Difference between revisions of "Detailed Fire Modeling (Task 11)"

Task Overview

Background

This task describes the method to examine the consequences of a fire. This includes consideration of scenarios involving single compartments, multiple fire compartments, and the main control room. Factors considered include initial fire characteristics, fire growth in a fire compartment or across fire compartments, detection and suppression, electrical raceway fire barrier systems, and damage from heat and smoke. Special consideration is given to turbine generator (T/G) fires, hydrogen fires, high-energy arcing faults, cable fires, and main control board (MCB) fires. There are considerable improvements in the method for this task over the EPRI FIVE and EPRI's Fire PRA Implementation Guide (TR‑105928, no longer available on epri.com) in nearly all technical areas.

Purpose

In the preceding tasks, the analyses were organized around compartments, assuming that a fire would have widespread impact within the compartment. In Task 11, for those compartments found to be potentially risk-significant (i.e., unscreened compartments), a detailed analysis approach is provided. As part of the detailed analysis, fire growth and propagation is modeled and possibility of fire suppression before damage to a specific target set is analyzed.

The detailed fire modeling process generally follows a common step structure, but the details of the analyses often vary depending on the specifics of the postulated fire scenario. This task provides separate procedures for three general categories of fire scenarios: fires affecting target sets located inside one compartment (discussed in Section 11.5.1); fires affecting the main control room (MCR; Section 11.5.2); and fires affecting target sets located in more than one fire compartment (multicompartment fire analysis; Section 11.5.3).

Task 11 provides final estimates for the frequency of occurrence of fire scenarios involving a specific fire ignition source failing a predefined target set before fire protection succeeds in protecting the target set. This result is combined in the final quantification steps that follow this task, with the CCDP/CLERP given failure of the target set to estimate the CDF/LERF contribution for each fire scenario. The CCDP/CLERP may include modified human error probabilities based on fire scenario specifics.

Scope

Detailed fire modeling encompasses an analysis of the physical fire behavior (i.e., fire growth and propagation analysis), equipment damage, fire detection, and fire suppression. The fire scenarios to analyze as part of this detailed analysis task are divided into three categories:

• General single compartment fire scenarios. This general category covers fire scenarios damaging target sets located within the same compartment, exclusive of those scenarios within or impacting the MCR. In general, in this category, the fire ignition source is in the same compartment as the target set. The majority of fire scenarios analyzed generally falls into this category. The procedures applicable to the analysis of these fire scenarios are presented in Section 11.5.1.
• MCR fire scenarios. This general category covers all fires that occur within the MCR. This category also covers scenarios involving fires in compartments other than the MCR that may force MCR abandonment. The MCR analysis procedures are presented in Section 11.5.2.
• Multicompartment fire scenarios: This general category covers all fire scenarios where it is postulated that a fire may spread from one compartment to another and damage target elements in multiple compartments. In this category of scenarios, damaging effects of a fire (e.g., heat) are assumed to spread beyond the compartment of fire origin. The multicompartment fire analysis procedures are presented in Section 11.5.3.

A detailed fire modeling analysis is performed for each fire scenario in each unscreened fire compartment. For many compartments, it may be appropriate to develop several fire scenarios to appropriately represent the range of unscreened fire ignition sources (i.e., scenarios that would not screen out in Task 8) that might contribute to the fire risk. Detailed fire modeling may utilize a range of tools to assess fire growth and damage behavior, and the fire detection and suppression response, for specific fire scenarios.

The ultimate output of Task 11 is a set of fire scenarios, frequency of occurrence of those scenarios, and a list of target sets (in terms of fire PRA components) associated with the scenarios. For scenarios involving the MCR, the possibility of forced abandonment is also noted. Note that a fire scenario represents a specific chain of events starting with ignition of a fire ignition source, propagation of the fire effects to other items, and possibility of damaging a set of items identified as a target set before successful fire suppression.

