Resilience-based optimal firefighting to prevent domino effects in process plants

Salvatore Cincotta; N. Khakzad; Valerio Cozzani; Genserik Reniers

doi:10.1016/j.jlp.2019.02.004

Resilience-based optimal firefighting to prevent domino effects in process plants

Salvatore Cincotta, N. Khakzad, Valerio Cozzani, Genserik Reniers

Safety and Security Science

Research output: Contribution to journal › Article › Scientific › peer-review

26 Citations (Scopus)

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Abstract

Domino effects triggered by fire can cause extremely severe damages to the chemical and process plants. In the need of a more effective prevention of fire domino effects, the present study focuses on firefighting which has received less attention compared to passive and active fire protection systems. Considering both the vulnerability and recoverability phases during fire domino effects, we have introduced a methodology for optimal identification of firefighting strategies so as to increase the resiliency of process plants in dealing with fire escalation scenarios. The area above the resilience curve (AARC), which is equal to the accumulation of loss of resilience over time, was considered as the metric to identify the optimal firefighting strategies. In other words, the strategy leading to the lowest AARC can be selected as the optimal strategy from a resiliency perspective

Original language	English
Pages (from-to)	82-89
Number of pages	8
Journal	Journal of Loss Prevention in the Process Industries
Volume	58
DOIs	https://doi.org/10.1016/j.jlp.2019.02.004
Publication status	Published - 2019

Keywords

Bayesian network
Domino effect
Firefighting
Optimization
Resilience

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10.1016/j.jlp.2019.02.004

Manuscript_for productionAccepted author manuscript, 803 KBLicence: CC BY-NC-ND

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title = "Resilience-based optimal firefighting to prevent domino effects in process plants",

abstract = "Domino effects triggered by fire can cause extremely severe damages to the chemical and process plants. In the need of a more effective prevention of fire domino effects, the present study focuses on firefighting which has received less attention compared to passive and active fire protection systems. Considering both the vulnerability and recoverability phases during fire domino effects, we have introduced a methodology for optimal identification of firefighting strategies so as to increase the resiliency of process plants in dealing with fire escalation scenarios. The area above the resilience curve (AARC), which is equal to the accumulation of loss of resilience over time, was considered as the metric to identify the optimal firefighting strategies. In other words, the strategy leading to the lowest AARC can be selected as the optimal strategy from a resiliency perspective",

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T1 - Resilience-based optimal firefighting to prevent domino effects in process plants

AU - Cincotta, Salvatore

AU - Khakzad, N.

AU - Cozzani, Valerio

AU - Reniers, Genserik

PY - 2019

Y1 - 2019

N2 - Domino effects triggered by fire can cause extremely severe damages to the chemical and process plants. In the need of a more effective prevention of fire domino effects, the present study focuses on firefighting which has received less attention compared to passive and active fire protection systems. Considering both the vulnerability and recoverability phases during fire domino effects, we have introduced a methodology for optimal identification of firefighting strategies so as to increase the resiliency of process plants in dealing with fire escalation scenarios. The area above the resilience curve (AARC), which is equal to the accumulation of loss of resilience over time, was considered as the metric to identify the optimal firefighting strategies. In other words, the strategy leading to the lowest AARC can be selected as the optimal strategy from a resiliency perspective

AB - Domino effects triggered by fire can cause extremely severe damages to the chemical and process plants. In the need of a more effective prevention of fire domino effects, the present study focuses on firefighting which has received less attention compared to passive and active fire protection systems. Considering both the vulnerability and recoverability phases during fire domino effects, we have introduced a methodology for optimal identification of firefighting strategies so as to increase the resiliency of process plants in dealing with fire escalation scenarios. The area above the resilience curve (AARC), which is equal to the accumulation of loss of resilience over time, was considered as the metric to identify the optimal firefighting strategies. In other words, the strategy leading to the lowest AARC can be selected as the optimal strategy from a resiliency perspective

KW - Bayesian network

KW - Domino effect

KW - Firefighting

KW - Optimization

KW - Resilience

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DO - 10.1016/j.jlp.2019.02.004

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JO - Journal of Loss Prevention in the Process Industries

JF - Journal of Loss Prevention in the Process Industries

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Resilience-based optimal firefighting to prevent domino effects in process plants

Abstract

Keywords

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