Experimental study on thermal safety analysis of flexible polyurethane at various facade inclined structures under low ambient pressure condition

•Morphological analysis of flame spreading behavior of flexible polyurethane were provided.•Global burning rate was illustrated by theory of effect pressure and pool fire.•The influence of pressure on flame height and temperatures was studied theoretically.•Pressure effects on upward flame spread be...

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Bibliographic Details
Published in:Engineering structures 2018-12, Vol.176, p.11-19
Main Authors: Ma, Xin, Tu, Ran, Ding, Chao, Zeng, Yi, Xu, Li, Fang, Tingyong
Format: Article
Language:English
Subjects:
Atmospheric pressure
Burning
Burning characteristics
Burning rate
Combustion
Construction materials
Energy conservation
Experiments
Flame temperature
Flexible polyurethane
Heat transfer
Inclination angle
Insulation
Low air pressure
Morphology
Polyurethane
Polyurethane resins
Pressure effects
Progressions
Pyrolysis
Spreading
Temperature
Velocity
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Summary:•Morphological analysis of flame spreading behavior of flexible polyurethane were provided.•Global burning rate was illustrated by theory of effect pressure and pool fire.•The influence of pressure on flame height and temperatures was studied theoretically.•Pressure effects on upward flame spread behavior were interpreted in heat transfer mechanism. Experimental and theoretical investigations are conducted to analyze the influences of low atmospheric pressure on burning behavior of building facade insulation material flexible polyurethane (FPU). Comparison experiments for downward flame spread process over FPU under various facade inclined structures were performed at Hefei (99.8 kPa) and Lhasa (66.5 kPa), respectively. Characteristic parameters including burning rate (i.e. mass loss rate), flame spread velocity and flame height were studied in this paper. Firstly, morphological experimental results exhibited that the combustion was slower in reduced pressure condition and wider specimens showed more gradual flame spreading. Secondly, an inverted V-shaped spreading pyrolysis front was observed, and a “two-terminal” combustion behavior was found for narrow FPU board by partial molten flow combustion, which is critical to practical fire rescue techniques. Thirdly, power-law progressions of burning rate vs. pressure was proposed with an exponent ranging from 0.61 to 1.39, which can be illustrated by utilizing classical theory for sub-atmospheric pressure pool fire. Further, the increasing facade inclination angle significantly enhanced the flame spreading velocity, which suppressed the effect of pressure at high inclination angles. The flame temperature was measured to be increased at the lower pressure causing faster flame puffing. Finally, a linear relationship was determined between the pressure index values obtained by flame height vs. pressure and the inclination angle.
ISSN:0141-0296
1873-7323
DOI:10.1016/j.engstruct.2018.08.106