Related Element of ASME/ANS PRA Standard

Fire Scenario Selection (FSS)

Related EPRI 1011989 NUREG/CR‑6850 Appendices

Appendix E, Appendix for Chapters 8 and 11, Severity Factors

Appendix F, Appendix for Chapter 8, Walkdown Forms

Appendix G, Appendix for Chapters 8 and 11, Heat Release Rates

Appendix H, Appendix for Chapters 8 and 11, Damage Criteria

Appendix L, Appendix for Chapter 11, Main Control Board Fires

Appendix M, Appendix for Chapter 11, High Energy Arcing Faults

Appendix N, Appendix for Chapter 11, Hydrogen Fires

Appendix O, Appendix for Chapter 11, Turbine Generator Fires

Appendix P, Appendix for Chapter 11, Detection and Suppression Analysis

Appendix Q, Appendix for Chapter 11, Passive Fire Protection Features

Appendix R, Appendix for Chapter 11, Cable Fires

Appendix S, Appendix for Chapter 11, Fire Propagation to Adjacent Cabinets

Appendix T, Appendix for Chapter 11, Smoke Damage

Fire Modeling Tools

Fire modeling tools include a range of complexity, from Excel-based tools which rely on physics-based algebraic relationships such as EPRI FIVE and the NRC FDT^s, to moderately complex tools such as CFAST's two-zone computational model, up to the most complex (and computationally-demanding) finite element analysis tools such as FDS.

Fire Model Verification and Validation

NUREG‑1824 EPRI 1011999 documents the verification and validation (V&V) of five fire models that are commonly used in NPP applications. The models in the V&V report include:

• NRC's NUREG‑1805 Revision 1
• EPRI's Fire-Induced Vulnerability Evaluation Revision 1 (FIVE-REV 1)
• National Institute of Standards and Technology's (NIST) Consolidated Model of Fire Growth and Smoke Transport (CFAST) Version 5
• NIST's Fire Dynamics Simulator (FDS) Version 4
• Electricite de France's (EdF) MAGIC Version 4.1.1

NUREG‑1824 Supplement 1 EPRI 3002002182 updates the original NUREG‑1824 / EPRI 1011999 report with additional experiments and uses the latest versions of the fire modeling software available at the time of publication. The models in the V&V report include:

• NRC's Fire Dynamics Tools (FDT^s Version 1805.1)
• EPRI's Fire-Induced Vulnerability Evaluation (FIVE Revision 2)
• NIST's CFAST Version 7.0.0
• EdF's MAGIC Version 4.1.3
• NIST's FDS Version 6.2.0

Fire Models Included in V&V Guidance

EPRI FIVE

NRC Fire Dynamics Tools - NUREG‑1805

NIST CFAST

NIST FDS and Smokeview

EdF's MAGIC is available through EPRI for EPRI members

Fire Model User's Guide

NUREG‑1934 EPRI 1023259 provides guidance on the proper application of fire models to nuclear power plant fire scenarios. Eight (8) different example fire scenarios are developed and discussed in this report.

Ignition Source Specific Fire Modeling Guidance

Recommended HRR Values

The following tables summarize the latest research on HRR probability distributions. These distributions were developed to increase realism in modeling electrical cabinet fires and transient fires. As such, HRR probability distributions available in earlier publications (such as Appendix G of NUREG/CR-6850) are bounding. In the case of electric motors and transformers, the latest HRR probability distributions are based on equipment sizes so that the fires can also be realistically characterized.

Electrical Cabinets (NUREG‑2178 Volume 1)

NUREG‑2178 Volume 1 / EPRI 3002005578 provides HRR distributions for electrical enclosures.

