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Korea Hydro & Nuclear Power Co., Ltd - Revised Response to RAI 434-8352 for Question 19-85 (Rev.2)
	ML18086B653
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Issue date:	03/27/2018
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19-85_Rev.2 - 1 / 3 KEPCO/KHNP REVISED RESPONSE TO REQUEST FOR ADDITIONAL INFORMATION APR1400 Design Certification Korea Electric Power Corporation / Korea Hydro & Nuclear Power Co., LTD Docket No.52-046 RAI No.:

434-8352 SRP Section:

SRP 19 Application Section: 19.1 Date of RAI Issue:

03/08/2016 Question No. 19-85 10 CFR 52.47(a)(27) states that a DC application must contain an FSAR that includes a description of the design-specific PRA and its results. In addition, Standard Review Plan (SRP)

Chapter 19.0, draft Revision 3, Items 25 through 37 on Pages 19.0-18 and 19.0-19 provide the acceptance criteria for a PRA-based seismic margin analysis (SMA) submitted in support of a design certification (DC) application, in part, it states that The staff will determine that the applicant has performed a PRA-based SMA to determine the seismic capacity of the plant and for each sequence that may lead to core damage or large release. In addition, SRP Chapter 19,Section III Review Procedures / Design-Specific PRA (PRA-Based SMA), states It is important that the plant systems analysis focus on those sequences leading to core damage or containment failures, including applicable sequences leading to the following containment failures: (1) loss of containment integrity, (2) loss of containment isolation, and (3) loss of function for prevention of containment bypass. The applicant should address the following operating modes in the analysis: (1) at power (full power), (2) low power, and (3) shutdown.

In APR1400 DCD, Section 19.1.5.1.1 Description of the Seismic Risk Evaluation, the applicant describes the methodology (Tasks (a) through (g)) used to evaluate the seismic margin.

However, the staff review finds that, among these tasks, only Task (b) Development of seismic equipment list and Task (e) Fragility analysis are discussed in detail in Sections 19.1.5.1.1.1 and 19.1.5.1.1.2, respectively. Therefore, in order for the staff to reach a reasonable assurance finding, please address by providing and discussing in detail the analyses performed for Tasks (a), (c), (d), (f), and (g) in theAPR1400 DCD, including the following items:

a) Consequential initiating events that were actually quantified in the seismic model b) Recoveries of mitigating systems and seismic related failures that were credited in the PRA-based seismic margin analysis (SMA) c)

The modeling of structures, systems, and components (SSCs) that are not on the seismic equipment list (SEL) in SMA analysis, if any

19-85_Rev.2 - 2 / 3 KEPCO/KHNP d) The protection against flooding, spraying, steam impingement, pipe whip, jet forces, missiles, fire and the effect of failure of any non-seismic Category I equipment e) Evaluation of human error probabilities (HEPs) for the operator actions included in the analysis f)

Operator actions that were identified as being important to mitigating seismic accident sequences g) Accident sequences (at cutset level) that were examined to assess the plant-level high confidence of low probability of failures (HCLPF) capacity h) Evaluation of containment performance as described in Section 5.1.1 of DC/COL-ISG-20 as referenced in the SRP so that the appropriate Level 2 SSCs are appropriately included in the SEL i)

Significant functions, SSCs, and operator actions that are limiting in determining the plant-level HCLPF capacity.

Response - (Rev. 2)

The PRA-based seismic margin analysis (SMA) for at-power conditions was performed. Both at-power and LPSD SMA results reflect the latest PRA model updates. Details of the at-power PRA-based SMA are documented in DCD 19.1.5.1, Seismic Risk Evaluation and includes the plant systems analysis focus on those sequences leading to core damage or containment failures, including applicable sequences leading to loss of containment integrity, loss of containment isolation, and loss of function for prevention of containment bypass. provides the DCD markups summarizing how the APR1400 PRA-based SMA was applied to at power conditions. Results of the at-power PRA-based SMA include the seismic cutsets and the sequence HCLPF capacities, as well as assessment of random failures and operator actions. In order to provide the modeling information, the detail information for event trees and failure mode and effects analysis for the at-power conditions are provided in Attachments 2 and 3. In addition, Attachment 4 provides a cross-walk to how the at-power PRA-based SMA was developed to follow NRC Interim Staff Guidance on Implementation of a Probabilistic Risk Assessment-Based Seismic Margin Analysis for New Reactors DC/COL-ISG-020. Attachment 5 provides the information of the fault tree in APR1400 PRA-based SMA for at-power.

DCD Section 19.1.5.1.1 and 19.1.5.1.2 are to be revised to reflect the at-power PRA-based SMA results, as shown in Attachment 1, and address each of the RAI items (a) through (i), and cross-referenced with the respective DCD subsection to address the item, as shown below:

a) Treatment of consequential initiating events is described in Section 19.1.5.1.2.1 of the DCD Rev. 1 (Refer to Attachment 1).

b) Recoveries of mitigating systems and seismic related failures that were credited in the PRA-based seismic margin analysis (SMA) are described in Section 19.1.5.1.1.4.9 j of the DCD Rev. 1 (Refer to Attachment 1).

19-85_Rev.2 - 3 / 3 KEPCO/KHNP c)

The modeling of structures, systems, and components (SSCs) that are not on the seismic equipment list (SEL) in SMA analysis is discussed in 19.1.5.1.1.2 of the DCD Rev. 1 (Refer to Attachment 1).

d) The protection against flooding, spraying, steam impingement, pipe whip, jet forces, missiles, fire and the effect of failure of any non-seismic Category I equipment is discussed in Section 19.1.5.1.1.4.9 h of the DCD Rev. 1 (Refer to Attachment 1).

e) Human error probabilities (HEPs) for the operator actions included in the analysis is discussed in Section 19.1.5.1.1.4.9 p of the DCD Rev. 1 (Refer to Attachment 1).

f)

Operator actions that were identified as being important to mitigating seismic accident sequences are described in Section 19.1.5.1.2.4 of the DCD Rev. 1 (Refer to ).

g) Accident sequences (at cutset level) that were examined to assess the plant-level HCLPF capacity is described in Section 19.1.5.1.2.4 of the DCD Rev. 1 (Refer to ).

h) The at-power SMA event trees include top events that evaluate containment performance, and cutsets are provided for all the seismic event trees. Containment failure, containment isolation failure and loss of function for prevention of containment bypass is described Section 19.1.5.1.2.4 of the DCD Rev. 1 (Refer to Attachment 1).

i)

Significant functions, SSCs, and operator actions that are limiting in determining the plant-level HCLPF capacity is discussed in Section of the DCD Rev. 1 (Refer to ).

Impact on DCD The previous DCD markup which relate to DCD Section 19.1.2.3 and 19.1.5.1 will be withdrawn.

These section will be superseded as discussed above, and provided in Attachment 1.

Impact on PRA There is no impact on the PRA.

Impact on Technical Specifications There is no impact on the Technical Specifications.

Impact on Technical/Topical/Environmental Reports There is no impact on any Technical, Topical, or Environmental Report.

TABLE OF CONTENTS NUMBER TITLE PAGE 19.1.2.3 PRA Technical Adequacy............................................................................. 4 19.1.5.1 Seismic Risk Evaluation................................................................................ 6 19.1.5.1.1 Description of the Seismic Risk Evaluation.................................................. 6 19.1.5.1.1.1 Selection of Review Level Earthquake....................................................... 10 19.1.5.1.1.2 Development of Seismic Equipment List.................................................... 10 19.1.5.1.1.3 Identification of Seismic Initiating Event Categories................................. 13 19.1.5.1.1.4 Development of System Models................................................................. 14 19.1.5.1.1.4.1 Direct Core Damage (S-DMG)................................................................... 14 19.1.5.1.1.4.2 Station Blackout (S-SBO)........................................................................... 16 19.1.5.1.1.4.3 Loss of All Instrumentation and Control (S-IC)......................................... 17 19.1.5.1.1.4.4 Main Steam Line Break (S-MSLB)............................................................. 18 19.1.5.1.1.4.5 Total Loss of Component Cooling Water (S-TLOCCW)........................... 18 19.1.5.1.1.4.6 Anticipated Transient Without Scram (S-ATWS)...................................... 20 19.1.5.1.1.4.7 Loss of Coolant Accidents.......................................................................... 20 19.1.5.1.1.4.8 Loss of Off-Site Power................................................................................ 22 19.1.5.1.1.4.9 Seismic Event Additions to Internal Events Fault Trees............................ 22 19.1.5.1.1.5 Seismic Fragility Analysis........................................................................... 26 19.1.5.1.2 Determination of Seismic Margin in the Design......................................... 27 19.1.5.1.2.1 Seismic Equipment List............................................................................... 27 19.1.5.1.2.2 Seismic Fragility Analysis Results.............................................................. 28 19.1.5.1.2.3 Plant Level HCLPF..................................................................................... 29 19.1.5.1.2.4 3 Risk Insights................................................................................................ 31 19.1.5.1.2.4.1 Core Damage Risk Insights......................................................................... 31 19.1.5.1.2.4.2 Containment Failure Risk Insights.............................................................. 35 19.1.9 Combined License Information................................................................... 38 19.1.10 References................................................................................................... 40 APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (1/150)

LIST OF TABLES NUMBER TITLE PAGE Table 19.1-4

..................................................................................................................... 41 Table 19.1-41 Systems Considered for Seismic Equipment List..................................... 42 Table 19.1-42 Seismic Equipment List.............................................................................. 44 Table 19.1-43 Seismic Fragility Analysis Results Summary............................................. 63 Table 19.1-44A At-Power Seismic Event Direct Core Damage Initiator Cutsets............... 68 Table 19.1-44B At-power Seismic Event Top 100 core damage cutsets of Non-Direct Core Damage Initiator......................................................................................... 79 Table 19.1-44C At-power Direct Containment Failure cutsets.......................................... 117 Table 19.1-44D At-power Seismic event Top 100 containment failure cutsets of Non-Direct Containment Failure Initiator.................................................................... 124 APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (2/150)

LIST OF FIGURES NUMBER TITLE PAGE Figure 19.1-48A At-Power Seismic Event Tree.............................................................. 148 Figure 19.1-48B At-Power Seismically Induced Small LOCA Event Tree.................... 149 Figure 19.1-48C At-Power Seismically Induced LOOP Event Tree.............................. 150 APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (3/150)

19.1.2.3 PRA Technical Adequacy The content of the Probabilistic Risk Assessment (PRA) and the steps taken to provide for its technical quality are consistent with the guidance in the ASME/ANS PRA Standard and NRC RG 1.200. This PRA Standard presents high level requirements (HLRs) for various PRA technical elements and, for each HLR, a set of more detailed supporting requirements (SRs). The supporting requirements are related to the three capability categories addressed in the standard.

These requirements were formulated for application to operating nuclear power plants, and in some cases cannot be explicitly satisfied for a PRA performed in the design phase.

Table 19.1-1 provides a summary of the degree to which the APR1400 PRA relates to the capability categories for the nine technical elements addressed in the ASME/ANS PRA Standard.

A COL applicant and/or holder that references the APR1400 design certification should conduct a peer review of the PRA relative to the ASME/ANS PRA Standard prior to use of the PRA to support risk-informed applications (COL 19.1(5)). The findings and observations from this review should be dispositioned after the review to provide reasonable assurance that captured issues are addressed. Changes that are made to the PRA model and associated documentation as a result of this resolution process are to be conducted in a manner consistent with Subsection 19.1.2.4.

The ASME/ANS PRA Standard does not fully address Low Power and Shutdown (LPSD) modes of operation (the standard is still in draft form). For analyses in which the ASME/ANS PRA Standard does not directly apply, the APR1400 PRA has used the latest industry guidance available to perform assessments commensurate with the uses of the PRA. This additional guidance includes the following:

a. Internal fire analysis: The internal fire PRA uses the guidance provided in NUREG/CR-6850 and its supplement for at-power fire analysis, and NUREG/CR-7114 for LPSD fire analysis. These reports document This report documents the latest methodology available for practical assessment of internal fires in nuclear power plants. Limitations in applying this methodology because some design details are not yet available are addressed in Subsection 19.1.5.2.

b. LPSD analysis: The ASME/ANS PRA Standard and the associated NRC guidance on PRA adequacy apply only to accidents initiated from power operation. The APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (4/150)

APR1400 PRA also addresses LPSD modes. The LPSD PRA methodology and level of detail are consistent with industry practice. The LPSD methodology and modeling are state of the art and are designed to meet the requirements of the draft ANS/ASME LPSD PRA Standard (Reference 9).

c. PRA-based seismic margins assessment: The APR1400 PRA uses a PRA-based SMA approach to evaluate potential vulnerabilities to seismic events. The methodology and level of detail used to develop the PRA-based SMA are consistent with industry practice at the DC stage. The methods as implemented for the United States is consistent with guidance in SECY-93-087 and follows the general approach delineated in the NRC staff interim guidance document DC/COL-ISG-020 (Reference 57). A self-assessment has been conducted to ensure that the technical adequacy of APR1400 PRA-based SMA meets NRC recognized guidance and requirements. ISG-028 (Reference 79) and ASME/ANS Standard. Technical adequacy is confirmed for at-power PRA-based SMA following guidance in the ASME/ANS standard, including: 1) Seismic Hazard Analysis: is performed in accordance with section 5.2-1 of ASME/ANS Standard; 2) Seismic Fragility Analysis: is performed in accordance with 5.2-2 of ASME/ANS Standard; and 3)

Seismic Plant Response Analysis: is performed in accordance with 5.2-3 of ASME/ANS Standard. Self-assessment for LPSD PRA-based SMA has been conducted to follow the guidelines in the draft ANS/ASME LPSD PRA Standard.

However, since the PRA-based SMA was conducted for the design certification, it does not reflect unavailable information due to site-specific, as-built and/or as-operated plant conditions.

d. Other external events: The APR1400 PRA for design certification uses a screening method to address other external events that could represent challenges to safe operation. The screening approach follows guidance provided in the ASME/ANS PRA Standard.

APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (5/150)

19.1.5.1 Seismic Risk Evaluation The scope of a seismic risk evaluation is limited due to the design-specific aspects within the scope of the design certification (DC). The design-specific PRA developed for the DC stage does not evaluate site specific information (e.g., local hazards, switchyard and offsite grid configuration, and ultimate heat sink) and cannot explicitly model all aspects of the design (e.g., balance of plant).

Without a site-specific probabilistic seismic hazard analysis (PSHA), as-built information, etc., the NRC guidance allows for a PRA-based seismic margin analysis to evaluate risk at the DC stage. Evaluation of the risk due to seismic events was performed using a PRA-based seismic margins approach for the ARR1400. This subsection describes the seismic risk evaluation including the results of the evaluation. The scope of this analysis is at-power operation. The seismic risk evaluation for low power and shutdown states is presented in Section 19.1.6.5.

19.1.5.1.1 Description of the Seismic Risk Evaluation The seismic margin methodology was applied to estimate the seismic margin and accident sequences for APR 1400. The seismic margin for the APR1400 is evaluated by using PRA-based SMA. This methodology satisfies the recommendation of SECY-93-087 (Reference 8), as modified and approved by EPRI 3002000709 (Reference 77), for a seismic risk evaluation. The PRA-based SMA identifies potential vulnerabilities and demonstrates seismic margins beyond the design basis safe shutdown earthquake (SSE).

The capacity of components required to bring the plant to safe and stable conditions is assessed. The plant structures, systems, and components (SSCs) identified as important to seismic risk are addressed.

a.

Selection of review level earthquake The starting point to perform PRA-based SMA is to select a review level earthquake (RLE). PRA-based SMA demonstrates that sufficient margin in seismic design exists by showing the high confidence of low probability of failures (HCLPFs) of the plant and components is greater than or equal to the RLE. The RLE is 1.67 times of the certified seismic design response spectra (CSDRS) in Chapter 3, which are shown in Figure 3.7-1 and 3.7-2. The RLE APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (6/150)

for APR1400 is 0.5g which is 1.67 times of SSE and is consistent with the requirement of DC/COL-ISG-020.

b.

Development of seismic equipment list The seismic equipment list (SEL) is developed from the internal events PRA model. The SEL provides a documented list of SSCs that could be used to response to an earthquake or mitigate potential plant damage initiated by a seismic event. Also, earthquake-specific SSCs such as passive components and structures related to a safety function, which are not addressed in the internal events PRA model, are included in the fragility analysis and system analysis.

c.

Identification of seismic initiating event category Initiating events due to a seismic event are identified based on the internal events PRA. However, there are some major differences between seismic and internal events for the purpose of identifying the initiating event category, which are as follows: 1) seismic events may damage passive plant components and structures (e.g., steam generators, auxiliary building, etc.) that are not explicitly modeled in the internal events PRA; and 2) seismic events may simultaneously damage multiple SSCs in the plant.

d.

Development of system models The PRA-based SMA system models are developed from the internal events PRA model to include the important accident sequences. This model also contains random failures and human errors from the internal events PRA.

System models are modified to accommodate a seismic event and seismic induced failures. The model is used to estimate seismic margins and to identify vulnerabilities in the design.

e.

Fragility analysis Per ISG-020 (Reference 57), two methods can be used to calculate the structure, system and component HCLPF capacity to demonstrate a seismic margin over the design-specific CSDRS. They are the Conservative Deterministic Failure Margin (CDFM) approach and the Separation of Variables approach. For the APR1400 Design Certification application, the CDFM approach is used. As APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (7/150)

delineated in ISG-020, APR1400 design-specific documents and drawings are reviewed to identify potential failure modes of the individual SSCs and APR1400 design-specific seismic demands are used. As for capacity, code capacities are used and inelastic energy absorption capability, if any, is considered. The resulting HCLPF capacities are described in DCD Section 19.1.5.1.2.2.

At the design certification phase, specific design data for the balance of plant (BOP) components, such as material properties, analysis results, qualification test information, etc. are not available. Appendix E of EPRI-NP-1002988 (Reference 58) presents example calculations showing that the equipment designed for 0.25 g SSE can have 0.5 g or higher HCLPF considering the conservatism in the design process. The EPRI-NP-6041 (Reference 39) indicates that Seismic Category I concrete structure and BOP equipment can have 0.5 g HCLPF as long as the structure and the equipment are designed in accordance with the current code and standard and the anchorage is rugged.

The generic fragility data provided by the Electric Power Research Institute (EPRI) Utility Requirements Document (Reference 37) show the BOP components have HCLPF capacities higher than 0.5 g.

The seismic capacity for equipment qualified by testing should ensure that the equipment should remain functional operation within 1.67 times the required response spectra (RRS) as provided in the respective equipments procurement specification. The seismic demands to equipment defined in terms of RRS should use CSDRS-based seismic input and account for the structural amplifications caused by the supporting structures, including soil-structure interaction effects and supporting systems, and incorporate an additional seismic margin factor (1.67 times RRS).

f.

Evaluation for the plant seismic capacity There are two acceptable approaches to evaluate the plant seismic margin as described in NUREG/CR-4482 (Reference 38).

1) Min-max method, in which HCLPF is assessed for accident sequences by taking the lower HCLPF value for components operating under OR logic and the highest HCLPF value for components operating under AND logic.

APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (8/150)

2) Convolution method, in which probabilities of non-seismic and operator failures are included in the calculation as well as the component fragilities.

This is a fully quantitative approach in which the importance and contribution of seismic as well as non-seismic failures can be assessed quantitatively.

For the APR1400 PRA-based SMA, the min-max method is selected as the appropriate method at the design certification phase since detailed plant-specific data are unavailable at the design certification stage. This method is accomplished by calculating HCLPFs for each seismic core damage cutset.

Cutset HCLPFs are determined considering seismic-induced failures. Cutsets with random equipment failures and/or operator action failures are reviewed separately.

g.

Demonstration of seismic margin in the design The objective is to demonstrate that there is sufficient seismic margin in the design. If the plant HCLPF earthquake is less than the RLE, modification of the design or refinements of the model are required. A PRA-based seismic margin analysis should provide a clear understanding of significant seismic vulnerabilities and other seismic insights to demonstrate the seismic robustness of a standard design. Accordingly, the level of detail of a PRA-based seismic margin analysis needs to be sufficient to gain risk insights, in conjunction with the assumptions made in the PRA-based seismic margin analysis, and to identify and support requirements important to the design and plant operation. To this end, Part 5, Requirements for Seismic Events at-Power PRA, of the American Society of Mechanical Engineers/American Nuclear Society (ASME/ANS) PRA standard, RA-Sa-2009 (Reference 2) is used to the extent practical and as endorsed by RG 1.200, An Approach for Determining the Technical Adequacy of Probabilistic Risk Assessment Results for Risk-Informed Activities, Revision 2 (Reference 3), in guiding the PRA-based seismic margin analysis supporting a DC application.

h. Sensitivities and Uncertainties APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (9/150)

Uncertainties are taken into account explicitly in the fragility development and in evaluating non-seismic failures of equipment. Because the APR1400 PRA-based SMA is primarily qualitative, no sensitivity studies are conducted.

19.1.5.1.1.1 Selection of Review Level Earthquake Development of the PRA-based SMA uses a Review Level Earthquake (RLE) which has a reasonable probability of occurring, but does not mask or overwhelm systems needed to respond to the event. For the APR1400, the RLE is selected based on the design response spectra of the site-independent SSE which is developed from the certified seismic design response spectra (CSDRS). The peak ground acceleration (PGA) of the CSDRS has been established as 0.3g for the APR1400 design for both the horizontal and vertical directions.

To perform the PRA-based SMA, the RLE is selected as 1.67 times the SSE or 0.5g which is consistent with the requirement of ISG-020.

19.1.5.1.1.2 Development of Seismic Equipment List The SEL provides a documented list of the plant SSCs that could be used to respond to an earthquake or mitigate potential reactor plant damage initiated by a seismic event. This design certification SEL then is used to develop the PRA-based SMA systems logic model (i.e., event trees and fault trees).

While the objectives of the internal events PRA and PRA-based SMA are similar, there are differences between the SSCs included in each of the models. As a result, not all SSCs included in the internal events PRA model are included in the SEL. For example, many balance-of-plant components, such as the main feedwater system, condensate system, condensate storage and transfer system, AAC diesel generator, steam generator blowdown system are not considered in the PRA-based SMA since they depend on offsite power, which is expected to be unavailable after a seismic event. In addition, some SSCs are not modeled explicitly in the internal events PRA but must be considered in the PRA-based SMA and, therefore, in the SEL. Examples include distribution systems such as piping, cable trays, ventilation ducts, and structural items such as masonry block walls that could fail and damage nearby safety equipment. The containment polar crane is designed as seismic category II in accordance with NRC RG 1.29. The dynamic behaviors according to the seismic event are restricted by the seismic restraints, which prevent the crane from jumping of falling during an earthquake. This crane is designed to maintain their integrity APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (10/150)

during and after SSE. Normal parking position of the polar crane is based on a location that does not interface with seismic category I equipment. Jib cranes are also designed to be physically separated during at-power operation. Therefore, these cranes are assumed not to impact seismic category I equipment during at-power conditions.

The first step in developing the SEL was to determine the potential initiating events that could occur as a result of a seismic event. Initiating events considered could occur either directly as a result of the earthquake or due to random or consequential events that occur subsequent to the earthquake. A discussion of initiating events evaluated in the PRA-based SMA, including consequential initiating events, is provided in Section 19.1.5.1.1.3.

Identification of potential initiating events make use of the internal events PRA for guidance. The safety functions that would be required to respond to initiating events identified above were determined based on EPRI NP-6041 (Reference 39) and NUREG-1407 (Reference 40). These safety functions are:

a.

Reactivity control

b.

Reactor Coolant System (RCS) pressure control

c.

RCS inventory control

d.

Decay heat removal

e.

Containment integrity The front-line systems used to meet the five safety functions were identified from the internal events PRA, including the additional required support systems.

Unlike the internal events PRA, only systems that do not require offsite power were selected.

Because the offsite power grid, switchyard insulators, and large transformers have relatively low seismic capacity, they cannot be relied on to provide power after a major earthquake.

Only systems that can be supported by the onsite emergency ac power sources are considered.

The initial list of equipment for the SEL is then identified using the following data sources:

a.

List of basic events from the internal events PRA

b.

The internal events PRA systems notebooks APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (11/150)

c.

Piping and instrumentation diagrams (P&IDs)

d.

Electrical diagrams (for offsite power and emergency power)

e.

Plant arrangement drawings

f.

Emergency Operating Guidelines (EOGs)

For the PRA-based SMA, the initial list of equipment was identified beginning with the internal events PRA and reviewing the system P&IDs and electrical diagrams to provide reasonable assurance that all necessary components are on the SEL. For example, components needed to provide reasonable assurance of system integrity or electrical isolation were examined. These components were identified and added to the SEL when appropriate. Small, passive, in-line filters that are supported only by the piping or ducting, and instrumentation, which are not required for mitigation of the seismic accident sequence are not included on the SEL (e.g., local instrumentation may be excluded, unless it is part of a plant procedure that would be implemented during a seismic event).

The following assumptions were used to develop the SEL: and the following components are considered to have seismically rugged capacity

a. The following components are considered to have seismically rugged capacity (i.e., having a HCLPF 2.5 times CSDRS)

a. 1) Piping and supports

b. 2) HVAC ducting, supports, and dampers

c. 3) Cable trays and supports, and electrical conduit

d. 4) Motor-operated valves

e. 5) Air-operated valves

f.

6) Solenoid-operated valves

g. 7) Pilot-operated safety relief valves

h. 8) Relief valves APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (12/150)

i.

9) Manual valves

j.

10) Check valves

k. 11) Instrumentation such as resistance temperature detectors, pressure transmitters, etc.

19.1.5.1.1.3 Identification of Seismic Initiating Event Categories Identification of feasible seismic initiating event categories for the PRA-based SMA is based on the initiating events defined for the internal events PRA. These events were reviewed to identify those that could be caused by a seismic event which would also impair equipment needed to mitigate the event. Then a determination was made as to whether the seismic-induced failures would require a unique response or would be evaluated by the seismic fault tree models.

All seismic events are assumed to cause a loss of offsite power (LOOP) and that transient event is explicitly considered. Other transient events considered in the internal events PRA could result from failure of plant components or systems. Failure of other support systems, e.g., loss of a 4kV AC bus, could occur during a seismic event. Due to the correlated simultaneous failures of multiple 4kV AC buses by earthquake, it is considered as seismic event specific Station Blackout (SBO). Therefore, for all the seismic specific initiators with total loss of a supporting system should be considered. The examples for this are loss of a 4kV AC bus and loss of one train safety-related DC bus. All the initiators by the total loss of a supporting system in the internal event are considered in the seismic event analysis.

The other initiating events that should be considered are supporting system failures due to a seismic event which are not considered in the internal event analysis. An example is loss of all I&C caused by the seismic-induced failure of ESF-CCS GC, LC and PPS cabinets.

In such an event, the plant operators would have no ability to control plant parameters.

Consequently, this event is evaluated explicitly. Similarly, the ATWS event requires unique plant response and the seismic event could induce the failures that prevent inserting the control rods.

Loss of coolant accident (LOCA) events are also considered to be induced by a seismic event. Large, medium, and small LOCAs are considered explicitly in the PRA-based SMA.

Excessive LOCAs are those breaks in the RCS that have a break flow larger than evaluated APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (13/150)

for large LOCA events considered in the internal events PRA. Excessive LOCA events could occur when multiple seismic failures occur simultaneously in the RCS. Such events as well as vessel rupture are considered as a direct core damage event and are considered bounded by auxiliary building or containment building failures. An interfacing systems LOCA is considered not credible and is discussed further below.

19.1.5.1.1.4 Development of System Models System logic models, i.e., fault trees, that were developed for the internal events PRA model were used as the basis for the PRA-based SMA logic models. The PRA-based SMA logic models include the seismic failures. Details of the fault tree logic model development for systems where explicit evaluation of seismic failures needed to be included are provided in the subsections that follow. The developed model was for seismic induced initiating events which were identified and shown in the seismic induced initiating event tree illustrated in figure 19.1-48A.

19.1.5.1.1.4.1 Direct Core Damage (S-DMG)

A seismic event that causes significant structural failure is assumed to preclude equipment operation and operator actions needed to prevent core damage because structural failure could cause widespread equipment failures. The fault tree for top event S-DMG was created to model seismic failure of structures. Failures included in this fault tree include the following:

Reactor Containment Two separate failures were considered in modeling seismic structural failure of the reactor containment, failure of the external containment structure and failure on the internal containment structure.

Auxiliary Building Seismic structural failure of the Auxiliary Building is modeled as direct core damage.

Nuclear Island Seismic induced sliding of the Nuclear Island is modeled as direct core damage.

APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (14/150)

Turbine Building Seismic structural failure of the Turbine Building is modeled as direct core damage.

Compound Building Seismic structural failure of the Compound Building is modeled as direct core damage.

EDG building and diesel fuel oil tank building are related to the function of EDG, but the EDG building and diesel fuel oil tank building would not impact to auxiliary building, because the governing failure mode for EDG building is the shear wall failure which is directed to the pararell of auxiliary building and diesel fuel oil tank building is located under the ground, therefore, it do not affect auxiliary building.

A seismic event that causes significant RCS component failure is assumed to lead to excessive LOCA which cannot be accommodated by the ECCS, and it is assumed to lead to direct core damage. These seismic induced failures are also included in the S-DMG.

Failures included in this fault tree include the following:

Reactor Pressure Vessel (RPV)

Seismic induced column support failure of the RPV is modeled as direct core damage.

Reactor Pressure Vessel Internal Failure Seismic induced core support barrel lower flange failure of the RPV internal is modeled as direct core damage.

Steam Generator Seismic induced Anchor failure of snubber lever support assembly failure of the Steam Generator is modeled as direct core damage.

Steam Generator Nozzle APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (15/150)

Seismic induced economizer nozzle failure of the Steam Generator is modeled as direct core damage.

Pressurizer Seismic induced pressurizer skirt support failure is modeled as direct core damage.

Reactor Coolant Pump (RCP)

Seismic induced RCP upper horizontal column support failure is modeled as direct core damage.

S-DMG is assumed to lead to containment integrity failure upon the seismic event. Thus it is assumed to lead to large release.

19.1.5.1.1.4.2 Station Blackout (S-SBO)

As described in the section 19.1.5.1.1.3, LOOP is assumed with the occurrence of seismic event and off-site power recovery is not credited in the seismic event. The HCLPFs for EDG building and diesel fuel oil tank building are higher than that for the auxiliary building and NI stability. Consequently, when these two buildings are failed then the auxiliary building is assumed to be failed. The failure of all three buildings would cause the unavailability of all EDGs, and it would lead to SBO. Therefore, the failure of EDGs will lead to the SBO without off-site power recovery and consequently lead to the direct core damage. The seismic induced failures of the equipment leads to seismically induced SBO.

Emergency Diesel Generator Building Diesel Fuel Oil Tank Building Emergency Diesel Generators (EDG)

Emergency Diesel Fuel Oil transfer pump Starting Air Tank Diesel Fuel Oil Day Tank APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (16/150)

Diesel Fuel Oil Storage Tank Silencer Air Intake Filter Lube Oil Water Heat Exchanger Motor Driven Fuel Oil Feed Pump EDG Room Emergency Exhaust Fan 125V DC Control Center 4.16kV MCSG Batteries & Racks Additionally, S-SBO is assumed to lead to containment isolation failure due to the loss of all I&C before or at the time of core damage.

