| author name = Drouin M

{{#Wiki_filter:U.S. NUCLEAR REGULATORY COMMISSION                                                      November 2002 OFFICE OF NUCLEAR REGULATORY RESEARCH                                                                Division 1 DRAFT REGULATORY GUIDE

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M.T. Drouin (301)415-6675 DRAFT REGULATORY GUIDE DG-1122 AN APPROACH FOR DETERMINING THE TECHNICAL ADEQUACY OF PROBABILISTIC RISK ASSESSMENT RESULTS FOR RISK-INFORMED ACTIVITIES A. INTRODUCTION In 1995, the NRC issued a Policy Statement (Ref. 1) on the use of probabilistic risk analysis (PRA), encouraging its use in all regulatory matters. The Policy Statement states that . . . the use of PRA technology should be increased to the extent supported by the state of the art in PRA methods and data and in a manner that complements the NRCs deterministic approach. Since that time, many uses have been implemented or undertaken, including modification of NRCs reactor safety inspection program and initiation of work to modify reactor safety regulations.

Consequently, confidence in the information derived from a PRA is an important issue: the accuracy of the technical content must be sufficient to justify the specific results and insights that are used to support the decision under consideration.

This regulatory guide is being developed to describe one acceptable approach for determining that the quality of the PRA, in toto or for those parts that are used to support an application, are sufficient to provide confidence in the results such that they can be used in regulatory decision making for light-water reactors. This guidance is intended to be consistent with NRCs PRA policy statement and subsequent, more detailed, guidance in Regulatory Guide 1.174 (Ref. 2). It is also intended to reflect and endorse guidance provided by standards-setting and nuclear industry organizations.

This regulatory guide is being issued in draft form to involve the public in the early stages of the development of a regulatory position in this area. It has not received complete staff review or approval and does not represent an official NRC staff position.

Public comments are being solicited on this draft guide (including any implementation schedule) and its associated regulatory analysis or value/impact statement. Comments should be accompanied by appropriate supporting data. Written comments may be submitted to the Rules and Directives Branch, Office of Administration, U.S. Nuclear Regulatory Commission, Washington, DC 20555-0001. Comments may be submitted electronically or downloaded through the NRCs interactive web site at <WWW.NRC.GOV> through Rulemaking. Copies of comments received may be examined at the NRC Public Document Room, 11555 Rockville Pike, Rockville, MD. Comments will be most helpful if received by          February 14, 2003.

Requests for single copies of draft or active regulatory guides (which may be reproduced) or for placement on an automatic distribution list for single copies of future draft guides in specific divisions should be made to the U.S. Nuclear Regulatory Commission, Washington, DC 20555, Attention: Reproduction and Distribution Services Section, or by fax to (301)415-2289; or by email to DISTRIBUTION@NRC.GOV. Electronic copies of this draft regulatory guide are available through the NRCs interactive web site (see above); the NRCs web site <WWW.NRC.GOV> in the Electronic Reading Room under Document Collections, Regulatory Guides; and in the NRCs ADAMS Documents at the same web site, under Accession Number ML023360076.

Regulatory guides are issued to describe to the public methods acceptable to the NRC staff for implementing specific parts of the NRCs regulations, to explain techniques used by the staff in evaluating specific problems or postulated accidents, and to provide guidance to applicants.

Regulatory guides are not substitutes for regulations, and compliance with regulatory guides is not required. Regulatory guides are issued in draft form for public comment to involve the public in developing the regulatory positions. Draft regulatory guides have not received complete staff review; they therefore do not represent official NRC staff positions.

B. DISCUSSION Existing Guidance Related to the Use of PRA in Reactor Regulatory Activities Since the PRA Policy Statement was issued, a number of documents have been written that provide guidance on the use of PRA information in reactor regulatory activities. These include:

* At NRC, regulatory guidance documents have been written to address risk-informed applications that use PRA information. These include Regulatory Guide 1.174 (Ref. 2) and Standard Review Plan (SRP) Chapter 19 (Ref. 3), which provide general guidance on applications that address changes to the licensing basis. Key aspects of these documents are:

They describe a risk-informed integrated decision-making process that characterizes how risk information is used, and, more specifically, that such information is one element of the decision-making process. That is, decisions are expected to be reached in an integrated fashion, considering traditional engineering and risk information, and may be based on qualitative factors as well as quantitative analyses and information.

They reflect the staffs recognition that the PRA needed to support regulatory decisions can vary, i.e., that the scope, level of detail, and quality of the PRA is to be commensurate with the application for which it is intended and the role the PRA results play in the integrated decision process. For some applications and decisions, only particular parts1 of the PRA are needed to be used. In other applications, a full scope PRA is needed. General guidance regarding scope, level of detail, and quality for a PRA is provided in the documents.

While written in the context of one reactor regulatory activity (license amendments),

In addition, for specific applications, guidance is provided in separate regulatory guides for such applications as inservice testing (Ref. 4), inservice inspection (Ref. 5), quality assurance (Ref. 6), and technical specifications (Ref. 7). SRP chapters were also prepared for each of the application-specific regulatory guides with the exception of quality assurance.

* PRA standards have been under development by the American Society of Mechanical Engineers (ASME) and American Nuclear Society (ANS). On April 5, 2002, ASME issued a standard for a full-power, internal events (excluding fire) Level 1 PRA and a limited Level 2 PRA (Ref. 8). In the future, ANS plans to issue standards for PRAs for evaluating external events and internal fire risk and risk from low power and shutdown modes of operation.

1 In this regulatory guide, a part of a PRA can be understood as being equivalent to that piece of the analysis for which an applicable PRA standard identifies a supporting level requirement.

* Reactor owners groups have been developing and applying a PRA peer review program for several years. In a letter dated April 24, 2000, the Nuclear Energy Institute (NEI) submitted NEI-00-02 (Ref. 9) to the NRC for review in the context of the staffs work to risk-inform the scope of special treatment requirements contained in 10 CFR Part 50 (discussed in SECY-99-256 -Ref. 10).

