Human Reliability Analysis-Based Method for Manual Fire Suppression Analysis in an Integrated Probabilistic Risk Assessment

Sakurahara, Tatsuya; Mohaghegh, Zahra; Kee, Ernie

doi:10.1115/1.4044792

Cited by 4 publications

(2 citation statements)

References 31 publications

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“…As mentioned in Section 3.1, the I-PRA methodological framework ( Figure 11) developed by UIUC integrates simulation models of the underlying human and physical failure mechanisms with the existing plant PRA through a probabilistic interface [28,74]. The dynamic coupling [75,76] between the human performance and the physical failure simulation in I-PRA is similar in its nature to simulation-based PRA (or dynamic PRA).Methods being researched can be applied for advanced reactors and new plants as industry and the regulatory agency deem advantageous, using dynamic with static coupling or fully simulationbased/dynamic PRA. Meanwhile, the Interface Module ('e' in Figure 11) in the I-PRA offers the possibility of reliably using dynamic simulation approaches linked with the existing PRA of aging plants.…”

Section: Time Dependent Scenario Modelingmentioning

confidence: 99%

Risk Importance Ranking of Fire Data Parameters to Enhance Fire PRA Model Realism

Biersdorf

Bui

Sakurahara

et al. 2020

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Fire is historically and analytically a significant contributor to nuclear power plant risk. The level of fire risk and the methods, tools, and data for modeling this risk are highly debated by experts. One area of debate is the input data used in fire modeling and how to deal with this data's high rate of uncertainty. This report outlines work performed for determining the key parameters causing this uncertainty and how it propagates into nuclear power plant PRA models. This research used the Integrated Probabilistic Risk Assessment (I-PRA) method and paves the way to correctly assess and reduce data uncertainty in fire modeling.

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Section: Time Dependent Scenario Modelingmentioning

confidence: 99%

Risk Importance Ranking of Fire Data Parameters to Enhance Fire PRA Model Realism

Biersdorf

Bui

Sakurahara

et al. 2020

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“…In PRA, human reliability (HRA) is commonly performed to account for the human failure events and the impact of performance influencing factors. A number of recent PRA studies have considered human performance under fire scenarios, For example, Bui et al 21 and Sakurahara et al 22 modelled the first responder performance more realistically and considered the interface between the first responder performance and fire propagation more explicitly in a switchgear room of a nuclear power plant. In a similar application, Wang et al 23 and Kloos et al 24…”

Section: Introductionmentioning

confidence: 99%

Incorporation of technical, human and organizational risks in a dynamic probabilistic fire risk model for high‐rise residential buildings

et al. 2020

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While probabilistic risk assessment (PRA) is an explicit methodology for complying with the performance requirements of the Building Code of Australia (BCA) or similar codes, it traditionally focuses only on technical risks of fire safety systems in a building. There are growing concerns that performance-based fire engineering designs underestimate safety risk levels in high-rise residential buildings. Existing fire risk models account for failures of technical systems but ignore human and organizational errors (HOEs) and the complex interactions among these variables. Probabilistic models in other applications, such as offshore platforms and nuclear plants, demonstrate the importance of HOE inclusion in risk models and the resulting impacts on overall risk. This paper proposes a comprehensive technical-human-organizational risk (T-H-O-Risk) methodology to enhance the PRA approach by quantifying human and organizational risks in a probabilistic model using Bayesian Network (BN) analysis of HOEs and System Dynamics (SD) modelling for dynamic characterization of risk variations over time. While risk modelling itself is not novel, the current research develops unique and specific enhancements to existing risk approaches by integrating HOE risks with technical risks in a comprehensive dynamic and probabilistic model for high-rise residential buildings. Three case studies are conducted to demonstrate the application of this comprehensive approach to the designs of various high-rise residential buildings ranging from 18 to 24 storeys. Societal risks are represented in F-N curves. Results show that in general, fire safety designs that do not consider HOEs underestimate overall risks generally by20%-and can reach up to 42% in an extreme case. Furthermore, risks over time due to HOEs vary by as much as 30% over a 10-year period. A sensitivity analysis indicates that deficient training, poor safety culture and ineffective emergency plans have significant impact on overall risk.

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Uncertainty-Based Validation Methodology and Experimental Analysis for External Control Room Human Performance Simulation: Application to Fire Probabilistic Risk Assessment of Nuclear Power Plants

Albati,

Sakurahara,

Reihani

et al. 2024

Nuclear Science and Engineering

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Human Reliability Analysis-Based Method for Manual Fire Suppression Analysis in an Integrated Probabilistic Risk Assessment

Cited by 4 publications

References 31 publications

Risk Importance Ranking of Fire Data Parameters to Enhance Fire PRA Model Realism

Risk Importance Ranking of Fire Data Parameters to Enhance Fire PRA Model Realism

Incorporation of technical, human and organizational risks in a dynamic probabilistic fire risk model for high‐rise residential buildings

Uncertainty-Based Validation Methodology and Experimental Analysis for External Control Room Human Performance Simulation: Application to Fire Probabilistic Risk Assessment of Nuclear Power Plants

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