19.1.5.1.1.4.3 Loss of All Instrumentation and Control (S-IC)

Mitigation of an accident requires that the operators have adequate indication available to progress through the emergency operation guidelines and operate the equipment necessary to control the plant. However, plant instrumentation and control (I&C) are not explicitly modeled in the internal events PRA. Loss of instrumentation and control is assumed to result directly in core damage.

Of the equipment on the SEL, Table 19.1-42, the ESF-CCS GC, ESF-CCS LC, and plant protection system (PPS) cabinets are needed to route and process signals and indications needed for the operators to control plant parameters and equipment. The cabinets all are located on the 156-foot elevation and have the same parameters for fragility values.

Specific fragility assessments of the cabinets were not performed. Rather, all cabinets were assigned a HCLPF of 0.5g and seismic failure of all the cabinets was modeled with a single, correlated failure.

The 480V MCC cabinets are located on the various building elevation, and specific fragility assessment of the cabinets were not performed. Loss of all 480V MCC is conservatively APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (17/150)

modeled as the one correlated event which leads to total loss of I&C. In addition to the seismic failure of the cabinets, loss of all 120 VAC instrumentation power also could cause a total loss of I&C. Loss of all 120 VAC is modeled as failure of the inverter and regulating transformer on each of the four 120 VAC power channels.

Though the failure of the equipment below does not directly cause loss of instrumentation

& control, it will cause numerous component failures. Thus the failure of the equipment below will cause similar circumstances as S-IC with respect to accident mitigation.

Therefore the equipment failures below are assumed to cause the initiating event as S-IC.

125V DC Battery Chargers 480V Load Center 480V Motor Control Center (MCC)

Main Control Room (MCR) Safety Consoles S-IC is assumed to lead to containment isolation failure due to the loss of all I&Cs before or at the time of core damage.

19.1.5.1.1.4.4 Main Steam Line Break (S-MSLB)

Seismic induced failure of MSSV, MSADV or MSSV is assumed to MSLB for which reactivity control is not assured, since steam line failure at auxiliary building location cause the containment isolation fail. Consequently, this initiating event is assumed to lead to direct core damage.

S-MSLB is assumed to lead to containment isolation failure due to the opening path through main steam line upon the seismic induced failure of the components above.

19.1.5.1.1.4.5 Total Loss of Component Cooling Water (S-TLOCCW)

Seismic induced failures of equipment which are lead to prompt or delayed loss of total CCW or total Essential Service Water (ESW) is defined as seismic induced total loss of component cooling water. Over time, the loss of ESW and CCW are essentially the same with respect to accident mitigation under seismic event. This initiating event is assumed to lead to direct core damage due to the loss of all cooling water over time. The seismic induced failures which will cause this initiating event are below.

APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (18/150)

Essential Service Water Intake Structure (ESW IS)

Component Cooling Water Heat Exchanger (CCW HX) Building Essential Service Water Pump CCW Heat Exchangers CCW Pump CCW Surge Tank Essential Chilled Water Pumps Essential Chillers ECW Compression Tank ECW Air Separator Essential Chilled Water System Control Panel AFWP Room Cubicle Cooler CCWP Room Cubicle Cooler SI Room Cubicle Cooler SC Pump & Mini-flow HX. Room Cubicle Cooler Mech. Pen. Room Cubicle Cooler CS Pump Room Cubicle Cooler Auxiliary Charging Pump Room Cubicle Cooler Charging Pump Room Cubicle Cooler Electrical Penetration Room Area Cubicle Cooler I&C Equipment Room Cubicle Cooler APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (19/150)

EDG Room Emergency Cubicle Cooler EDG Room Emergency Cubicle Cooler Essential Chiller & Pump Cubicle Cooler ESW Pump Room Supply Fan Containment failure event for this initiator is considered containment isolation failure and late overpressure failure before or at the time of core damage.

19.1.5.1.1.4.6 Anticipated Transient Without Scram (S-ATWS)

Seismic induced ATWS is modeled based on the seismic failure of control element drive mechanism (CEDM) leading to CEDM binding in the extension shaft. Due to the total failure of CEA insertion and limited capacity of secondary heat removal during the early phase of the accident, this initiator is assumed to directly lead to core damage.

S-ATWS is assumed to lead to containment failure due to the lower HCLPF of mitigation system than ATWS initiating event before or at the time of core damage.

19.1.5.1.1.4.7 Loss of Coolant Accidents Modeling of LOCAs for the PRA-based SMA is performed to identify insights related to seismic design of the plant. As with the internal events PRA, three sizes of LOCAs are considered, small, medium, and large. For seismic-initiated breaches in the RCS, there are significant uncertainties in the size of the break that would result from any specific failure.

That is, any seismic-induced failure of the RCS could result in a spectrum of break flow and analytical means are not available to predict the specific size of a break that would occur due to seismic-induced failure or the likelihood of a break range given a spectrum of potential seismically-induced failures.

Given the analytical limitations for determining seismic-induced LOCA break flow, a practice was employed to use available information to evaluate and express the three LOCA categories for the PRA-based SMA. For the PRA-based SMA, the available component fragility data are evaluated for identifying LOCA events and component seismic failures, that are considered to result in nuclear steam supply system (NSSS) boundary breaches, are used to categorize LOCA size categories. Component failures that can result in NSSS boundary breaches are sorted by maximum potential size. Then, the maximum size for APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (20/150)

each failure is grouped into the size range from the internal events LOCA categories mentioned previously.

Although multiple, smaller, breaches of the RCS could occur simultaneously and result in a total flow that would be considered in a larger LOCA category than that being considered for each individual failures, consideration of such effects is beyond the ability to identify with existing data sources and assumed to result in direct core damage. Additionally, no means is available to determine the degree of correlation between different seismic-induced failures of the RCS. Consequently, it is not feasible to use existing data to determine how multiple, seismically-induced, failures of the RCS would result in a specific plant response.

Use of the maximum potential break size from each of the identified RCS failures is considered adequate for use in the PRA-based SMA to determine the plant-level HCLPF and identify seismic-related insights.

The occurrence of a LOCA after a seismic event presents unique challenges to accident mitigation. The seismic failures having potentially sufficient breach size are modeled as follows:

Pressurizer Seismic failure of the Pressurizer Surge Line is modeled as Large LOCA.

Pressurizer spray nozzle Seismic failure of the Pressurizer spray nozzle is modeled as Medium LOCA.

Various RCS small piping or Tubing Line Seismic failure of the RCS small piping or tubing line is modeled as Small LOCA S-LLOCA and S-MLOCA are assumed to lead to direct core damage and also containment failure due to lower HCLPF of mitigation than LLOCA or MLOCA initiating event.

After an S-SLOCA, mitigation systems are assumed available. In the event of a loss of mitigation systems after S-SLOCA occurs, it would lead to core damage. This would also lead to a loss of containment isolation and late over pressurization before or at the time of core damage. The event tree for S-SLOCA is illustrated in figure 19.1-48B.

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19.1.5.1.1.4.8 Loss of Off-Site Power Seismic induced LOOP is assumed, should no initiating event causing seismic induced SSC damage occur. After an S-LOOP, mitigation systems are assumed available. In the event of a loss of mitigation systems after S-LOOP occurs, it would lead to core damage.

This would also lead to a loss of containment isolation and late over pressurization before or at the time of core damage. The event tree for S-SLOOP is illustrated in figure 19.1-48C.

19.1.5.1.1.4.9 Seismic Event Additions to Internal Events Fault Trees The internal events PRA model were modified to include seismically-induced failures.

Since not all the plant equipment have specific fragility data, BOP components in the SEL were assigned a HCLPF of 0.5g. However, seismic failure of each plant component was modeled as a separate basic event to identify important components to mitigate seismic induced initiating events.

The major assumptions for the PRA-based SMA system model are as follows:

a. The loss of offsite power from the earthquake occurs due to the failure of the switchyard or transformer stations outside the plant. It is generally known that the weak link in the offsite power system is ceramic insulators installed in the switchyard and transformer station. Assuming that the offsite power system has the similar type of ceramic insulators, the HCLPF capacity for the offsite power is assigned to be 0.09g (Reference 7977). It is assumed that the seismic event would result in a LOOP, since offsite power equipment is not seismic Category I.

b. No credit is taken for non-safety-related systems, and they are assumed in the model to have failed or to be non-functional due to the seismic event.

c. In the PRA-based SMA system fault trees, the operator actions in the random failure cutsets from the internal events PRA are assumed to apply.

d. If components are same, located on same building location and elevation, they are treated as the fully correlated. To account for potential correlation and dependencies, the correlation between component seismic capacities was assigned binary values of 0 or 1 (fully independent or fully dependent).

Consequently, the components of the same type in the system conservatively APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (22/150)

assumed to be 100% correlated and assigned them as 1; the specific correlation is described in Table 19.1-42.

e. Failure of the reactor trip signal is not modeled since the breakers for motor generator sets would be de-energized following a LOOP due to a seismic event, thereby causing the release of control rods into the core even if the reactor trip function fails. However, seismic induced mechanical failure was modeled to represent the inability of control rod insertion.

f.

The following seismic Category I buildings and structures are identified as buildings and structures that involve safety-related SSCs to prevent core damage.

1) Reactor Containment Building

2) Reactor Containment Internal

3) Auxiliary Building

4) CCW heat exchanger building

5) ESW building

6) Emergency Diesel generator building/Diesel Fuel Oil tank building

g. The HCLPFs of turbine building and compound building is assumed to be 1.67 times CSDRS equal to or exceed HCLPF 0.5g, given design details for turbine building and compound building are not available. The failure of these buildings is assumed to result in impact to safety-related SSCs and direct core damage. at the Beyond Design Basis.

h. Seismic spatial interactions between seismic Category I equipment and non-seismically qualified equipment will be avoided by proper equipment layout and design. This interaction includes flooding, spraying, steam jet impingement, pipe whip, jet forces, missiles, fire and the effect of failure of any non-seismic Category I equipment. Such effects cannot be performed, because site-specific SSCs location and layout details are not available. The COL holder should review these seismic spatial interactions during the seismic walkdown (COL 19.1(4)).

APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (23/150)

i.

Vulnerability of a relay to seismic-induced chatter is highly dependent on the specific type, make and model of relay. The HCLPF for relays is assumed to be 1.67 times CSDRS, given design details for relays are not available.

j.

No credit is given to recovery of the mitigation systems and seismic induced failures.

k. When the seismic induced initiating event occurs at the high level of HCLPF (e.g. Large LOCA, Medium LOCA etc.), it is assumed that SSCs for mitigation would not be available and it leads to directly core damage and containment failure.

l.

At APR1400 design, no RCP seal design information was available for seismic fragility development. However, the RCP motor is supported by motor stand, which is direct load path of seismic inertia of the motor to the pump and its support. Consequently, seismically induced stress in the RCP sealing is assumed to be small such that the seal failure at a seismic event will not govern seismic fragility of the RCP. Therefore, it is assumed to be bounded by Small LOCA.

m. At APR1400 design, steam generator tube design information was not available for seismic fragility development. For The steam generator tube fragility, a HCLPF of 2.5 times CSDRS was assumed. HCLPF of steam generator tube is equal to or higher than the HCLPF for the steam generator nozzle. The COL applicant is to demonstrate that HCLPF of steam generator tube is equal to or higher than 2.5 times CSDRS the HCLPF for the steam generator nozzle.

n. To derive core damage cutsets for the seismic induced initiating events which do not directly lead to core damage. i.e. Small LOCA and LOOP, the event trees of at-power internal event PRA were used. In the event trees, the reactor trip failure was excluded because seismic induced ATWS is separately treated. ATWS due to binding of control extension shaft in CEDM is unique event for the PRA-based SMA, thus seismic induced ATWS is separately treated.

o. To identify dominant containment failure cutsets for the seismic induced initiating events which are not directly lead to containment failure, Level 1 APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (24/150)

event trees above was extended to incorporate containment isolation failure and late overpressure failure as the most probable containment failure modes.

Failure of the containment heat removal was classified as late overpressure failure whether the reactor cavity is flooded or not. Therefore BMT (Basemat Melt-Through) is explicitly considered in the model.

p. HEPs for all operator actions are set to 0.1 to easily identify human failure events in the cutsets. If single operator action is in the cutset with only seismic induced failures, the operator action is considered important. The relative importance of the operator action is based on the HEPs in the internal event model. The performance-shaping factor such as ground motion intensity, location of the action, and time for the action are considered. The damage state of all of the operator action in APR1400 is assumed to be in the most severe condition, because HCLPF of the SSCs except for structures and NSSS are 0.5g. The performance shape factors with the consideration of the seismic condition are assumed (e.g. 5 for MCR or 10 for local area) in accordance with EPRI 3002000709 (Reference 77).

q. As indicated in the EPRI 3002000709 (Reference 77), seismic induced breaks in one or a very few small impulse lines connected to the primary circuits cannot be precluded, given the large number of such lines and their unusual configurations. Therefore, it is a common (although not a universal) practice in Seismic PRAs to include such a Very Small LOCA (VSLOCA) as an additional assumed failure impact in every seismically initiated accident sequence. The EPRI 3002000709 (Reference 77) presents four optional approaches to model the VSLOCA. In this analysis, the approach of option 2 is adopted, i.e., the VSLOCA has the seismic capacity of 0.3g HCLPF.

r.

As indicated in the EPRI 1025287 (Reference 78), the HCLPF value of ruggedness SSCs for a site is above about 2.5 times GMRS. In order to avoid that the PRA-based SMA-results masked by such inherently ruggedness items (e.g. distribution systems, check valve, small instrumentation, etc.), HCLPF capacity are assumed to be rugged. be 2.5 times CSDRS. The COL applicant should confirm that the SSCs are rugged with HCLPFs equal to or higher than 2.5 times CSDRS. (COL19.1(8)).

APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (25/150)

s. Plant walkdown are assumed to should be conducted to confirm the assumptions and information used in PRA-based SMA, HCLPF fragilities and LPSD procedures for at-power and LPSD condition. Walkdowns also would address impacts of the seismic induced flooding, fire, and accessibility issues affecting operator actions. However, plant specific seismic walkdowns are not applicable for DC application phase. and Consequently, the COL holder should demonstrate execute the seismic walkdown (COL 19.1(4)).

t.

The remote shutdown room is not considered in the PRA-based SMA, and no credit is taken for operator actions from the remote shutdown room in the PRA-based SMA.

19.1.5.1.1.5 Seismic Fragility Analysis The lack of site-specific information for a DC application limits the ability to conduct a more meaningful assessment of the secondary effects following a seismic event. For example, effects of consequential line breaks causing jet impingement cannot be performed because the physical plant layout and construction details are not available. the site-specific SSC location and layout details are not available. The COL holder should review such seismic spatial interactions during the seismic walkdown (COL 19.1(4)). Similarly, any assessment of human error probability values cannot be performed. Because the DC uses a PRA-based SMA, however, changes in probability value do not affect the overall conclusions of the results, i.e., the plant level HCLPF. If there are any secondary effects causing changes in the HCLPF of SSCs, it will be included in the model.

Seismic fragilities are calculated for specific structures and NSSS components. With the exception of the nuclear island (containment building and auxiliary building), emergency diesel generator building, diesel fuel oil tank building, and the nuclear steam supply system (NSSS), fragility values for the other components included in the SEL are assumed to have a HCLPF equal to or exceeding 1.67 times CSDRS. In addition to them, turbine building, compound building, CCW Hx. building and ESW IS are assumed to have a HCLPF equal to or exceeding HCLPF 0.5g. For this SMA the HCLPF is 0.5g.

According to DC/COL-ISG-020, two methods are acceptable for determining seismic fragility of the structures, systems, and components (SSCs) to demonstrate a seismic margin over the design-specific CSDRS. They are the Conservative Deterministic Failure Margin (CDFM) method and the Separation of Variables (SOV) method. The CDFM APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (26/150)

method requires code allowable as capacity and design analysis demand while the SOV method requires determination of medians and variabilities associated with capacities, equipment response, and structural response. The CDFM method is selected for this evaluation for the APR1400 Design Certification application.

19.1.5.1.2 Determination of Seismic Margin in the Design 19.1.5.1.2.1 Seismic Equipment List The seismic equipment list (SEL) is developed from the internal events PRA model. The SEL provides a documented list of the plant SSCs that could be used to respond to an earthquake or mitigate potential reactor plant damage initiated by a seismic event. The plant has a number of systems that are available for safe shutdown after a seismic event.

In selecting the systems, the following potential seismic initiating event scenarios were considered:

a. Direct core damage scenarios such as building collapse or RCS component catastrophic failure (S-DMG)

b. Station blackout (S-SBO)

c. Loss of all I&C (S-IC)

d. Main Steam Line Break (S-MSLB)

e. Anticipated transient without scram (S-ATWS)

f.

Total Loss of Component Cooling Water (S-TLOCCW)

g. Large break LOCA (S-LLOCA)

h. Medium break LOCA (S-MLOCA)

i.

Small break LOCA (S-SLOCA)

j.

Loss of offsite power (S-LOOP)

As with typical PRA-based SMAs, the analysis considers equipment needed to supply offsite power to be of very low seismic capacity. If offsite power is available after an earthquake, then the earthquake was relatively mild and such events would cause very little APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (27/150)

damage, with virtually all of the safety systems being available for accident mitigation following such a mild event. Additionally, it would be reasonably expected that much of the balance-of-plant systems would also be undamaged.

The following scenarios are not considered further for the SEL:

a.

Interfacing Systems LOCA (ISLOCA) - The active ISLOCA-related valves are on the SEL. Check valves have very high seismic capacity, and a potential ISLOCA from these valves following a seismic event is considered not significant.

b.

Initiating Event with Partial Failure of Support System - Initiating events such as loss of one train DC power or loss of one train cooling water are not considered as seismically induced initiators because all the same redundant components in the support system will fail simultaneously by earthquake due to an assumed full correlated failure.

Table 19.1-41 lists the systems that were evaluated for the PRA-based SMA with their associated plant designators. Only specific portions of these systems are included in the SEL and SMA models.

Because the support systems provide support functions for multiple front-line systems, their availability after an earthquake is critical for success-ful mitigation of the seismic event.

As described in Subsection 19.1.5.1.1.2, the P&IDs and electrical single-line diagrams were used as the initial input to the SEL. The internal events PRA basic events were then reviewed to provide reasonable assurance that all appropriate equipment was included in the SEL. The SELs are is presented in Table 19.1-42, which includes approximately 350 components. The system modeling and structures associated with the SEL equipment are discussed in Subsection 19.1.5.1.1.4.

19.1.5.1.2.2 Seismic Fragility Analysis Results The following building structures and the RCS components of the APR1400 standard design are evaluated by the CDFM method using the design-specific information within the scope of the DC application. The resulting HCLPF capacities and the associated failure modes of the SSCs are summarized in Table 19.1-43.

All the other SSCs are assumed to meet the 1.67 times CSDRS and assumed to have HCLPF of 0.5g conservatively.

APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (28/150)

a.

Safety-related building structures

1) Reactor containment building

2) Reactor containment internal

3) Auxiliary building

4) Emergency diesel generator building/Diesel fuel oil tank building

b.

RCS components

1) Reactor pressure vessel (RPV)

2) Reactor vessel internals (RVI)

3) Control element drive mechanism (CEDM)

4) Pressurizer (PZR)

5) Steam generators (SG)

6) Reactor coolant pumps (RCP)

7) Reactor coolant loop (RCL) piping The APR1400 PRA-based SMA is bounding assumed to bound for the selected site., site-specific SSC and soil effects (including sliding, overturning, liquefaction, and slope failure)

The COL applicant will confirm and update from new information from the site, e.g. site features, design departures, etc., that the PRA-based seismic margin assessment is bounding for the selected site, site-specific SSCs and soil effects (including sliding, overturning, liquefaction, and slope failure). (COL 19.1(8)).

The dominant contributors to the plant HCLPF are provided in Table 19.1-44A, B, C and D.

19.1.5.1.2.3 Plant Level HCLPF The dominant top cutsets for core damage or containment failure is derived through the system analysis. The top 100 core damage and containment failure cutsets include: all of the seismic induced failure sequences; all of the operator action failure with a seismic event; the random failure event with seismic event; and the random failure and operator action APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (29/150)

failure with a seismic event. These top cutsets are representative for the seismic accident sequences and used to develop the plant level HCLPF. The cutsets representing the combination of seismic event, random failure and operator action failure are used only to develop the insights. The cutsets are grouped into the categories below based on the basic event type in the cutset;

a. Seismic event(s) only

b. Seismic event(s) and Human Failure Event(s)

c. Seismic event(s) and Random Equipment Failure Event(s)

d. Seismic event(s), Human Failure Event(s) and Random Equipment Failure Event(s)

The plant level HCLPF is calculated based on the min-max approach. The plant level HCLPF is obtained by directly applying the cutsets into the equation below.

Plant Level HCLPF= Min{Max(cutset(1)), Max(cutset(2)),....Max(cutset(n))}

where, (n) is the number for cutsets which includes seismic failure event(s) only.

For example, the plant level HCLPF by the seismic induced initiators not directly leading to core damage is can be calculated as follows. Let us assume that the cutsets from seismic induced initiators of LOOP, Small LOCA and Large LOCA which includes seismic induced failure(s) only are as follows.

Cutset 1: SEIS-LOOP-0.09G

SEIS-SIPP01-FAIL-0.5G

SEIS-CSPP01-FAIL-0.5G Cutset 2: SEIS-RCS-LEAK-0.3G

SEIS-SIPP01-FAIL-0.5G

SEIS-CSPP01-FAIL-0.5G Cutset 3: SEIS-PIPE-RCS-FAIL-0.55G Cutset 4: SEIS-RCS-LEAK-0.3G

EIS-SIPP02-FAIL-0.5G

MSOPH-S-ASC-SLOCA Cutset 5: SEIS-LOOP-0.09G

SEIS-AFMP-FAIL-0.5G

SEIS-CSPP01-FAIL-0.5G

DGDGR-A-DGA

DGDGR-B-DGB By applying the cutsets to the min-max equation, the plant level HCLPF can be obtained by the loop initiator below.

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Plant level HCLPF = Min{Max(0.09g, 0.5g, 0.5g), Max(0.3g, 0.5g, 0.5g), Max(0.55g)

Max(0.3g, 0.5g)*0.1, Max(0.09g, 0.5g, 0.5g)*2.5E-2*2.5E-2}

= Min(0.5g, 0.5g, 0.55g, >0.5g, >0.5g) = 0.5g The APR1400 PRA-based SMA considered sequence-level HCLPFs and fragilities for all sequences leading to core damage or containment failures up to approximately one and two thirds the ground motion acceleration of the Design Basis SSE. The plant HCLPF was calculated by finding the lowest HCLPF sequence. The resultant plant level HCLPF value equal to 0.5g, which is greater than or equal to the RLE. Therefore, the plant level HCLPF demonstrates the APR1400 design can withstand a review level earthquake of 1.67 times the CSDRS and the assessment of the seismic capacity of the APR1400 design meets the expectations of SECY-93-087.

19.1.5.1.2.4 Risk Insights 19.1.5.1.2.4.1 Core Damage Risk Insights All the core damage cutsets with single direct core damage event are shown in Table 19.1-44A. The top 100 core damage cutsets, having more than 2 basic events (including seismic induced events) are shown in Table 19.1-44B. As discussed above, based on the cutsets review, the plant HCLPF of APR1400 for core damage is 0.5g. Consequently, APR1400 meets the requirement to withstand a review level earthquake of 1.67 times CSDRS. The important at-power insights, core damage cutsets and HCLPF values for the APR1400 PRA-based SMA are as follows:

a. APR1400 has 57 structures, any one of which fails leads to direct core damage due to the catastrophic failure of RCS or safety-related components. The 7 structures are listed in section 19.1.5.1.1.4.1 and 19.1.5.1.1.4.2. The structure failure induced S-DMG HCLPF is 0.5g. The sequence HCLPF is 0.5g, because each of structure is 0.94g, 0.51g, 0.52g, 0.5g and 0.5g. The results are led by the collapse of seismic category II building (e.g. turbine building and compound building), COL applicant confirm that the HCLPF of turbine building and compound building is equal to or higher than 1.67 times CSDRSHCLPF 0.5g. The 5 structures are listed in the section 19.1.5.1.1.4.1. Therefore the structure failure induced S-DMG HCLPF is 0.5g.

APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (31/150)

b. APR1400 has 6 RCS components, any one of which fails leads to direct core damage due to the catastrophic failure of RCS. The HCLPF of the each component is 0.92g, 0.51g, 0.6g, 0.54g, 0.63g and 1.31g. The 6 RCS components are listed in the section 19.1.5.1.1.4.1. Therefore the RCS component catastrophic failure induced DCD HCLPF is 0.51g.

c. APR1400 has 13 components, any one of which fails leads to SBO thus resulting in core damage. The HCLPF of the each component is same as 0.5g. The 13 components are listed in the section 19.1.5.1.1.4.2. Therefore the S-SBO HCLPF is 0.5g.

d. APR1400 has 4 components, any one of which fails leads to S-IC thus resulting in core damage. The HCLPF of the each component is same as 0.5g. except for one component type. The exceptional one component type is all the screen-outed plant-wide distributed equipment. It has the HCLPF of 0.75g. The 4 components are listed in the section 19.1.5.1.1.4.3. Therefore the S-IC HCLPF is 0.5g.

e. APR1400 has 3 components, any one of which failure leads to S-MSLB thus resulting in core damage. The HCLPF of the each component is same as 0.5g.

The 3 components are listed in the section 19.1.5.1.1.4.4. Therefore the S-MSLB HCLPF is 0.5g.

f. APR1400 has 25 24 SSCs, any one of which fails leads to S-TLOCCW thus resulting in core damage. The HCLPF of the each SSC is same as 0.5g. The 25 24 SSCs are listed in the section 19.1.5.1.1.4.5. Therefore the S-TLOCCW HCLPF is 0.5g.

g. APR1400 has 1 component, of which fails leads to S-ATWS thus resulting in core damage. The HCLPF of the component is same as 0.64g. The component is listed in the section 19.1.5.1.1.4.6. Therefore the S-ATWS HCLPF is 0.64g.

h. APR 1400 has 2 components, of which fails leads to S-LLOCA, S-MLOCA thus resulting in core damage. The S-LLOCA HCLPF is 0.55g and the S-MLOCA HCLPF is 0.51g. In case of large LOCA and medium LOCA have the relatively lower HCLPF than usual, it because the HCLPF result have the conservatism (e.g.

enveloped 9 site response spectrum and design). When the plant specific design information is reflected in the HCLPF, it may result in higher value. COL applicant has to demonstrate that the design of NSSS to have higher 2.5 times CSDRS.

APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (32/150)

i. APR1400 has 2 seismic induced initiating events which do not directly led to core damage. They are small LOCA and LOOP. The sequence level HCLPF for Small LOCA and LOOP are 0.5g and both 0.5g.

j. Important seismic induced failures for non-direct core damage initiators are seismic induced failures of a motor driven auxiliary feed water pump, turbine driven auxiliary feed water pump, containment spray pump, shutdown cooling pump, and safety injection pump. These SSCs are related to perform the secondary heat removal, RCS injection and long term containment heat removal.

k. Important operator actions for non-direct core damage initiators are as follows.

- RCOPH-S-SDSE-FW (Operator Fails to Open POSRVs in Early Phase for F&B Operation): Failure of operator action to open POSRV cause failure of feed &

bleed operation. The failure of feed & bleed operation and secondary heat removal after seismic induced LOOP or SLOCA event leads to core damage.

- SIOPH-S-IRWSTCOOL (Operator Fails to Cool IRWST Water Using SCS Pump): Failure of operator action to cool IRWST water using SCS pump causes the failure of long term containment heat removal. The failure of long term containment heat removal and secondary heat removal after seismic induced S-LOOP or SLOCA event leads to core damage.

- SIOPH-S-INJ (Operator Fails to Align SCS for Injection): Failure of operator action fails to align SCS for injection causes the failure of the SCS injection.

The failure of the SCS injection and SI injection after seismic event of LOOP or SLOCA leads to core damage.

- MSOPH-S-ASC-SLOCA (Operator Fails to Perform Aggressive Secondary Cooldown After SLOCA): Failure of operator action to perform aggressive secondary cooldown causing causes the failure of the aggressive secondary cooldown. The failure of operator action to perform aggressive secondary cooldown and SI injection after seismic event of SLOCA leads to core damage.

- AFOPH-S-ALT-LT (Operator Fails to Transfer AFW Source from AFWST to RWT): Failure of operator action to transfer AFW source from AFWST to RWT causes the failure of secondary heat removal. The failure of secondary heat APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (33/150)

removal and long term containment heat removal after seismic event of SLOCA or S-LOOP leads to core damage.

Based on the internal events, and the final HEPs are calculated by applying a with a performance shaping factor. The important operator actions resulting from the final HEPs are in the following order:

1) MSOPH-S-ASC-SLOCA

2) RCOPH-S-SDSE-FW

3) SIOPH-S-INJ

4) AFOPH-S-ALT-LT

5) SIOPH-S-IRWSTCOOL

l. Important random failure events for non-direct core damage initiators are as follows.

- DGDGR-A-DGA, DGDGR-B-DGB, DGDGR-C-DGC, DGDGR-D-DGD (FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01A, B, C and D):

Failure of EDG A, B, C or D with LOOP leads to failure of essential power supply partially.

- RCPVWQ4-200/1/2/3 (4/4 CCF of RC PV V200/201/202/203): CCF of RC PV V200/201/202/203 cause the failure of the feed & bleed operation. The failure of feed and bleed operation and failure of secondary heat removal leads to core damage.

- CSMPM2A-PP01A, CSMPM2B-PP01B (CS PUMP 1 PP01A/ CS PUMP 2 PP01B UNAVAILABLE DUE TO T&M): Failure of CS Pump 01A& 01B is related to the failure of long term containment heat removal. The failure of long term containment heat removal and secondary heat removal after seismic event of S-LOOP or SLOCA leads to core damage.

- SIMPM1A-SCPP01A, SIMPM1B-SCPP01B (SC PUMP PP01A or 01B UNAVAILABLE DUE TO T&M): Failure of SC pump 01A & 01B is related to the failure of long term containment heat removal. The failure of long term APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (34/150)

containment heat removal and secondary heat removal after seismic event of S-LOOP or SLOCA leads to core damage.

19.1.5.1.2.4.2 Containment Failure Risk Insights All the containment failure cutsets which are directly resulted from single seismic induced damage are shown Table 19.1-44C. The top 100 containment failure cutsets which are composed of more than 2 failure events including seismic induced failure event are shown in Table 19.1-44D. Based on the cutsets review, the plant HCLPF of APR1400 for containment failure is 0.5g. The important insights, containment failure cutsets and HCLPF values for the APR1400 PRA-based SMA are as follows:

a. APR1400 has 57 structures, any one of which failure leads to direct core damage due to the catastrophic failure of RCS or safety-related components. The 7 structures are listed in section 19.1.5.1.1.4.1 and 19.1.5.1.1.4.2. The structure failure induced S-DMG HCLPF is 0.5g. This containment failure can be classified as early containment failure. This event is also assumed to directly lead to the containment structural failure. The sequence HCLPF is 0.5g, because each of structure is 0.94g, 0.51g, 0.52g, 0.5g and 0.5g. The results are driven by the collapse of seismic category II building (e.g. turbine building and compound building). The COL applicant is to confirm that the HCLPF of turbine building and compound building is equal to or higher than 1.67 times CSDRSHCLPF 0.5g. The 5 structures are listed in the section 19.1.5.1.1.4.1. Therefore the structure failure induced S-DMG HCLPF is 0.5g. This containment failure can be classified as early containment failure.

b. APR1400 has 6 RCS components, any one of which failure leads to direct core damage due to the catastrophic failure of RCS. This event is also assumed to directly lead to the containment structural failure due to impact to the containment from the large movement or vibration of RCS, and the containment structural failure.