On August 16, 2002, NEI submitted draft industry guidance for self-assessments (Ref. 11) to address the use of industry peer review results in demonstrating conformance with the ASME PRA standard. This additional guidance, which is intended to be incorporated into a revision of NEI-00-02 (per NEI, see Reference 11), contains:

* SECY-00-0162 (Ref. 12) describes an approach for addressing PRA quality, including identification of the scope and minimal functional attributes of a technically acceptable PRA.

* SECY-02-0070 (Ref. 13) provides a revision of Regulatory Guide 1.174 and SRP Chapter 19, and informed the Commission of the staffs plan for endorsement of the then pending ASME and ANS consensus standards and peer review programs on PRA. The endorsement was to be provided in a new regulatory guide (this document) and a new SRP Chapter (Ref. 14). Figure 1 displays the relationship among existing guidance, standards and industry guidance, and this regulatory guide.

* SECY-02-0176 (Ref. 15) discusses, in a proposed draft regulatory guide DG 1121, how References 8 and 9, and this draft guide, could be used in the context of the proposed new rule (i.e., 50.69).

Purposes of this Regulatory Guide The purposes of this regulatory guide are to provide guidance to licensees in determining the technical adequacy of a PRA used in a risk-informed integrated decision making process, and to endorse standards and industry guidance. Guidance is provided in four areas:

(1)      A minimal set of functional requirements of a technically acceptable PRA.

(3)      Demonstration that the PRA (in toto or specific parts) used in regulatory applications is of sufficient technical adequacy.

(4)      Documentation that the PRA (in toto or specific parts) used in regulatory applications is of sufficient technical adequacy.

This regulatory guide provides more detailed guidance, relative to Regulatory Guide 1.174, on PRA technical adequacy in a risk-informed integrated decision-making process. It does not provide guidance on how PRA results are used in the application-specific decision-making processes; that guidance is provided in such documents as References 4 through 7, and the proposed DG1121, provided in Reference 15. Recognizing that many applications include the use of a full-scope PRA, this document provides guidance on the minimum technical attributes of such a PRA. However, it also recognized that, in some applications and decisions, methods other than 3

PRA (such as bounding analyses) can be used to address risk issues; guidance on such alternative methods is not provided in this guide.

Relationship to Other Guidance Documents This regulatory guide is a supporting document to other NRC regulatory guides that address risk-informed activities. These guides include, at a minimum, (1) Regulatory Guide 1.174 and SRP Chapter 19 (Refs. 2 and 3), which provide general guidance on applications that address changes to the licensing basis, and (2) the regulatory guides for specific applications such as for inservice testing, inservice inspection, quality assurance, and technical specifications is in References 4 through 7. There are corresponding SRP chapters for the application-specific guides.

Figure 1 shows the relationship of this new regulatory guide and risk-informed activities, application specific guidance, consensus PRA standards, and industry programs (e.g., NEI-00-02).

Figure 1. Relationship of DG-1122 to Other Risk-Informed Guidance C. REGULATORY POSITION

: 1.      Functional Requirements of a Technically Acceptable PRA This section describes one acceptable approach for defining the technical adequacy for an acceptable PRA of a commercial nuclear power plant. In establishing the technical adequacy of a PRA for a particular application, both the scope and level of detail of the PRA need to be addressed. The scope is defined in terms of: (a) those events that can challenge the plant and, if not prevented or mitigated, would eventually result in core damage, and/or a large release, and (b) the metrics used to define risk. The level of detail required of the PRA model is determined ultimately by the application. However, a minimal level of detail is necessary to ensure that the impact of designed-in dependencies (e.g., support system dependencies, functional dependencies and dependencies on operator actions) are correctly captured and the PRA represents the as-built, 4

as-operated plant. This minimal level of detail is implicit in the technical characteristics and attributes discussed in this section. This section, consequently, provides guidance in three areas:

(1)       The scope defining the PRA (2)      The elements of a PRA (3)       The technical attributes and characteristics for a full-scope PRA This guidance is given in accordance with SECY-00-0162.

1.1      Scope of PRA The scope of a PRA addressed in this regulatory guide defines what challenges are to be included in the analysis and the level of analysis to be performed. Specifically, the scope is defined in terms of:

* the metrics used in characterizing the risk,

* the plant operating states for which the risk is to be evaluated, and

* the types of initiating events that can potentially challenge and disrupt the normal operation of the plant.

The metrics typically used for risk characterization in risk-informed integrated decision-making process are CDF and LERF (as surrogates for latent and early fatality risks, respectively).

Issues related to the reliability of barriers, in particular containment integrity and consequence mitigation, are addressed through other parts of this decision-making process, such as consideration of defense in depth. To provide the risk perspective for use in decision making, a Level 1 PRA is required to provide CDF. A limited Level 2 PRA is needed to address LERF.

An essential aspect of the risk characterization is an understanding of the associated uncertainties. Regulatory decision-making utilizing risk insights must be based on a full understanding of the contributors to the PRA results and the impacts of the uncertainties, both those that are explicitly accounted for in the results and those that are not. Consequently, as each technical element of the PRA is performed, the sources of uncertainty are identified and analyzed such that their impact are understood at this level (e.g., accident sequence development, human reliability) and on the risk results (i.e., CDF and LERF).

For the many applications and decisions that involve consideration of total plant risk, or to maximize the benefit from the PRA results and insights, the risk characterization (CDF and LERF) should account for all plant operating states and initiating events, either quantitatively or qualitatively.

Plant operating states (POSs) are used to subdivide the plant operating cycle into unique states such that the plant response can be assumed to be the same for all subsequent accident initiating events. Operational characteristics (such as reactor power level; in-vessel temperature, pressure, and coolant level; equipment operability; and changes in decay heat load or plant conditions that allow new success criteria) are examined to identify those important to defining plant operational states. The important characteristics are used to define the states, and the fraction of time spent in each state is estimated using plant specific information. The risk perspective is based on the total risk connected with the operation of the reactor, which includes not only full power operation, but also low power and shutdown conditions.

Initiating events are the events that have the ability to challenge the condition of the plant.