Electrical Enclosures

Enclosure Class / Function Group	Enclosure Ventilation (Open or Closed Doors)	Fuel Type† (TS/QTP/SIS or TP Cables)	Gamma Distribution
			(a) Default				(b) Low Fuel Loading				(c) Very Low Fuel Loading
			α	β	P75 (kW)	P98 (kW)	α	β	P75 (kW)	P98 (kW)	α	β	P75 (kW)	P98 (kW)
1 - Switchgear and Load Centers	Closed	TS/QTP/SIS	0.32	79	30	170	Not Applicable				Not Applicable
	Closed	TP	0.99	44	60	170
2 - MCCs and Battery Chargers	Closed	TS/QTP/SIS	0.36	57	25	130	Not Applicable				Not Applicable
	Closed	TP	1.21	30	50	130
3 - Power Inverters	Closed	TS/QTP/SIS	0.23	111	25	200	Not Applicable				Not Applicable
	Closed	TP	0.52	73	50	200
4a - Large Enclosures     >1.42 m3 (>50 ft3)	Closed	TS/QTP/SIS	0.23	223	50	400	0.23	111	25	200	0.38	32	15	75
	Closed	TP	0.52	145	100	400	0.52	73	50	200	0.88	21	25	75
	Open	TS/QTP/SIS	0.26	365	100	700	0.26	182	50	350	0.38	32	15	75
	Open	TP	0.38	428	200	1000	0.38	214	100	500	0.88	21	25	75
4b - Medium Enclosures     ≤1.42 m3 (50 ft3) and     > 0.34 m3 (12 ft3)	Closed	TS/QTP/SIS	0.23	111	25	200	0.27	51	15	100	0.88	12	15	45
	Closed	TP	0.52	73	50	200	0.52	36	25	100	0.88	12	15	45
	Open	TS/QTP/SIS	0.23	182	40	325	0.19	92	15	150	0.88	12	15	45
	Open	TP	0.51	119	80	325	0.3	72	25	150	0.88	12	15	45
4c - Small Enclosures     ≤ 0.34 m3 (12 ft3)	Not Applicable	All	0.88	12	15	45	Not Applicable				Not Applicable
† Legend for Fuel Type: TS = Thermoset, TP = Thermoplastic, QTP = Qualified Thermoplastic, SIS = Synthetic Insulated Switchboard Wire or XLPE-Insulated Conductor

Motors and Dry Transformers (NUREG‑2178 Volume 2)

NUREG‑2178 Volume 2 / EPRI 3002016052 provides HRR distributions for motors and dry transformers.

Motors

Motor Classification Group	Motor Size (horsepower)	Gamma Distribution
		α	β	P75 (kW)	P98 (kW)
A	>5-30	1.34	3.26	6	15
B	>30-100	1.17	8.69	14	37
C	>100	1.10	24.19	37	100

Dry Transformers

Transformer Classification Group	Transformer Power (kVA)	Gamma Distribution
		α	β	P75 (kW)	P98 (kW)
A	>45-75	0.38	12.84	6	30
B	>75-750	0.41	28.57	15	70
C	>750	0.46	50.26	30	130

Transients (NUREG‑2233)

NUREG‑2233 / EPRI 3002018231 provides HRR distributions for both generic and "transient combustible control location" (TCCL) type transient fires. The report also provides values for total energy release (TER) and zones of influence (ZOIs), but only HRRs are included here.

Transients

Type	Gamma Distribution
	α	β	P75 (kW)	P98 (kW)
Generic	0.271	141	41.6	278
TCCL	0.314	67.3	24.6	143

Additional Fire Modeling Considerations

Time-to-Damage Models for Cables

Three approaches are documented for assessing the time-to-damage for cables.

Location Factor

When the fire is located near a wall or in a corner, less air can be entrained into the fire plume. Less air entrainment into the fire plume produces higher plume temperatures. The flames from fires in contact with wall and corner surfaces tend to be longer, also resulting in higher plume temperatures. For such fires, a location factor, traditionally 2 for fires near a wall or 4 for fires near a corner, has been applied as a correction to the plume temperature calculation. NUREG‑2178 Volume 2 / EPRI 3002016052 Section 6 demonstrates that the traditional approach is overly conservative, and presents new factors based on the distance from the source to a corner or wall:

Configuration	Location Factor
	0–0.3 m [0–1 ft]	0.3–0.6 m [1–2 ft]	>0.6 m [2 ft]
Corner	4	2	1
Wall	1	1	1

EPRI 3002005303 provides the technical basis for the work in NUREG‑2178 Volume 2.