The HCLPF of the each component is 0.92g, 0.51g, 0.6g, 0.54g, 0.63g and 1.31g.

The 6 RCS components are listed in the section 19.1.5.1.1.4.1. Therefore the RCS component catastrophic failure induced S-DCF HCLPF is 0.51g. This containment failure can be classified as early containment failure.

c. APR1400 has 13 components, any one of which failure leads to S-SBO thus resulting in core damage. This event is also assumed to directly lead to the APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (35/150)

containment isolation failure due to the total loss of supporting system failure. The HCLPF of the each component is same as 0.5g. The 13 components are listed in the section 19.1.5.1.1.4.2. Therefore the S-SBO induced containment failure HCLPF is 0.5g. This containment failure can be classified as containment isolation failure.

d. APR1400 has 4 components, any one of which failure lead to S-IC thus resulting in core damage. The HCLPF of the each component is same as 0.5g except for one component type. The exceptional one component type is all the screen-outed plant-wide distributed equipment (e.g. BOP piping & supports, AOVs, cable trays &

supports, etc.). This event is also assumed to directly lead to the containment isolation failure due to the total loss of all instrumentation and control. It has the containment failure HCLPF of 0.75g. The 4 components are listed in the section 19.1.5.1.1.4.3. Therefore the S-IC containment HCLPF is 0.5g. This containment failure can be classified as containment isolation failure.

e. APR1400 has 3 components, any one of which failure lead to S-MSLB thus resulting in core damage. This event is also assumed to directly lead to the containment isolation failure through the failed main steam line components. The HCLPF of the each component is same as 0.5g. The 3 components are listed in the section 19.1.5.1.1.4.4. Therefore the S-MSLB containment failure HCLPF is 0.5g.

This containment failure can be classified as containment isolation failure.

f. For the seismic initiators of S-TLOCCW, S-SLOCA and S-LOOP, additional mitigation (e.g. Containment heat removal and Containment isolation failure) was considered for the containment failure.

g. Important seismic induced failures for non-direct containment failure initiators leading to containment failure are seismic induced failures of motor driven auxiliary feed water pump, turbine driven auxiliary feed water pump, containment spray pump, shutdown cooling pump, and safety injection pump. These SSCs are related to perform the secondary heat removal, RCS injection and long term containment heat removal.

h. Important operator actions for non-direct core damage initiators are as follows.

- AFOPH-S-ALT-LT (Operator Fails to Transfer AFW Source from AFWST to RWT): Failure of operator fails to transfer AFW source from AFWST to RWT APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (36/150)

causes the failure of secondary heat removal. The failure of secondary heat removal and long term containment heat removal after seismic event of SLOCA or S-LOOP leads to containment failure.

- MSOPH-S-ASC-SLOCA (Operator Fails to Perform Aggressive Secondary Cooldown After SLOCA): Failure of operator action to perform aggressive secondary cooldown causes the failure of the aggressive secondary cooldown.

The failure of operator to perform aggressive secondary cooldown, SI injection and Containment isolation after seismic event of SLOCA leads to containment failure.

- RCOPH-S-SDSE-FW (Operator Fails to Open POSRVs in Early Phase for F&B Operation): Failure of operator action to open POSRV cause failure of feed &

bleed operation. The failure of feed & bleed operation, secondary heat removal and Containment isolation after seismic induced LOOP or SLOCA event leads to containment failure.

- SIOPH-S-IRWSTCOOL (Operator Fails to Cool IRWST Water Using SCS Pump): Failure of operator action to open POSRV to cool IRWST water using SCS pump causes the failure of long term containment heat removal. The failure of long term containment heat removal, secondary heat removal and Containment isolation seismic induced S-LOOP or SLOCA event leads to containment isolation.

The final HEP based on the internal event is calculated with performance shaping factor. The important operator action is same as those in Section 19.1.5.1.2.3.1

i. m Important random failure events for non-direct containment failure initiators do not impact significantly in the PRA-based SMA results in the top 100 cutsets.

APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (37/150)

19.1.9 Combined License Information COL 19.1(4)

The COL applicant or holder is is to review as-designed and as-built information and conduct walkdowns as necessary to confirm that the assumptions used in the PRA (including PRA inputs to RAP and SAMDA) remain valid with respect to internal events, internal flood and fire events (fire barrier and fire barrier penetrations, routing and locations of pipe, cable, and conduit), and HRA analyses (development of operating procedures, emergency operating procedures, and severe accident management guidelines and training), external events including PRA-based seismic margins,and HCLPF fragilities, seismic spatial interactions and LPSD procedures. See Subsection 19.1.2.2.

COL 19.1(8)

The COL applicant is to will confirm and update that the PRA-based seismic margin assessment is bounding for the selected site, site-specific SSC and soil effects (including sliding, overturning liquefaction, and slope failure). The COL applicant will confirm and update from new information from the site, e.g. site features, design departures, etc., that the PRA-based seismic margin assessment is bounding for the selected site, site-specific SSC and soil effects (including sliding, overturning, liquefaction, and slope failure).

The COL applicant is to confirm that the as-built plant has adequate seismic margin and does not exceed the CDF and LRF design targets specified in Subsection 1.2.1.1.1 item e. See Subsection 19.1.5.1.2.

The COL applicant is to demonstrate that HCLPF capacity is equal to or exceed 1.67 times the GMRS HCLPF 0.5g for site-specific structures (ESW IS and CCW HX Building).

The COL applicant is to demonstrate that site-specific structures (the turbine building, compound building, ESW IS and CCW HX building) have a HCLPF capacity that is equal to or greater than 1.67 times GMRS and will update the PRA-based seismic margin analysis with the site-specific structure HCLPF values, accordingly.

APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (38/150)

The COL applicant is to demonstrate that HCLPF capacity is equal to or exceed 1.67 times the CSDRS for BOP components and is to complete the SEL.

The COL applicant is to demonstrate that the seismic capacity for equipment and relay qualified by testing should remain functionally operational within 1.67 times the required response spectra (CSDRS based RRS) in the procurement specification.

The COL applicant is to demonstrate that HCLPF capacity is equal to or exceed 1.67 times the CSDRSHCLPF 0.5g for turbine building and compound building.

The COL applicant is to demonstrate that HCLPF capacity is equal to or exceed 2.5 times the CSDRS for the inherently rugged items (such as valve, small instrumentation and distribution system. Etc.) are rugged.

The COL applicant is to demonstrate that the inherently rugged components identified in 19.1.5.1.1.2 have seismically rugged capacity.

The COL applicant is to demonstrate that the NSSS steam generator tube HCLPF is designed to have a HCLPF value higher than 2.5 times CSDRS HCLPF for the steam generator nozzle.

COL 19.1(22) The COL applicant is to demonstrate that failure of buildings that are not seismic Category I (e.g., turbine building and compound building) does not impact SSCs designed to be seismic Category I at the SSE level.

APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (39/150)

19.1.10 References

74. WSRC-TR-93-262, Rev. 1, Savannah River Site Generic Data Base Development, Westinghouse Safety Management Solution, May 1998.

75. NUREG/CR-4639 (EGG-2458), Nuclear computerized Library for Assessing Reactor Reliability (NUCLARR), May 1990.

76. U.S. Nuclear Regulatory Commission, SPAR Basic Event Unavailability Data and Results, 2010 Parameter Estimation Update, http://nrcoe.inel.gov/resultsdb/publicdocs/AvgPerf/TrainUA2010.pdf

77. EPRI 3002000709, Seismic Probabilistic Risk Assessment Implementation Guide, December, 2013

78. EPRI 1025287, Seismic Evaluation Guidance, February, 2013 7879. Risk Assessment of Operational Events Handbook External Events, Volume 2, R.1.01, USNRC, January 2008 7980. DC/COL-ISG-028, Assessing the Technical Adequacy of the advanced Light-Water Reactor Probabilistic Risk Assessment for the Design Certification Application and Combined License Application, U.S. Nuclear Regulatory Commission APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (40/150)

Table 19.1-4 (26 of 27)

No.

Insight Disposition Risk Insights from PRA Models 66 HCLPF capacity need to be equal to or exceed 1.67 times the GMRS HCLPF 0.5g for site-specific structures (ESWIS and CCW Hx Building) and The HCLPF capacity is equal to or exceeds 1.67 times the CSDRS for BOP components, and is to complete the SEL.

The COL applicant is to demonstrate that the seismic capacity for equipment and relay qualified by testing should remain functionally operational within 1.67 times the required response spectra (CSDRS based RRS) in the procurement specification.

The HCLPF for turbine building and compound building need to be equal to or higher than 1.67 times CSDRS HCLPF 0.5g.

The COL applicant is to demonstrate that site-specific structures (the turbine building, compound building, ESW IS and CCW HX building) have a HCLPF capacity that is equal to or greater than 1.67 time GMRS and will update the PRA-based seismic margin analysis with the site-specific structure HCLPF values, accordingly.

HCLPF capacity for Inherently rugged items (such as valve, small instrumentation and distribution system. Etc.). is equal to or exceed 2.5 times the CSDRS. The COL applicant is to demonstrate that the inherently rugged components identified in 19.1.5.1.1.2 have seismically rugged ca-pacity.

The HCLPF for NSSS needs to be equal to or higher than 2.5 times CSDRS The important operator action and random failure event for PRA-based SMA should be managed by COL holder to improve the human error.

COL 19.1(8)

Subsection 19.1.5.1.2.4 APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (41/150)

Table 19.1-41 (1 of 2)

Systems Considered for Seismic Equipment List System Description Actuation Reactor trip Safety Injection (SI)

Containment isolation (CIS)

Containment ventilation isolation (CVIS)

Main steam line isolation Feedwater line isolation AFW start EDG start and load sequence CRD Control rods RCS Reactor Coolant System, including RC Pumps, SG, PZR, POSRVs MS Main Steam: MSSVs, MSIVs, MSADVs AFW Auxiliary Feedwater (MD and TD)

CVCS Chemical Volume & Control System: Charging, pressurizer spray, and RCP seal injection SC Shutdown Cooling System CS Containment Spray SI Safety Injection CCW Component Cooling Water ESW Essential Service Water ECW Essential Chilled Water EDG HVAC Emergency Diesel Generator Area HVAC System E-I&C HVAC Electrical and I&C Equipment Areas HVAC System ESW/CCW HVAC ESW Pump Building / CCW HX Building HVAC System Aux Bldg HVAC Aux Building Controlled Area HVAC System Aux Bldg HVAC Aux Building Clean Area HVAC System APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (42/150)

Table 19.1-41 (2 of 2)

System Description MCR Main Control Room Consoles ESF ESF Cabinets RX Trip Reactor Trip Switchgear DG Fuel Diesel Fuel Oil Transfer System EDG Emergency Diesel Generators EP Electrical power APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (43/150)

Table 19.1-42 (1 of 19)

Seismic Equipment List No.

Equipment ID Equipment Description Floor Elevation Building Correlation Factor1) 1 1-431-M-RV01 Reactor Pressure Vessel 69'-156' Containment 1

2 Reactor Vessel Internals 69'-156' Containment 1

3 1-431-M-SG01 Steam Generator #1 114'-136' Containment 1

4 1-431-M-SG02 Steam Generator #2 114'-136' Containment 5

1-431-M-PZ01 Pressurizer 114'-156' Containment 1

6 1-431-M-PP01A Reactor Coolant Pump #1 114'-136' Containment 1

7 1-431-M-PP01B Reactor Coolant Pump #2 114'-136' Containment 8

1-431-M-PP01C Reactor Coolant Pump #3 114'-136' Containment 9

1-431-M-PP01D Reactor Coolant Pump #4 114'-136' Containment 10 1-441-M-TK01A Safety Injection Tank 1 136' Containment 1

11 1-441-M-TK01B Safety Injection Tank 2 136' Containment 12 1-441-M-TK01C Safety Injection Tank 3 136' Containment 13 1-441-M-TK01D Safety Injection Tank 4 136' Containment 14 1-451-M-HE01 Regenerative Heat Exchanger 128' Containment 1

15 1-451-M-PP01A Charging Pumps #1 55' Aux.

1 16 1-451-M-PP01B Charging Pumps #2 55' Aux.

17 1-451-M-HE02 Letdown Heat Exchanger 100' Containment 1

1) Fully Correlated equipment have 1 correlation factor APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (44/150)

Table 19.1-42 (2 of 19)

No.

Equipment ID Equipment Description Floor Elevation Building Correlation Factor 18 1-521-V-0012 Main Steam Isolation Valve 137' Aux.

1 19 1-521-V-0011 Main Steam Isolation Valve 137' Aux.

20 1-521-V-0014 Main Steam Isolation Valve 137' Aux.

21 1-521-V-0013 Main Steam Isolation Valve 137' Aux.

22 1-521-V-0101 Main Steam Atmospheric Dump Valve 137' Aux.

1 23 1-521-V-0102 Main Steam Atmospheric Dump Valve 137' Aux.

24 1-521-V-0104 Main Steam Atmospheric Dump Valve 137' Aux.

25 1-521-V-0103 Main Steam Atmospheric Dump Valve 137' Aux.

26 1-461-M-TK01A Component Cooling Water Surge Tank 172' Aux.

1 27 1-461-M-TK01B Component Cooling Water Surge Tank 172' Aux.

28 1-633-M-CH01A Essential Chiller (includes Compressor Condenser, Evaporator, controls, RVs, Tanks) 78' Aux.

1 29 1-633-M-CH02A Essential Chiller (includes Compressor Condenser, Evaporator, controls, RVs, Tanks) 78' Aux.

30 1-633-M-CH01B Essential Chiller (includes Compressor Condenser, Evaporator, controls, RVs, Tanks) 78' Aux.

31 1-633-M-CH02B Essential Chiller (includes Compressor Condenser, Evaporator, controls, RVs, Tanks) 78' Aux.

32 1-607-M-HV33A MDAFW Pump Room Unit 78' Aux.

1 33 1-607-M-CW33A MDAFW Pump Room Cubical Cooler Cooling Coil 78' Aux.

34 1-607-M-HV33B MDAFW Pump Room Unit 78' Aux.

35 1-607-M-CW33B MDAFW Pump Room Cubical Cooler Cooling Coil 78' Aux.

APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (45/150)

Table 19.1-42 (3 of 19)

No.

Equipment ID Equipment Description Floor Elevation Building Correlation Factor 36 1-431-V-0200 POSRV 200 136' Containment 1

37 1-431-V-0201 POSRV 201 136' Containment 38 1-431-V-0132 MOV Control Valves (POSRV 201) 136' Containment 39 1-431-V-0133 MOV Control Valves (POSRV 201) 136' Containment 40 1-431-V-0202 POSRV 202 136' Containment 41 1-431-V-0134 MOV Control Valves (POSRV 202) 136' Containment 42 1-431-V-0135 MOV Control Valves (POSRV 202) 136' Containment 43 1-431-V-0203 POSRV 203 136' Containment 44 1-431-V-0136 MOV Control Valves (POSRV 203) 136' Containment 45 1-431-V-0137 MOV Control Valves (POSRV 203) 136' Containment 46 1-441-M-PP01A SDC Pump 1 50' Aux.

1 47 1-441-M-PP01B SDC Pump 2 50' Aux.

48 1-441-M-PP02A SI Pump 1 50' Aux.

1 49 1-441-M-PP02B SI Pump 2 50' Aux.

50 1-441-M-PP02C SI Pump 3 50' Aux.

51 1-441-M-PP02D SI Pump 4 50' Aux.

52 1-441-M-HE01A SDC HX 1 50' Aux.

1 53 1-441-M-HE01B SDC HX 2 50' Aux.

54 1-441-M-HE02A SDC Miniflow HX 1 50' Aux.

1 55 1-441-M-HE02B SDC Miniflow HX 2 50' Aux.

APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (46/150)

Table 19.1-42 (4 of 19)

No.

Equipment ID Equipment Description Floor Elevation Building Correlation Factor 56 1-442-M-PP01A Containment Spray Pump 1 50' Aux.

1 57 1-442-M-PP01B Containment Spray Pump 2 50' Aux.

58 1-442-M-HE01A Containment Spray Heat Exchanger 55' Aux.

1 59 1-442-M-HE01B Containment Spray Line 2 Heat Exchanger 55' Aux.

60 1-442-M-HE02A CS Pump 1 Miniflow Heat Exchanger 50' Aux.

1 61 1-442-M-HE02B CS Pump 2 Miniflow Heat Exchanger 50' Aux.

62 1-461-M-PP01A CCW Pump 1A 55' Aux.

1 63 1-461-M-PP02A CCW Pump 2A 55' Aux.

64 1-461-M-PP01B CCW Pump 1B 55' Aux.

65 1-461-M-PP02B CCW Pump 2B 55' Aux.

66 1-461-M-HE01A CCW Heat Exchanger 1A 100' CCW HX Building 1

67 1-461-M-HE02A CCW Heat Exchanger 2A 100' CCW HX Building 68 1-461-M-HE03A CCW Heat Exchanger 3A 100' CCW HX Building 69 1-461-M-HE01B CCW Heat Exchanger 1B 100' CCW HX Building 70 1-461-M-HE02B CCW Heat Exchanger 2B 100' CCW HX Building 71 1-461-M-HE03B CCW Heat Exchanger 3B 100' CCW HX Building APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (47/150)

Table 19.1-42 (5 of 19)

No.

Equipment ID Equipment Description Floor Elevation Building Correlation Factor 72 1-462-M-PP01A ESW Pump 1A 69' ESW building 1

73 1-462-M-PP02A ESW Pump 2A 69' ESW building 74 1-462-M-PP01B ESW Pump 1B 69' ESW building 75 1-462-M-PP02B ESW Pump 2B 69' ESW building 76 1-542-M-PP01A Aux Feedwater Pump C (Turbine Driven) 78' Aux.

1 77 1-542-M-PP01B Aux Feedwater Pump D (Turbine Driven) 78' Aux.

78 1-542-M-PP02A Aux Feedwater Pump A (Motor Driven) 78' Aux.

1 79 1-542-M-PP02B Aux Feedwater Pump B (Motor Driven) 78' Aux.

80 1-591-M-PP22A Fuel Oil Feed Pump 100' EDG Building 1

81 1-591-M-PP22B Fuel Oil Feed Pump 100' EDG Building 82 1-591-M-PP22C Fuel Oil Feed Pump 100' Aux.

1 83 1-591-M-PP22D Fuel Oil Feed Pump 100' Aux.

84 1-595-M-TK01A Diesel Fuel Oil Storage Tank A 63' EDG Building 1

85 1-595-M-TK01B Diesel Fuel Oil Storage Tank B 63' EDG Building 86 1-595-M-TK01C Diesel Fuel Oil Storage Tank C 65' Aux.

1 87 1-595-M-TK01D Diesel Fuel Oil Storage Tank D 65' Aux.

88 1-595-M-PP01A Diesel Fuel Oil Transfer Pump 63' EDG Building 1

89 1-595-M-PP01B Diesel Fuel Oil Transfer Pump 63' EDG Building 90 1-595-M-PP02A Diesel Fuel Oil Transfer Pump 63' EDG Building 91 1-595-M-PP02B Diesel Fuel Oil Transfer Pump 63' EDG Building APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (48/150)

Table 19.1-42 (6 of 19)

No.

Equipment ID Equipment Description Floor Elevation Building Correlation Factor 92 1-595-M-PP01C Diesel Fuel Oil Transfer Pump 65' Aux.

1 93 1-595-M-PP01D Diesel Fuel Oil Transfer Pump 65' Aux.

94 1-595-M-PP02C Diesel Fuel Oil Transfer Pump 65' Aux.

95 1-595-M-PP02D Diesel Fuel Oil Transfer Pump 65' Aux.

96 1-595-M-TK02A Diesel Fuel Oil Day Tank A 121' EDG Building 1

97 1-595-M-TK02B Diesel Fuel Oil Day Tank B 121' EDG Building 98 1-595-M-TK02C Diesel Fuel Oil Day Tank C 120' Aux.

1 99 1-595-M-TK02D Diesel Fuel Oil Day Tank D 120' Aux.

100 1-601-V-Y0011A Electro-Hydraulic Inlet Damper 172' Aux.

1 101 1-601-V-Y0011B Electro-Hydraulic Inlet Damper 172' Aux.

102 1-602-M-AH02A EDG Room Exhaust Fan/Motor 100' EDG Building 1

103 1-602-M-AH02B EDG Room Exhaust Fan/Motor 100' EDG Building 104 1-602-M-AH02C EDG Room Exhaust Fan/Motor 172' Aux.

1 105 1-602-M-AH02D EDG Room Exhaust Fan/Motor 172' Aux.

106 1-591-M-DG01A 4.16kV CLASS 1E DIESEL GENERATORS 1-591-M-DG01A 100' EDG Building 1

107 1-591-M-DG01B 4.16kV CLASS 1E DIESEL GENERATORS 1-591-M-DG01B 100' EDG Building 108 1-591-M-DG01C 4.16kV CLASS 1E DIESEL GENERATORS 1-591-M-DG01C 100' Aux.

1 109 1-591-M-DG01D 4.16kV CLASS 1E DIESEL GENERATORS 1-591-M-DG01D 100' Aux.

APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (49/150)

Table 19.1-42 (7 of 19)

No.

Equipment ID Equipment Description Floor Elevation Building Correlation Factor 110 1-606-M-HV10A CS PUMP & MINIFLOW HEAT EXCHANGER RM Aux Bld Controlled Area HVAC Fan/Motor 50' Aux.

1 111 1-606-M-CW10A CS (Quad C) Mini Flow HX Room Cubical Cooler Cooling Coil 50' Aux.

112 1-606-M-HV10B CS PUMP & MINIFLOW HEAT EXCHANGER RM Aux Bld Controlled Area HVAC Fan/Motor 50' Aux.

113 1-606-M-CW10B CS (Quad D) Mini Flow HX Room Cubical Cooler Cooling Coil 50' Aux.

114 1-606-M-HV11A SI PUMP RM Aux Bld Controlled Area HVAC Fan/Motor 50' Aux.

1 115 1-606-M-CW11A SI Pump (Quad C) Room Cubical Cooler Cooling Coil 50' Aux.

116 1-606-M-HV11B SI PUMP RM Aux Bld Controlled Area HVAC Fan/Motor 50' Aux.

117 1-606-M-CW11B SI Pump (Quad D) Room Cubical Cooler Cooling Coil 50' Aux.

118 1-606-M-HV12A SI PUMP RM Aux Bld Controlled Area HVAC Fan/Motor 50' Aux.

119 1-606-M-CW12A SI Pump (Quad A) Room Cubical Cooler Cooling Coil 55' Aux.

120 1-606-M-HV12B SI PUMP RM Aux Bld Controlled Area HVAC Fan/Motor 50' Aux.

121 1-606-M-CW12B SI Pump (Quad B) Room Cubical Cooler Cooling Coil 50' Aux.

122 1-606-M-HV16A SC PUMP & MINIFLOW HEAT EXCHANGER RM Cubical Cooler 50' Aux.

1 123 1-606-M-CW16A SC Pump & Mini Flow HX Room Cubical Cooler Cooling Coil 50' Aux.

124 1-606-M-HV16B SC PUMP & MINIFLOW HEAT EXCHANGER RM Cubical Cooler 50' Aux.

125 1-606-M-CW16B SC Pump & Mini Flow HX Room Cubical Cooler Cooling Coil 50' Aux.

126 1-606-M-HV18A CHARGING PUMP RM Cubicle Cooler 55' Aux.

1 127 1-606-M-HV18B CHARGING PUMP RM Cubicle Cooler 55' Aux.

APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (50/150)

Table 19.1-42 (8 of 19)

No.

Equipment ID Equipment Description Floor Elevation Building Correlation Factor 128 1-606-V-Y0001A Aux Building Controlled Area (I) Emergency Exhaust ACU Outlet Damper 156' Aux.

1 129 1-606-V-Y0001B Aux Building Controlled Area (II) Emergency Exhaust ACU Outlet Damper 195' Aux.

130 1-606-V-Y0002A Aux Building Controlled Area (I) Emergency Exhaust ACU Inlet Damper 156' Aux.

131 1-606-V-Y0002B Aux Building Controlled Area (II) Emergency Exhaust ACU Inlet Damper 195' Aux.

132 1-607-M-HV31A Ess. Chiller Room Cubical Cooler 78' Aux.

1 133 1-607-M-CW31A Ess. Chiller Room Cubical Cooler Cooling Coil 78' Aux.

134 1-607-M-HV31B Ess. Chiller Room Cubical Cooler 78' Aux.

135 1-607-M-CW31B Ess. Chiller Room Cubical Cooler Cooling Coil 78' Aux.

136 1-607-M-HV32A Ess. Chiller Room Cubical Cooler 78' Aux.

137 1-607-M-CW32A Ess. Chiller Room Cubical Cooler Cooling Coil 78' Aux.

138 1-607-M-HV32B Ess. Chiller Room Cubical Cooler 78' Aux.

139 1-607-M-CW32B Ess. Chiller Room Cubical Cooler Cooling Coil 78' Aux.

APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (51/150)

Table 19.1-42 (9 of 19)

No.

Equipment ID Equipment Description Floor Elevation Building Correlation Factor 140 1-606-M-HV13A CCW PUMP RM Aux Bld Controlled Area HVAC Fan/Motor 55' Aux.

1 141 1-606-M-CW13A CCW Pump (Quad A) Room Cubical Cooler Cooling Coil 55' Aux.

142 1-606-M-HV13B CCW PUMP RM Aux Bld Controlled Area HVAC Fan/Motor 55' Aux.

143 1-606-M-CW13B CCW Pump (Quad B) Room Cubical Cooler Cooling Coil 55' Aux.

144 1-606-M-HV14A CCW PUMP RM Aux Bld Controlled Area HVAC Fan/Motor 55' Aux.

145 1-606-M-CW14A CCW Pump (Quad C) Room Cubical Cooler Cooling Coil 55' Aux.

146 1-606-M-HV14B CCW PUMP RM Aux Bld Controlled Area HVAC Fan/Motor 55' Aux.

147 1-606-M-CW14B CCW Pump (Quad D) Room Cubical Cooler Cooling Coil 55' Aux.

148 1-606-M-HV21B AUX. CHARGING PUMP RM Aux Bld Controlled Area HVAC Fan/Motor 55' Aux.

1 149 1-606-M-HV17A SC HEAT EXCHANGER RM Aux Bld Controlled Area HVAC Fan/Motor 55' Aux.

1 150 1-606-M-CW17A SC HX Room Cubical Cooler Cooling Coil 55' Aux.

151 1-606-M-HV17B SC HEAT EXCHANGER RM Aux Bld Controlled Area HVAC Fan/Motor 55' Aux.

152 1-606-M-CW17B SC HX Room Cubical Cooler Cooling Coil 55' Aux.

153 1-606-M-HV15A CS HEAT EXCHANGER RM Aux Bld Controlled Area HVAC Fan/Motor 55' Aux.

1 154 1-606-M-CW15A CS HX Room Cubical Cooler Cooling Coil 55' Aux.

155 1-606-M-HV15B CS HEAT EXCHANGER RM Aux Bld Controlled Area HVAC Fan/Motor 55' Aux.

APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (52/150)

Table 19.1-42 (10 of 19)

No.

Equipment ID Equipment Description Floor Elevation Building Correlation Factor 156 1-607-M-HV33A MDAFW Pump Room Cubical Cooler Cooling Coil 78' Aux.

1 157 1-607-M-CW33A MDAFW Pump Room Cubical Cooler Cooling Coil 78' Aux.

158 1-607-M-HV33B MDAFW Pump Room Cubical Cooler Cooling Coil 78' Aux.

159 1-607-M-CW33B MDAFW Pump Room Cubical Cooler Cooling Coil 78' Aux.

160 1-603-M-HV01A CLASS 1E SWITCHGEAR 01C RM Cubical Cooler 78' Aux.

1 161 1-603-M-HV01B CLASS 1E SWITCHGEAR 01D RM Cubical Cooler 78' Aux.

162 1-603-M-HV02A CLASS 1E LOADCENTER 01C RM Cubical Cooler 78' Aux.

163 1-603-M-HV02B CLASS 1E LOADCENTER 01D RM Cubical Cooler 78' Aux.

164 1-603-M-HV03A CHANNEL A DC&IP EQUIP. RM CC Cubical Cooler 78' Aux.

1 165 1-603-M-HV03B CHANNEL B DC&IP EQUIP. RM Cubical Cooler 78' Aux.

166 1-603-M-HV04A CHANNEL C DC&IP EQUIP. RM Cubical Cooler 78' Aux.

167 1-603-M-HV04B CHANNEL D DC&IP EQUIP. RM Cubical Cooler 78' Aux.

168 1-603-M-HV05A MUX A RM Cubical Cooler 78' Aux.

1 169 1-603-M-HV05B MUX B RM Cubical Cooler 78' Aux.

170 1-603-M-HV07A CLASS-1E SWITCHGEAR 01A RM Cubical Cooler 78' Aux.

1 171 1-603-M-HV07B CLASS-1E SWITCHGEAR 01B RM Cubical Cooler 78' Aux.

172 1-603-M-CW07B Class 1E Switchgear 01B Room Cubical Cooler Cooling Coil 78' Aux.

173 1-603-M-CW01C Class 1E Switchgear 01C Room Cubical Cooler Cooling Coil 78' Aux.

174 1-603-M-CW03A Channel A DC&IP Equip Room Cubical Cooler Cooling Coil 78' Aux.

1 175 1-603-M-CW04C Channel C DC&IP Equip Room Cubical Cooler Cooling Coil 78' Aux.

APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (53/150)

Table 19.1-42 (11 of 19)

No.

Equipment ID Equipment Description Floor Elevation Building Correlation Factor 176 1-603-M-CW02C Class 1E Load Center 01C Room Cubical Cooler Cooling Coil 78' Aux.

1 178 1-603-M-CW02D Class 1E Load Center 01D Room Cubical Cooler Cooling Coil 78' Aux.

177 1-603-M-CW07A Class 1E Switchgear 01A Room Cubical Cooler Cooling Coil 78' Aux.

1 179 1-603-M-CW01D Class 1E Switchgear 01D Room Cubical Cooler Cooling Coil 78' Aux.

180 1-603-M-CW03B Channel B DC&IP Equip Room Cubical Cooler Cooling Coil 78' Aux.

1 181 1-603-M-CW04D Channel D DC&IP Equip Room Cubical Cooler Cooling Coil 78' Aux.

182 1-603-M-HV06B 480V CLASS 1-E MCC 01B RM Cubical Cooler 100' Aux.

1 183 1-603-M-CW06B 480V Class 1E MCC 01B Room Cubical Cooler Cooling Coil 100' Aux.

184 1-603-M-CW06A 480V Class 1E MCC 01A Room Cubical Cooler Cooling Coil 100' Aux.