These events include failure of equipment from either internal plant causes such as hardware faults, operator actions, floods or fires, or external plant causes such as earthquakes or high winds. The risk perspective should be based on the total risk, which includes events from both internal and external sources.

1.2    Elements of a PRA Table 1 provides the list of general technical elements that are necessary for a PRA. A PRA that is missing one or more of these elements would not be considered a complete PRA. A brief discussion of the objective and purpose that these elements should accomplish is provided below.

* Interpretation of results 1.2.1  Level 1 Technical Elements Initiating event analysis identifies and characterizes the random internal events that both challenge normal plant operation during power or shutdown conditions and require successful mitigation by plant equipment and personnel to prevent core damage from occurring. Events that have occurred at the plant and those that have a reasonable probability of occurring are identified and characterized. An understanding of the nature of the events is performed such that a grouping of the events into event classes, with the classes defined by similarity of system and plant responses (based on the success criteria), may be performed to manage the large number of potential events that can challenge the plant.

Success criteria analysis determines the minimum requirements for each function (and ultimately the systems used to perform the functions) to prevent core damage (or to mitigate a release) given an initiating event. The requirements defining the success criteria are based on acceptable engineering analyses that represent the design and operation of the plant under consideration. For a function to be successful, the criteria are dependent on the initiator and the conditions created by the initiator. The codes used to perform the analyses for developing the success criteria are validated and verified for both technical integrity and suitability to assess plant conditions for the reactor pressure, temperature, and flow range of interest, and they accurately analyze the phenomena of interest. Calculations are performed by personnel who are qualified to perform the types of analyses of interest and are well trained in the use of the codes.

Accident sequence development analysis models, chronologically, the different possible progression of events (i.e., accident sequences) that can occur from the start of the initiating event to either successful mitigation or to core damage. The accident sequences account for the systems and operator actions that are used (and available) to mitigate the initiator based on the defined success criteria and plant operating procedures (e.g., plant emergency and abnormal operating procedures and as practiced in simulator exercises). The availability of a system includes consideration of the functional, phenomenological, and operational dependencies and interfaces between the different systems and operator actions during the course of the accident progression.

Systems analysis identifies the different combinations of failures that can preclude the ability of the system to perform its function as defined by the success criteria. The model representing the various failure combinations includes, from an as-built and as-operated perspective, the system hardware and instrumentation (and their associated failure modes) and the human failure events that would prevent the system from performing its defined function. The basic events representing equipment and human failures are developed in sufficient detail in the model to account for dependencies between the different systems and to distinguish the specific equipment or human event (and its failure mechanism) that has a major impact on the systems ability to perform its function.

Parameter estimation analysis quantifies the frequencies of the identified initiating events and quantifies the equipment failure probabilities and equipment unavailabilities of the modeled systems. The estimation process includes a mechanism for addressing uncertainties, has the ability to combine different sources of data in a coherent manner, and represents the actual operating history and experience of the plant and applicable generic experience as applicable.

Human reliability analysis identifies and provides probabilities for the human failure events that can negatively impact normal or emergency plant operations. The human failure events associated with normal plant operation include the events that leave the system (as defined by the success criteria) in an unrevealed, unavailable state. The human failure events associated with emergency plant operation include the events that, if not performed, do not allow the needed system to function. Quantification of the probabilities of these human failure events is based on plant and accident specific conditions, where applicable, including any dependencies among actions and conditions.

Quantification provides an estimation of the CDF given the design, operation, and maintenance of the plant. This CDF is based on the summation of the estimated CDF from each initiator class. If truncation of accident sequences and cutsets is applied, truncation limits are set so that the overall model results are not impacted significantly and that important accident sequences are not eliminated. Therefore, the truncation limit can vary for each accident sequence.

Consequently, the truncation value is selected so that the accident sequence CDF before and after truncation only differs by less than one significant figure.

Interpretation of results entails examining and understanding the results of the PRA and identifying the important contributors sorted by initiating events, accident sequences, equipment failures, and human errors. Methods such as importance measure calculations (e.g., Fussel-Vessely, risk achievement, risk reduction, and Birnbaum) are used to identify the contributions of various events to the model estimation of core damage frequency for both individual sequences and the model as a total. An important aspect in understanding the PRA results is understanding the associated uncertainties. Sources of uncertainty are identified and their impact on the results analyzed. The sensitivity of the model results to model boundary conditions and other key assumptions is evaluated using sensitivity analyses to look at key assumptions both individually or in logical combinations. The combinations analyzed are chosen to fully account for interactions among the variables.

1.2.2    Level 2 Technical Elements Plant damage state analysis groups similar core damage scenarios together to allow a practical assessment of the severe accident progression and containment response resulting from the full spectrum of core damage accidents identified in the Level 1 analysis. The plant damage state analysis defines the attributes of the core damage scenarios that represent important boundary conditions to the assessment of severe accidents progression and containment response that ultimately affect the resulting source term. The attributes address the dependencies 7

between the containment systems modeled in the Level 2 analysis with the core damage accident sequence models to fully account for mutual dependencies. Core damage scenarios with similar attributes are grouped together to allow for efficient evaluation of the Level 2 response.

Severe accident progression analysis models the different series of events that challenge containment integrity for the core damage scenarios represented in the plant damage states. The accident progressions account for interactions among severe accident phenomena and system and human responses to identify credible containment failure modes, including failure to isolate the containment. The timing of major accident events and the subsequent loadings produced on the containment are evaluated against the capacity of the containment to withstand the potential challenges. The containment performance during the severe accident is characterized by the timing (e.g., early versus late), size (e.g., catastrophic versus bypass), and location of any containment failures. The codes used to perform the analysis are validated and verified for both technical integrity and suitability. Calculations are performed by personnel qualified to perform the types of analyses of interest and well trained in the use of the codes.