Radiation effects modeling

Chapter 2 of NUREG‑2178 Volume 2 / EPRI 3002016052 evaluates radiation emission models used to assess horizontal zone of influence. The two commonly-implemented empirical models – the point source method and the solid flame method – are compared against a computational model (Fire Dynamics Simulator). The results of this chapter recommended that the adjusted solid flame model should generally be considered a preferred method over the point source method because the adjusted flame model shows somewhat better characteristics in terms of a) NOT under-predicting and b) improved statistical error and bias. This applies to all fire types, where the flame is unobstructed. The modeling of obstructed radiation circumstances as present in electrical cabinets is discussed in the context of Bin 15 electrical cabinet fire modeling.

High Energy Arcing Fault (HEAF) Research

EPRI and the NRC are currently developing further methods and data on the risk impact of HEAF events; for example frequencies, fault duration, and zone of influence (e.g., copper versus aluminum). EPRI has issued the following white paper reports:

• EPRI 3002015992 provides an overview of nuclear power station electrical distribution systems and covers fault protection system concepts, fault isolation times, the potential impact of HEAFs on Class 1E electrical distribution systems, and typical industry practices and programs that help ensure proper operation. This report also provides some preliminary risk insights based on a review of existing data.
• EPRI 3002011922 reviews the operating experience to gain insights about equipment type, event characteristics, and the range of damage for HEAF events occurring at nuclear power plants within the United States and internationally. This paper also explores recent U.S. and international HEAF test programs for low- and medium-voltage electrical equipment and summarizes the insights gained from these test programs, including the potential role of aluminum oxidation in HEAF severity.
• EPRI 3002015459 demonstrates that an effective preventive maintenance program is important in minimizing the likelihood and/or severity of a HEAF event. Sixty‑four percent (64%) of HEAF events were determined to be preventable, and the most prevalent cause of failure was inadequate maintenance. These data demonstrate that proper maintenance can prevent most HEAF events. Effective maintenance practices and strategies are summarized in this report by equipment type, including circuit breakers, bus ducts, protective relays, and cables.

Fire Propagation and Suppression Guidance

Detection-Suppression Event Tree

For electrical cabinet fires, Section 5 of NUREG‑2230 / EPRI 3002016051 presents a revised detection-suppression event tree model for characterizing fire detection and suppression activities in response to a fire event (revised compared with the original model described in Appendix P of NUREG/CR‑6850 and Chapter 14 of NUREG/CR‑6850 Supplement 1). This modification is intended to capture the potential for plant personnel suppression during the early stages of an electrical cabinet fire. For other fire types, the original model described in Appendix P of NUREG/CR‑6850 and Chapter 14 of NUREG/CR‑6850 Supplement 1 should be used.

Fire Damage Criteria

Cable Tray Fire Propagation

FAQ 08‑0049, Section 11 of Supplement 1 clarifies the limits of the empirical cable tray fire propagation model in EPRI 1011989, NUREG/CR‑6850. The model can lead to conservative estimates of cable fire growth rates and unrealistically short room burnout times when used outside the ZOI (i.e., outside the fire plume that extends above the ignition source).

NUREG/CR‑7010 documents the results of experiments to better understand and quantify the burning characteristics of grouped electrical cables commonly found in nuclear power plants. Volume 1 studies horizontal cable trays and Volume 2 studies vertical shafts and corridors. The experiments in Volume 1 address horizontal, ladder-back trays filled with unshielded cables in open configurations. The results of the full-scale experiments have been used to validate a simple model called FLASH‑CAT (Flame Spread over Horizontal Cable Trays). The document also provides verification and validation material for the FLASH‑CAT model. Volume 2 performed experiments on vertical cable tray configurations and enclosure effects. Volume 2 also extends the FLASH‑CAT model to address cable trays within enclosures and vertical tray configurations.

Manual Non-Suppression Probability Estimates

Various reports have documented updates to the manual non-suppression probability data. The latest updates for each event type are summarized below.

Incipient Detection

NUREG‑2180 NRC guidance on crediting incipient detection systems in fire PRA is discussed in NUREG‑2180. The issuance of NUREG‑2180 retires FAQ 08‑0046 (Chapter 13 of NUREG/CR‑6850 Supplement 1) as documented in the July 1, 2016 letter to NEI.