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Citation |
Moscatello A, Ledda G, Uggenti AC, Gerboni R, Carpignano A. Safety (Basel) 2022; 8(4): e80. |
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Copyright |
(Copyright © 2022, MDPI: Multidisciplinary Digital Publishing Institute) |
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DOI |
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PMID |
unavailable |
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Abstract |
Complex installations that involve dangerous substances, such as oil and gas or nuclear plants, must mandatorily undergo a quantitative risk assessment (QRA) according to current regulations. This requires, among others, the simulation of hundreds of accidental scenarios, which are typically carried out using empirical tools due to their fast response. Nonetheless, since they are not able to guarantee sufficient accuracy, especially when complex geometries are involved, computational fluid dynamics (CFD) tools are increasingly used. In this work, a high-pressure accidental release of a sour gas (CH4-H2S) in an offshore platform under several wind conditions is considered. A methodology used to perform a wind sensitivity analysis via CFD, while avoiding high computational costs, is presented. The wind intensity impact on some risk-related figures of merit, such as the high lethality or irreversible injuries areas, is discussed in relation to the flammability and toxicity limits of the released mixture. The results show that even a very low amount of H2S in the released mixture can strongly affect the threat zones. A progressive decrease in the toxic and flammable volumes in the platform is observed as the wind velocity increases; nonetheless, a saturation effect appears in high wind speed scenarios. Language: en |
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Keywords |
computational fluid dynamics (CFD); gas release; hydrogen sulfide; risk; safety; wind intensity |