Source term analysis characterizes the radiological release to the environment resulting from each severe accident sequence leading to containment failure or bypass. The characterization includes the time, elevation, and energy of the release and the amount, form, and size of the radioactive material that is released to the environment. The source term analysis is sufficient to determine whether a large early release or a large late release occurs. A large early release is one involving significant, unmitigated releases from containment in a time frame prior to effective evacuation of the close-in population such that there is a potential for early health effects.

Such accidents generally include unscrubbed releases associated with early containment failure at or shortly after vessel breach, containment bypass events, and loss of containment isolation. With large late release, significant, unmitigated release from containment occurs in a time frame that allows effective evacuation of the close-in population such that early fatalities are unlikely.

Quantification integrates the accident progression models and source term evaluation to provide estimates of the frequency of radionuclide releases that could be expected following the identified core damage accidents. This quantitative evaluation reflects the different magnitudes and timing of radionuclide releases and specifically allows for identification of the LERF and the probability of a large late release.

Interpretation of results entails examining results from importance measure calculations (e.g., Fussel-Vesely, risk achievement, risk reduction, and Birnbaum) to identify the contributions of various events to the model estimation of LERF and large late release probability for both individual sequences and the model as a total. Sources of uncertainty are identified and their impact o the results analyzed. An important aspect in understanding the PRA results is understanding the associated uncertainties. The sensitivity of the model results to model boundary conditions and other key assumptions is evaluated using sensitivity analyses to look at key assumptions both individually or in logical combinations. The combinations analyzed are chosen to fully account for interactions among the variables.

1.2.3    Internal Floods Technical Elements Flood identification analysis identifies the plant areas where flooding could pose significant risk. Flooding areas are defined on the basis of physical barriers, mitigation features, and propagation pathways. For each flooding area, flood sources that are due to equipment (e.g.,

piping, valves, pumps) and other sources internal to the plant (e.g., tanks) are identified along with the affected SSCs. Flooding mechanisms are examined that include failure modes of components, human-induced mechanisms, and other water releasing events. Flooding types (e.g., leak, 8

1.2.4    Internal Fire Technical Elements Screening analysis identifies fire areas where fires could pose a significant risk. Fire areas that are not risk significant can be "screened out" from further consideration in the PRA analysis.

Both qualitative and quantitative screening criteria can be used. The former address whether an unsuppressed fire in the area poses a nuclear safety challenge; the latter are compared against a bounding assessment of the fire-induced core damage frequency for the area. The potential for fires involving multiple areas is addressed. Assumptions used in the screening analysis are verified through appropriate plant walkdowns. Key screening analysis assumptions and results, e.g., the area-specific conditional core damage probabilities (assuming fire-induced loss of all equipment in the area), are documented.

Fire initiation analysis determines the frequency and physical characteristics of the detailed (within-area) fire scenarios analyzed for the unscreened fire areas. The analysis identifies a range of scenarios that will be used to represent all possible scenarios in the area. The possibility of seismically induced fires is considered. The scenario frequencies reflect plant-specific experience, quantified in a manner that is consistent with their use in the subsequent fire damage analysis (discussed below). Each scenario is physically characterized in terms that will support the fire damage analysis (especially with respect to fire modeling).

Fire damage analysis determines the conditional probability that sets of potentially risk-significant components (including cables) will be damaged in a particular mode, given a specified fire scenario. The analysis addresses components whose failure will cause an initiating event, affect the plants ability to mitigate an initiating event, or affect potentially risk significant equipment 9

(e.g., through suppression system actuation). Damage from heat, smoke, and exposure to suppressants is considered. If fire models are used to predict fire-induced damage, compartment-specific features (e.g., ventilation, geometry) and target-specific features (e.g., cable location relative to the fire) are addressed. The fire suppression analysis accounts for the scenario-specific time to detect, respond to, and extinguish the fire. The models and data used to analyze fire growth, fire suppression, and fire-induced component damage are consistent with experience from actual nuclear power plant fire experience as well as experiments.

Plant response analysis involves the modification of appropriate plant transient and LOCA PRA models to determine the conditional core damage probability, given damage to the sets of components defined in the fire damage analysis. All potentially significant fire-induced initiating events, including such "special" events as loss of plant support systems and interactions between multiple nuclear units during a fire event, are addressed. The analysis addresses the availability of non-fire affected equipment (including control) and any required manual actions. For fire scenarios involving control room abandonment, the analysis addresses the circuit interactions raised in Reference 16, including the possibility of fire-induced damage prior to transfer to the alternate shutdown panels. The human reliability analysis of operator actions addresses fire effects on operators (e.g., heat, smoke, loss of lighting, effect on instrumentation) and fire-specific operational issues (e.g., fire response operating procedures, training on these procedures, potential complications in coordinating activities). In addition, an important aspect in understanding the PRA results is understanding the associated uncertainties; sources of uncertainty are identified and their impact o the results analyzed. The sensitivity of the model results to model boundary conditions and other key assumptions is evaluated using sensitivity analyses to look at key assumptions both individually or in logical combinations. The combinations analyzed are chosen to fully account for interactions among the variables.

1.2.5    External Hazards Technical Elements Screening and bounding analysis identifies external events other than earthquake (such as river-induced flooding) that may challenge plant operations and require successful mitigation by plant equipment and personnel to prevent core damage from occurring. The term "screening out" is used here for the process whereby an external event is excluded from further consideration in the PRA analysis. There are two fundamental screening criteria embedded here. An event can be screened out if either (1) it meets the design criteria, or (2) it can be shown using an analysis that the mean value of the design-basis hazard used in the plant design is less than 10-5/year, and that the conditional core-damage probability is less than 10-1, given the occurrence of the design-basis hazard. An external event that cannot be screened out using either of these criteria is subjected to the detailed-analysis.

1.3        Technical Adequacy of a PRA Tables 2 and 3 describe, for each technical element of a PRA, the technical characteristics and attributes that provide one acceptable approach for determining the technical adequacy of the PRA such that the goals and purposes, defined in Regulatory Position 1.2, are accomplished.

