Quantitative Risk Assessment Approach to a Dynamic Safety Evaluation: Skikda’s Coastal City Liquefied Gas Plant

Concerns about the risk of catastrophic accidents have prompted governments and industries to develop new methods for identifying and evaluating potential hazards. The most promising strategy involves assembling a collection of quantitative risk assessment techniques (QRA). The use of (QRA) is rapid...

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Veröffentlicht in:	International journal of performability engineering 2023, Vol.19 (1), p.10
Hauptverfasser:	Abderraouf, Bouafia, Mohammed, Bougofa, Mohamed Salah, Medjra, Ahmed, Mebarki
Format:	Artikel
Sprache:	eng
Schlagworte:	Accidents Damage Evaluation Extreme values Fire hazards Hazard identification Hazards Health risk assessment Industrial plants Industrial safety Liquefied natural gas Overpressure Probabilistic risk assessment Statistical analysis
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container_title	International journal of performability engineering
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creator	Abderraouf, Bouafia Mohammed, Bougofa Mohamed Salah, Medjra Ahmed, Mebarki
description	Concerns about the risk of catastrophic accidents have prompted governments and industries to develop new methods for identifying and evaluating potential hazards. The most promising strategy involves assembling a collection of quantitative risk assessment techniques (QRA). The use of (QRA) is rapidly spreading across industries, having been adapted primarily from probabilistic risk assessment approaches developed in other industries. The Netherlands Organization (TNO) developed the (QRA) for the external safety of industrial plants against fire and explosion hazards. Escalation of primary events that trigger accidental scenarios may have a significant impact on industrial risk, increasing the overall expected frequency of single scenarios and resulting in extremely severe damages involving multiple plant units simultaneously. The present study applied a methodology developed for quantifying the risk of liquefied natural gas (LNG) containment loss. To begin, an industrial facility is separated into modules based on its structural characteristics. Following that, the relevant fire and explosion scenarios are identified, along with their frequency of occurrence. Recently developed equipment damage probability models were used to determine the probability of the final scenario occurring. SAFETI software was used to model and calculate risks. Finally, the individual risks (thermal and overpressure exceedance curves) are calculated, as well as the societal risk (FN curve). The findings demonstrate the critical importance of quantitative risk assessment in identifying critical equipment and addressing prevention and protection measures.
doi_str_mv	10.23940/ijpe.23.01.p2.1019
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subjects	Accidents Damage Evaluation Extreme values Fire hazards Hazard identification Hazards Health risk assessment Industrial plants Industrial safety Liquefied natural gas Overpressure Probabilistic risk assessment Statistical analysis
title	Quantitative Risk Assessment Approach to a Dynamic Safety Evaluation: Skikda’s Coastal City Liquefied Gas Plant
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