Flame temperature distribution from ISO2685 standard propane-air burner using CFD
This analysis considers the computational simulations of the temperature distribution of a propane-air customary flame combusted from an aeronautical fire-certification set according to the ISO2685standard. The numerical codes have been executed in Computational Fluid Dyanmics using the k-ω SST turb...
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my.uniten.dspace-64262020-09-10T03:34:03Z Flame temperature distribution from ISO2685 standard propane-air burner using CFD Bheekhun, N. Abu Talib, A.R. Hasini, H. Hassan, M.R. This analysis considers the computational simulations of the temperature distribution of a propane-air customary flame combusted from an aeronautical fire-certification set according to the ISO2685standard. The numerical codes have been executed in Computational Fluid Dyanmics using the k-ω SST turbulence model coupled with eddy-dissipation. The result shows that the maximum predicted temperature using the standard flame settings exceeds the required temperature for evaluation of a fire-resistive material. The mole fractions of the by-products, carbon dioxide and water have also been predicted. © (2014) Trans Tech Publications, Switzerland. 2017-12-08T09:39:32Z 2017-12-08T09:39:32Z 2014 http://dspace.uniten.edu.my/jspui/handle/123456789/6426 |
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This analysis considers the computational simulations of the temperature distribution of a propane-air customary flame combusted from an aeronautical fire-certification set according to the ISO2685standard. The numerical codes have been executed in Computational Fluid Dyanmics using the k-ω SST turbulence model coupled with eddy-dissipation. The result shows that the maximum predicted temperature using the standard flame settings exceeds the required temperature for evaluation of a fire-resistive material. The mole fractions of the by-products, carbon dioxide and water have also been predicted. © (2014) Trans Tech Publications, Switzerland. |
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author |
Bheekhun, N. Abu Talib, A.R. Hasini, H. Hassan, M.R. |
spellingShingle |
Bheekhun, N. Abu Talib, A.R. Hasini, H. Hassan, M.R. Flame temperature distribution from ISO2685 standard propane-air burner using CFD |
author_facet |
Bheekhun, N. Abu Talib, A.R. Hasini, H. Hassan, M.R. |
author_sort |
Bheekhun, N. |
title |
Flame temperature distribution from ISO2685 standard propane-air burner using CFD |
title_short |
Flame temperature distribution from ISO2685 standard propane-air burner using CFD |
title_full |
Flame temperature distribution from ISO2685 standard propane-air burner using CFD |
title_fullStr |
Flame temperature distribution from ISO2685 standard propane-air burner using CFD |
title_full_unstemmed |
Flame temperature distribution from ISO2685 standard propane-air burner using CFD |
title_sort |
flame temperature distribution from iso2685 standard propane-air burner using cfd |
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2017 |
url |
http://dspace.uniten.edu.my/jspui/handle/123456789/6426 |
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1677776757317435392 |
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13.159267 |