185 1-606-M-HV19A Mechanical Pen Room HVAC Fan/Motor 100' Aux.

1 186 1-606-M-HV19B Mechanical Pen Room HVAC Fan/Motor 100' Aux.

187 1-602-M-HV12C EDG Room Emergency Cubical Cooler 100' Aux.

1 188 1-602-M-AH12C EDG Room Emergency Cubical Cooler Fan/Motor 100' Aux.

189 1-602-M-HV13C EDG Room Emergency Cubical Cooler 100' Aux.

190 1-602-M-AH13C EDG Room Emergency Cubical Cooler Fan/Motor 100' Aux.

191 1-602-M-HV12D EDG Room Emergency Cubical Cooler 100' Aux.

192 1-602-M-AH12D EDG Room Emergency Cubical Cooler Fan/Motor 100' Aux.

193 1-602-M-HV13D EDG Room Emergency Cubical Cooler 100' Aux.

194 1-602-M-AH13D EDG Room Emergency Cubical Cooler Fan/Motor 100' Aux.

APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (54/150)

Table 19.1-42 (12 of 19)

No.

Equipment ID Equipment Description Floor Elevation Building Correlation Factor 195 1-603-M-HV09A ELECT. PENETRATION RM Cubical Cooler 120' Aux.

1 196 1-603-M-HV09B ELECT. PENETRATION (D) RM Cubical Cooler 120' Aux.

197 1-603-M-HV14B 480V CLASS-1E MCC 03B RM Cubical Cooler 120' Aux.

1 198 1-603-M-CW14B 480V Class 1E MCC 03B Room Cubical Cooler Cooling Coil 120' Aux.

199 1-606-M-HV20A Mechanical Pen Room HVAC Fan/Motor 120' Aux.

1 200 1-606-M-HV20B Mechanical Pen Room HVAC Fan/Motor 120' Aux.

201 1-606-M-CW20B Mechanical Penetration Room Cubical Cooler Cooling Coil 120' Aux.

202 1-603-M-HV10A 480V CLASS-1E MCC 03C RM Cubical Cooler 137' Aux.

1 203 1-603-M-HV10B 480V CLASS-1E MCC 03D RM Cubical Cooler 137' Aux.

204 1-603-M-CW10D 480V Class 1E MCC 03D Room Cubical Cooler Cooling Coil 137' Aux.

205 1-603-M-HV14A 480V CLASS-1E MCC 03A RM Cubical Cooler 137' Aux.

206 1-603-M-HV15A 480V CLASS-1E MCC 04A RM Cubical Cooler 137' Aux.

207 1-603-M-HV15B 480V CLASS-1E MCC 04B RM Cubical Cooler 137' Aux.

208 1-603-M-CW15B 480V Class 1E MCC 04B Room Cubical Cooler Cooling Coil 137' Aux.

209 1-603-M-CW10C 480V Class 1E MCC 03C Room Cubical Cooler Cooling Coil 137' Aux.

210 1-603-M-CW15A 480V Class 1E MCC 04A Room Cubical Cooler Cooling Coil 137' Aux.

211 1-603-M-CW14A 480V Class 1E MCC 03A Room Cubical Cooler Cooling Coil 137' Aux.

212 1-603-M-HV12A PENETRATION MUX A RM Cubical Cooler 137' Aux.

1 213 1-603-M-HV12B PENETRATION MUX B RM Cubical Cooler 137' Aux.

214 1-603-M-CW12B Pent. MUX B Room Cubical Cooler Cooling Coil 137' Aux.

APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (55/150)

Table 19.1-42 (13 of 19)

No.

Equipment ID Equipment Description Floor Elevation Building Correlation Factor 215 1-603-M-HV11A ELECT. PENETRATION RM Cubical Cooler 137' Aux.

1 216 1-603-M-HV11B ELECT. PENETRATION RM (D) Cubical Cooler 137' Aux.

217 1-603-M-HV13A ELECTRICAL PENETRATION RM(A) Cubical Cooler 137' Aux.

218 1-603-M-HV13B ELECTRICAL PENETRATION RM(B) Cubical Cooler 137' Aux.

219 1-603-M-CW13B Elect Penetration Room B Cubical Cooler Cooling Coil 137' Aux.

220 1-603-M-HV18A RSC RM Cubical Cooler 137' Aux.

1 221 1-603-M-HV18B RSC RM Cubical Cooler 137' Aux.

222 1-603-M-CW18B RSC Room Cubical Cooler Cooling Coil 137' Aux.

223 1-603-M-HV16A I&C Equipment Room (A) Cubical Cooler 157' Aux.

1 224 1-603-M-HV16B I&C Equipment Room (B) Cubical Cooler 157' Aux.

225 1-603-M-CW16B I&C Equip Room B Cubical Cooler Cooling Coil 157' Aux.

226 1-603-M-HV17A I&C Equipment Room (C) Cubical Cooler 157' Aux.

227 1-603-M-HV17B I&C Equipment Room (D) Cubical Cooler 157' Aux.

228 1-603-M-CW17D I&C Equip Room D Cubical Cooler Cooling Coil 157' Aux.

229 1-603-M-CW16A I&C Equip Room A Cubical Cooler Cooling Coil 157' Aux.

230 1-603-M-CW17C I&C Equip Room C Cubical Cooler Cooling Coil 157' Aux.

231 1-601-M-CW01A Control Room Supply AHU Cooling Coil 172' Aux.

1 232 1-601-M-CW01B Control Room Supply AHU Cooling Coil 172' Aux.

APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (56/150)

Table 19.1-42 (14 of 19)

No.

Equipment ID Equipment Description Floor Elevation Building Correlation Factor 233 1-602-M-HV12A EDG Room Emergency Cubical Cooler 100' EDG Building 1

234 1-602-M-HV12B EDG Room Emergency Cubical Cooler 100' EDG Building 235 1-602-M-HV13A EDG Room Emergency Cubical Cooler 135' EDG Building 1

236 1-602-M-HV13B EDG Room Emergency Cubical Cooler 135' EDG Building 237 1-605-M-AH01A ESW Pump Room Supply Fan 90' ESW building 1

238 1-605-M-AH02A ESW Pump Room Supply Fan 90' ESW building 239 1-605-M-AH01B ESW Pump Room Supply Fan 90' ESW building 240 1-605-M-AH02B ESW Pump Room Supply Fan 90' ESW building 241 1-633-M-PP01A Essential Chilled Water Pump 78' Aux.

1 242 1-633-M-PP01B Essential Chilled Water Pump 78' Aux.

243 1-633-M-PP02A Essential Chilled Water Pump 78' Aux.

244 1-633-M-PP02B Essential Chilled Water Pump 78' Aux.

245 1-751-J-PM01 RO Console (Frame) 157' Aux.

1 246 1-751-J-PM02 TO/EO Console (Frame) 157' Aux.

247 1-751-J-PM03 SS Console (Frame) 157' Aux.

248 1-751-J-PM04 STA Console (Frame) 157' Aux.

249 1-751-J-PM05 Safety Console (Frame) 157' Aux.

1 250 1-752-J-PA03A ESF-CCS Cabinet(A, B, C, D) 157' Aux.

1 251 1-752-J-PA03B ESF-CCS Group Controller Cabinet (Ch.BE) 157' Aux.

252 1-752-J-PA03C ESF-CCS Group Controller Cabinet (Ch.CE) 157' Aux.

253 1-752-J-PA03D ESF-CCS Group Controller Cabinet (Ch.DE) 157' Aux.

APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (57/150)

Table 19.1-42 (15 of 19)

No.

Equipment ID Equipment Description Floor Elevation Building Correlation Factor 254 1-752-J-PA14A Plant Protection System Cabinet(A) 157' Aux.

1 255 1-752-J-PA14B PPS Cabinet Ch.B-1 157' Aux.

256 1-752-J-PA14C Plant Protection System Cabinet(C) 157' Aux.

257 1-752-J-PA14D PPS Cabinet Ch.D-1 157' Aux.

258 1-772-E-SW01A Reactor Trip Switchgear 137' Aux.

1 259 1-772-E-SW01B Reactor Trip Switchgear 137' Aux.

260 1-772-E-SW01C Reactor Trip Switchgear 137' Aux.

261 1-772-E-SW01D Reactor Trip Switchgear 137' Aux.

262 1-823-E-SW01A CLASS 1E AB 4.16kV SWGR 01A 78' Aux.

1 263 1-823-E-SW01B CLASS 1E AB 4.16kV SWGR 01B 78' Aux.

264 1-823-E-SW01C CLASS 1E AB 4.16kV SWGR 01C 78' Aux.

265 1-823-E-SW01D CLASS 1E AB 4.16kV SWGR 01D 78' Aux.

266 1-825-E-LC01A CLASS 1E AUX. BLDG 480V LOAD CENTER 1-825-E-LC01A 78' Aux.

1 267 1-825-E-TR01A 480V LOAD CENTER XFMR 78' Aux.

268 1-825-E-LC01B CLASS 1E AUX. BLDG 480V LOAD CENTER 1-825-E-LC01B(DIV.II) 78' Aux.

269 1-825-E-TR01B 480V LOAD CENTER XFMR 78' Aux.

270 1-825-E-LC01C CLASS 1E AUX. BLDG 480V LOAD CENTER 1-825-E-LC01C 78' Aux.

271 1-825-E-TR01C 480V LOAD CENTER XFMR 78' Aux.

272 1-825-E-LC01D CLASS 1E AUX. BLDG 480V LOAD CENTER 1-825-E-LC01D 78' Aux.

273 1-825-E-TR01D 480V LOAD CENTER XFMR 78' Aux.

APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (58/150)

Table 19.1-42 (16 of 19)

No.

Equipment ID Equipment Description Floor Elevation Building Correlation Factor 274 1-827-E-MC01C CLASS 1E AUX. BLDG 480V MCC 1-827-E-MC01C 78' Aux.

1 275 1-827-E-MC01C-3 120/208V AC DIST. PNL 78' Aux.

276 1-827-E-MC01D CLASS 1E AUX. BLDG 480V MCC 1-827-E-MC01D 78' Aux.

277 1-827-E-MC01D-3 120/208V AC DIST. PNL 78' Aux.

278 1-827-E-MC02C CLASS 1E AUX. BLDG 480V MCC 1-827-E-MC02C 78' Aux.

279 1-827-E-MC02C-3 120/208V AC DIST. PNL 78' Aux.

280 1-827-E-MC02D CLASS 1E AUX. BLDG 480V MCC 1-827-E-MC02D 78' Aux.

281 1-827-E-MC02D-3 120/208V AC DIST. PNL 78' Aux.

282 1-827-E-MC01A CLASS 1E AUX. BLDG 480V MCC 1-827-E-MC01A 100' Aux.

1 283 1-827-E-MC01A-3 120/208V AC DIST. PNL 100' Aux.

284 1-827-E-MC01B CLASS 1E AUX. BLDG 480V MCC 1-827-E-MC01B 100' Aux.

285 1-827-E-MC01B-3 120/208V AC DIST. PNL 100' Aux.

286 1-827-E-MC04C CLASS 1E AUX. BLDG 480V MCC 1-827-E-MC04C 100' Aux.

287 1-827-E-MC04C-3 120/208V AC DIST. PNL 100' Aux.

288 1-827-E-MC04D CLASS 1E AUX. BLDG 480V MCC 1-827-E-MC04D(DIV. II) 100' Aux.

289 1-827-E-MC04D-3 120/208V AC DIST. PNL 100' Aux.

290 1-827-E-MC03B CLASS 1E AUX. BLDG 480V MCC 1-827-E-MC03B 120' Aux.

1 291 1-827-E-MC03B-3 120/208V AC DIST. PNL 120' Aux.

APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (59/150)

Table 19.1-42 (17 of 19)

No.

Equipment ID Equipment Description Floor Elevation Building Correlation Factor 292 1-827-E-MC03A CLASS 1E AUX. BLDG 480V MCC 1-827-E-MC03A 137' Aux.

1 293 1-827-E-MC03A-3 120/208V AC DIST. PNL 137' Aux.

294 1-827-E-MC03C CLASS 1E AUX. BLDG 480V MCC 1-827-E-MC03C 137' Aux.

295 1-827-E-MC03C-3 120/208V AC DIST. PNL 137' Aux.

296 1-827-E-MC03D CLASS 1E A/B 480V MCC 1-827-E-MC03D 137' Aux.

297 1-827-E-MC03D-3 120/208V AC DIST. PNL 137' Aux.

298 1-827-E-MC04A CLASS 1E AUX. BLDG 480V MCC 1-827-E-MC04A 137' Aux.

299 1-827-E-MC04A-3 120/208V AC DIST. PNL 137' Aux.

300 1-827-E-MC04B CLASS 1E AUX. BLDG 480V MCC 1-827-E-MC04B 137' Aux.

301 1-827-E-MC04B-3 120/208V AC DIST. PNL 137' Aux.

302 1-827-E-MC02A CLASS 1E ESW STRUCTURE AREA 480V MCC 1-827-E-MC02A 100' ESW building 1

303 1-827-E-MC02A-3 120/208V AC DIST. PNL 100' ESW building 304 1-827-E-MC02B CLASS 1E ESW STRUCTURE AREA 480V MCC 1-827-E-MC02B 100' ESW building 305 1-827-E-MC02B-3 120/208V AC DIST. PNL 100' ESW building 306 1-827-E-MC05A CLASS 1E EDG-A BLDG 480V MCC 1-827-E-MC05A 100' EDG Building 307 1-827-E-MC05A-3 120/208V AC DIST. PNL 100' EDG Building 308 1-827-E-MC05B CLASS 1E EDG-B BLDG 480V MCC 1-827-E-MC05B 100' EDG Building 309 1-827-E-MC05B-3 120/208V AC DIST. PNL 100' EDG Building APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (60/150)

Table 19.1-42 (18 of 19)

No.

Equipment ID Equipment Description Floor Elevation Building Correlation Factor 310 1-841-E-MC01A CLASS 1E 125V DC CONTROL CENTER (A/B) 78' Aux.

1 311 1-841-E-MC01A-C1 CLASS 1E 125V DC DISTR. PNL 1 78' Aux.

312 1-841-E-MC01A-D1 CLASS 1E 125V DC DISTR. PNL 2 78' Aux.

313 1-841-E-MC01B CLASS 1E 125V DC CONTROL CENTER (A/B) 78' Aux.

314 1-841-E-MC01B-C1 CLASS 1E 125V DC DISTR. PNL 1 78' Aux.

315 1-841-E-MC01B-D1 CLASS 1E 125V DC DISTR. PNL 2 78' Aux.

316 1-841-E-MC01C CLASS 1E 125V DC CONTROL CENTER (A/B) 78' Aux.

317 1-841-E-MC01C-D1 CLASS 1E 125V DC DISTR. PNL 78' Aux.

318 1-841-E-MC01D CLASS 1E 125V DC CONTROL CENTER (A/B) 78' Aux.

319 1-841-E-MC01D-D1 CLASS 1E 125V DC DISTR. PNL 2 78' Aux.

320 1-841-E-BC01A CLASS 1E BATT. CHARGER (A/B) 78' Aux.

1 321 1-841-E-BC01B CLASS 1E BATT. CHARGER (A/B) 78' Aux.

322 1-841-E-BC01C CLASS 1E BATT. CHARGER (A/B) 78' Aux.

323 1-841-E-BC01D CLASS 1E BATT. CHARGER (A/B) 78' Aux.

324 1-841-E-BC02A CLASS 1E BATT. CHARGER (STAND-BY) (A/B) 78' Aux.

325 1-841-E-BC02B CLASS 1E BATT. CHARGER (STAND-BY) (A/B) 78' Aux.

326 1-841-E-BC02C CLASS 1E BATT. CHARGER (STAND-BY) (A/B) 78' Aux.

327 1-841-E-BC02D CLASS 1E BATT. CHARGER (STAND-BY) (A/B) 78' Aux.

APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (61/150)

Table 19.1-42 (19 of 19)

No.

Equipment ID Equipment Description Floor Elevation Building Correlation Factor 328 1-841-E-BT01A CLASS 1E 125V DC BATTERY 100' Aux.

1 329 1-841-E-BT01B CLASS 1E 125V DC BATTERY 100' Aux.

330 1-841-E-BT01C CLASS 1E 125V DC BATTERY 78' Aux.

1 331 1-841-E-BT01D CLASS 1E 125V DC BATTERY 78' Aux.

332 1-842-E-IN01A CLASS 1E CH.A 40KVA INVERTER (A/B) 78' Aux.

1 333 1-842-E-IN01B CLASS 1E CH.A 40KVA INVERTER (A/B) 78' Aux.

334 1-842-E-IN01C CLASS 1E CH.C 40KVA INVERTER (A/B) 78' Aux.

335 1-842-E-IN01D CLASS 1E CH.C 40KVA INVERTER (A/B) 78' Aux.

336 1-842-E-IN02A CLASS 1E SAFETY MOV INVERTER (RC SYS ONLY) 78' Aux.

1 337 1-842-E-IN02B CLASS 1E SAFETY MOV INVERTER 30KVA 78' Aux.

338 1-842-E-IN02C CLASS 1E SAFETY MOV INVERTER 78' Aux.

339 1-842-E-IN02D CLASS 1E SAFETY MOV INVERTER 30KVA 78' Aux.

340 1-842-E-TR01A CLASS 1E REGULATING TRANSFORMER 78' Aux.

1 341 1-842-E-TR01B CLASS 1E REGULATING TRANSFORMER 78' Aux.

342 1-842-E-TR01C CLASS 1E REGULATING TRANSFORMER 78' Aux.

343 1-842-E-TR01D CLASS 1E REGULATING TRANSFORMER 78' Aux.

APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (62/150)

Table 19.1-43 (1 of 5)

Seismic Fragility Analysis Results Summary Component Location Failure mode HCLPF (g)

Buildings Reactor Containment building CTMT Tan. shear fail near the base 0.94 Stability of NI Structure CTMT basemat Sliding toward the turbine building 0.52 Reactor Containment Internal CTMT Tan. shear fail near the base 1.09 Auxiliary Building Auxiliary Building Shear fail of shear wall at the basemat 0.51 Emergency Diesel Generator Building Emergency Diesel Generator Building Shear fail of shear wall at the basemat 0.87 Diesel Fuel Oil Tank Building Diesel Fuel Oil Tank Building Shear fail of shear wall at the basemat 0.73 Turbine Building Turbine Building Collapse into Aux BLDG

[1][4]

Compound Building Compound Building Collapse into Aux BLDG

[1][4]

CCW HX Building CCW HX Building Generic

[5][4]

ESW IS ESW Building Generic

[5][4]

RCS Components Reactor Pressure Vessel CTMT El. 69'~156' Column support 0.92 Reactor Vessel Internal CTMT El. 69'~156' Core Sup. Barrel lower flange 0.51 CEDM (Control Element Drive Mechanism)

CTMT Binding of Cntrl. extension shaft 0.64 Steam Generator CTMT El.

114'~136'06 Anch. fail of snubber lever support asm.

0.6 Steam Generator Nozzle CTMT El.

114'~136'06 Economizer nozzle 0.54 Pressurizer CTMT El. 114'~156' Skirt support 0.63 Pressurizer nozzle CTMT El. 114'~156' Spray nozzle 0.51 Reactor Coolant System Piping CTMT Surge line nozzle 0.55 Reactor Coolant Pumps CTMT El.

114'~136'06 Upper horiz. column support 1.31 BOP components (mechanical, electrical and I&C components)

Charging Pumps Aux. BLDG El. 55' Generic

[1]

Regenerative Heat Exchanger CTMT El. 114' Generic

[1]

Letdown Heat Exchanger CTMT El. 100' Generic

[1]

Auxiliary Charging Pump Aux. BLDG El. 55' Generic

[1]

APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (63/150)

Table 19.1-43 (2 of 5)

Component Location Failure mode HCLPF (g)

Safety Injection Tanks CTMT. El. 136' 06" Generic

[1]

Shutdown Cooling Pumps Aux. BLDG El. 50' Generic

[1]

Shutdown Cooling Heat Exchanger Aux. BLDG El. 50' Generic

[1]

SC Pump Miniflow Heat Exchanger Aux. BLDG El. 50' Generic

[1]

Safety Injection Pump Aux. BLDG El. 50' Generic

[1]

Containment Spray Pump Aux. BLDG El. 50' Generic

[1]

CS Miniflow Heat Exchanger Aux. BLDG El. 50' Generic

[1]

Containment Spray Heat Exchanger Aux. BLDG El. 55' Generic

[1]

Main Steam Isolation Valves Aux. BLDG El.

137'06" Generic

[1]

Main Steam Atmospheric Valves(ADV)

Aux. BLDG El.

137'06" Generic

[1]

Main Steam Safety Valves Aux. BLDG El.

137'06" Generic

[1]

AFW Pump-Motor Driven Aux. BLDG El. 78' Generic

[1]

AFW Pump-Turbine Driven Aux. BLDG El. 78' Generic

[1]

Emergency Diesel Generators EDG El. 100' Aux. BLDG El. 100' Generic

[1]

Emergency Diesel Generators (Aux. Building)

AB Aux. BLDG.

El. 100' Generic

[1]

Emergency Diesel Fuel Oil transfer pump EDG El. 65' Aux. BLDG El. 63' Generic

[1]

Emergency Diesel Fuel Oil transfer pump (Aux. Building)

AB Aux. BLDG.

El. 63' Generic

[1]

Starting Air Tank Aux. BLDG El. 100' Generic

[1]

Diesel Fuel Oil Day Tank EDG El. 121' Aux. BLDG El. 120' Generic

[1]

Diesel Fuel Oil Day Tank (Aux. Building)

AB Aux. BLDG.

El. 120' Generic

[1]

Diesel Fuel Oil Storage Tank EDG El. 63' Aux. BLDG El. 65' Generic

[1]

Diesel Fuel Oil Storage Tank (Aux.Building)

Aux. El. 65' Generic

[1]

Silencer Aux. BLDG El. 100' Generic

[1]

Air Intake Filter Aux. BLDG El. 109' Generic

[1]

APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (64/150)

Table 19.1-43 (3 of 5)

Component Location Failure mode HCLPF (g)

Lube Oil Water Hx Aux. BLDG El. 100' Generic

[1]

Motor Driven Fuel Oil Feed Pump EDG El. 100' Aux. BLDG El. 100' Generic

[1]

Motor Driven Fuel Oil Feed Pump (Aux. Building)

AB Aux. BLDG.

El. 100' Generic

[1]

Essential Service Water Pump ESW IS. El. 69' Generic

[1]

CCW Heat Exchangers CCW HX BLDG El.

100' Generic

[1]

CCW Pump Aux. BLDG El. 55' Generic

[1]

CCW Surge Tank Aux. BLDG El. 172' Generic

[1]

Essential Chilled Water Pumps Aux. BLDG. El. 78' Generic

[1]

Essential Chillers Aux. BLDG El. 78' Generic

[1]

ECW Compression Tank Aux. BLDG El. 172' Generic

[1]

ECW Air Separator Aux. BLDG El. 78' Generic

[1]

Essential Chilled Water System Control Panel Aux. BLDG El. 78' Generic

[1]

AFWP Room Cubicle Cooler-MD Aux. BLDG El. 78' Generic

[1]

CCWP Room Cubicle Cooler Aux. BLDG El. 55' Generic

[1]

SI Room Cubicle Cooler Aux. BLDG El. 50' Aux. BLDG El. 55' Generic

[1]

SC Pump & Mini-flow Hx. Room Cubicle Cooler Aux. BLDG El. 50' Aux. BLDG El. 55' Generic

[1]

Mech. Pen. Room Cubicle Cooler Aux. BLDG El. 100' Aux. BLDG El. 120' Generic

[1]

CS Pump Room Cubicle Cooler Aux. BLDG El. 50' Aux. BLDG El. 55' Generic

[1]

Aux Charging Pump Room Cubicle Cooler Aux. BLDG El. 55' Generic

[1]

Charging Pump Room Cubicle Cooler Aux. BLDG El. 55' Generic

[1]

Elect. Pen. Room Area Cubicle Cooler Aux. BLDG El. 120' Aux. BLDG El.

137'6" Generic

[1]

Elect. Pen. Room Area Cubicle Cooler (El. 137')

AB Aux. BLDG.

El. 137' Generic

[1]

I&C Equipment Room Cubical Cooler AB Aux. BLDG.

El. 157' Generic

[1]

APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (65/150)

Table 19.1-43 (4 of 5)

Component Location Failure mode HCLPF (g)

EDG Room Emergency Cubicle Cooler EDG El. 100' Generic

[1]

EDG Room Emergency Cubicle Cooler EDG El. 135' Generic

[1]

Essential Chiller & Pump Cubicle Cooler Aux. BLDG El. 78' Generic

[1]

CCW HX. Room Supply Fans CCW HX B El. 100' CCW HX El. 126' Generic

[1]

ESW Pump Room Supply Fan ESW IS. El. 90' Generic

[1]

EDG Room Emergency Exhaust Fan EDG El. 100' Aux. BLDG El. 172' Generic

[1]

EDG Room Emergency Exhaust Fan (Aux. Building)

AB Aux. BLDG. El.

172' Generic

[1]

Control Room Emergency Makeup ACU Aux. BLDG El. 172' Generic

[1]

ESF-CCS GC Cabinet Aux. BLDG El. 156' Generic

[1]

ESF-CCS LC Cabinet Aux. BLDG El. 156' Aux. BLDG El.

137'6" Generic

[1]

Plant Protection System Cabinet Aux. BLDG El. 156' Generic

[1]

Reactor Trip Switchgear Aux. BLDG El.

137'6" Generic

[1]

MCR Operator Consoles Aux. BLDG El. 156' Generic

[1]

MCR Safety Consoles Aux. BLDG El. 156' Generic

[1]

125V DC Battery Chargers Aux. BLDG El. 78' Generic

[1]

SI Inverter Aux. BLDG El. 78' Generic

[1]

120V AC Inverter(VBPSS)

Aux. BLDG El. 78' Generic

[1]

Regulating Transformer Aux. BLDG El. 78' Generic

[1]

125V DC Control Center Aux. BLDG El. 78' Generic

[1]

4.16kV MCSG Aux. BLDG El. 78' Generic

[1]

480V Load Center Aux. BLDG El. 78' Generic

[1]

480V MCC(Aux. EL.137'06")

Aux. BLDG El.

137'06" Generic

[1]

480V MCC(Aux. EL.120')

Aux. BLDG El. 120' Generic

[1]

480V MCC(Aux. EL.100')

Aux. BLDG El. 100' Generic

[1]

480V MCC(Aux. EL.78')

Aux. BLDG El. 78' Generic

[1]

480V MCC(ESW IS EL.100')

ESW IS. El. 90' Generic

[1]

Batteries & Racks Aux. BLDG El. 78' Aux. BLDG El. 100' Generic

[1]

APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (66/150)

Table 19.1-43 (5 of 5)

Component Location Failure mode HCLPF (g)

Off-Site Power various Generic 0.09[3][2]

Reactor Coolant System RCS Small piping or tubing line various Generic 0.3[4][3]

BOP Piping & Supports various Generic 0.75g[2]

HVAC Ducting & Dampers various Generic 0.75g[2]

Cable Trays & Supports various Generic 0.75g[2]

Motor Operated Valves various Generic 0.75g[2]

Air Operated Valves various Generic 0.75g[2]

Electrical Conduit various Generic 0.75g[2]

Relief and Check Valves various Generic 0.75g[2]

Resistance Temperature Detectors various Generic 0.75g[2]

Pressure Transmitters various Generic 0.75g[2]

Key Assumptions

[1] The component is assigned to COL item (COL 19.1(8)) and HCLPF value is assumed to be equal to or exceed 1.67 times CSDRS.

[2] Inherently Ruggedness Item were assumed as CSDRS x 2.5 = 0.75g

- EPRI-1025287 (Reference 78) COL item (COL 19.1(8))

[3] [2] HCLPF based on generic value from Risk Assessment of Operational Events Handbook Volume 2 - External Events, R.1.01, January 2008, USNRC (Reference 79 78).

[4] [3] HCLPF based on Option 2 in "SPRA implementation guide", EPRI 3002000709 (Reference

77)

[5] [4] Turbine building, compound building, ESW IS and CCW HX Building are assigned to COL item (COL 19.1(8)) and HCLPF value is assumed to be equal to or exceed 1.67 times GMRS HCLPF 0.5g. For quantification purposes, a HCLPF value of 0.5g is assumed for the site-specific structures (turbine building, compound building, ESW IS and CCW HX building). The COL applicant will demonstrate these site-specific structures HCLPF will be equal to or greater than 1.67 times GMRS. (COL 19.1(8))

APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (67/150)

Table 19.1-44A (1 of 11)

At-Power Seismic Event Direct Core Damage Initiator Cutsets No.

BE. Prob.

Cutsets Sequence Level HCLPF Basic Event Cutset Description 1

1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-480V-LC-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE 480V Load Center 1.00E+00 SIE-FLAG-IC FLAG FOR Loss of All Instrumentation and Control 2

1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-480V-MCC-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE 480V MCC 1.00E+00 SIE-FLAG-IC FLAG FOR Loss of All Instrumentation and Control 3

1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-4KV-BUS-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE 4.16kV MCSG 1.00E+00 SIE-FLAG-SBO FLAG FOR Seismic-Induced SBO 4

1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CCHX-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE CCW Heat Exchangers 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 5

1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CCLR-ACVPP-0.5G SEISMIC INDUCED FAILURE OF THE Aux Charging Pump Room Cubicle Cooler 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 6

1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CCLR-EPA-0.5G SEISMIC INDUCED FAILURE OF THE Elect. Pen. Room Area Cubicle Cooler 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 7

1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CCLR-EPA-137-0.5G SEISMIC INDUCED FAILURE OF THE Elect. Pen. Room Area Cubicle Cooler (EL.137')

1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (68/150)

Table 19.1-44A (2 of 11)

No.

BE. Prob.

Cutsets Sequence Level HCLPF Basic Event Cutset Description 8

1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CCLR-IC-0.5G SEISMIC INDUCED FAILURE OF THE I&C Eq. Room Cubicle Cooler (EL.157')

1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 9

1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CCLR-EDG-100-0.5G SEISMIC INDUCED FAILURE OF THE EDG Room Emergency Cubicle Cooler (EL.100')

1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 10 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CCLR-EDG-135-0.5G SEISMIC INDUCED FAILURE OF THE EDG Room Emergency Cubicle Cooler (EL.135')

1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 11 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CCLR-MPR-0.5G SEISMIC INDUCED FAILURE OF THE Mech. Pen. Room Cubicle Cooler 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 12 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CCPP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE CCW Pump 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 13 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CCTK-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE CCW Surge Tank 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 14 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CCW-BLDG-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE CCW Hx Building 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (69/150)

Table 19.1-44A (3 of 11)

No.

BE. Prob.

Cutsets Sequence Level HCLPF Basic Event Cutset Description 15 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CPD-FAIL-0.5G SEISMIC FAILURE OF COMPOUND BUILDING COLLAPE INTO AUXILIARY BLDG 1.00E+00 SIE-FLAG-DMG-CF FLAG FOR Seismic Events Leading to Direct Core Damage with Containment Structural Damage 16 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CSHX01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Heat Exchanger 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 17 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CSHX02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE CS Miniflow Hx 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 18 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-DC-BC-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE 125V DC Battery Chargers 1.00E+00 SIE-FLAG-IC FLAG FOR Loss of All Instrumentation and Control 19 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-DC-BT-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Batteries & Racks 1.00E+00 SIE-FLAG-SBO FLAG FOR Seismic-Induced SBO 20 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-DC-MCC-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE 125V DC Control Center 1.00E+00 SIE-FLAG-SBO FLAG FOR Seismic-Induced SBO APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (70/150)

Table 19.1-44A (4 of 11)

No.

