Thermal modeling for supporting firefighting and emergency response planning

Wan, Bryan; Parker, Trent; Wang, Qingsheng

doi:10.1002/prs.12399

Cited by 1 publication

(2 citation statements)

References 42 publications

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“…In Section 3.2, the distribution of the injury areas above 180°C has been elaborated for 18 scenarios. Another injury criteria based on the probability of injury or death, and the probabilities of having first‐degree burn, second‐degree burn, and death are calculated based on the TDU (D) using Equations and 3–28,32–34 . Exactly 50% fatality and 100% fatality are calculated and compared with the above injury criteria

\begin{matrix} P_{r} = {normalc}_{1} + {normalc}_{2} lnD \end{matrix}

\begin{matrix} P_{i} = F_{k} ∙ \frac{1}{2} [1 + \erf (\frac{P_{r} - 5}{\sqrt{2}})] \end{matrix}

where the probit variable

P_{r}

is adopted to transform the TDU to the probability of injury or death represented as

P_{i}

.…”

Section: Resultsmentioning

confidence: 99%

“…Another injury criteria based on the probability of injury or death, and the probabilities of having first-degree burn, second-degree burn, and death are calculated based on the TDU (D) using Equations 8 and 9. [32][33][34] Exactly 50% fatality and 100% fatality are calculated and compared with the above injury criteria where the probit variable P r is adopted to transform the TDU to the probability of injury or death represented as P i . F k is correction factor and erf is the error function.…”

Section: Comparison Of Different Injury Criteriamentioning

confidence: 99%

See 1 more Smart Citation

Modeling and risk analysis of large‐scale crude oil pool fire on an offshore facility

Wang,

Wang

et al. 2023

Process Safety Progress

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Large‐scale pool fires on offshore platforms can have disastrous consequences. Wind load is an essential component of the marine environment; hence, wind‐shielding facilities are installed on the platforms as needed. A computational fluid dynamics technique is used in this study to model large‐scale pool fires. The effects of wind load and windshields on large‐scale pool fires are investigated. Furthermore, the impact of the large‐scale pool fire on personnel is evaluated based on thermal radiation dose. It has been discovered that the growing horizontal momentum of the wind load might result in a significant distance of fatal injury. The windshields have double‐edged effects, including that: (1) they can reduce the injury distance by preventing the spread of fire products; and (2) they could block the release of heat and smoke. It is advised that while installing windshields on offshore platforms, different fire scenarios need to be considered. This research can be used to provide technical support for the development of the emergency evacuation strategy and layout design of offshore platforms.

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