Table 2. Summary of Technical Characteristics and Attributes of a PRA Element                            Technical Characteristics and Attributes PRA Full Power, Low Power and Shutdown Level 1 PRA (internal events -- transients and LOCAs)

* based on best-estimate engineering analyses applicable to the actual plant Analysis                  design and operation

* includes necessary and sufficient equipment (safety and non-safety)

Assumptions include the decisions and judgments that were made in the course of the analysis.

Table 2. Summary of Technical Characteristics and Attributes of a PRA Element                          Technical Characteristics and Attributes Systems Analysis      models developed in sufficient detail to:

* reflect the as built, as operated plant including how it has performed during the plant history

* identification and definition of the human failure events that would result in Analysis                initiating events or pre- and post-accident human failure events that would impact the mitigation of initiating events

* assessment of accident progression timing, including timing of loss of containment failure integrity 12

Table 2. Summary of Technical Characteristics and Attributes of a PRA Element                          Technical Characteristics and Attributes Quantification

* grouping of radionuclide releases into smaller subset of representative source terms with emphasis on large early release (LER) and on large late release (LLR)

* the documentation is sufficient to facilitate independent peer reviews defensibility

* Assumptions include those decisions and judgments that were made in the course of the analysis.

Analysis                  6 flood areas and SSCs located within each area 6 flood sources and flood mechanisms 6 the type of water release and capacity 6 the structures functioning as drains and sumps

* identification of flooding induced initiating events on the basis of a structured and systematic process

* unscreened events areas are subjected to appropriate level of evaluations (including detailed fire PRA evaluations as described below) as appropriate Fire Initiation

* all potentially significant fire scenarios in each unscreened area are Analysis                addressed

* fire scenario frequencies reflect plant-specific features

* analysis addresses scenario-specific factors affecting fire growth, suppression, and component damage

* models and data are consistent with experience from actual fire experience as well as experiments

* includes evaluation of propagation of fire and fire effects (e.g., smoke) between fire compartments Plant Response

When necessary, human error data is modified to reflect unique circumstances related to the external event under consideration

* unique aspects of common causes, correlations, and dependencies are included

* the integration/quantification accounts for the uncertainties in each of the inputs (i.e., hazard, fragility, system modeling) and final quantitative results such as CDF and LERF

: 2.      CONSENSUS PRA STANDARDS AND INDUSTRY PRA PROGRAMS One acceptable approach to demonstrate conformance with Regulatory Position 1 is to use an industry consensus PRA standard; in addition, an alternative and acceptable approach to using an industry consensus PRA standard is to use an industry-developed peer review program.

2.1      Consensus PRA Standards One example of an industry consensus PRA standard is the ASME standard (Ref. 8), with a scope for a PRA for Level 1 and limited Level 2 (LERF) for full-power operation and internal events (excluding internal fires). The staff regulatory position regarding this document is provided in Appendix A to this regulatory guide. If it is demonstrated that the parts of a PRA that are used to support an application comply with the ASME standard, when supplemented to account for the staffs regulatory positions contained in Appendix A, it is considered that the PRA is adequate to support that risk-informed regulatory application.

Additional appendices will be added in future updates to this regulatory guide to address PRAs for other risk contributors, such as accidents caused by external hazards or internal fire or caused during the low power and shutdown modes of operation.

: 1. The PRA standard provides well-defined criteria against which the strengths and weaknesses of the PRA may be judged so that decision makers can determine the degree of reliance that can be placed on the PRA results of interest.

: 2. The standard is based on current good practices as reflected in publicly available documents.

The need for the documentation to be publicly available follows from the fact that the standard may be used to support safety decisions.

: 3. To facilitate the use of the standard for a wide range of applications, categories can be defined to aid in determining the applicability of the PRA for various types of applications.

: 4. The standard thoroughly and completely defines what is technically required and should, where appropriate, identify one or more acceptable methods.

: 5. The standard requires a peer review process that identifies and assesses where the technical requirements of the standard are not met. The standard needs to ensure that the peer review process:

6 determines whether methods identified in the standard have been used appropriately; 6 determines that, when acceptable methods are not specified in the standard, or when alternative methods are used in lieu of those identified in the standard, the methods used are adequate to meet the requirements of the standard; 6 assesses the significance of the results and insights gained from the PRA of not meeting the technical requirements in the standard; 6 highlights assumptions that may significantly impact the results and provides an assessment of the reasonableness of the assumptions; 6 is flexible and accommodates alternative peer review approaches; and 6 includes a peer review team that is composed of members who are knowledgeable in the technical elements of a PRA, are familiar with the plant design and operation, and are independent with no conflicts of interest.

: 6. The standard addresses the maintenance and update of the PRA to incorporate changes that can substantially impact the risk profile so that the PRA adequately represents the current as-built and as-operated plant.

: 7. The standard is a living document. Consequently, it should not impede research. It is structured so that, when improvements in the state of knowledge occur, the standard can easily be updated.

2.2    Industry Peer Review Program An acceptable approach that can be used to ensure technical adequacy is to perform a peer review of the PRA. A peer review process can be used to identify the strengths and weaknesses in the PRA and their importance to the confidence in the PRA results. Specifically, an alternative and acceptable approach to using the ASME standard is to use the industry-developed peer review program (Ref. 9), with a scope for a PRA for Level 1 and limited Level 2 (LERF) for full-power operation and internal events (excluding internal floods and fires). The staff regulatory position on this document is provided in Appendix B to this regulatory guide. When the staffs regulatory positions contained in Appendix B are taken into account, use of this document can be used to demonstrate that the PRA is adequate to support a risk-informed application.

The team qualifications determine the credibility and adequacy of the peer reviewers. To avoid any perception of a technical conflict of interest, the peer reviewers will not have performed any actual work on the PRA. The members of the peer review team must have technical expertise in the PRA elements they review, including experience in the specific methods that are used to perform the PRA elements. This technical expertise includes experience in performing (not just reviewing) the work in the element assigned for review. Knowledge of the key features specific to the plant design and operation is essential. Finally, each member of the peer review team must be knowledgeable in the peer review process, including the desired characteristics and attributes used to assess the adequacy of the PRA.