BE. Prob.

Cutsets Sequence Level HCLPF Basic Event Cutset Description 21 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-DG-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Emergency Diesel Generators 0.5g SEIS-DG-CD-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Emergency Diesel Generators (Aux. Building) 1.00E+00 SIE-FLAG-SBO FLAG FOR Seismic-Induced SBO 22 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-DGFT-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Air Intake Filter 1.00E+00 SIE-FLAG-SBO FLAG FOR Seismic-Induced SBO 23 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-DGHX-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Lube Oil Water Hx 1.00E+00 SIE-FLAG-SBO FLAG FOR Seismic-Induced SBO 24 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-DGPP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Motor Driven Fuel Oil Feed Pump 0.5g SEIS-DGPP-CD-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Motor Driven Fuel Oil Feed Pump (Aux. Building) 1.00E+00 SIE-FLAG-SBO FLAG FOR Seismic-Induced SBO 25 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-DGSL-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Silencer 1.00E+00 SIE-FLAG-SBO FLAG FOR Seismic-Induced SBO 26 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-DGTK40-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Starting Air Tank 1.00E+00 SIE-FLAG-SBO FLAG FOR Seismic-Induced SBO APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (71/150)

Table 19.1-44A (5 of 11)

No.

BE. Prob.

Cutsets Sequence Level HCLPF Basic Event Cutset Description 27 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-DOMPS-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Emergency Diesel Fuel Oil transfer pump 0.5g SEIS-DOMPS-CD-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Emergency Diesel Fuel Oil transfer pump (Aux. Building) 1.00E+00 SIE-FLAG-SBO FLAG FOR Seismic-Induced SBO 28 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-DOTK01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Diesel Fuel Oil Storage Tank 0.5g SEIS-DOTK01-CD-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Diesel Fuel Oil Storage Tank (Aux. Building) 1.00E+00 SIE-FLAG-SBO FLAG FOR Seismic-Induced SBO 29 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-DOTK02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Diesel Fuel Oil Day Tank 0.5g SEIS-DOTK02-CD-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Diesel Fuel Oil Day Tank (Aux. Building) 1.00E+00 SIE-FLAG-SBO FLAG FOR Seismic-Induced SBO 30 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-ESF-RPS-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE ESF-CCS GC Cabinet 1.00E+00 SIE-FLAG-IC FLAG FOR Loss of All Instrumentation and Control 31 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-ESWIS-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE ESWIS 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (72/150)

Table 19.1-44A (6 of 11)

No.

BE. Prob.

Cutsets Sequence Level HCLPF Basic Event Cutset Description 32 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-IPINV-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE 120V AC Inverter(VBPSS) 1.00E+00 SIE-FLAG-IC FLAG FOR Loss of All Instrumentation and Control 33 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-IPREGTR-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Regulating Transformer 1.00E+00 SIE-FLAG-IC FLAG FOR Loss of All Instrumentation and Control 34 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-MSADV-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Main Steam Atmospheric Valves(ADV) 1.00E+00 SIE-FLAG-MSLB FLAG FOR Seismic-Induced MSLB 35 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-MSIV-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Main Steam Isolation Valves 1.00E+00 SIE-FLAG-MSLB FLAG FOR Seismic-Induced MSLB 36 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-MSSV-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Main Steam Safety Valves 1.00E+00 SIE-FLAG-MSLB FLAG FOR Seismic-Induced MSLB 37 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-RP-PM05-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE MCR SAFETY CONSOLE 1.00E+00 SIE-FLAG-IC FLAG FOR Loss of All Instrumentation and Control 38 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-SIHX01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Shutdown Cooling Heat Exchanger 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (73/150)

Table 19.1-44A (7 of 11)

No.

BE. Prob.

Cutsets Sequence Level HCLPF Basic Event Cutset Description 39 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-SIHX02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE SC Pump Miniflow Heat Exchanger 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 40 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-SXPP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Essential Service Water Pump 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 41 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-TB-FAIL-0.5G SEISMIC FAILURE OF THE TURBINE BUILDING COLLAPE INTO AUXILIARY BLDG 1.00E+00 SIE-FLAG-DMG-CF FLAG FOR Seismic Events Leading to Direct Core Damage with Containment Structural Damage 42 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-VGAH02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE EDG Room Emergency Exhaust Fan 0.5g SEIS-VGAH02-CD-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE EDG Room Emergency Exhaust Fan (Aux. Building) 1.00E+00 SIE-FLAG-SBO FLAG FOR Seismic-Induced SBO 43 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-VGAH-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE ESW Pump Room Supply Fan 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 44 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-VKHV10-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE CS Pump Room Cubicle Cooler 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (74/150)

Table 19.1-44A (8 of 11)

No.

BE. Prob.

Cutsets Sequence Level HCLPF Basic Event Cutset Description 45 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-VKHV11/12-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE SI Room Cubicle Cooler 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 46 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-VKHV13/14-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE CCWP Room Cubicle Cooler 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 47 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-VKHV16-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE SC Pump & Mini-flow Hx.

Room Cubicle Cooler 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 48 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-VKHV18-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Charging Pump Room Cubicle Cooler 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 49 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-VOHV32-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Essential Chiller & Pump Cubicle Cooler 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 50 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-VOHV33-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFWP Room Cubicle Cooler-MD 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 51 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-WOCH-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Essential Chillers 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (75/150)

Table 19.1-44A (9 of 11)

No.

BE. Prob.

Cutsets Sequence Level HCLPF Basic Event Cutset Description 52 1.00E+00

%SEISMIC 0.5g 0.5g SEIS-WOLP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Essential Chilled Water System Control Panel 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 53 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-WOPP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Essential Chilled Water Pumps 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 54 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-WOTK02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE ECW Air Separator 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 55 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-WOTK-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE ECW Compression Tank 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 56 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.51g 0.51g SEIS-AB-FAIL-0.51G SEISMIC FAILURE OF AUXILIARY BUILDING 1.00E+00 SIE-FLAG-DMG-CF FLAG FOR Seismic Events Leading to Direct Core Damage with Containment Structural Damage 57 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.51g 0.51g SEIS-RVI-RCS-0.51G SEISMIC INDUCED RX VESSESL INTERNAL FAILURE 1.00E+00 SIE-FLAG-DMG-CF FLAG FOR Seismic Events Leading to Direct Core Damage with Containment Structural Damage 58 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.51g 0.51g SEIS-PZRNOZZ-RCS-FAIL-0.51G SEISMICALLY-INDUCED MEDIUM LOCA DUE TO PZR NOZZ FAILURE 1.00E+00 SIE-FLAG-MLOCA FLAG FOR SEISMICALLY-INDUCED MEDIUM LOCA APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (76/150)

Table 19.1-44A (10 of 11)

No.

BE. Prob.

Cutsets Sequence Level HCLPF Basic Event Cutset Description 59 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.52g 0.52g SEIS-NI-FAIL-0.52G SEISMIC INDUCED FAILURE OF Nuclear Island failure 1.00E+00 SIE-FLAG-DMG-CF FLAG FOR Seismic Events Leading to Direct Core Damage with Containment Structural Damage 60 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.54g 0.54g SEIS-SGNOZZ-RCS-FAIL-0.54G SEISMIC INDUCED FAILURE OF Steam Generator Nozzle 1.00E+00 SIE-FLAG-DMG-CF FLAG FOR Seismic Events Leading to Direct Core Damage with Containment Structural Damage 61 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.55g 0.55g SEIS-PIPE-RCS-FAIL-0.55G SEISMICALLY-INDUCED LARGE LOCA DUE TO RCS PIPE FALURE 1.00E+00 SIE-FLAG-LLOCA FLAG FOR SEISMICALLY-INDUCED LARGE LOCA 62 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.6g 0.6g SEIS-SG-RCS-FAIL-0.6G SEISMICALLY-INDUCED SG SUPPORT FALURE 1.00E+00 SIE-FLAG-DMG-CF FLAG FOR Seismic Events Leading to Direct Core Damage with Containment Structural Damage 63 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.63g 0.63g SEIS-PZR-RCS-FAIL-0.63G SEISMICALLY-INDUCED PZR SKIRT FAILURE 1.00E+00 SIE-FLAG-DMG-CF FLAG FOR Seismic Events Leading to Direct Core Damage with Containment Structural Damage 64 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.64g 0.64g SEIS-CEDM-RCS-FAIL-0.64G SEISMIC INDUCED FAILURE OF THE CEDM (Control Element Drive Mechanism) 1.00E+00 SIE-FLAG-ATWS FLAG FOR Seismic-Induced ATWS APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (77/150)

Table 19.1-44A (11 of 11)

No.

BE. Prob.

Cutsets Sequence Level HCLPF Basic Event Cutset Description 65 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.75g 0.75g SEIS-ALL-SSC-0.75G Generic Seismic Equipment Failure all eqiupment correlated to failure at 0.75g HCLPF 1.00E+00 SIE-FLAG-IC FLAG FOR Loss of All Instrumentation and Control 66 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.92g 65 0.92g SEIS-RV-RCS-FAIL-0.92G SEISMICALLY-INDUCED REACTOR VESSEL FALURE 1.00E+00 SIE-FLAG-DMG-CF FLAG FOR Seismic Events Leading to Direct Core Damage with Containment Structural Damage 67 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.94g 66 0.94g SEIS-CTS-EX-FAIL-0.94G SEISMIC FAILURE OF CONTAINMENT EXTERIOR 1.00E+00 SIE-FLAG-DMG-CF FLAG FOR Seismic Events Leading to Direct Core Damage with Containment Structural Damage 68 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 1.09g 67 1.09g SEIS-CTS-IN-FAIL-1.09G SEISMIC FAILURE OF CONTAINMENT INTERNAL STRUCTURE 1.00E+00 SIE-FLAG-DMG-CF FLAG FOR Seismic Events Leading to Direct Core Damage with Containment Structural Damage 69 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 1.31g 68 1.31g SEIS-RCP-RCS-FAIL-1.31G SEISMICALLY-INDUCED RCP SUPPORT FALURE 1.00E+00 SIE-FLAG-DMG-CF FLAG FOR Seismic Events Leading to Direct Core Damage with Containment Structural Damage APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (78/150)

Table 19.1-44B (1 of 36)

At-power Seismic Event Top 100 core damage cutsets of Non-Direct Core Damage Initiator No.

BE. Prob.

Basic Event Cutset Description Sequence Level HCLPF 1

1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 0.5g SEIS-SIPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Shutdown Cooling Pumps 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 2

1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 0.5g SEIS-SIPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Shutdown Cooling Pumps 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA 3

1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 0.5g SEIS-SI-INV-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE SI INVERTER 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (79/150)

Table 19.1-44B (2 of 36)

No.

BE. Prob.

Basic Event Cutset Description Sequence Level HCLPF 4

1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 5

1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 0.5g SEIS-SI-INV-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE SI INVERTER 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA 6

1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA 7

1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 0.5g SEIS-SIPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Shutdown Cooling Pumps 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (80/150)

Table 19.1-44B (3 of 36)

No.

BE. Prob.

Basic Event Cutset Description Sequence Level HCLPF 8

1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 0.5g SEIS-SIPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Shutdown Cooling Pumps 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA 9

1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 0.5g SEIS-SI-INV-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE SI INVERTER 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 10 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 11 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 0.5g SEIS-SI-INV-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE SI INVERTER 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (81/150)

Table 19.1-44B (4 of 36)

No.

BE. Prob.

Basic Event Cutset Description Sequence Level HCLPF 12 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA 13 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 0.5g SEIS-SIPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Shutdown Cooling Pumps 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA 14 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 0.5g SEIS-SIT-FAIL-0.5G SEISMIC FAILURE OF SITS 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA 15 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 1.00E-01 AFOPH-S-ALT-LT Operator Fails to Transfer AFW Source From AFWST to RWT 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 0.5g SEIS-SIPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Shutdown Cooling Pumps 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (82/150)

Table 19.1-44B (5 of 36)

No.

BE. Prob.

Basic Event Cutset Description Sequence Level HCLPF 16 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 1.00E-01 AFOPH-S-ALT-LT Operator Fails to Transfer AFW Source From AFWST to RWT 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 0.5g SEIS-SI-INV-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE SI INVERTER 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 17 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 1.00E-01 AFOPH-S-ALT-LT Operator Fails to Transfer AFW Source From AFWST to RWT 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 0.5g SEIS-SI-INV-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE SI INVERTER 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA 18 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 1.00E-01 MSOPH-S-ASC-SLOCA Operator Fails to Perform Aggressive Secondary Cooling After SLOCA 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA 19 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 1.00E-01 RCOPH-S-SDSE-FW Operator Fails to Open POSRVs in Early Phase for F&B Operation 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (83/150)

Table 19.1-44B (6 of 36)

No.

BE. Prob.

Basic Event Cutset Description Sequence Level HCLPF 20 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 1.00E-01 RCOPH-S-SDSE-FW Operator Fails to Open POSRVs in Early Phase for F&B Operation 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA 21 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 1.00E-01 RCOPH-S-SDSE-FW Operator Fails to Open POSRVs in Early Phase for F&B Operation 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 22 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 1.00E-01 RCOPH-S-SDSE-FW Operator Fails to Open POSRVs in Early Phase for F&B Operation 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA 23 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 1.00E-01 SIOPH-S-IRWSTCOOL Operator Fails to Cool IRWST Water Using SCS Pump APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (84/150)

Table 19.1-44B (7 of 36)

No.

BE. Prob.

Basic Event Cutset Description Sequence Level HCLPF 24 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA 1.00E-01 SIOPH-S-IRWSTCOOL Operator Fails to Cool IRWST Water Using SCS Pump 25 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 1.00E-01 SIOPH-S-IRWSTCOOL Operator Fails to Cool IRWST Water Using SCS Pump 26 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA 1.00E-01 SIOPH-S-IRWSTCOOL Operator Fails to Cool IRWST Water Using SCS Pump APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (85/150)

Table 19.1-44B (8 of 36)

No.

BE. Prob.

Basic Event Cutset Description Sequence Level HCLPF 27 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA 1.00E-01 SIOPH-S-IRWSTCOOL Operator Fails to Cool IRWST Water Using SCS Pump 28 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA 1.00E-01 SIOPH-S-INJ Operator Fails to Align SCS for Injection 29 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 1.00E-01 AFOPH-S-ALT-LT Operator Fails to Transfer AFW Source From AFWST to RWT 1.00E-01 RCOPH-S-SDSL OPERATOR FAILS TO OPEN 1 OF 4 SDS VALVE LATE PHASE 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 30 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 1.00E-01 AFOPH-S-ALT-LT Operator Fails to Transfer AFW Source From AFWST to RWT 1.00E-01 RCOPH-S-SDSL OPERATOR FAILS TO OPEN 1 OF 4 SDS VALVE LATE PHASE 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (86/150)

Table 19.1-44B (8 of 36)

No.

BE. Prob.

Basic Event Cutset Description Sequence Level HCLPF 31 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 1.00E-01 AFOPH-S-ALT-LT Operator Fails to Transfer AFW Source From AFWST to RWT 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA 1.00E-01 SIOPH-S-IRWSTCOOL Operator Fails to Cool IRWST Water Using SCS Pump 32 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 2.50E-02 DGDGR-A-DGA FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01A 2.50E-02 DGDGR-B-DGB FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01B 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 33 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 2.50E-02 DGDGR-A-DGA FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01A 2.50E-02 DGDGR-B-DGB FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01B 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (87/150)

Table 19.1-44B (9 of 36)

No.

BE. Prob.

Basic Event Cutset Description Sequence Level HCLPF 34 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 2.50E-02 DGDGR-A-DGA FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01A 2.50E-02 DGDGR-B-DGB FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01B 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 35 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 2.50E-02 DGDGR-A-DGA FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01A 2.50E-02 DGDGR-B-DGB FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01B 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA 36 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 2.50E-02 DGDGR-A-DGA FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01A 2.50E-02 DGDGR-B-DGB FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01B 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (88/150)

Table 19.1-44B (10 of 36)

No.

BE. Prob.

Basic Event Cutset Description Sequence Level HCLPF 37 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 2.50E-02 DGDGR-C-DGC FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01C 2.50E-02 DGDGR-D-DGD FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01D 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 0.5g SEIS-SIPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Shutdown Cooling Pumps 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 38 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 2.50E-02 DGDGR-C-DGC FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01C 2.50E-02 DGDGR-D-DGD FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01D 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 0.5g SEIS-SIPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Shutdown Cooling Pumps 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (89/150)

Table 19.1-44B (11 of 36)

No.

BE. Prob.

Basic Event Cutset Description Sequence Level HCLPF 39 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 2.50E-02 DGDGR-C-DGC FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01C 2.50E-02 DGDGR-D-DGD FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01D 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 0.5g SEIS-SIPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Shutdown Cooling Pumps 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 40 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 2.50E-02 DGDGR-C-DGC FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01C 2.50E-02 DGDGR-D-DGD FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01D 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 0.5g SEIS-SIPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Shutdown Cooling Pumps 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (90/150)

Table 19.1-44B (12 of 36)

No.

BE. Prob.

Basic Event Cutset Description Sequence Level HCLPF 41 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 1.44E-02 DGDGM-A-DGA DG 01A UNAVAILABLE DUE TO T&M 2.50E-02 DGDGR-B-DGB FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01B 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 42 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 1.44E-02 DGDGM-A-DGA DG 01A UNAVAILABLE DUE TO T&M 2.50E-02 DGDGR-B-DGB FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01B 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (91/150)

Table 19.1-44B (13 of 36)

No.

BE. Prob.

Basic Event Cutset Description Sequence Level HCLPF 43 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 1.44E-02 DGDGM-A-DGA DG 01A UNAVAILABLE DUE TO T&M 2.50E-02 DGDGR-B-DGB FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01B 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 44 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 1.44E-02 DGDGM-A-DGA DG 01A UNAVAILABLE DUE TO T&M 2.50E-02 DGDGR-B-DGB FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01B 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA 45 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 1.44E-02 DGDGM-A-DGA DG 01A UNAVAILABLE DUE TO T&M 2.50E-02 DGDGR-B-DGB FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01B 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (92/150)

Table 19.1-44B (14 of 36)

No.

BE. Prob.

Basic Event Cutset Description Sequence Level HCLPF 46 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 1.44E-02 DGDGM-B-DGB DG 01B UNAVAILABLE DUE TO T&M 2.50E-02 DGDGR-A-DGA FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01A 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 47 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 1.44E-02 DGDGM-B-DGB DG 01B UNAVAILABLE DUE TO T&M 2.50E-02 DGDGR-A-DGA FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01A 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (93/150)

Table 19.1-44B (15 of 36)

No.

BE. Prob.

Basic Event Cutset Description Sequence Level HCLPF 48 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 1.44E-02 DGDGM-B-DGB DG 01B UNAVAILABLE DUE TO T&M 2.50E-02 DGDGR-A-DGA FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01A 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 49 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 1.44E-02 DGDGM-B-DGB DG 01B UNAVAILABLE DUE TO T&M 2.50E-02 DGDGR-A-DGA FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01A 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA 50 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 1.44E-02 DGDGM-B-DGB DG 01B UNAVAILABLE DUE TO T&M 2.50E-02 DGDGR-A-DGA FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01A 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (94/150)

Table 19.1-44B (16 of 36)

No.

BE. Prob.

Basic Event Cutset Description Sequence Level HCLPF 51 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 1.44E-02 DGDGM-C-DGC DG 01C UNAVAILABLE DUE TO T&M 2.50E-02 DGDGR-D-DGD FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01D 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 0.5g SEIS-SIPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Shutdown Cooling Pumps 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 52 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 1.44E-02 DGDGM-C-DGC DG 01C UNAVAILABLE DUE TO T&M 2.50E-02 DGDGR-D-DGD FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01D 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 0.5g SEIS-SIPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Shutdown Cooling Pumps 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (95/150)

Table 19.1-44B (17 of 36)

No.

BE. Prob.

Basic Event Cutset Description Sequence Level HCLPF 53 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 1.44E-02 DGDGM-C-DGC DG 01C UNAVAILABLE DUE TO T&M 2.50E-02 DGDGR-D-DGD FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01D 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 0.5g SEIS-SIPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Shutdown Cooling Pumps 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 54 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 1.44E-02 DGDGM-C-DGC DG 01C UNAVAILABLE DUE TO T&M 2.50E-02 DGDGR-D-DGD FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01D 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 0.5g SEIS-SIPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Shutdown Cooling Pumps 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (96/150)

Table 19.1-44B (18 of 36)

No.

BE. Prob.

Basic Event Cutset Description Sequence Level HCLPF 55 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 1.44E-02 DGDGM-D-DGD DG 01D UNAVAILABLE DUE TO T&M 2.50E-02 DGDGR-C-DGC FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01C 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 0.5g SEIS-SIPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Shutdown Cooling Pumps 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 56 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 1.44E-02 DGDGM-D-DGD DG 01D UNAVAILABLE DUE TO T&M 2.50E-02 DGDGR-C-DGC FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01C 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 0.5g SEIS-SIPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Shutdown Cooling Pumps 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (97/150)

Table 19.1-44B (19 of 36)

No.

BE. Prob.

Basic Event Cutset Description Sequence Level HCLPF 57 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 1.44E-02 DGDGM-D-DGD DG 01D UNAVAILABLE DUE TO T&M 2.50E-02 DGDGR-C-DGC FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01C 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 0.5g SEIS-SIPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Shutdown Cooling Pumps 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 58 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 1.44E-02 DGDGM-D-DGD DG 01D UNAVAILABLE DUE TO T&M 2.50E-02 DGDGR-C-DGC FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01C 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 0.5g SEIS-SIPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Shutdown Cooling Pumps 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA 59 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 2.10E-04 RCPVWQ4-200/1/2/3 4/4 CCF OF RC PV V200/201/202/203 FAIL TO OPEN 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (98/150)

Table 19.1-44B (20 of 36)

No.

BE. Prob.

Basic Event Cutset Description Sequence Level HCLPF 60 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 2.10E-04 RCPVWQ4-200/1/2/3 4/4 CCF OF RC PV V200/201/202/203 FAIL TO OPEN 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA 61 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 2.10E-04 RCPVWQ4-200/1/2/3 4/4 CCF OF RC PV V200/201/202/203 FAIL TO OPEN 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 62 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 2.10E-04 RCPVWQ4-200/1/2/3 4/4 CCF OF RC PV V200/201/202/203 FAIL TO OPEN 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (99/150)

Table 19.1-44B (21 of 36)

No.

BE. Prob.

Basic Event Cutset Description Sequence Level HCLPF 63 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 1.44E-02 DGDGM-A-DGA DG 01A UNAVAILABLE DUE TO T&M 1.44E-02 DGDGM-B-DGB DG 01B UNAVAILABLE DUE TO T&M 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 64 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 1.44E-02 DGDGM-A-DGA DG 01A UNAVAILABLE DUE TO T&M 1.44E-02 DGDGM-B-DGB DG 01B UNAVAILABLE DUE TO T&M 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (100/150)

Table 19.1-44B (22 of 36)

No.

BE. Prob.

Basic Event Cutset Description Sequence Level HCLPF 65 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 1.44E-02 DGDGM-A-DGA DG 01A UNAVAILABLE DUE TO T&M 1.44E-02 DGDGM-B-DGB DG 01B UNAVAILABLE DUE TO T&M 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 66 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 1.44E-02 DGDGM-A-DGA DG 01A UNAVAILABLE DUE TO T&M 1.44E-02 DGDGM-B-DGB DG 01B UNAVAILABLE DUE TO T&M 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA 67 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 1.44E-02 DGDGM-A-DGA DG 01A UNAVAILABLE DUE TO T&M 1.44E-02 DGDGM-B-DGB DG 01B UNAVAILABLE DUE TO T&M 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (101/150)

Table 19.1-44B (23 of 36)

No.

BE. Prob.

Basic Event Cutset Description Sequence Level HCLPF 68 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 1.44E-02 DGDGM-C-DGC DG 01C UNAVAILABLE DUE TO T&M 1.44E-02 DGDGM-D-DGD DG 01D UNAVAILABLE DUE TO T&M 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 0.5g SEIS-SIPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Shutdown Cooling Pumps 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 69 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 1.44E-02 DGDGM-C-DGC DG 01C UNAVAILABLE DUE TO T&M 1.44E-02 DGDGM-D-DGD DG 01D UNAVAILABLE DUE TO T&M 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 0.5g SEIS-SIPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Shutdown Cooling Pumps 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (102/150)

Table 19.1-44B (24 of 36)

No.

BE. Prob.

Basic Event Cutset Description Sequence Level HCLPF 70 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 1.44E-02 DGDGM-C-DGC DG 01C UNAVAILABLE DUE TO T&M 1.44E-02 DGDGM-D-DGD DG 01D UNAVAILABLE DUE TO T&M 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 0.5g SEIS-SIPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Shutdown Cooling Pumps 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 71 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 1.44E-02 DGDGM-C-DGC DG 01C UNAVAILABLE DUE TO T&M 1.44E-02 DGDGM-D-DGD DG 01D UNAVAILABLE DUE TO T&M 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 0.5g SEIS-SIPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Shutdown Cooling Pumps 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (103/150)

Table 19.1-44B (25 of 36)

No.

BE. Prob.

Basic Event Cutset Description Sequence Level HCLPF 72 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 7.12E-03 CSMPM2A-PP01A CS PUMP 1 PP01A UNAVAILABLE DUE TO T&M 2.50E-02 DGDGR-D-DGD FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01D 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 0.5g SEIS-SIPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Shutdown Cooling Pumps 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 73 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 7.12E-03 CSMPM2A-PP01A CS PUMP 1 PP01A UNAVAILABLE DUE TO T&M 2.50E-02 DGDGR-D-DGD FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01D 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 0.5g SEIS-SIPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Shutdown Cooling Pumps 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (104/150)

Table 19.1-44B (26 of 36)

No.

BE. Prob.

Basic Event Cutset Description Sequence Level HCLPF 74 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 7.12E-03 CSMPM2A-PP01A CS PUMP 1 PP01A UNAVAILABLE DUE TO T&M 2.50E-02 DGDGR-D-DGD FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01D 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 0.5g SEIS-SIPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Shutdown Cooling Pumps 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 75 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 7.12E-03 CSMPM2A-PP01A CS PUMP 1 PP01A UNAVAILABLE DUE TO T&M 2.50E-02 DGDGR-D-DGD FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01D 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 0.5g SEIS-SIPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Shutdown Cooling Pumps 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (105/150)

Table 19.1-44B (27 of 36)

No.

BE. Prob.

Basic Event Cutset Description Sequence Level HCLPF 76 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 7.12E-03 CSMPM2B-PP01B CS PUMP PP01B UNAVAILABLE DUE TO T&M 2.50E-02 DGDGR-C-DGC FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01C 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 0.5g SEIS-SIPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Shutdown Cooling Pumps 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 77 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 7.12E-03 CSMPM2B-PP01B CS PUMP PP01B UNAVAILABLE DUE TO T&M 2.50E-02 DGDGR-C-DGC FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01C 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 0.5g SEIS-SIPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Shutdown Cooling Pumps 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (106/150)

Table 19.1-44B (28 of 36)

No.

BE. Prob.

Basic Event Cutset Description Sequence Level HCLPF 78 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 7.12E-03 CSMPM2B-PP01B CS PUMP PP01B UNAVAILABLE DUE TO T&M 2.50E-02 DGDGR-C-DGC FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01C 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 0.5g SEIS-SIPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Shutdown Cooling Pumps 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 79 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 7.12E-03 CSMPM2B-PP01B CS PUMP PP01B UNAVAILABLE DUE TO T&M 2.50E-02 DGDGR-C-DGC FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01C 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 0.5g SEIS-SIPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Shutdown Cooling Pumps 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (107/150)

Table 19.1-44B (29 of 36)

No.

BE. Prob.

Basic Event Cutset Description Sequence Level HCLPF 80 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 2.50E-02 DGDGR-A-DGA FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01A 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 7.12E-03 SIMPM1B-SCPP01B SC PUMP PP01B UNAVAILABLE DUE TO T&M 81 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 2.50E-02 DGDGR-A-DGA FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01A 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA 7.12E-03 SIMPM1B-SCPP01B SC PUMP PP01B UNAVAILABLE DUE TO T&M APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (108/150)

Table 19.1-44B (30 of 36)

No.

BE. Prob.

Basic Event Cutset Description Sequence Level HCLPF 82 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 2.50E-02 DGDGR-A-DGA FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01A 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 7.12E-03 SIMPM1B-SCPP01B SC PUMP PP01B UNAVAILABLE DUE TO T&M 83 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 2.50E-02 DGDGR-A-DGA FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01A 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA 7.12E-03 SIMPM1B-SCPP01B SC PUMP PP01B UNAVAILABLE DUE TO T&M 84 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 2.50E-02 DGDGR-A-DGA FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01A 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA 7.12E-03 SIMPM1B-SCPP01B SC PUMP PP01B UNAVAILABLE DUE TO T&M APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (109/150)

Table 19.1-44B (30 of 36)

No.

BE. Prob.

Basic Event Cutset Description Sequence Level HCLPF 85 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 2.50E-02 DGDGR-B-DGB FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01B 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 7.12E-03 SIMPM1A-SCPP01A SC PUMP PP01A UNAVAILABLE DUE TO T&M 86 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 2.50E-02 DGDGR-B-DGB FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01B 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA 7.12E-03 SIMPM1A-SCPP01A SC PUMP PP01A UNAVAILABLE DUE TO T&M APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (110/150)

Table 19.1-44B (31 of 36)

No.

BE. Prob.

Basic Event Cutset Description Sequence Level HCLPF 87 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 2.50E-02 DGDGR-B-DGB FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01B 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 7.12E-03 SIMPM1A-SCPP01A SC PUMP PP01A UNAVAILABLE DUE TO T&M 88 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 2.50E-02 DGDGR-B-DGB FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01B 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA 7.12E-03 SIMPM1A-SCPP01A SC PUMP PP01A UNAVAILABLE DUE TO T&M 89 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 2.50E-02 DGDGR-B-DGB FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01B 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA 7.12E-03 SIMPM1A-SCPP01A SC PUMP PP01A UNAVAILABLE DUE TO T&M APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (111/150)

Table 19.1-44B (32 of 36)

No.

BE. Prob.

Basic Event Cutset Description Sequence Level HCLPF 90 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 2.50E-02 DGDGR-A-DGA FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01A 6.66E-03 PFHBO1B-SW01B-H2 PCB SW01B-H2 4.16KV SWGR SW01B FROM UAT FAILS TO OPEN 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 91 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 2.50E-02 DGDGR-A-DGA FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01A 6.66E-03 PFHBO1B-SW01B-H2 PCB SW01B-H2 4.16KV SWGR SW01B FROM UAT FAILS TO OPEN 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (112/150)

Table 19.1-44B (33 of 36)

No.

BE. Prob.

