples 38

Robust Targets

• EEFP calculations assume that fragility of the target is 1.0 (when struck by a missile, that target will fail to perform its function)

• Some targets are very robust/sturdy and are not damaged by all missile types o Analyses done to estimate what missile types can damage certain robust targets, to reduce the number of missiles (# of Missiles) used in the EEFP calculation

• NEI 17-02 provides missile ratios for target 39 type/failure mode

Robust Target Types and Failure Modes

• Several robust target types:

o Exposed Pipes o Exposed Tanks o SSCs below Concrete Roofs o SSCs behind Steel Doors

• Pipes, tanks and roofs are further divided based on thickness and pipe diameter

• Failure modes are perforation and crushing/crimping 40

Example EEFP Calculation Torna MIP # of Target Fragil EEFP do (Near Missiles Expos ity Intens Groun (non- ed ity d robust) Area Target (ft2)

)

F2 1.1E-10 155,000 12 1.0 2.0E-04 F3 3.6E-10 155,000 12 1.0 6.7E-04 F4 6.3E-10 205,000 12 1.0 1.5E-03 F5 1.6E-09 240,000 12 1.0 4.6E-03 41 F6 2.4E-09 240,000 12 1.0 6.9E-03

Alex Gilbreath PRA Engineer, Southern Nuclear TMRE PRA Modeling

Overview

• The TMRE PRA model is the basis for the risk-informed license amendment.

o Calculate risk associated with non-conforming SSCs.

o Starting point is the plant-specific peer-reviewed internal events model.

43

Event Tree/Fault Tree Selection

• The TMRE assumes LOOP/RX Trip will occur o LOOP and SBO event trees typically represent the tornado accident sequence.

o Other trees should be reviewed for tornado impact as well.

• The TMRE assumes LOOP is non-recoverable 44

Compliant/Degraded Case

• The purpose of the TMRE is to calculate the difference in risk between plant configurations.

o Compliant case o Degraded case - Nonconforming SSCs 45

Other Modeling Considerations

• Operator actions in the PRA must be examined for feasibility.

o Structure Considerations o Timing Considerations

• Non-feasible operator actions are not credited (i.e.

set to 1 or TRUE) in both cases

• TMRE model accounts for failure of non-Category I structures and exposed non-safety related SSCs.

46

Target Impact Basic Events 47

PRA Technical Adequacy

• Internal Events o Peer-reviewed o As-built, as-designed o Address open findings

• TMRE specific supporting requirements 48

Leo Shanley Manager, JENSEN HUGHES TMRE Quantify Risk and Sensitivity Analyses

Topics Covered

• Overview of CDF and LERF Quantification

• TMRE Sensitivity Analyses o Zonal vs. Uniform Missile Distribution o MIP for Highly Exposed Targets o Base Case Conservatisms o Open F&Os

• Risk Metrics and Thresholds 50

Compliant vs. Degraded Cases

• RG 1.174 requires an evaluation of the change in risk (CDF and LERF)

• Compliant Case o Configuration where the plant is built per the required design/licensing bases o All SSCs required to be protected against missiles are assumed to be so protected, even if they are not

• Degraded Case o This is the current configuration of the plant (i.e.,

with potential non-conformances for tornado 51 missile protection)

Quantify Risk

• Need to quantify the compliant case and the degraded case for CDF and LERF o Increase in CDF/LERF (i.e., the delta) is simply:

CDF = CDFDegraded - CDFCompliant LERF = LERFDegraded - LERFCompliant 52

Sensitivity Analyses

• TMRE-specific sensitivity calculations are discussed in NEI 17-02 o Zonal vs. Uniform Missile Distribution o Missile Impact Parameter for Highly Exposed Targets o Compliant Case Conservatisms

• Address open findings in the internal events PRA model 53

Zonal vs. Uniform Missile Distribution

• MIP was derived from simulation results for a plant with a uniform missile distribution o Realistic missile distribution is variable (i.e., zonal) o Large local missile inventory may lead to higher missile fluxes and thus higher target hit probabilities

• Sensitivity studies done to determine potential magnitude of missile hit probability 54

Zonal vs. Uniform Missile Distribution

• Threshold to perform sensitivity:

o CDF > 10-7/yr or LERF 10-8/yr

• Increase EEFP for targets with Risk Achievement Worth (RAW) > 2.0 o Only affects basic events for F4 - F6 tornadoes o Increase EEFP by 2.75x

• Quantify CDF and LERF 55

Highly Exposed Targets

• SSCs for which all the following apply:

o Not located inside a Category I structure (i.e., either outside or in a non-Category I structure) o Not protected against horizontal missiles o Has an elevation less than 30 above grade 56

Sensitivity for Highly Exposed Targets

• Threshold to perform sensitivity:

o CDF > 10-7/yr or LERF 10-8/yr

• Increase EEFP for highly exposed targets with Risk Achievement Worth (RAW) > 2.0 o Only affects basic events for F4 - F6 tornadoes o Increase EEFP by 2.5x

• Quantify CDF and LERF 57

Sensitivity for Conservative Assumptions

• Conservative assumptions in the compliant case may not be conservative for CDF and LERF calculations o Review cutsets in the top 90% of the TMRE compliant case to identify conservatisms related to SSC failures o Perform a sensitivity study to determine the potential impact of conservative equipment failures 58

Comparison to Risk Thresholds

• Evaluate against risk thresholds in RG 1.174 o CDF < 10-6/yr and LERF < 10-7/yr

• Address defense-in-depth and safety margins 59

Ken Lowery Senior Licensing Engineer TMRE Southern Nuclear License Amendment Request

LAR Process

• Preparation

• Pre-Submittal Meeting

• Submittal

• Acceptance Review

• RAIs

• SER 61

TMRE LAR Development

• Overall Objective of a TMRE LAR

• Summary Description

• Detailed Description o Background information o Current Licensing Basis requirements for tornado missile protection o Reason for the proposed change 62

TMRE LAR Development (cont.)

• Technical Evaluation o TMRE Methodology o Traditional Engineering Considerations (RG 1.174)

• Defense-in-Depth

• Safety Margins o Risk Assessment (RG 1.174) 63

TMRE LAR Development (cont.)

• Regulatory Evaluation o Applicable Regulatory Requirements/Criteria o No Significant Hazards Consideration Analysis

• Environmental Consideration 64

Summary 65