: 3.      Demonstrating the Technical Adequacy of a PRA Used To Support a Regulatory Application This section of the regulatory guide addresses the third purpose identified above, namely, to provide guidance to licensees on an approach acceptable to the NRC staff to demonstrate that the PRA used, in toto or for those parts that are used to support a regulatory application),are of sufficient quality to support the analysis. The role of this regulatory guide to support a specific application is discussed in the following sections.

3.2      Scope of Risk Contributors Addressed by the PRA Model Based on the definition of the application, and in particular the acceptance criteria or guidelines, the scope of risk contributors (internal and external initiating events and modes of plant operation) for the PRA can be identified. For example, if the application is designed around using the acceptance guidelines of Regulatory Guide 1.174, the evaluations of core damage frequency 18

(CDF), CDF, large early release frequency (LERF), and LERF should be performed with a full-scope PRA, including external initiating events and all modes of operation. However, since most PRAs do not address this full scope, the decision makers must make allowances for these omissions. Examples of approaches to making allowances include the introduction of compensatory measures, restriction of the implementation of the proposed change to those aspects of the plant covered by the risk model, and use of bounding arguments to cover the risk contributions not addressed by the model. This regulatory guide does not address this aspect of decision making, but it is focused specifically on the quality of the PRA information used.

The PRA standards and industry PRA programs that have been, or are in the process of being, developed address a specific scope. For example, the ASME PRA standard (Ref. 8) addresses internal events at full power for a limited Level2 PRA analysis. Similarly NEI-00-02 (Ref. 9) is a peer review process for the same scope (with the exception of internal flooding, which is not considered in NEI-00-02). Neither addresses external (including internal fire) initiating events nor the low power and shutdown modes of operation. The different PRA standards or industry PRA programs are addressed separately in appendices to this regulatory guide. In using this regulatory guide, the applicant will identify which of these appendices is applicable to the PRA analysis.

For the first, assurance that the parts of the PRA used in the application have been performed in a technically correct manner implies that: (a) the PRA model, or those parts of the model required to support the application, represents the as-built and as-operated plant, which, in turn, implies that the PRA is up to date and reflects the current design and operating practices, (b) the PRA logic model has been developed in a manner consistent with industry practice and that it correctly reflects the dependencies of systems and components on one another and on operator actions, and (c) the probabilities and frequencies used are estimated consistently with the definitions of the corresponding events of the logic model.

For the second, the current state of the art in PRA technology is that there are issues for which there is no consensus on methods of analysis. Furthermore, PRAs are models, and in that sense the developers of those models rely on certain approximations to make the models tractable, and on certain assumptions to address uncertainties as to how to model specific issues.

: 1.      USNRC, Use of Probabilistic Risk Assessment Methods in Nuclear Activities: Final Policy Statement, Federal Register, Vol. 60, p. 42622 (60 FR 42622), August 16, 1995.

1 Requests for single copies of draft or active regulatory guides (which may be reproduced) and certain SRP sections, or for placement on an automatic distribution list for single copies of future draft guides in specific divisions should be made in writing to the U.S. Nuclear Regulatory Commission, Washington, DC 20555, Attention: Reproduction and Distribution Services Section, or by fax to (301)415-2289; email

: 13.      USNRC, Publication of Revisions 1 to Regulatory Guide 1.174 and SRP Chapter 19 and Notice of a Staff Plan for Endorsing Consensus Probabilistic Risk Assessment Standards and Industry Peer Review Programs, SECY-02-0070, April 24, 2002.5

Copies are available at current rates from the U.S. Government Printing Office, P.O. Box 37082, Washington, DC 20402-9328 (telephone (202)512-1800); or from the National Technical Information Service by writing NTIS at 5285 Port Royal Road, Springfield, VA 22161; (telephone (703)487-4650; <http://www.ntis.gov/ordernow>. Copies are available for inspection or copying for a fee from the NRC Public Document Room at 11555 Rockville Pike, Rockville, MD; the PDRs mailing address is USNRC PDR, Washington, DC 20555; telephone (301)415-4737 or (800)397-4209; fax (301)415-3548; email is PDR@NRC.GOV.

Table A-1            Staff Position on ASME RA-S-2002 Index No                    Issue                    Position                        Resolution Chapter 1 1.1              The standard is only for current    Clarification "This Standard sets forth requirements for PRAs generation LWRs, the                              used to support risk-informed decisions for requirements may not be sufficient                commercial light water reactor nuclear power or adequate for other types of                    plants, and prescribes a method for applying these reactors                                          requirements for specific applications (additional or revised requirements may be needed for more advanced reactor designs)."

1.2 - 1.7                 -----------------           No objection               ----------------------------

Tbl 1.3-1                 -----------------          No objection              ----------------------------

Chapter 2 2.1                        -----------------           No objection               ----------------------------

Table A-1            Staff Position on ASME RA-S-2002 Index No                Issue                  Position                        Resolution Accident   The definition provided is very     Clarification accident sequence, a representation in terms of sequence    general and does not distinguish                  an initiating event followed by a sequence of the different types of accident                    failures or successes of events (such as system, sequences developed in a PRA.                      function, or operator performance) that can This distinction is necessary                      lead to undesired consequences, with a because some of the SRs are                        specified end state (e.g., core damage or large dependent on the accident                          early release). A representation in terms of an sequence type.                                    initiating event followed by a combination of system, function, and operator failures or successes, of an accident that can lead to undesired consequences, with a specified end state (e.g., core damage or large early release). An accident sequence may contain many unique variations of events (minimal cut sets) that are similar.

accident sequence, class, a grouping of accident sequences by initiator type (e.g.,

accident sequence, functional, the sequence of events are represented by the key safety functions necessary to mitigate the effects of the initiating event.

accident sequence, systemic, the sequence of events are represented by the front-line systems necessary to mitigate the effects of the initiating event.

accident sequence, scenario, the sequence of events are represented by the specific components or trains, support systems and operator actions necessary to mitigate the effects of the initiating event.

addition, it is not clear what is meant by large fraction. The term                  dominant, significant, important, contributor, "dominant" is also used to modify                  an entity or entities (contributor(s) or event(s) other events such as contributors,                  such as failure of a specific piece(s) of human events.                                      equipment, human failure event(s), accident sequence(s)) that exercises the most influence Several different terms (modifiers)                or control to an outcome, and where each are used in the standard. In some                  dominant entity has the ability to effect the places, these modifiers are used                    second significant figure of the quantitative interchangeably (to have the same                  outcome (i.e., x.yE-z).

meaning) and in other places, they are used to convey different meanings (e.g., used to distinguish whether a requirement is imposed).