Basic Event Cutset Description Sequence Level HCLPF 92 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 2.50E-02 DGDGR-A-DGA FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01A 6.66E-03 PFHBO1B-SW01B-H2 PCB SW01B-H2 4.16KV SWGR SW01B FROM UAT FAILS TO OPEN 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 93 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 2.50E-02 DGDGR-A-DGA FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01A 6.66E-03 PFHBO1B-SW01B-H2 PCB SW01B-H2 4.16KV SWGR SW01B FROM UAT FAILS TO OPEN 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA 94 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 2.50E-02 DGDGR-A-DGA FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01A 6.66E-03 PFHBO1B-SW01B-H2 PCB SW01B-H2 4.16KV SWGR SW01B FROM UAT FAILS TO OPEN 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (113/150)

Table 19.1-44B (34 of 36)

No.

BE. Prob.

Basic Event Cutset Description Sequence Level HCLPF 95 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 2.50E-02 DGDGR-B-DGB FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01B 6.66E-03 PFHBO1A-SW01A-H2 PCB SW01A-H2 4.16KV SWGR SW01A FROM UAT FAILS TO OPEN 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 96 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 2.50E-02 DGDGR-B-DGB FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01B 6.66E-03 PFHBO1A-SW01A-H2 PCB SW01A-H2 4.16KV SWGR SW01A FROM UAT FAILS TO OPEN 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (114/150)

Table 19.1-44B (35 of 36)

No.

BE. Prob.

Basic Event Cutset Description Sequence Level HCLPF 97 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 2.50E-02 DGDGR-B-DGB FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01B 6.66E-03 PFHBO1A-SW01A-H2 PCB SW01A-H2 4.16KV SWGR SW01A FROM UAT FAILS TO OPEN 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 98 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 2.50E-02 DGDGR-B-DGB FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01B 6.66E-03 PFHBO1A-SW01A-H2 PCB SW01A-H2 4.16KV SWGR SW01A FROM UAT FAILS TO OPEN 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA 99 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 2.50E-02 DGDGR-B-DGB FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01B 6.66E-03 PFHBO1A-SW01A-H2 PCB SW01A-H2 4.16KV SWGR SW01A FROM UAT FAILS TO OPEN 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (115/150)

Table 19.1-44B (36 of 36)

No.

BE. Prob.

Basic Event Cutset Description Sequence Level HCLPF 100 1.00E+00 %SEISMIC DUMMY SEISMIC EVENT 0.5g 2.50E-02 DGDGR-C-DGC FAILS TO RUN EMERGENCY DIESEL GENERATOR DG01C 6.66E-03 PFHBO2B-SW01D-G2 PCB SW01D-G2 4.16KV SWGR SW01D FROM UAT FAILS TO OPEN 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 0.5g SEIS-SIPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Shutdown Cooling Pumps 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (116/150)

Table 19.1-44C (1 of 7)

At-power Direct Containment Failure cutsets No.

BE. Prob.

Cutsets Sequence Level HCLPF Basic Event Cutset Description 1

1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-480V-LC-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE 480V Load Center 1.00E+00 SIE-FLAG-IC FLAG FOR Loss of All Instrumentation and Control 2

1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-480V-MCC-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE 480V MCC 1.00E+00 SIE-FLAG-IC FLAG FOR Loss of All Instrumentation and Control 3

1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-4KV-BUS-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE 4.16kV MCSG 1.00E+00 SIE-FLAG-SBO FLAG FOR Seismic-Induced SBO 4

1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-DC-BC-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE 125V DC Battery Chargers 1.00E+00 SIE-FLAG-IC FLAG FOR Loss of All Instrumentation and Control 5

1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-DC-BT-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Batteries & Racks 1.00E+00 SIE-FLAG-SBO FLAG FOR Seismic-Induced SBO 6

1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-DC-MCC-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE 125V DC Control Center 1.00E+00 SIE-FLAG-SBO FLAG FOR Seismic-Induced SBO 7

1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-DG-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Emergency Diesel Generators 0.5g SEIS-DG-FAIL-CD-0.5G SEISMIC INDUCED FAILURE OF THE Emergency Diesel Generators (Aux.

Building) 1.00E+00 SIE-FLAG-SBO FLAG FOR Seismic-Induced SBO APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (117/150)

Table 19.1-44C (2 of 7)

No.

BE. Prob.

Cutsets Sequence Level HCLPF Basic Event Cutset Description 8

1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-DGFT-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Air Intake Filter 1.00E+00 SIE-FLAG-SBO FLAG FOR Seismic-Induced SBO 9

1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-DGHX-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Lube Oil Water Hx 1.00E+00 SIE-FLAG-SBO FLAG FOR Seismic-Induced SBO 10 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-DGPP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Motor Driven Fuel Oil Feed Pump 0.5g SEIS-DGPP-CD-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Motor Driven Fuel Oil Feed Pump (Aux. Building) 1.00E+00 SIE-FLAG-SBO FLAG FOR Seismic-Induced SBO 11 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-DGSL-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Silencer 1.00E+00 SIE-FLAG-SBO FLAG FOR Seismic-Induced SBO 12 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-DGTK40-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Starting Air Tank 1.00E+00 SIE-FLAG-SBO FLAG FOR Seismic-Induced SBO 13 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-DOMPS-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Emergency Diesel Fuel Oil transfer pump 0.5g SEIS-DOMPS-CD-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Emergency Diesel Fuel Oil transfer pump (Aux. Building) 1.00E+00 SIE-FLAG-SBO FLAG FOR Seismic-Induced SBO APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (118/150)

Table 19.1-44C (3 of 7)

No.

BE. Prob.

Cutsets Sequence Level HCLPF Basic Event Cutset Description 14 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-DOTK01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Diesel Fuel Oil Storage Tank 0.5g SEIS-DOTK01-CD-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Diesel Fuel Oil Storage Tank (Aux.

Building) 1.00E+00 SIE-FLAG-SBO FLAG FOR Seismic-Induced SBO 15 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-DOTK02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Diesel Fuel Oil Day Tank 0.5g SEIS-DOTK02-CD-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Diesel Fuel Oil Day Tank (Aux.

Building) 1.00E+00 SIE-FLAG-SBO FLAG FOR Seismic-Induced SBO 16 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-ESF-RPS-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE ESF-CCS GC Cabinet 1.00E+00 SIE-FLAG-IC FLAG FOR Loss of All Instrumentation and Control 17 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-IPINV-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE 120V AC Inverter(VBPSS) 1.00E+00 SIE-FLAG-IC FLAG FOR Loss of All Instrumentation and Control 18 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-IPREGTR-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Regulating Transformer 1.00E+00 SIE-FLAG-IC FLAG FOR Loss of All Instrumentation and Control 19 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-MSADV-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Main Steam Atmospheric Valves(ADV) 1.00E+00 SIE-FLAG-MSLB FLAG FOR Seismic-Induced MSLB APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (119/150)

Table 19.1-44C (4 of 7)

No.

BE. Prob.

Cutsets Sequence Level HCLPF Basic Event Cutset Description 20 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-MSIV-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Main Steam Isolation Valves 1.00E+00 SIE-FLAG-MSLB FLAG FOR Seismic-Induced MSLB 21 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-MSSV-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Main Steam Safety Valves 1.00E+00 SIE-FLAG-MSLB FLAG FOR Seismic-Induced MSLB 22 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-RP-PM05-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE MCR SAFETY CONSOLE 1.00E+00 SIE-FLAG-IC FLAG FOR Loss of All Instrumentation and Control 23 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-VGAH02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE EDG Room Emergency Exhaust Fan 0.5g SEIS-VGAH02-CD-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE EDG Room Emergency Exhaust Fan (Aux. Building) 1.00E+00 SIE-FLAG-SBO FLAG FOR Seismic-Induced SBO 24 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CPD-FAIL-0.5G SEISMIC FAILURE OF COMPOUND BUILDING COLLAPE INTO AUXILIARY BLDG 1.00E+00 SIE-FLAG-DMG-CF FLAG FOR Seismic Events Leading to Direct Core Damage with Containment Structural Damage 25 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-TB-FAIL-0.5G SEISMIC FAILURE OF THE TURBINE BUILDING COLLAPE INTO AUXILIARY BLDG 1.00E+00 SIE-FLAG-DMG-CF FLAG FOR Seismic Events Leading to Direct Core Damage with Containment Structural Damage APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (120/150)

Table 19.1-44C (5 of 7)

No.

BE. Prob.

Cutsets Sequence Level HCLPF Basic Event Cutset Description 26 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.52g 0.52g SEIS-NI-FAIL-0.52G SEISMIC FAILURE OF Nuclear Island 1.00E+00 SIE-FLAG-DMG-CF FLAG FOR Seismic Events Leading to Direct Core Damage with Containment Structural Damage 27 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.51g 0.51g SEIS-AB-FAIL-0.51G SEISMIC FAILURE OF AUXILIARY BUILDING 1.00E+00 SIE-FLAG-DMG-CF FLAG FOR Seismic Events Leading to Direct Core Damage with Containment Structural Damage 28 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.51g 0.51g SEIS-RVI-RCS-0.51G SEISMIC INDUCED RX VESSESL INTERNAL FAILURE 1.00E+00 SIE-FLAG-DMG-CF FLAG FOR Seismic Events Leading to Direct Core Damage with Containment Structural Damage 29 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.51g 0.51g SEIS-PZRNOZZ-RCS-FAIL-0.51G SEISMICALLY-INDUCED MEDIUM LOCA DUE TO PZR NOZZ FAILURE 1.00E+00 SIE-FLAG-MLOCA FLAG FOR SEISMICALLY-INDUCED MEDIUM LOCA 30 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.54g 0.54g SEIS-SGNOZZ-RCS-FAIL-0.54G SEISMIC INDUCED FAILURE OF Steam Generator Nozzle 1.00E+00 SIE-FLAG-DMG-CF FLAG FOR Seismic Events Leading to Direct Core Damage with Containment Structural Damage 31 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.55g 0.55g SEIS-PIPE-RCS-FAIL-0.55G SEISMICALLY-INDUCED LARGE LOCA DUE TO RCS PIPE FALURE 1.00E+00 SIE-FLAG-LLOCA FLAG FOR SEISMICALLY-INDUCED LARGE LOCA APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (121/150)

Table 19.1-44C (6 of 7)

No.

BE. Prob.

Cutsets Sequence Level HCLPF Basic Event Cutset Description 32 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.6g 0.6g SEIS-SG-RCS-FAIL-0.6G SEISMICALLY-INDUCED SG SUPPORT FALURE 1.00E+00 SIE-FLAG-DMG-CF FLAG FOR Seismic Events Leading to Direct Core Damage with Containment Structural Damage 33 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.63g 0.63g SEIS-PZR-RCS-FAIL-0.63G SEISMICALLY-INDUCED PZR SKIRT FAILURE 1.00E+00 SIE-FLAG-DMG-CF FLAG FOR Seismic Events Leading to Direct Core Damage with Containment Structural Damage 34 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.64g 0.64g SEIS-CEDM-RCS-FAIL-0.64G SEISMIC INDUCED FAILURE OF THE CEDM (Control Element Drive Mechanism) 1.00E+00 SIE-FLAG-ATWS FLAG FOR Seismic-Induced ATWS 35 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.75g 0.75g SEIS-ALL-SSC-0.75G Generic Seismic Equipment Failure all eqiupment correlated to failure at 0.75g HCLPF 1.00E+00 SIE-FLAG-IC FLAG FOR Loss of All Instrumentation and Control 36 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.92g 35 0.92g SEIS-RV-RCS-FAIL-0.92G SEISMICALLY-INDUCED REACTOR VESSEL FALURE 1.00E+00 SIE-FLAG-DMG-CF FLAG FOR Seismic Events Leading to Direct Core Damage with Containment Structural Damage 37 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.94g 36 0.94g SEIS-CTS-EX-FAIL-0.94G SEISMIC FAILURE OF CONTAINMENT EXTERIOR 1.00E+00 SIE-FLAG-DMG-CF FLAG FOR Seismic Events Leading to Direct Core Damage with Containment Structural Damage APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (122/150)

Table 19.1-44C (7 of 7)

No.

BE. Prob.

Cutsets Sequence Level HCLPF Basic Event Cutset Description 38 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 1.09g 37 1.09g SEIS-CTS-IN-FAIL-1.09G SEISMIC FAILURE OF CONTAINMENT INTERNAL STRUCTURE 1.00E+00 SIE-FLAG-DMG-CF FLAG FOR Seismic Events Leading to Direct Core Damage with Containment Structural Damage 39 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 1.31g 38 1.31g SEIS-RCP-RCS-FAIL-1.31G SEISMICALLY-INDUCED RCP SUPPORT FALURE 1.00E+00 SIE-FLAG-DMG-CF FLAG FOR Seismic Events Leading to Direct Core Damage with Containment Structural Damage APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (123/150)

Table 19.1-44D (1 of 24)

At-power Seismic event Top 100 containment failure cutsets of Non-Direct Containment Failure Initiator No.

BE. Prob.

Cutsets Sequence Level HCLPF Basic Event Cutset Description 1

1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 0.5g SEIS-SI-INV-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE SI INVERTER 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 2

1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 0.5g SEIS-SIPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Shutdown Cooling Pumps 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 3

1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 0.5g SEIS-SI-INV-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE SI INVERTER 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (124/150)

Table 19.1-44D (2 of 24)

No.

BE. Prob.

Cutsets Sequence Level HCLPF Basic Event Cutset Description 4

1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 0.5g SEIS-SIPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Shutdown Cooling Pumps 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA 5

1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 6

1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (125/150)

Table 19.1-44D (3 of 24)

No.

BE. Prob.

Cutsets Sequence Level HCLPF Basic Event Cutset Description 7

1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 0.5g SEIS-SI-INV-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE SI INVERTER 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 8

1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 0.5g SEIS-SIPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Shutdown Cooling Pumps 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 9

1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 0.5g SEIS-SI-INV-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE SI INVERTER 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (126/150)

Table 19.1-44D (4 of 24)

No.

BE. Prob.

Cutsets Sequence Level HCLPF Basic Event Cutset Description 10 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 0.5g SEIS-SIPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Shutdown Cooling Pumps 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA 11 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 12 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA 13 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CCHX-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE CCW Heat Exchangers 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (127/150)

Table 19.1-44D (5 of 24)

No.

BE. Prob.

Cutsets Sequence Level HCLPF Basic Event Cutset Description 14 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CCHX-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE CCW Heat Exchangers 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 15 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CCHX-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE CCW Heat Exchangers 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 16 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CCLR-ACVPP-0.5G SEISMIC INDUCED FAILURE OF THE Aux Charging Pump Room Cubicle Cooler 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 17 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CCLR-ACVPP-0.5G SEISMIC INDUCED FAILURE OF THE Aux Charging Pump Room Cubicle Cooler 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 18 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CCLR-ACVPP-0.5G SEISMIC INDUCED FAILURE OF THE Aux Charging Pump Room Cubicle Cooler 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (128/150)

Table 19.1-44D (6 of 24)

No.

BE. Prob.

Cutsets Sequence Level HCLPF Basic Event Cutset Description 19 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CCLR-EDG-100-0.5G SEISMIC INDUCED FAILURE OF THE EDG Room Emergency Cubicle Cooler (EL.100')

0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 20 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CCLR-EDG-100-0.5G SEISMIC INDUCED FAILURE OF THE EDG Room Emergency Cubicle Cooler (EL.100')

0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 21 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CCLR-EDG-100-0.5G SEISMIC INDUCED FAILURE OF THE EDG Room Emergency Cubicle Cooler (EL.100')

1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 22 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CCLR-EDG-135-0.5G SEISMIC INDUCED FAILURE OF THE EDG Room Emergency Cubicle Cooler (EL.135')

0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (129/150)

Table 19.1-44D (7 of 24)

No.

BE. Prob.

Cutsets Sequence Level HCLPF Basic Event Cutset Description 23 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CCLR-EDG-135-0.5G SEISMIC INDUCED FAILURE OF THE EDG Room Emergency Cubicle Cooler (EL.135')

0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 24 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CCLR-EDG-135-0.5G SEISMIC INDUCED FAILURE OF THE EDG Room Emergency Cubicle Cooler (EL.135')

1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 25 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CCLR-EPA-0.5G SEISMIC INDUCED FAILURE OF THE Elect. Pen. Room Area Cubicle Cooler 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 26 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CCLR-EPA-0.5G SEISMIC INDUCED FAILURE OF THE Elect. Pen. Room Area Cubicle Cooler 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 27 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CCLR-EPA-0.5G SEISMIC INDUCED FAILURE OF THE Elect. Pen. Room Area Cubicle Cooler 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (130/150)

Table 19.1-44D (8 of 24)

No.

BE. Prob.

Cutsets Sequence Level HCLPF Basic Event Cutset Description 28 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CCLR-EPA-137-0.5G SEISMIC INDUCED FAILURE OF THE Elect. Pen. Room Area Cubicle Cooler (EL.137')

0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 29 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CCLR-EPA-137-0.5G SEISMIC INDUCED FAILURE OF THE Elect. Pen. Room Area Cubicle Cooler (EL.137')

0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 30 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CCLR-EPA-137-0.5G SEISMIC INDUCED FAILURE OF THE Elect. Pen. Room Area Cubicle Cooler (EL.137')

1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 31 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CCLR-IC-0.5G SEISMIC INDUCED FAILURE OF THE I&C Eq. Room Cubicle Cooler (EL.137')

0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (131/150)

Table 19.1-44D (9 of 24)

No.

BE. Prob.

Cutsets Sequence Level HCLPF Basic Event Cutset Description 32 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CCLR-IC-0.5G SEISMIC INDUCED FAILURE OF THE I&C Eq. Room Cubicle Cooler (EL.137')

0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 33 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CCLR-IC-0.5G SEISMIC INDUCED FAILURE OF THE I&C Eq. Room Cubicle Cooler (EL.137')

1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 34 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CCLR-MPR-0.5G SEISMIC INDUCED FAILURE OF THE Mech. Pen. Room Cubicle Cooler 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 35 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CCLR-MPR-0.5G SEISMIC INDUCED FAILURE OF THE Mech. Pen. Room Cubicle Cooler 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 36 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CCLR-MPR-0.5G SEISMIC INDUCED FAILURE OF THE Mech. Pen. Room Cubicle Cooler 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (132/150)

Table 19.1-44D (10 of 24)

No.

BE. Prob.

Cutsets Sequence Level HCLPF Basic Event Cutset Description 37 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CCPP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE CCW Pump 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 38 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CCPP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE CCW Pump 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 39 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CCPP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE CCW Pump 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 40 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CCTK-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE CCW Surge Tank 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 41 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CCTK-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE CCW Surge Tank 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (133/150)

Table 19.1-44D (11 of 24)

No.

BE. Prob.

Cutsets Sequence Level HCLPF Basic Event Cutset Description 42 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CCTK-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE CCW Surge Tank 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 43 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CCW-BLDG-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE CCW Hx Building 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 44 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CCW-BLDG-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE CCW Hx Building 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 45 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CCW-BLDG-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE CCW Hx Building 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 46 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.5g SEIS-ESWIS-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE ESWIS 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (134/150)

Table 19.1-44D (12 of 24)

No.

BE. Prob.

Cutsets Sequence Level HCLPF Basic Event Cutset Description 47 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.5g SEIS-SXPP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Essential Service Water Pump 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 48 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.5g SEIS-VGAH-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE ESW Pump Room Supply Fan 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 49 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.5g SEIS-VKHV10-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE CS Pump Room Cubicle Cooler 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 50 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.5g SEIS-VKHV11/12-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE SI Room Cubicle Cooler 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (135/150)

Table 19.1-44D (13 of 24)

No.

BE. Prob.

Cutsets Sequence Level HCLPF Basic Event Cutset Description 51 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.5g SEIS-VKHV13/14-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE CCWP Room Cubicle Cooler 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 52 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.5g SEIS-VKHV16-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE SC Pump & Mini-flow Hx. Room Cubicle Cooler 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 53 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.5g SEIS-VKHV18-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Charging Pump Room Cubicle Cooler 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 54 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.5g SEIS-VOHV32-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Essential Chiller & Pump Cubicle Cooler 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (136/150)

Table 19.1-44D (14 of 24)

No.

BE. Prob.

Cutsets Sequence Level HCLPF Basic Event Cutset Description 55 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.5g SEIS-VOHV33-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFWP Room Cubicle Cooler-MD 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 56 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.5g SEIS-WOCH-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Essential Chillers 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 57 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.5g SEIS-WOLP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Essential Chilled Water System Control Panel 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 58 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.5g SEIS-WOPP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Essential Chilled Water Pumps 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 59 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.5g SEIS-WOTK02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE ECW Air Separator 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (137/150)

Table 19.1-44D (15 of 24)

No.

BE. Prob.

Cutsets Sequence Level HCLPF Basic Event Cutset Description 60 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.5g SEIS-WOTK-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE ECW Compression Tank 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 61 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-ESWIS-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE ESWIS 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 62 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-ESWIS-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE ESWIS 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 63 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 0.5g SEIS-SIPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Shutdown Cooling Pumps 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (138/150)

Table 19.1-44D (16 of 24)

No.

BE. Prob.

Cutsets Sequence Level HCLPF Basic Event Cutset Description 64 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 0.5g SEIS-SIT-FAIL-0.5G SEISMIC FAILURE OF SITS 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA 65 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 0.5g SEIS-SXPP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Essential Service Water Pump 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 66 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 0.5g SEIS-VGAH-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE ESW Pump Room Supply Fan 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 67 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 0.5g SEIS-VKHV10-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE CS Pump Room Cubicle Cooler 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (139/150)

Table 19.1-44D (17 of 24)

No.

BE. Prob.

Cutsets Sequence Level HCLPF Basic Event Cutset Description 68 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 0.5g SEIS-VKHV11/12-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE SI Room Cubicle Cooler 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 69 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 0.5g SEIS-VKHV13/14-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE CCWP Room Cubicle Cooler 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 70 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 0.5g SEIS-VKHV16-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE SC Pump & Mini-flow Hx. Room Cubicle Cooler 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 71 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 0.5g SEIS-VKHV18-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Charging Pump Room Cubicle Cooler 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (140/150)

Table 19.1-44D (18 of 24)

No.

BE. Prob.

Cutsets Sequence Level HCLPF Basic Event Cutset Description 72 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 0.5g SEIS-VOHV32-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Essential Chiller & Pump Cubicle Cooler 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 73 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 0.5g SEIS-VOHV33-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFWP Room Cubicle Cooler-MD 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 74 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 0.5g SEIS-WOCH-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Essential Chillers 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 75 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 0.5g SEIS-WOLP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Essential Chilled Water System Control Panel 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (141/150)

Table 19.1-44D (19 of 24)

No.

BE. Prob.

Cutsets Sequence Level HCLPF Basic Event Cutset Description 76 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 0.5g SEIS-WOPP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Essential Chilled Water Pumps 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 77 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 0.5g SEIS-WOTK02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE ECW Air Separator 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 78 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 0.5g SEIS-WOTK-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE ECW Compression Tank 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 79 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-SXPP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Essential Service Water Pump 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 80 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-VGAH-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE ESW Pump Room Supply Fan 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (142/150)

Table 19.1-44D (20 of 24)

No.

BE. Prob.

Cutsets Sequence Level HCLPF Basic Event Cutset Description 81 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-VKHV10-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE CS Pump Room Cubicle Cooler 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 82 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-VKHV11/12-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE SI Room Cubicle Cooler 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 83 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-VKHV13/14-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE CCWP Room Cubicle Cooler 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 84 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-VKHV16-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE SC Pump & Mini-flow Hx. Room Cubicle Cooler 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 85 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-VKHV18-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Charging Pump Room Cubicle Cooler 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 86 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-VOHV32-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Essential Chiller & Pump Cubicle Cooler 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (143/150)

Table 19.1-44D (21 of 24)

No.

BE. Prob.

Cutsets Sequence Level HCLPF Basic Event Cutset Description 87 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-VOHV33-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFWP Room Cubicle Cooler-MD 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 88 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-WOCH-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Essential Chillers 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 89 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-WOLP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Essential Chilled Water System Control Panel 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 90 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-WOPP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Essential Chilled Water Pumps 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 91 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-WOTK02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE ECW Air Separator 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW 92 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-WOTK-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE ECW Compression Tank 1.00E+00 SIE-FLAG-TLOCCW FLAG FOR Seismic-Induced TLOCCW APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (144/150)

Table 19.1-44D (22 of 24)

No.

BE. Prob.

Cutsets Sequence Level HCLPF Basic Event Cutset Description 93 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 1.00E-01 AFOPH-S-ALT-LT Operator Fails to Transfer AFW Source From AFWST to RWT 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 0.5g SEIS-SI-INV-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE SI INVERTER 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA 94 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 1.00E-01 AFOPH-S-ALT-LT Operator Fails to Transfer AFW Source From AFWST to RWT 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 0.5g SEIS-SIPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Shutdown Cooling Pumps 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA 95 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 1.00E-01 MSOPH-S-ASC-SLOCA Operator Fails to Perform Aggressive Secondary Cooling After SLOCA 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 0.5g SEIS-SIPP02-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Safety Injection Pump 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (145/150)

Table 19.1-44D (23 of 24)

No.

BE. Prob.

Cutsets Sequence Level HCLPF Basic Event Cutset Description 96 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 1.00E-01 RCOPH-S-SDSE-FW Operator Fails to Open POSRVs in Early Phase for F&B Operation 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 97 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 1.00E-01 RCOPH-S-SDSE-FW Operator Fails to Open POSRVs in Early Phase for F&B Operation 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA 98 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 1.00E-01 RCOPH-S-SDSE-FW Operator Fails to Open POSRVs in Early Phase for F&B Operation 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (146/150)

Table 19.1-44D (24 of 24)

No.

BE. Prob.

Cutsets Sequence Level HCLPF Basic Event Cutset Description 99 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 1.00E-01 RCOPH-S-SDSE-FW Operator Fails to Open POSRVs in Early Phase for F&B Operation 0.5g SEIS-AFTP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Turbine Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.3g SEIS-RCS-LEAK-0.3G SEISMICALLY-INDUCED SMALL LOCA 1.00E+00 SIE-FLAG-SLOCA FLAG FOR SEISMICALLY-INDUCED SMALL LOCA 100 1.00E+00

%SEISMIC DUMMY SEISMIC EVENT 0.5g 0.5g SEIS-AFMP-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE AFW Pump-Motor Driven 0.5g SEIS-CSPP01-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Containment Spray Pump 0.09g SEIS-LOOP-0.09G SEISMICALLY-INDUCED LOOP 1.00E+00 SIE-FLAG-LOOP FLAG FOR SEISMICALLY-INDUCED LOOP 1.00E-01 SIOPH-S-IRWSTCOOL Operator Fails to Cool IRWST Water Using SCS Pump APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (147/150)

Figure 19.1-48A At-Power Seismic Event Tree APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (148/150)

Figure 19.1-48B At-Power Seismically Induced Small LOCA Event Tree APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (149/150)

Figure 19.1-48C At-Power Seismically Induced LOOP Event Tree APR1400 DCD TIER 2 RAI 434-8352 - Question 19-85 Rev.2 (150/150)

A2-1

1.

At-Power Seismic Event Tree for Core Damage Seismic event trees for core damage were developed to represent the accident progression and significant equipment failures that can be expected following a seismic event at-power operation.

A series of three event trees was developed to model all significant accident sequences.

Modeling of all accident sequences begins with the S-LOOP event tree where the initiating event represents any seismic event that causes a loss of offsite power (LOOP). The other one event tree is entered by a transfer from sequences on the first event tree. Multiple event trees are used to reduce the number of sequences shown on any one tree resulting in easier viewing of the pictorial representation. The three event trees are shown in Figures 1 through 3. The accident sequences and top events represented are described below.

1.1 Primary Seismic Event Tree for Core Damage Modeling of all seismic-initiated accident sequences begins with the S-LOOP event tree, shown in Figure 1. Seismic accident sequences that result in a LOOP are considered in this analysis.

Top events shown on the event tree are arranged, from left to right, by decreasing severity.

Each top event is described in Table 1. The initiating event S-LOCA and S-LOOP is transferred to secondary Event tree to represent the accident sequence. The other 8 initiating event is treated as direct core damage. Thus, the secondary Event trees for 8 initiating event is not considered.

Table 1 Primary Seismic Event Tree for Core Damage Top Event Top Event Top Event Description Consequence of Sequence SEISMIC EVENT Seismic Event S-DMG Seismic Events Leading to Direct Core Damage with Containment Structural Damage Direct to Core Damage S-SBO Seismic-Induced SBO Direct to Core Damage S-IC Loss of All Instrumentation and Control Direct to Core Damage S-MLSB Seismic-Induced MSLB Direct to Core Damage S-TLOCCW Seismic Induced TLOCCW Direct to Core Damage S-ATWS Seismic-Induced ATWS Direct to Core Damage S-LLOCA Seismic-Induced LLOCA Direct to Core Damage S-MLOCA Seismic-Induced MLOCA Direct to Core Damage S-SLOCA Small LOCA or RCP Seal LOCA Transferred to ET S-SLOCA S-LOOP Seismic Event Causes LOOP Transferred to ET S-LOOP RAI 434-8352 - Question 19-85 Rev.2 (1/9)

A2-2 1.2 S-SLOCA Event Tree Each top event on the S-SLOCA event tree is described in Table 2.

Table 2 S-SLOCA Event Tree Top Event Top Event Top Event Description Success Criteria S-SIS SAFETY INJECTION 1 of 4 SI pumps provides DVI injection S-SHR DEL. AFW AND REM. STEAM 1 of 4 AF pumps to 1 of 2 SGs, and 1 MSADV or 1 MSSV on associated SG S-ASC AGGRESSIVE SECONDARY COOLING 1 of 4 AF pumps provides AFW to 1 of 2 SGs, 1 of 4 SITs injects borated water into RCS, and RCS is rapidly depressurized using 1 of 2 MSADVs on associated SG on associated SG S-SCSI SCS Injection 1 of 2 SCS pumps provides injection from IRWST S-BLEED SAFETY DEPRESSURIZATION 2 of 4 POSRVs need to open S-LHR CONTAINMENT HEAT REMOVAL 1

of 2

CS pumps provides containment cooling or 1 of 2 SC pumps provides IRWST cooling 1.3 S-LOOP Event Tree Each top event on the S-LOOP event tree is described in Table 3.

Table 3 S-LOOP Event Tree Top Event Top Event Top Event Description Success Criteria S-RPC POSRV STUCK OPEN RECLOSE AFTER RCS PRESS. CHALLENGE Primary pressure transient limited by steam relief using one MSSV to below POSRV lift setting or all opened POSRV must reclose.

S-SHR DEL. AFW AND REM. STEAM 1 of 4 AF pumps to 1 of 2 SGs, and 1 MSADV or 1 MSSV on associated SG S-BLEED SAFETY DEPRESSURIZATION 2 of 4 POSRVs need to open S-FEED SAFETY INJECTION FOR FEED 1 of 4 SI pumps provides DVI injection S-LHR CONTAINMENT HEAT REMOVAL 1

of 2

CS pumps provides containment cooling or 1 of 2 SC pumps provides IRWST cooling RAI 434-8352 - Question 19-85 Rev.2 (2/9)

A2-3 Figure 1 Primary At-Power Seismic Event Tree RAI 434-8352 - Question 19-85 Rev.2 (3/9)

A2-4 Figure 2 S-SLOCA Event Tree RAI 434-8352 - Question 19-85 Rev.2 (4/9)

A2-5 Figure 3 S-LOOP Event Tree RAI 434-8352 - Question 19-85 Rev.2 (5/9)

A2-6

2.

