Diverse analytical models and empirical correlations for calculating
the geometry and thermal radiation characteristics of large hydrocarbon
pool fires were examined. The radiation characteristics of liquefied
natural gas, liquefied petroleum gas, gasoline, and other hydrocarbon
fires were stressed. Also covered were the limitations of currently
available models, the thermal radiation damage to exposed human skin,
and the criteria for determining thermal radiation hazards. It was
concluded that the analysis and correlation results could be used
as a sequential algorithm for the evaluation of thermal radiation
hazards produced by hydrocarbon pool fires.
%0 Journal Article
%1 Mudan:1984
%A Mudan, K. S.
%D 1984
%J Progress in Energy and Combustion Science
%K and burning combustion; damage; fire flame flow geometry; hazard; hazards; hydrocarbon liquids; organic propagation; properties radiation radiation; rate; safety thermal thermochemical toxicity
%P 59--80
%R 10.1016/0360-1285(84)90119-9
%T Thermal radiation hazards from hydrocarbon pool fires
%V 10
%X Diverse analytical models and empirical correlations for calculating
the geometry and thermal radiation characteristics of large hydrocarbon
pool fires were examined. The radiation characteristics of liquefied
natural gas, liquefied petroleum gas, gasoline, and other hydrocarbon
fires were stressed. Also covered were the limitations of currently
available models, the thermal radiation damage to exposed human skin,
and the criteria for determining thermal radiation hazards. It was
concluded that the analysis and correlation results could be used
as a sequential algorithm for the evaluation of thermal radiation
hazards produced by hydrocarbon pool fires.
@article{Mudan:1984,
abstract = {Diverse analytical models and empirical correlations for calculating
the geometry and thermal radiation characteristics of large hydrocarbon
pool fires were examined. The radiation characteristics of liquefied
natural gas, liquefied petroleum gas, gasoline, and other hydrocarbon
fires were stressed. Also covered were the limitations of currently
available models, the thermal radiation damage to exposed human skin,
and the criteria for determining thermal radiation hazards. It was
concluded that the analysis and correlation results could be used
as a sequential algorithm for the evaluation of thermal radiation
hazards produced by hydrocarbon pool fires.},
added-at = {2010-01-05T23:12:10.000+0100},
author = {Mudan, K. S.},
biburl = {https://www.bibsonomy.org/bibtex/21c2b8e926e8bac296ce5c61e35883018/sjp},
citeulike-article-id = {2310018},
doi = {10.1016/0360-1285(84)90119-9},
interhash = {c7d68d1c9ab36321771f0821f2ff081a},
intrahash = {1c2b8e926e8bac296ce5c61e35883018},
journal = {Progress in Energy and Combustion Science},
keywords = {and burning combustion; damage; fire flame flow geometry; hazard; hazards; hydrocarbon liquids; organic propagation; properties radiation radiation; rate; safety thermal thermochemical toxicity},
pages = {59--80},
priority = {2},
timestamp = {2010-01-19T17:39:44.000+0100},
title = {Thermal radiation hazards from hydrocarbon pool fires},
volume = 10,
year = 1984
}