Specifically, these modifiers include: important, significant and dominant.

the term is used to mean realistic which is already stated in the requirement (see SC-B1) key safety     The functions listed are imprecise    Qualification "...These include reactivity control, core heat functions      and redundant (e.g., core heat                      removal, reactor pressure control, reactor removal is redundant with both                      coolant inventory control, reactor coolant heat reactor coolant inventory control                  removal, decay heat removal, and containment and reactor coolant heat removal)                  integrity in appropriate combinations..."

large early   QHOs address both early and           Clarification "...of off-site emergency response and protective release        latent fatalities where LERF is                     actions such that there is a potential for early used as a surrogate for the early                   health effects."

fatality QHO, therefore, the definition to include the potential for early health effects is necessary.

Skill of the   This term is used in the standard     Qualification skill of the craft: that level skill expected of the craft          and a definition is necessary.                      personnel performing the associated function unavailability Fraction of time is one method for   Qualification "The probability that a system or component is calculating unavailability, it is not              not capable of supporting its function..."

suitable for calculating unavailabilities such as failure on demand.

Table A-1              Staff Position on ASME RA-S-2002 Index No                   Issue                    Position                          Resolution IE-A4        As written, the distinction between    Clarification Cat II: "USE a structured approach .... to assess Cat II and III could be taken to                     and document the possibility of an initiating event mean that only those initiating                       resulting from individual systems or train events resulting from failures of                     failures."

complete systems as opposed to single trains of systems will be considered.

IE-A5        As written, there is an implication     Clarification "....INCORPORATE (a) events that have occurred that more work is needed in (a):                      at condition other than at-power operation (i.e.,

not every event that occurs at other                  during low power or shutdown conditions, unless than at-power operation should be                    it is determined that an event is not applicable incorporated.                                        to at-power operation. (b) events...."

IE-A6        As written, there is an implication     Clarification Cat II: "INTERVIEW plant operations, ... to that more work is needed for Cat II                   determine if potential initiating event have been than for Cat III, since it is not clear               overlook." Information from interviews whether the interviews from other                     conducted at similar plants may be used.

plants are to be used instead of or as a complement to plant specific interviews. However, interviews from other plants would appear to be more resource intensive.

IE-B2,B3, B4           --------------------------   No objection                 --------------------------

IE-B1        For the functional IE categories       Clarification "....in the Quantification element (para.4.5.8).

and quantification IE categories, as                  Functional initiating event categories refer to written, it is implied that two                      initiating events grouped for the purpose of different groupings are performed.                    accident sequence definition, while quantification Therefore two different sets of                      initiating event categories refer to those grouped accident sequences would be                          for separate quantification of the accident developed and quantified. In                          sequences. When initiating events are not grouped addition, the definitions provided                    for either of these purposes, PROVIDE a separate are too limiting, other IE                            accident-sequence evaluation for each selected categories can exist for grouping.                    initiating event."

IE-C2,C3,                 -----------------           No objection               ----------------------------

C4,C6,C7,C8, C10, C11 IE-C1        As written, there appears to be an     Clarification "...USE the most recent applicable data to internal inconsistency -- SR                          quantify the initiating event frequencies.

requires the "USE of the most                        JUSTIFY excluded data that is not considered recent data" then requires                            to be either recent or applicable (e.g., provide justification to exclude "data from                  evidence via design or operational change that the initial year of commercial                        the data are no longer applicable). CREDIT operation. Further in IE-C5, SR                      recovery actions(see note) as appropriate; JUSTIFY requires justification of "exclusion                  each such credit (as evidenced such as through of earlier years"                                    procedures or training). Data from the initial year of commercial operation may be excluded; if It is not clear what is an acceptable                excluded, JUSTIFY.

justification for deviating from the                      Note: these recovery actions are those standard, as such the requirement                        implied in IE-C4(c) or those implied and is too open ended.                                        discussed in IE-C6 through IE-C9."

4.5.2. - AS                                               No objection Table 4.5.2-1      HLR-AS-B is inconsistent with the       Clarification HLR-AS-B Dependencies due to initiating HLR written for Table 4.5.2-2(b).                     events, human interface, functional dependencies, The SRs in Table 4.5.2-2(b) are                       environmental and spatial impacts, and common appropriate for the HLR as written                    cause failures shall be addressed.

for that table.                                        "Dependencies that can impact the ability of the mitigating systems to operate and function shall be addressed."

Tables 4.5.2-2(a) thru 4.5.2-2(c)

Table 4.5.2-                   -----------------           No objection                 ----------------------------

AS-A1, A2,A3                   -----------------           No objection                 ----------------------------

,A11 AS-A6              As written, with the term "when         Clarification "Where practical, sequentially ORDER....in the practical," there is no minimum,                      accident progression. Where not practical, there is no SR for when it is not                      provide the bases and provide the rationale practical.                                            used for the ordering."

SC-A1, A2,A3                 -----------------           No objection               ----------------------------

A4, A5,A6 SC-B2, B3,B4                 -----------------           No objection               ----------------------------

B5, B6 SC-B1              The meaning of "best-estimate" as     Qualification Cat II: "USE appropriate realistic best-estimate used in this requirement does not                  generic analyses/evaluations.....requiring detailed agree with the definition in Section                computer modeling. Realistic models or analyses 2; in the SC-B1 context it is                      may be supplemented..."

redundant with "realistic" and is                  Cat III: "USE best-estimate realistic, plant-not needed.                                        specific models...."