Seismic Event Tree for Containment failure Seismic event trees for containment failure were developed to represent the accident progression and significant equipment failures that can be expected following a seismic event at-power operation. Seismic event trees for containment failure were developed by extending the Seismic event tree for core damage to incorporate containment isolation failure and late overpressure failures as the most probable containment failure modes. The seismic accident sequences for Containment failure are described in Table 4. The seven of total ten seismic initiating events lead to the direct containment failure, and three seismic initiating events are considered the mitigation feature and operator actions. The three event trees which does not cause the non-direct containment failures are shown in Figures 4 through 6.

Table 4 Seismic Initiating Event for Containment failure Seismic Initiating Event Seismic Initiating Event Description Consequence of Sequence S-DMG Seismic Events Leading to Direct Core Damage with Containment Structural Damage Direct to Containment failure S-SBO Seismic-Induced SBO Direct to Containment Isolation failure S-IC Loss of All Instrumentation and Control Direct to Containment Isolation failure S-MLSB Seismic-Induced MSLB Direct to Containment Isolation failure S-TLOCCW Seismic Induced TLOCCW Containment Isolation and late overpressure failure S-ATWS Seismic-Induced ATWS Direct to Containment failure S-LLOCA Seismic-Induced LLOCA Direct to Containment failure S-MLOCA Seismic-Induced MLOCA Direct to Containment failure S-SLOCA Small LOCA Containment Isolation and late overpressure failure S-LOOP Seismic-Induced LOOP Containment Isolation and late overpressure failure The top event on the containment failure event tree is described in Table 5.

Table 5 Containment Failure Event Tree Top Event Top Event Top Event Description Success Criteria S-CIS CONTAINMENT ISOLATION SYSTEM Success of the containment isolation S-CSR1 CONTIANMENT HEAT REMOVAL 1 of 2 CS pumps provides long-term heat removal in recirculation mode RAI 434-8352 - Question 19-85 Rev.2 (6/9)

A2-7 Figure 4 S-TLOCCW Containment Failure Event Tree RAI 434-8352 - Question 19-85 Rev.2 (7/9)

A2-8 Figure 5 S-SLOCA Containment Failure Event Tree RAI 434-8352 - Question 19-85 Rev.2 (8/9)

A2-9 Figure 6 S-LOOP Containment Failure Event Tree RAI 434-8352 - Question 19-85 Rev.2 (9/9)

A3-1 Table. At-Power PRA-based SMA FMEA Results SSCs Location Failure mode HCLPF (g)

FMEA for Core Damage FMEA for Containment Failure Remark IE ID in Seismic ET IE FLAG in Seismic ET Basic Event ID Reactor Containment building Reactor Containment building Tan. shear fail near the base 0.94 DIRECT CORE DAMAGE due to RCS Catastrophic Failure i.e. Excessive LOCA LOSS of CONTAINMEN T INTEGRITY is assumed due to Containment Structure Failure Containment Bldg Structural Failure and Subsequent RCS Structural Failure S-DMG SIE-FLAG-DMG-CF SEIS-CTS-EX-FAIL-0.94G Reactor Containment Internal Reactor Containment building Tan. shear fail near the base 1.09 DIRECT CORE DAMAGE due to RCS Catastrophic Failure i.e. Excessive LOCA LOSS of CONTAINMEN T INTEGRITY is assumed due to Containment Structure Failure Containment Bldg Structural Failure and Subsequent RCS Structural Failure S-DMG SIE-FLAG-DMG-CF SEIS-CTS-IN-FAIL-1.09G Nuclear Island CMNT Basement Sliding toward the turbine building 0.52 DIRECT CORE DAMAGE due to RCS Catastrophic Failure i.e. Excessive LOCA LOSS of CONTAINMEN T INTEGRITY is assumed due to Containment Structure Failure Containment Bldg Structural Failure and Subsequent RCS Structural Failure S-DMG SIE-FLAG-DMG-CF SEIS-NI-FAIL-0.52G Auxiliary Building Auxiliary Building Shear fail of shear wall at the basemat 0.51 DIRECT CORE DAMAGE due to RCS Catastrophic Failure i.e. Excessive LOCA LOSS of CONTAINMEN T INTEGRITY is assumed due to Containment Structure Failure Aux bldg. is assumed to collapse to containment bldg.

Containment Bldg Structural Failure and Subsequent RCS Structural Failure S-DMG SIE-FLAG-DMG-CF SEIS-AB-FAIL-0.51G Emergency Diesel Generator Building Emergency Diesel Generator Building Shear fail of shear wall at the basemat 0.87 Mitigation Modeling is Required (Failure of EDG A&B Only)

Mitigation Modeling is Required (Failure of EDG A&B Only)

EDG C&D are installed in the Aux Bldg It is not modeled due to high seismic capacity greater than EDG. Thus, seismic N/A SEIS-DG-BLDG-FAIL-0.87G RAI 434-8352 - Question 19-85 Rev.2 (1/18)

A3-2 Table. At-Power PRA-based SMA FMEA Results SSCs Location Failure mode HCLPF (g)

FMEA for Core Damage FMEA for Containment Failure Remark IE ID in Seismic ET IE FLAG in Seismic ET Basic Event ID failure of EDG building is included in the EDG failure.

Diesel Fuel Oil Tank Building Diesel Fuel Oil Tank Building Shear fail of shear wall at the basemat 0.73 Mitigation Modeling is Required (Failure of EDG A&B Only)

Mitigation Modeling is Required (Failure of EDG A&B Only)

EDG C&D are installed in the Aux Bldg It is not modeled due to the relatively low failure impact (loss of 2 EDGs out of 4 EDGs) and higher HCLPF than EDG components which causes EDG unavailable.

N/A SEIS-DG-FOTK-STRUCT-073G Turbine Building Turbine Building Collapse into Aux Bldg

[4]

DIRECT CORE DAMAGE due to RCS Catastrophic Failure i.e. Excessive LOCA LOSS of CONTAINMEN T INTEGRITY is assumed due to Containment Structure Failure Turbine bldg. is assumed to collapse to containment bldg.

Impact to Rx Bldg and Subsequent RCS Catastrophic Failure S-DMG SIE-FLAG-DMG-CF SEIS-TB-FAIL-0.5G Compound Building Compound Building Collapse into Aux Bldg

[4]

DIRECT CORE DAMAGE due to RCS Catastrophic Failure i.e. Excessive LOCA LOSS of CONTAINMEN T INTEGRITY is assumed due to Containment Structure Failure Compound Bldg is assumed to collapse to containment bldg.

Impact to Rx Bldg and Subsequent RCS Catastrophic Failure S-DMG SIE-FLAG-DMG-CF SEISMIC-CPD-FAIL-0.5G Reactor Pressure Vessel CTMT El.

69'~156' Column support 0.92 DIRECT CORE DAMAGE due to RCS Catastrophic Failure i.e. Excessive LOCA LOSS of CONTAINMEN T INTEGRITY is assumed due to Containment Structure Failure RCS Catastrophic Failure is assumed to lead to Containment Structural Failure S-DMG SIE-FLAG-DMG-CF SEIS-RV-RCS-FAIL-0.92G RAI 434-8352 - Question 19-85 Rev.2 (2/18)

A3-3 Table. At-Power PRA-based SMA FMEA Results SSCs Location Failure mode HCLPF (g)

FMEA for Core Damage FMEA for Containment Failure Remark IE ID in Seismic ET IE FLAG in Seismic ET Basic Event ID Reactor Vessel Internal CTMT El.

69'~156' Core Sup.

Barrel lower flange 0.51 DIRECT CORE DAMAGE due to Loss of Flow through Core The Direct Containment failure is assumed conservatively considering the relatively high HCLPF RCS flow through the core is assumed to be blocked due to the Rx Internal Failure S-DMG SIE-FLAG-DMG-CF SEIS-RVI-RCS-FAIL-0.51G CEDM (Control Element Drive Mechanism)

CTMT Binding of cntrl.

extension shaft 0.64 DIRECT CORE DAMAGE is assumed conservatively considering the relatively high HCLPF ATWS DIRECT Containment Failure is assumed conservatively considering the relatively high HCLPF ATWS RCS Pressure spike is assumed not suppressed for the ATWS S-ATWS SIE-FLAG-ATWS SEIS-CEDM-RCS-FAIL-0.64G Steam Generator CTMT El.

114'~136'06 Anch. fail of snubber lever support asm.

0.6 DIRECT CORE DAMAGE due to RCS Catastrophic Failure i.e. Excessive LOCA LOSS of CONTAINMEN T INTEGRITY is assumed due to Containment Structure Failure RCS Catastrophic Failure is assumed to lead to Containment Structural Failure S-DMG SIE-FLAG-DMG-CF SEIS-SG-RCS-FAIL-0.6G Steam Generator Nozzle CTMT El.

114'~136'06 Enconomiz er nozzle 0.54 DIRECT CORE DAMAGE due to the very short available operator action time The Direct Containment failure is assumed conservatively considering the relatively high HCLPF SG Economizer nozzle failure leads to FWLB. It rapidly drains S/G secondary side thus operator action time for feed and bleed is very short.

Therefore DIRECT CORE DAMAGE is assumed.

S-DMG SIE-FLAG-DMG-CF SEIS-SGNOZZ-RCS-FAIL-0.54G RAI 434-8352 - Question 19-85 Rev.2 (3/18)

A3-4 Table. At-Power PRA-based SMA FMEA Results SSCs Location Failure mode HCLPF (g)

FMEA for Core Damage FMEA for Containment Failure Remark IE ID in Seismic ET IE FLAG in Seismic ET Basic Event ID Pressurizer CTMT El.

114'~156' Skirt support 0.63 DIRECT CORE DAMAGE due to RCS Catastrophic Failure i.e. Excessive LOCA LOSS of CONTAINMEN T INTEGRITY is assumed due to Containment Structure Failure RCS Catastrophic Failure is assumed to lead to Containment Structural Failure S-DMG SIE-FLAG-DMG-CF SEIS-PZR-RCS-FAIL-0.63G Pressurizer nozzle CTMT El.

114'~156' Spray nozzle 0.51 MLOCA MLOCA 4 inch diameter for PZR spray nozzle S-MLOCA SIE-FLAG-MLOCA SEIS-PZRNOZZ-RCS-FAIL-0.51G Reactor Coolant System Piping CTMT Surge line nozzle 0.55 LLOCA LLOCA 12 inch diameter for PZR Surge Line Nozzle S-LLOCA SIE-FLAG-LLOCA SEIS-PIPE-RCS-FAIL-0.55G Reactor Coolant Pumps CTMT El.

114'~136'06 Upper horiz.colu mn support 1.31 DIRECT CORE DAMAGE due to RCS Catastrophic Failure i.e. Excessive LOCA LOSS of CONTAINMEN T INTEGRITY is assumed due to Containment Structure Failure RCS Catastrophic Failure Causes Containment Structural Failure.

S-DMG SIE-FLAG-DMG-CF SEIS-RCP-RCS-FAIL-1.31G ESWIS ESW Building Generic

[4]

DIRECT CORE DAMAGE TLOCCW Mitigation Modeling is Required It is highly unlikely of long term operation of SI Pumps under seismic event thus DIRECT CORE DAMAGE is assumed S-TLOCCW SIE-FLAG-TLOCCW SEIS-ESWIS-FAIL-0.5G CCW Hx Building CCW Hx Building Generic

[4]

DIRECT CORE DAMAGE TLOCCW Mitigation Modeling is Required It is highly unlikely of long term operation of SI Pumps under seismic event thus DIRECT CORE DAMAGE is assumed S-TLOCCW SIE-FLAG-TLOCCW SEIS-CCW-BLDG-FAIL-0.5G RAI 434-8352 - Question 19-85 Rev.2 (4/18)

A3-5 Table. At-Power PRA-based SMA FMEA Results SSCs Location Failure mode HCLPF (g)

FMEA for Core Damage FMEA for Containment Failure Remark IE ID in Seismic ET IE FLAG in Seismic ET Basic Event ID Charging Pumps AB El. 55' Generic

[1]

Mitigation Modeling is Required Mitigation Modeling is Required Loss of CVCS N/A SEIS-CVPP01-FAIL-0.5G Regenerative Heat Exchanger CTMT El. 114' Generic

[1]

Mitigation Modeling is Required Mitigation Modeling is Required Loss of CVCS N/A SEIS-CVHX01-FAIL-0.5G Letdown Heat Exchanger CTMT El. 100' Generic

[1]

Mitigation Modeling is Required Mitigation Modeling is Required Loss of CVCS N/A N/A Auxiliary Charging Pump AB El. 55' Generic

[1]

Mitigation Modeling is Required Mitigation Modeling is Required Loss of Aux Charging PP N/A SEIS-CVPP03-FAIL-0.5G Safety Injection Tanks CTMT. El. 136' 06" Generic

[1]

Mitigation Modeling is Required Mitigation Modeling is Required RCS Catastrophic Failure Causes Containment Structural Failure N/A SEIS-SIT-FAIL-0.5G Shutdown Cooling Pumps AB El. 50' Generic

[1]

Mitigation Modeling is Required Mitigation Modeling is Required N/A SEIS-SIPP01-FAIL-0.5G Shutdown Cooling Heat Exchanger AB El. 50' Generic

[1]

Mitigation Modeling is Required Mitigation Modeling is Required N/A SEIS-SIHX01-FAIL-0.5G SC Pump Miniflow Heat Exchanger AB El. 50' Generic

[1]

Mitigation Modeling is Required Mitigation Modeling is Required N/A SEIS-SIHX02-FAIL-0.5G Safety Injection Pump AB El. 50' Generic

[1]

Mitigation Modeling is Required Mitigation Modeling is Required N/A SEIS-SIPP02-FAIL-0.5G Containment Spray Pump AB El. 50' Generic

[1]

Mitigation Modeling is Required Mitigation Modeling is Required N/A SEIS-CSPP01-FAIL-0.5G CS Miniflow Hx AB El. 50' Generic

[1]

Mitigation Modeling is Required Mitigation Modeling is Required N/A SEIS-CSHX02-FAIL-0.5G Containment Spray Heat Exchanger AB El. 55' Generic

[1]

Mitigation Modeling is Required Mitigation Modeling is Required N/A SEIS-CSHX01-FAIL-0.5G RAI 434-8352 - Question 19-85 Rev.2 (5/18)

A3-6 Table. At-Power PRA-based SMA FMEA Results SSCs Location Failure mode HCLPF (g)

FMEA for Core Damage FMEA for Containment Failure Remark IE ID in Seismic ET IE FLAG in Seismic ET Basic Event ID Main Steam Isolation Valves AB El. 137'06" Generic

[1]

DIRECT CORE DAMAGE MSLB Containment Isolation Failure is assumed due to the steamline break outside containment No assurance for subcriticality after MSLB. This leads to DIRECT CORE DAMAGE.

Broken Steam Line is Considered as Isolation Failure S-MSLB SIE-FLAG-MSLB SEIS-MSIV-FAIL-0.5G Main Steam Atmospheric Valves(ADV)

AB El. 137'06" Generic

[1]

DIRECT CORE DAMAGE MSLB Containment Isolation Failure is assumed due to the steamline break outside containment No assurance for subcriticality after MSLB. This leads to DIRECT CORE DAMAGE.

Isolation of ADV block MOV is assumed failed in a very short time after I.E.

Broken Steam Line is Considered as Isolation Failure S-MSLB SIE-FLAG-MSLB SEIS-MSADV-FAIL-0.5G Main Steam Safety Valves AB El. 137'06" Generic

[1]

DIRECT CORE DAMAGE MSLB Containment Isolation Failure is assumed due to the steamline break outside containment No assurance for subcriticality after MSLB. This leads to DIRECT CORE DAMAGE.

Broken Steam Line is Considered as Isolation Failure S-MSLB SIE-FLAG-MSLB SEIS-MSSV-FAIL-0.5G AFW Pump-Motor Driven AB El. 78' Generic

[1]

Mitigation Modeling is Required Mitigation Modeling is Required N/A SEIS-AFMP-FAIL-0.5G AFW Pump-Turbine Driven AB El. 78' Generic

[1]

Mitigation Modeling is Required Mitigation Modeling is Required N/A SEIS-AFTP-FAIL-0.5G RAI 434-8352 - Question 19-85 Rev.2 (6/18)

A3-7 Table. At-Power PRA-based SMA FMEA Results SSCs Location Failure mode HCLPF (g)

FMEA for Core Damage FMEA for Containment Failure Remark IE ID in Seismic ET IE FLAG in Seismic ET Basic Event ID Emergency Diesel Generators EDG El. 100' Generic

[1]

DIRECT CORE DAMAGE Station Blackout Containment Isolation Failure is assumed due to the isolation system failure caused by loss of all control S-SBO SIE-FLAG-SBO SEIS-DG-FAIL-0.5G Emergency Diesel Generators (Aux. Building)

AB El. 100' Generic

[1]

DIRECT CORE DAMAGE Station Blackout Containment Isolation Failure is assumed due to the isolation system failure caused by loss of all control S-SBO SIE-FLAG-SBO SEIS-DG-CD-FAIL-0.5G Emergency Diesel Fuel Oil transfer pump EDG El. 65' Generic

[1]

DIRECT CORE DAMAGE Station Blackout Containment Isolation Failure is assumed due to the isolation system failure caused by loss of all control S-SBO SIE-FLAG-SBO SEIS-DOMPS-FAIL-0.5G Emergency Diesel Fuel Oil transfer pump (Aux. Building)

AB El. 63' Generic

[1]

DIRECT CORE DAMAGE Station Blackout Containment Isolation Failure is assumed due to the isolation system failure caused by loss of all control S-SBO SIE-FLAG-SBO SEIS-DOMPS-CD-FAIL-0.5G Starting Air Tank AB El. 100' Generic

[1]

DIRECT CORE DAMAGE Station Blackout Containment Isolation Failure is assumed due to the isolation system failure caused by loss of all control S-SBO SIE-FLAG-SBO SEIS-DGTK40-FAIL-0.5G RAI 434-8352 - Question 19-85 Rev.2 (7/18)

A3-8 Table. At-Power PRA-based SMA FMEA Results SSCs Location Failure mode HCLPF (g)

FMEA for Core Damage FMEA for Containment Failure Remark IE ID in Seismic ET IE FLAG in Seismic ET Basic Event ID Diesel Fuel Oil Day Tank EDG El. 121' Generic

[1]

DIRECT CORE DAMAGE Station Blackout Containment Isolation Failure is assumed due to the isolation system failure caused by loss of all control S-SBO SIE-FLAG-SBO SEIS-DOTK02-FAIL-0.5G Diesel Fuel Oil Day Tank (Aux. Building)

AB El. 120' Generic

[1]

DIRECT CORE DAMAGE Station Blackout Containment Isolation Failure is assumed due to the isolation system failure caused by loss of all control S-SBO SIE-FLAG-SBO SEIS-DOTK02-CD-FAIL-0.5G Diesel Fuel Oil Storage Tank EDG El. 63' Generic

[1]

DIRECT CORE DAMAGE Station Blackout Containment Isolation Failure is assumed due to the isolation system failure caused by loss of all control S-SBO SIE-FLAG-SBO SEIS-DOTK01-FAIL-0.5G Diesel Fuel Oil Storage Tank (Aux.Building)

Aux. El. 65' Generic

[1]

DIRECT CORE DAMAGE Station Blackout Containment Isolation Failure is assumed due to the isolation system failure caused by loss of all control S-SBO SIE-FLAG-SBO SEIS-DOTK01-CD-FAIL-0.5G Silencer AB El. 100' Generic

[1]

DIRECT CORE DAMAGE Station Blackout Containment Isolation Failure is assumed due to the isolation system failure caused by loss of all control S-SBO SIE-FLAG-SBO SEIS-DGSL-FAIL-0.5G Air Intake Filter AB El. 109' Generic

[1]

DIRECT CORE DAMAGE Station Containment Isolation Failure is assumed due to the isolation S-SBO SIE-FLAG-SBO SEIS-DGFT-FAIL-0.5G RAI 434-8352 - Question 19-85 Rev.2 (8/18)

A3-9 Table. At-Power PRA-based SMA FMEA Results SSCs Location Failure mode HCLPF (g)

FMEA for Core Damage FMEA for Containment Failure Remark IE ID in Seismic ET IE FLAG in Seismic ET Basic Event ID Blackout system failure caused by loss of all control Lube Oil Water Hx AB El. 100' Generic

[1]

DIRECT CORE DAMAGE Station Blackout Containment Isolation Failure is assumed due to the isolation system failure caused by loss of all control S-SBO SIE-FLAG-SBO SEIS-DGHX-FAIL-0.5G Motor Driven Fuel Oil Feed Pump (EDG Building)

EDG El. 100' Generic

[1]

DIRECT CORE DAMAGE Station Blackout Containment Isolation Failure is assumed due to the isolation system failure caused by loss of all control S-SBO SIE-FLAG-SBO SEIS-DGPP-FAIL-0.5G Motor Driven Fuel Oil Feed Pump (Aux.

Building)

AB El. 100' Generic

[1]

DIRECT CORE DAMAGE Station Blackout Containment Isolation Failure is assumed due to the isolation system failure caused by loss of all control S-SBO SIE-FLAG-SBO SEIS-DGPP-CD-FAIL-0.5G Essential Service Water Pump ESW IS. El.

69' Generic

[1]

DIRECT CORE DAMAGE TLOCCW Mitigation Modeling is Required It is highly unlikely of long term operation of SI Pumps under seismic event thus DIRECT CORE DAMAGE is assumed S-TLOCCW SIE-FLAG-TLOCCW SEIS-SXPP-FAIL-0.5G CCW Heat Exchangers CCW Hx Bldg El. 100' Generic

[1]

DIRECT CORE DAMAGE TLOCCW Mitigation Modeling is Required It is highly unlikely of long term operation of SI Pumps under seismic event thus DIRECT CORE S-TLOCCW SIE-FLAG-TLOCCW SEIS-CCHX-FAIL-0.5G RAI 434-8352 - Question 19-85 Rev.2 (9/18)

A3-10 Table. At-Power PRA-based SMA FMEA Results SSCs Location Failure mode HCLPF (g)

FMEA for Core Damage FMEA for Containment Failure Remark IE ID in Seismic ET IE FLAG in Seismic ET Basic Event ID DAMAGE is assumed CCW Pump AB El. 55' Generic

[1]

DIRECT CORE DAMAGE TLOCCW Mitigation Modeling is Required It is highly unlikely of long term operation of SI Pumps under seismic event thus DIRECT CORE DAMAGE is assumed S-TLOCCW SIE-FLAG-TLOCCW SEIS-CCPP-FAIL-0.5G CCW Surge Tank AB El. 172' Generic

[1]

DIRECT CORE DAMAGE TLOCCW Mitigation Modeling is Required It is highly unlikely of long term operation of SI Pumps under seismic event thus DIRECT CORE DAMAGE is assumed S-TLOCCW SIE-FLAG-TLOCCW SEIS-CCTK-FAIL-0.5G Essential Chilled Water Pumps AB. El. 78' Generic

[1]

DIRECT CORE DAMAGE TLOCCW Mitigation Modeling is Required It is highly unlikely of long term operation of SI Pumps under seismic event thus DIRECT CORE DAMAGE is assumed S-TLOCCW SIE-FLAG-TLOCCW SEIS-WOPP-FAIL-0.5G Essential Chillers AB El. 78' Generic

[1]

DIRECT CORE DAMAGE TLOCCW Mitigation Modeling is Required It is highly unlikely of long term operation of SI Pumps under seismic event thus DIRECT CORE DAMAGE is assumed S-TLOCCW SIE-FLAG-TLOCCW SEIS-WOCH-FAIL-0.5G ECW Compression Tank AB El. 172' Generic

[1]

DIRECT CORE DAMAGE Mitigation Modeling is Required It is highly unlikely of long term operation of SI S-TLOCCW SIE-FLAG-TLOCCW SEIS-WOTK-FAIL-0.5G RAI 434-8352 - Question 19-85 Rev.2 (10/18)

A3-11 Table. At-Power PRA-based SMA FMEA Results SSCs Location Failure mode HCLPF (g)

FMEA for Core Damage FMEA for Containment Failure Remark IE ID in Seismic ET IE FLAG in Seismic ET Basic Event ID TLOCCW Pumps under seismic event thus DIRECT CORE DAMAGE is assumed ECW Air Separator AB El. 78' Generic

[1]

DIRECT CORE DAMAGE TLOCCW Mitigation Modeling is Required It is highly unlikely of long term operation of SI Pumps under seismic event thus DIRECT CORE DAMAGE is assumed S-TLOCCW SIE-FLAG-TLOCCW SEIS-WOTK02-FAIL-0.5G Essential Chilled Water System Control Panel AB El. 78' Generic

[1]

DIRECT CORE DAMAGE TLOCCW Mitigation Modeling is Required It is highly unlikely of long term operation of SI Pumps under seismic event thus DIRECT CORE DAMAGE is assumed S-TLOCCW SIE-FLAG-TLOCCW SEIS-WOLP-FAIL-0.5G AFWP Room Cubicle Cooler-MD AB El. 78' Generic

[1]

DIRECT CORE DAMAGE TLOCCW Mitigation Modeling is Required It is highly unlikely of long term operation of SI Pumps under seismic event thus DIRECT CORE DAMAGE is assumed S-TLOCCW SIE-FLAG-TLOCCW SEIS-VOHV33-FAIL-0.5G CCWP Room Cubicle Cooler AB El. 55' Generic

[1]

DIRECT CORE DAMAGE TLOCCW Mitigation Modeling is Required It is highly unlikely of long term operation of SI Pumps under seismic event thus DIRECT CORE DAMAGE is assumed S-TLOCCW SIE-FLAG-TLOCCW SEIS-VKHV13/14

-FAIL-0.5G RAI 434-8352 - Question 19-85 Rev.2 (11/18)

A3-12 Table. At-Power PRA-based SMA FMEA Results SSCs Location Failure mode HCLPF (g)

FMEA for Core Damage FMEA for Containment Failure Remark IE ID in Seismic ET IE FLAG in Seismic ET Basic Event ID SI Room Cubicle Cooler AB El. 50' AB El. 55' Generic

[1]

DIRECT CORE DAMAGE TLOCCW Mitigation Modeling is Required It is highly unlikely of long term operation of SI Pumps under seismic event thus DIRECT CORE DAMAGE is assumed S-TLOCCW SIE-FLAG-TLOCCW SEIS-VKHV11/12

-FAIL-0.5G SC Pump &

Mini-flow Hx.

Room Cubicle Cooler AB El. 50' AB El. 55' Generic

[1]

DIRECT CORE DAMAGE TLOCCW Mitigation Modeling is Required It is highly unlikely of long term operation of SI Pumps under seismic event thus DIRECT CORE DAMAGE is assumed S-TLOCCW SIE-FLAG-TLOCCW SEIS-VKHV16-FAIL-0.5G Mech. Pen.

Room Cubicle Cooler AB El. 100' Generic

[1]

DIRECT CORE DAMAGE TLOCCW Mitigation Modeling is Required It is highly unlikely of long term operation of SI Pumps under seismic event thus DIRECT CORE DAMAGE is assumed S-TLOCCW SIE-FLAG-TLOCCW SEIS-CCLR-MPR-0.5G CS Pump Room Cubicle Cooler AB El. 50' AB El. 55' Generic

[1]

DIRECT CORE DAMAGE TLOCCW Mitigation Modeling is Required It is highly unlikely of long term operation of SI Pumps under seismic event thus DIRECT CORE DAMAGE is assumed S-TLOCCW SIE-FLAG-TLOCCW SEIS-VKHV10-FAIL-0.5G Aux Charging Pump Room Cubicle Cooler AB El. 55' Generic

[1]

DIRECT CORE DAMAGE TLOCCW Mitigation Modeling is Required It is highly unlikely of long term operation of SI Pumps under seismic event thus DIRECT CORE DAMAGE is S-TLOCCW SIE-FLAG-TLOCCW SEIS-CCLR-ACVPP-0.5G RAI 434-8352 - Question 19-85 Rev.2 (12/18)

A3-13 Table. At-Power PRA-based SMA FMEA Results SSCs Location Failure mode HCLPF (g)

FMEA for Core Damage FMEA for Containment Failure Remark IE ID in Seismic ET IE FLAG in Seismic ET Basic Event ID assumed Charging Pump Room Cubicle Cooler AB El. 55' Generic

[1]

DIRECT CORE DAMAGE TLOCCW Mitigation Modeling is Required It is highly unlikely of long term operation of SI Pumps under seismic event thus DIRECT CORE DAMAGE is assumed S-TLOCCW SIE-FLAG-TLOCCW SEIS-VKHV18-FAIL-0.5G Elect. Pen.

Room Area Cubicle Cooler AB El. 120' Generic

[1]

DIRECT CORE DAMAGE TLOCCW Mitigation Modeling is Required It is highly unlikely of long term operation of SI Pumps under seismic event thus DIRECT CORE DAMAGE is assumed S-TLOCCW SIE-FLAG-TLOCCW SEIS-CCLR-EPA-0.5G Elect. Pen.

Room Area Cubicle Cooler (El. 137')

AB El. 137' Generic

[1]

DIRECT CORE DAMAGE TLOCCW Mitigation Modeling is Required It is highly unlikely of long term operation of SI Pumps under seismic event thus DIRECT CORE DAMAGE is assumed S-TLOCCW SIE-FLAG-TLOCCW SEIS-CCLR-EPA-137-0.5G I&C Equipment Room Cubical Cooler AB El. 157' Generic

[1]

DIRECT CORE DAMAGE TLOCCW Mitigation Modeling is Required It is highly unlikely of long term operation of SI Pumps under seismic event thus DIRECT CORE DAMAGE is assumed S-TLOCCW SIE-FLAG-TLOCCW SEIS-CCLR-IC-0.5G RAI 434-8352 - Question 19-85 Rev.2 (13/18)

A3-14 Table. At-Power PRA-based SMA FMEA Results SSCs Location Failure mode HCLPF (g)

FMEA for Core Damage FMEA for Containment Failure Remark IE ID in Seismic ET IE FLAG in Seismic ET Basic Event ID EDG Room Emergency Cubicle Cooler EDG El. 100' Generic

[1]

DIRECT CORE DAMAGE TLOCCW Mitigation Modeling is Required It is highly unlikely of long term operation of SI Pumps under seismic event thus DIRECT CORE DAMAGE is assumed S-TLOCCW SIE-FLAG-TLOCCW SEIS-CCLR-EDG-100-0.5G EDG Room Emergency Cubicle Cooler EDG El. 135' Generic

[1]

DIRECT CORE DAMAGE TLOCCW Mitigation Modeling is Required It is highly unlikely of long term operation of SI Pumps under seismic event thus DIRECT CORE DAMAGE is assumed S-TLOCCW SIE-FLAG-TLOCCW SEIS-CCLR-EDG-135-0.5G Essential Chiller & Pump Cubicle Cooler AB El. 78' Generic

[1]

DIRECT CORE DAMAGE TLOCCW Mitigation Modeling is Required It is highly unlikely of long term operation of SI Pumps under seismic event thus DIRECT CORE DAMAGE is assumed S-TLOCCW SIE-FLAG-TLOCCW SEIS-VOHV32-FAIL-0.5G CCW Hx.

Room Supply Fans CCW Hx B El.