SC-C1,                       -----------------           No objection               ----------------------------

C2,C3,C4 4.5.4 - SY 4.5.4.1                       -----------------           No objection               ----------------------------

Table 4.5.4-1                 -----------------           No objection               ----------------------------

Table A-1              Staff Position on ASME RA-S-2002 Index No                          Issue                    Position                          Resolution SY-A19            If there are not any engineering       Qualification Cat I and II: "...If engineering analyses are not analyses, there can be no                            available, ASSUME that the equipment/system justification for the assumption.                    fails with a probability of 1.0. or JUSTIFY the assumed failure probability."

SY-A23            There are no commonly used             Clarification "....is justified through an adequate recovery analysis methods for recovery in                      analysis or examination of data collected in the sense of repair, other than use                  accordance with DA-C14." (See DA-C14.)

SY-B2 thru                     -----------------           No objection                 ----------------------------

B9, SY-B12 thru B16 SY-B1              For Cat I, as written, this implies     Clarification For Cat I: "MODEL intra-system common-cause more effort than probably intended                    failures when supported by generic or plant-by this requirement.                                  specific data (an acceptable model is the screening approach of NUREG/CR-5485, which is consistent with DA-D5), or SHOW that they do not impact the results."

SY-B11            It is not clear what is an acceptable   Clarification "....MODEL them unless a justification is justification for deviating from the                  provided (i.e., that is unique to the system and standard; as such, the requirement                    highly reliable). ....."

SY-B12            It is not clear what is an acceptable   Clarification "COMPARE MODEL the limitation of the justification for deviating from the                  available inventories of air, power, and cooling standard; as such, the requirement                    with those required respect to supporting the is too open ended.                                    mission time. TREAT these inventories in the model unless a justification is provided."

SY-C1,C2 C3                     -----------------           No objection                 ----------------------------

4.5.5 - HR 4.5.5.1                         -----------------           No objection                 ----------------------------

Table 4.5.5-1                   -----------------           No objection                 ----------------------------

Table A-1              Staff Position on ASME RA-S-2002 Index No                         Issue                    Position                          Resolution HR-G1,                         -----------------           No objection                 ----------------------------

G2,G3, G5,G6, G7,G9 HR-G4              For Cat II, plant-specific thermal-     Clarification Cat II: "BASE the time available to complete hydraulic analysis is required                        actions on appropriate, realistic generic which seems inconsistent with SC-                     thermal-hydraulic analyses, or simulations B1 that allows realistic but "similar                  from similar plants (e.g., plant of similar plant" T-H for Cat II.                                design and operation). SPECIFY the point in time at which operators are expected to receive relevant indications.

Cat III: "BASE the time available to complete actions on plant-specific thermal-hydraulic analyses, or simulations SPECIFY the point in time at which operators are expected to receive relevant indications.

HR-G8              It is not clear what is an acceptable  Clarification  "DEFINE and JUSTIFY (provide evidence that justification; as such, the                            there are not any dependencies, e.g., shaping requirement is too open ended.                        factors, management, among the human failure events such that cutsets were inappropriately truncated) the minimum probability...."

HR-H1              To be consistent with HR-H2 and        Clarification  Cat I and II: "INCLUDE....the dominant HR-H3, it is necessary that this SR                    sequences. Recovery actions are limited to clearly indicate that recovery does                    those to which HRA techniques can be applied, not include repair, which is dealt                    such as system reconfiguration, or simple with actuarially, not by modeling                      actions such as manually opening or closing a via human reliability analysis.                        failed valve, but not repair."

Cat III: "INCLUDE.....components. Recovery actions are limited to those to which HRA techniques can be applied, such as system reconfiguration, or simple actions such as manually opening or closing a failed valve, but not repair."

HR-H2              The criteria provided for crediting      Qualification "....skill of the craft exist recovery actions are incomplete;                      (c) attention is given to the relevant there are other factors equally                        performance shaping factors provided in HR-important that are to be addressed                    G3 before credit can be allowed.                          (d) there is sufficient manpower to perform the action.

HR-I1                          -----------------           No objection                 ----------------------------

4.5.6 - DA 4.5.6.1                                                    No objection Table 4.5.6-1                  -----------------           No objection                 ----------------------------

Tables 4.5.6-2(a) thru 4.5.6-2(e) 32

Table A-1              Staff Position on ASME RA-S-2002 Index No                    Issue                    Position                        Resolution DA-A1,                   -----------------           No objection               ----------------------------

A2,A3 DA-B1,B2                  -----------------           No objection               ----------------------------

DA-C1,                   -----------------           No objection               ----------------------------

C2,C3,C4,C5, C6,C7, C8,C9, C10,C11, C12,C13, C15 DA-C14        This SR, which provides a               Qualification "IDENTIFY instances of plant-specific justification for crediting                           component repair from both plant-specific and equipment repair, assumes plant-                     industry experience and for each repair, specific data will be sufficient to                   COLLECT...."

justify this credit. For such components as pump repair, plant-specific data is insufficient and a broader base is necessary.

DA-D2, D4,               -----------------           No objection               ----------------------------

D6, D7 DA-D1        For Cat I, as written, the             Clarification  Cat I: "USE plant-specific parameter estimates requirements are not practical in                    for events modeling the unique design or that they are difficult if not                        operational features if available, or use generic impossible to meet. If the feature                    information modified as discussed in DA-D2; is unique, there may be little to no                  USE with generic information for the remaining plant-specific data.                                  events."

For Cat II and III, as written,                       Cat II: "CALCULATE realistic parameter requirements appear to be                            estimates for dominant contributors; if sufficient inconsistent with Table 1.3-1 and                    plant-specific data is not available, use a IE-C2                                                Bayesian update process of generic industry data. CHOOSE prior distributions as either non-informative, or representative of variability in industry data. CALCULATE parameter estimates for the remaining events by using generic industry data."

Cat III: "CALCULATE realistic parameter estimates; if sufficient plant-specific data is not available, use a Bayesian update process of generic industry data. CHOOSE prior distributions as either non-informative, or representative of variability in industry data."