100' CCW Hx El. 126' Generic

[1]

No Impact No Impact N/A N/A ESW Pump Room Supply Fan ESW IS. El. 90' Generic

[1]

DIRECT CORE DAMAGE TLOCCW Mitigation Modeling is Required It is highly unlikely of long term operation of SI Pumps under seismic event thus DIRECT CORE DAMAGE is assumed S-TLOCCW SIE-FLAG-TLOCCW SEIS-VGAH-FAIL-0.5G EDG Room Emergency EDG El. 100' Generic

[1]

DIRECT CORE Containment Isolation Failure S-SBO SIE-FLAG-SBO SEIS-VGAH02-RAI 434-8352 - Question 19-85 Rev.2 (14/18)

A3-15 Table. At-Power PRA-based SMA FMEA Results SSCs Location Failure mode HCLPF (g)

FMEA for Core Damage FMEA for Containment Failure Remark IE ID in Seismic ET IE FLAG in Seismic ET Basic Event ID Exhaust Fan (EDG Building)

DAMAGE Station Blackout is assumed due to the isolation system failure caused by loss of all control FAIL-0.5G EDG Room Emergency Exhaust Fan (Aux. Building)

AB El. 172' Generic

[1]

DIRECT CORE DAMAGE Station Blackout Containment Isolation Failure is assumed due to the isolation system failure caused by loss of all control S-SBO SIE-FLAG-SBO SEIS-VGAH02-CD-FAIL-0.5G Control Room Emergency Makeup ACU AB El. 172' Generic

[1]

No Impact No Impact N/A N/A ESF-CCS GC Cabinet AB El. 156' Generic

[1]

DIRECT CORE DAMAGE LOSS of Control Containment Isolation Failure is assumed due to the isolation system failure caused by loss of all control ESF-CCS GC, LC and PPS Cabinet Failure is Seismically Correlated.

Modeled as a single Event S-IC SIE-FLAG-IC SEIS-ESF-RPS-FAIL-0.5G ESF-CCS LC Cabinet AB El. 156' AB El. 137'6" Generic

[1]

DIRECT CORE DAMAGE LOSS of Control Containment Isolation Failure is assumed due to the isolation system failure caused by loss of all control ESF-CCS GC, LC and PPS Cabinet Failure is Seismically Correlated.

Modeled as a single Event S-IC SIE-FLAG-IC SEIS-ESF-RPS-FAIL-0.5G Plant Protection System Cabinet AB El. 156' Generic

[1]

DIRECT CORE DAMAGE LOSS of Control Containment Isolation Failure is assumed due to the isolation system failure caused by loss of all control ESF-CCS GC, LC and PPS Cabinet Failure is Seismically Correlated.

Modeled as a single Event S-IC SIE-FLAG-IC SEIS-ESF-RPS-FAIL-0.5G RAI 434-8352 - Question 19-85 Rev.2 (15/18)

A3-16 Table. At-Power PRA-based SMA FMEA Results SSCs Location Failure mode HCLPF (g)

FMEA for Core Damage FMEA for Containment Failure Remark IE ID in Seismic ET IE FLAG in Seismic ET Basic Event ID Reactor Trip Switchgear AB El. 137'6" Generic

[1]

No Impact No Impact N/A MCR Operator Consoles AB El. 156' Generic

[1]

No Impact No Impact MCR Safety Consoles AB El. 156' Generic

[1]

DIRECT CORE DAMAGE LOSS of Control Containment Isolation Failure is assumed due to the isolation system failure caused by loss of all control S-IC SIE-FLAG-IC SEIS-RP-PM05-FAIL-0.5G 125V DC Battery Chargers AB El. 78' Generic

[1]

DIRECT CORE DAMAGE LOSS of Control Containment Isolation Failure is assumed due to the isolation system failure caused by loss of all control S-IC SIE-FLAG-IC SEIS-DC-BC-FAIL-0.5G SI Inverter AB El. 78' Generic

[1]

Mitigation Modeling is Required Mitigation Modeling is Required SEIS-RC-INV-FAIL-0.5G 120V AC Inverter(VBPS S)

AB El. 78' Generic

[1]

DIRECT CORE DAMAGE LOSS of Control Containment Isolation Failure is assumed due to the isolation system failure caused by loss of all control S-IC SIE-FLAG-IC SEIS-IPINV-FAIL-0.5G Regulating Transformer AB El. 78' Generic

[1]

DIRECT CORE DAMAGE LOSS of Control Containment Isolation Failure is assumed due to the isolation system failure caused by loss of all control S-IC SIE-FLAG-IC SEIS-IPREGTR-FAIL-0.5G 125V DC Control Center AB El. 78' Generic

[1]

DIRECT CORE DAMAGE Containment Isolation Failure is assumed due to S-SBO SIE-FLAG-SBO SEIS-DC-MCC-FAIL-0.5G RAI 434-8352 - Question 19-85 Rev.2 (16/18)

A3-17 Table. At-Power PRA-based SMA FMEA Results SSCs Location Failure mode HCLPF (g)

FMEA for Core Damage FMEA for Containment Failure Remark IE ID in Seismic ET IE FLAG in Seismic ET Basic Event ID Station Blackout the isolation system failure caused by Station Blackout 4.16kV MCSG AB El. 78' Generic

[1]

DIRECT CORE DAMAGE Station Blackout Containment Isolation Failure is assumed due to the isolation system failure caused by Station Blackout S-SBO SIE-FLAG-SBO SEIS-4KV-BUS-FAIL-0.5G 480V Load Center AB El. 78' Generic

[1]

DIRECT CORE DAMAGE LOSS of Control Containment Isolation Failure is assumed due to the isolation system failure caused by loss of all control S-IC SIE-FLAG-IC SEIS-480V-LC-FAIL-0.5G 480V MCC(Aux.

EL.137'06")

AB El. 137'06" Generic

[1]

Mitigation Modeling is Required Mitigation Modeling is Required SEIS-480V-MCC-FAIL-0.5G 480V MCC(Aux.

EL.120')

AB El. 120' Generic

[1]

Mitigation Modeling is Required Mitigation Modeling is Required SEIS-480V-MCC-FAIL-0.5G 480V MCC(Aux.

EL.100')

AB El. 100' Generic

[1]

Mitigation Modeling is Required Mitigation Modeling is Required SEIS-480V-MCC-FAIL-0.5G 480V MCC(Aux.

EL.78')

AB El. 78' Generic

[1]

Mitigation Modeling is Required Mitigation Modeling is Required SEIS-480V-MCC-FAIL-0.5G 480V MCC(ESW IS EL.100')

ESW IS. El. 90' Generic

[1]

Mitigation Modeling is Required Mitigation Modeling is Required SEIS-480V-MCC-FAIL-0.5G Batteries &

Racks AB El. 78' AB El. 100' Generic

[1]

DIRECT CORE DAMAGE Station Blackout Containment Isolation Failure is assumed due to the isolation system failure caused by loss of S-SBO SIE-FLAG-SBO SEIS-DC-BT-FAIL-0.5G RAI 434-8352 - Question 19-85 Rev.2 (17/18)

A3-18 Table. At-Power PRA-based SMA FMEA Results SSCs Location Failure mode HCLPF (g)

FMEA for Core Damage FMEA for Containment Failure Remark IE ID in Seismic ET IE FLAG in Seismic ET Basic Event ID all control Off-Site Power various Generic 0.09[2]

LOOP is assumed failed LOOP is assumed failed S-LOOP SIE-FLAG-LOOP SEIS-LOOP-0.09g Various RCS small pipe and Tubing line various Generic 0.3[3]

SLCOA Small Leak from RCS is assumed at SSE SLCOA Small Leak from RCS is assumed at SSE S-SLOCA SIE-FLAG-SLOCA SEIS-RCS-LEAK-0.3g Key Assumptions

[1] The component is assigned to COL item (COL 19.1.(8)) and HCLPF value is assumed to be equal to or exceed 1.67 times CSDRS.

[2] HCLPF based on generic value from Risk Assessment of Operational Events Handbook Volume 2 - External Events, R.1.01, January 2008, USNRC (Reference 79).

[3] HCLPF based on Option 2 in "SPRA implementation guide", EPRI 3002000709 (Reference 77)

[4] For quantification purpose, a HCLPF value of 0.5g is assumed for the site-specific structures (turbine building, compound building, ESW IS and CCW heat exchanger building). The COL applicant will demonstrated these site-specific structures HCLPF values will be equal to or greater than 1.67 time GMRS. (COL 19.1(8))

RAI 434-8352 - Question 19-85 Rev.2 (18/18)

A4-1 APR1400 SMA - ISG-020 Implementation (At-Power)

DC-COL ISG-020 Guidance Implementation Met (1) seismic accident initiation events; Seismic Accident initiating event are selected based on FMEA in Section 19.1.5.1.1.4 of the DCD Markup Yes (2) a summary of the operating modes, accident sequences and event/fault trees, and damage levels considered in the analysis; a summary of the operating modes, accident sequences and event/fault trees, and damage levels considered in Section 19.1.5.1.1.4 of the DCD Markup Yes (3) the definition of the response spectrum shape used for the fragility analysis of SSCs, accident sequences, and the plant; For the APR1400, the RLE is selected based on the design response spectra of the site-independent SSE which is developed from the certified seismic design response spectra (CSDRS) in Section 19.1.5.1.1 a of the DCD Markup Yes (4) identification of the methods used to calculate sequence-level and plant-level HCLPFs for the sequences, operating modes, and damage levels considered; The methodology of the seismic risk evaluations are described in Section 19.1.5.1.1 f of the DCD Markup Yes (5) a table with the capacities (e.g., in terms of the median and logarithmic standard deviation of the fragilities) for the SSCs in the SEL; It is shown in Table 19.1-43 Yes (6) a summary description of the methods used for the derivation of the component fragilities, including a summary of how the component probability of failure is related to the ground motion parameter; The methodology of the seismic risk evaluations are described in Section 19.1.5.1.1 of the DCD Markup Yes (7) for equipment in the SEL which is qualified via tests, a description of the procurement specifications including the enhanced RRS as described in Section 5.1.2 of this ISG to ensure The methodology of the seismic risk evaluations are described in COL 19.1(8) of the DCD Markup Yes RAI 434-8352 - Question 19-85 Rev.2 (1/2)

A4-2 APR1400 SMA - ISG-020 Implementation (At-Power)

DC-COL ISG-020 Guidance Implementation Met appropriate HCLPF capacity of the procured equipment; (8) risk-significant SSCs, dominant cut-sets and sequences, and seismic event/fault trees; The results of the seismic risk evaluations are described in Section 19.1.5.1.2.4 and table 19.1-44A/B/C/D of the DCD Markup Yes (9) sequence-level and plant-level HCLPF capacities for the operating modes and damage levels; The results of the seismic risk evaluations are described in Section 19.1.5.1.2.4 and table 19.1-44A/B/C/D of the DCD Markup Yes (10) a summary of independent peer reviews; and, Given the limited information available at the DC stage for the PRA-based SMA, a peer review will be conducted after a plant specific Seismic PRA by COL holder. 1)

Yes (11) analysis assumptions, COL action items, interface items, and post licensing activities.

These related items are described in Section 19.1.5.1.1.4.9 for analysis assumption and 19.0.1 for COL items of the DCD Markup Yes Note 1): In order to review the PRA technical adequacy, a self-assessment was performed for the PRA-based SMA. Any findings and observations from self-assessment are dispositioned to provide reasonable assurance that issues are capture and addressed. Any changes required or affecting PRA model and associated documentation are conducted in a manner consistent with DCD section 19.1.2.4 RAI 434-8352 - Question 19-85 Rev.2 (2/2)

A5-1

1.

At-Power Seismic Fault Tree Modeling System logic models, i.e., fault trees, that were developed for the internal events PRA model were used as the basis for the PRA-based SMA logic models. The PRA-based SMA logic models include the seismic failures. Details of the fault tree logic model development for systems where explicit evaluation of seismic failures needed to be included are provided in the subsections that follow.

The naming convention is used for new basic event of seismic failures:

SEIS-CTS-EX-FAIL-0.94G SEIS : Prefix for Seismic failure event CTS-EX-FAIL : Failure mode of SSCs 0.94G : HCLPF value of SSCs Details of the fault tree logic model development for systems where explicit evaluation of seismic failures needed to be included are provided in the subsections that follow.

1.1 Direct Core Damage (S-DMG)

A seismic event that causes significant structural failure is assumed to preclude equipment operation and operator actions needed to prevent core damage. However, structural failure could cause widespread equipment failures. Since these structures were not explicitly included in the internal events model, a new fault tree, G-S-DMG, was created to model seismic failure of these structures. The G-S-DMG fault tree is shown in Figure 1. The new basic events for seismic failure related to S-DMG are included as below.

Basic Event ID Basic Event Description SSCs HCLPF (g)

SEIS-CTS-EX-FAIL-0.94G SEISMIC FAILURE OF CONTAINMENT EXTERIOR Reactor Containment building 0.94 SEIS-CTS-IN-FAIL-1.09G SEISMIC FAILURE OF CONTAINMENT INTERNAL STRUCTURE Reactor Containment Internal 1.09 RAI 434-8352 - Question 19-85 Rev.2 (1/16)

A5-2 Basic Event ID Basic Event Description SSCs HCLPF (g)

SEIS-NI-FAIL-0.52G SEISMIC INDUCED FAILURE OF THE Nuclear Island failure Nuclear Island 0.52 SEIS-AB-FAIL-0.51G SEISMIC FAILURE OF AUXILIARY BUILDING Auxiliary Building 0.51 SEIS-TB-FAIL-0.5G SEISMIC FAILURE OF THE TURBINE BUILDING COLLAPE INTO AUXILIARY BLDG Turbine Building 0.5 SEISMIC-CPD-FAIL-0.5G SEISMIC FAILURE OF COMPOUND BUILDING COLLAPE INTO AUXILIARY BLDG Compound Building 0.5 SEIS-RV-RCS-FAIL-0.92G SEISMICALLY-INDUCED REACTOR VESSEL FALURE Reactor Pressure Vessel 0.92 SEIS-RVI-RCS-FAIL-0.51G SEISMIC INDUCED RX VESSESL INTERNAL FAILURE Reactor Vessel Internal 0.51 SEIS-SG-RCS-FAIL-0.6G SEISMICALLY-INDUCED SG SUPPORT FALURE Steam Generator 0.6 SEIS-SGNOZZ-RCS-FAIL-0.54G SEISMIC INDUCED FAILURE OF THE Steam Generator Nozzle Steam Generator Nozzle 0.54 SEIS-PZR-RCS-FAIL-0.63G SEISMICALLY-INDUCED PZR SKIRT FAILURE Pressurizer 0.63 SEIS-RCP-RCS-FAIL-1.31G SEISMICALLY-INDUCED RCP SUPPORT FALURE Reactor Coolant Pumps 1.31 1.2 Seismic-Induced Station Blackout (S-SBO)

The occurrence of a SBO after a seismic event is assumed to lead to direct core damage. Since S-SBO were not explicitly included in the internal events model, a new fault tree, S-SBO, was created to model seismic failure of these structures. The S-SBO fault tree is shown in Figure 2.

The new basic events for seismic failure related to S-SBO are included as below.

Basic Event ID Basic Event Description SSCs HCLPF (g)

SEIS-DG-FAIL-0.5G SEISMIC INDUCED FAILURE OF Emergency Diesel Generators Emergency Diesel Generators 0.5 SEIS-DG-CD-FAIL-0.5G SEISMIC INDUCED FAILURE OF Emergency Diesel Generators (Aux. Building)

Emergency Diesel Generators (Aux.

Building) 0.5 SEIS-DOMPS-FAIL-0.5G SEISMIC INDUCED FAILURE OF Emergency Diesel Fuel Oil transfer pumps Emergency Diesel Fuel Oil transfer pump 0.5 SEIS-DOMPS-CD-FAIL-0.5G SEISMIC INDUCED FAILURE OF Emergency Diesel Fuel Oil transfer pumps(Aux. Building)

Emergency Diesel Fuel Oil transfer pump (Aux.

Building) 0.5 SEIS-DGTK40-FAIL-0.5G SEISMIC INDUCED FAILURE OF Starting Air Tanks Starting Air Tank 0.5 RAI 434-8352 - Question 19-85 Rev.2 (2/16)

A5-3 Basic Event ID Basic Event Description SSCs HCLPF (g)

SEIS-DOTK02-FAIL-0.5G SEISMIC INDUCED FAILURE OF Diesel Fuel Oil Day Tanks Diesel Fuel Oil Day Tank 0.5 SEIS-DOTK02-CD-FAIL-0.5G SEISMIC INDUCED FAILURE OF Diesel Fuel Oil Day Tanks (Aux. Building)

Diesel Fuel Oil Day Tank 0.5 SEIS-DOTK01-FAIL-0.5G SEISMIC INDUCED FAILURE OF Diesel Fuel Oil Storage Tanks Diesel Fuel Oil Storage Tank 0.5 SEIS-DOTK01-CD-FAIL-0.5G SEISMIC INDUCED FAILURE OF Diesel Fuel Oil Storage Tanks (Aux. Building)

Diesel Fuel Oil Storage Tank (Aux.Building) 0.5 SEIS-DGSL-FAIL-0.5G SEISMIC INDUCED FAILURE OF Silencers Silencer 0.5 SEIS-DGFT-FAIL-0.5G SEISMIC INDUCED FAILURE OF Air Intake Filters Air Intake Filter 0.5 SEIS-DGHX-FAIL-0.5G SEISMIC INDUCED FAILURE OF Lube Oil Water Hxs Lube Oil Water Hx 0.5 SEIS-DGPP-FAIL-0.5G SEISMIC INDUCED FAILURE OF Motor Driven Fuel Oil Feed Pumps Motor Driven Fuel Oil Feed Pump (EDG Building) 0.5 SEIS-DGPP-CD-FAIL-0.5G SEISMIC INDUCED FAILURE OF Motor Driven Fuel Oil Feed Pumps (Aux. Building)

Motor Driven Fuel Oil Feed Pump (Aux.

Building) 0.5 SEIS-VGAH02-FAIL-0.5G SEISMIC INDUCED FAILURE OF EDG Room Emergency Exhaust Fans EDG Room Emergency Exhaust Fan (EDG Building) 0.5 SEIS-VGAH02-CD-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE Room Emergency Exhaust Fans (Aux. Building)

EDG Room Emergency Exhaust Fan (Aux.

Building) 0.5 SEIS-DC-MCC-FAIL-0.5G SEISMIC INDUCED FAILURE OF 125V DC Control Centers 125V DC Control Center 0.5 SEIS-4KV-BUS-FAIL-0.5G SEISMIC INDUCED FAILURE OF 4.16kV MCSGs 4.16kV MCSG 0.5 SEIS-DC-BT-FAIL-0.5G SEISMIC INDUCED FAILURE OF Batteries & Racks Batteries &

Racks 0.5 1.3 Loss of All Instrumentation and Control (S-IC)

S-IC is modeled as occurring if failure of all four channels of 480 VAC power, 125V DC power and I&C cabinet (Safety Console, ESF-CCS GC, ESF-CCS LC and PPS cabinet) are lost.

Since I&C failures were not explicitly included in the internal events model, a new fault tree, S-LOIC-EQUIP-F, was created to model seismic failure of these structures. The S-LOIC-EQUIP-F fault tree is shown in Figure 3. The new basic events for seismic failure related to S-LOIC-EQUIP-F are included as below.

RAI 434-8352 - Question 19-85 Rev.2 (3/16)

A5-4 Basic Event ID Basic Event Description SSCs HCLPF (g)

SEIS-ESF-RPS-FAIL-0.5G SEISMIC INDUCED FAILURE OF ESF-CCS GC Cabinets ESF-CCS GC Cabinet 0.5 SEIS-ESF-RPS-FAIL-0.5G SEISMIC INDUCED FAILURE OF ESF-CCS GC Cabinet ESF-CCS LC Cabinet 0.5 SEIS-ESF-RPS-FAIL-0.5G SEISMIC INDUCED FAILURE OF ESF-CCS GC Cabinets Plant Protection System Cabinet 0.5 SEIS-RP-PM05-FAIL-0.5G SEISMIC INDUCED FAILURE OF MCR SAFETY CONSOLE MCR Safety Consoles 0.5 SEIS-DC-BC-FAIL-0.5G SEISMIC INDUCED FAILURE OF 125V DC Battery Chargers 125V DC Battery Chargers 0.5 SEIS-IPINV-FAIL-0.5G SEISMIC INDUCED FAILURE OF 120V AC Inverters (VBPSS) 120V AC Inverter(VBPSS) 0.5 SEIS-IPREGTR-FAIL-0.5G SEISMIC INDUCED FAILURE OF Regulating Transformers Regulating Transformer 0.5 SEIS-480V-LC-FAIL-0.5G SEISMIC INDUCED FAILURE OF 480V Load Centers 480V Load Center 0.5 1.4 Seismic-Induced Main Steam Line Break (S-MSLB)

The occurrence of a MSLB after a seismic event is assumed to lead to direct core damage. Since SEIS-MSLB were not explicitly included in the internal events model, a new fault tree, S-MSLB, was created to model seismic failure of these structures. The SEIS-MSLB fault tree is shown in Figure 4. The new basic events for seismic failure related to S-MSLB are included as below.

Basic Event ID Basic Event Description SSCs HCLPF (g)

SEIS-MSIV-FAIL-0.5G SEISMIC INDUCED FAILURE OF Main Steam Isolation Valves Main Steam Isolation Valves 0.5 SEIS-MSADV-FAIL-0.5G SEISMIC INDUCED FAILURE OF Main Steam Atmospheric Valves(ADV)

Main Steam Atmospheric Valves(ADV) 0.5 SEIS-MSSV-FAIL-0.5G SEISMIC INDUCED FAILURE OF Main Steam Safety Valves Main Steam Safety Valves 0.5 1.5 Seismic-Induced Total Loss of Component Cooling Water (S-TLOCCW)

The occurrence of a TLOCCW after a seismic event is assumed to lead to direct core damage.

Since S-TLOCCW were not explicitly included in the internal events model, a new fault tree, S-TLOCCW, was created to model seismic failure of these structures. The G-S-TLOCCW fault RAI 434-8352 - Question 19-85 Rev.2 (4/16)

A5-5 tree is shown in Figure 5. The new basic events for seismic failure related to S-TLOCCW are included as below.

Basic Event ID Basic Event Description SSCs HCLPF (g)

SEIS-ESWIS-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE ESWIS ESWIS 0.5 SEIS-CCW-BLDG-FAIL-0.5G SEISMIC INDUCED FAILURE OF THE CCW Hx Building CCW Hx Building 0.5 SEIS-SXPP-FAIL-0.5G SEISMIC INDUCED FAILURE OF Essential Service Water Pumps Essential Service Water Pump 0.5 SEIS-CCHX-FAIL-0.5G SEISMIC INDUCED FAILURE OF CCW Heat Exchangers CCW Heat Exchangers 0.5 SEIS-CCPP-FAIL-0.5G SEISMIC INDUCED FAILURE OF CCW Pumps CCW Pump 0.5 SEIS-CCTK-FAIL-0.5G SEISMIC INDUCED FAILURE OF CCW Surge Tanks CCW Surge tank 0.5 SEIS-WOPP-FAIL-0.5G SEISMIC INDUCED FAILURE OF Essential Chilled Water Pumps Essential Chilled Water Pumps 0.5 SEIS-WOCH-FAIL-0.5G SEISMIC INDUCED FAILURE OF Essential Chillers Essential Chillers 0.5 SEIS-WOTK-FAIL-0.5G SEISMIC INDUCED FAILURE OF ECW Compression Tanks ECW Compression Tank 0.5 SEIS-WOTK02-FAIL-0.5G SEISMIC INDUCED FAILURE OF ECW Air Separators ECW Air Separator 0.5 SEIS-WOLP-FAIL-0.5G SEISMIC INDUCED FAILURE OF Essential Chilled Water System Control Panels Essential Chilled Water System Control Panel 0.5 SEIS-VOHV33-FAIL-0.5G SEISMIC INDUCED FAILURE OF AFWP Room Cubicle Coolers-MD AFWP Room Cubicle Cooler-MD 0.5 SEIS-VKHV13/14-FAIL-0.5G SEISMIC INDUCED FAILURE OF CCWP Room Cubicle Coolers CCWP Room Cubicle Cooler 0.5 SEIS-VKHV11/12-FAIL-0.5G SEISMIC INDUCED FAILURE OF SI Room Cubicle Coolers SI Room Cubicle Cooler 0.5 SEIS-VKHV16-FAIL-0.5G SEISMIC INDUCED FAILURE OF SC Pump & Mini-flow Hx. Room Cubicle Coolers SC Pump &

Mini-flow Hx.

Room Cubicle Cooler 0.5 SEIS-CCLR-MPR-0.5G SEISMIC INDUCED FAILURE OF Mech. Pen. Room Cubicle Coolers Mech. Pen.

Room Cubicle Cooler 0.5 SEIS-VKHV10-FAIL-0.5G SEISMIC INDUCED FAILURE OF CS Pump Room Cubicle Coolers CS Pump Room Cubicle Cooler 0.5 SEIS-CCLR-ACVPP-0.5G SEISMIC INDUCED FAILURE OF Aux Charging Pump Room Cubicle Coolers Aux Charging Pump Room Cubicle Cooler 0.5 RAI 434-8352 - Question 19-85 Rev.2 (5/16)

A5-6 Basic Event ID Basic Event Description SSCs HCLPF (g)

SEIS-VKHV18-FAIL-0.5G SEISMIC INDUCED FAILURE OF Charging Pump Room Cubicle Coolers Charging Pump Room Cubicle Cooler 0.5 SEIS-CCLR-EPA-0.5G SEISMIC INDUCED FAILURE OF Elect. Pen. Room Area Cubicle Coolers Elect. Pen.

Room Area Cubicle Cooler 0.5 SEIS-CCLR-EPA-137-0.5G SEISMIC INDUCED FAILURE OF Elect. Pen. Room Area Cubicle Coolers (EL.137')

Elect. Pen.

Room Area Cubicle Cooler (El. 137')

0.5 SEIS-CCLR-IC-0.5G SEISMIC INDUCED FAILURE OF I&C Eq. Room Cubicle Coolers (EL.137')

I&C Equipment Room Cubical Cooler 0.5 SEIS-CCLR-EDG-100-0.5G SEISMIC INDUCED FAILURE OF EDG Room Emergency Cubicle Coolers (EL.100')

EDG Room Emergency Cubicle Cooler 0.5 SEIS-CCLR-EDG-135-0.5G SEISMIC INDUCED FAILURE OF EDG Room Emergency Cubicle Coolers (EL.135')

EDG Room Emergency Cubicle Cooler 0.5 SEIS-VOHV32-FAIL-0.5G SEISMIC INDUCED FAILURE OF Essential Chiller &

Pump Cubicle Coolers Essential Chiller &

Pump Cubicle Cooler 0.5 SEIS-VGAH-FAIL-0.5G SEISMIC INDUCED FAILURE OF ESW Pump Room Supply Fans ESW Pump Room Supply Fan 0.5 1.6 Seismic-Induced Anticipated Transient Without Scram (S-ATWS)

The occurrence of a S-ATWS after a seismic event is assumed to lead to direct core damage.

Since S-ATWS were not explicitly included in the internal events model, a new fault tree, S-ATWS, was created to model seismic failure of these structures. The S-ATWS fault tree is shown in Figure 6. The new basic events for seismic failure related to S-ATWS are included as below.

Basic Event ID Basic Event Description SSCs HCLPF (g)

SEIS-CEDM-RCS-FAIL-0.64G SEISMIC INDUCED FAILURE OF THE CEDM (Control Element Drive Mechanism)

CEDM (Control Element Drive Mechanism) 0.64 RAI 434-8352 - Question 19-85 Rev.2 (6/16)

A5-7 1.7 Large LOCA (S-LLOCA)

The occurrence of a large LOCA after a seismic event is assumed to lead to direct core damage.

Since S-LLOCA were not explicitly included in the internal events model, a new fault tree, S-LLOCA, was created to model seismic failure of these structures. The S-LLOCA fault tree is shown in Figure 7. The new basic events for seismic failure related to S-LLOCA are included as below.

Basic Event ID Basic Event Description SSCs HCLPF (g)

SEIS-PIPE-RCS-FAIL-0.55G SEISMICALLY-INDUCED LARGE LOCA DUE TO RCS PIPE FALURE Reactor Coolant System Piping 0.55 1.8 Medium LOCA (M-LOCA)

The occurrence of a Medium LOCA after a seismic event is assumed to lead to direct core damage. Since S-MLOCA were not explicitly included in the internal events model, a new fault tree, S-MLOCA, was created to model seismic failure of these structures. The S-LLOCA fault tree is shown in Figure 8. The new basic events for seismic failure related to S-LLOCA are included as below.

Basic Event ID Basic Event Description SSCs HCLPF (g)

SEIS-PZRNOZZ-RCS-FAIL-0.51G SEISMICALLY-INDUCED MEDIUM LOCA DUE TO PZR NOZZ FAILURE Pressurizer nozzle 0.51 1.9 Small LOCA (S-SLOCA)

The occurrence of a small LOCA after a seismic event presents unique challenges to accident mitigation. NSSS seismic failures presented below table were evaluated for contribution to Small LOCA. Where appropriate the NSSS seismic failures where used to model Small LOCA.

The G-S-SLOCA fault tree is shown in Figure 9.

Basic Event ID Basic Event Description SSCs HCLPF (g)

SEIS-RCS-LEAK-0.3g SEISMICALLY-INDUCED SMALL LOCA Reactor Coolant System 0.3 RAI 434-8352 - Question 19-85 Rev.2 (7/16)

A5-8 1.10 Seismic Event Causes LOOP (S-LOOP)

The occurrence of a LOOP after a seismic event presents unique challenges to accident mitigation. The G-S-LOOP fault tree is shown in Figure 10. The new basic events for seismic failure related to S-LOOP are included as below.

Basic Event ID Basic Event Description SSCs HCLPF (g)

SEIS-LOOP-0.09g SEISMICALLY-INDUCED LOOP 0.09 RAI 434-8352 - Question 19-85 Rev.2 (8/16)

A5-9 Figure 1 - G-S-DMG Fault Tree RAI 434-8352 - Question 19-85 Rev.2 (9/16)

A5-10 Figure 2 - S-SBO-EQUIP Fault Tree RAI 434-8352 - Question 19-85 Rev.2 (10/16)

A5-11 Figure 3 - S-LOIC-EQUIP-F Fault Tree RAI 434-8352 - Question 19-85 Rev.2 (11/16)

A5-12 Figure 4 - SEIS-MSLB Fault Tree RAI 434-8352 - Question 19-85 Rev.2 (12/16)

A5-13 Figure 5 - G-S-TLOCCW Fault Tree RAI 434-8352 - Question 19-85 Rev.2 (13/16)

A5-14 Figure 6 - G-S-ATWS Fault Tree Figure 7 - G-S-LLOCA Fault Tree RAI 434-8352 - Question 19-85 Rev.2 (14/16)

A5-15 Figure 8 - G-S-MLOCA Fault Tree Figure 9 - G-S-SLOCA Fault Tree RAI 434-8352 - Question 19-85 Rev.2 (15/16)

A5-16 Figure 10 - G-S-LOOP Fault Tree RAI 434-8352 - Question 19-85 Rev.2 (16/16)

ML18086B653

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