Comparison of Pyrolysis Behavior Results between the Cone Calorimeter and the Fire Propagation Apparatus Heat Sources

Girods, Pierre; Bal, Hamdi; Biteau, Hubert; Rein, Guillermo; Torero, José L.

doi:10.3801/iafss.fss.10-889

Cited by 25 publications

(9 citation statements)

References 14 publications

(29 reference statements)

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“…Bal and Rein extended the work of Jiang et al to consider the possibility of other parameters affecting the ignition time at high flux but again showed that it is influenced mainly by in‐depth absorption. In a related work, differences in the pyrolysis behavior induced by a cone heater or the FM Global Fire Propagation Apparatus (FPA) are discussed .…”

Section: Introductionmentioning

confidence: 99%

Absorption and reflection of infrared radiation by polymers in fire‐like environments

et al. 2011

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SUMMARY In large‐scale fires, the input of energy to burning materials occurs predominantly by radiative transfer. The in‐depth (rather than just surface) absorption of radiant energy by a polymer influences its ignition time and burning rate. The present investigation examines two methods for obtaining the absorption coefficient of polymers for infrared radiation from high‐temperature sources: a broadband method and a spectral method. Data on the total average broadband transmittance for 11 thermoplastics are presented (as are reflectance data), and the absorption coefficient is found to vary with thickness. Implications for modeling of mass loss experiments are discussed. Copyright © 2011 John Wiley & Sons, Ltd.

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Section: Introductionmentioning

confidence: 99%

Absorption and reflection of infrared radiation by polymers in fire‐like environments

et al. 2011

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“…For irradiance values lower than 50 kW.m −2 , the decomposition and charring of the condensed phase occur without any type of sustained flaming combustion. Therefore, the heating of the material and its reaction rate are only controlled by the intensity level of the radiant heat source . It seems natural that when the imposed irradiance level at the surface of the material is reduced, the amount of energy received and thus the temperature rise will be lower on the surface and in depth.…”

Section: Resultsmentioning

confidence: 99%

Effects of reduced oxygen environment on the reaction to fire of a poly(urethane‐isocyanurate) foam

2016

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Summary Thanks to their thermal insulation properties, rigid polyisocyanurate foams are commonly used in the modern built environment, as well as in transportation and industrial applications. However, the fire behaviour of this kind of foam remains one of the most limiting factors for their wider use as insulation material in some sectors. Indeed, this type of material is thermally and chemically reactive. The general scope of this study is to investigate the effects of a reduced oxygen atmosphere on the reaction to fire of flame‐retardant polyisocyanurate foam. This paper reports the results of an experimental campaign, which was performed using a controlled‐atmosphere cone calorimeter, coupled to a Fourier transform infrared spectrophotometer. The dependence of the results on both oxygen concentration and irradiance level is presented and discussed. The chemical compositions of the identified gaseous products were qualified and quantified during both the decomposition and the combustion processes. Copyright © 2016 John Wiley & Sons, Ltd.

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“…This function is minimal at the surface Y F,s (0, t ). The in‐depth degradation depends on the spectral characteristic of the heat source, the radiative properties of the polymer and more particularly on its emissivity and on its transmissivity, defined on Figure by the absorption coefficient κ( x , t ) . Generally the emission spectra of large flame are continuous in the infrared.…”

Section: Fire Behaviour At Materials Scalementioning

confidence: 99%

Modelling decomposition and fire behaviour of small samples of a glass‐fibre‐reinforced polyester/balsa‐cored sandwich material

et al. 2012

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This publication presents the experimental and numerical methods to model the devolatilization process of a glass‐fibre‐reinforced polyester/balsa‐cored sandwich material on small scale. The fundamental modelling of the source term in pyrolysis‐based fire simulations requires as input data the thermochemical properties of solid fuel and the kinetic parameters of the devolatilization process. First, the thermal decomposition of both elements composing the sandwich structure was studied by thermogravimetry coupled with gas analysis, in air and pure nitrogen atmospheres at several heating rates, in order to define a comprehensive multi‐step reaction pathway. A differential equation system is defined to model these decomposition processes. The kinetic parameters were then estimated by solving the system of equations by an inverse problem. Second, the fire behaviour of each element was studied separately and then combined in the sandwich structure on the cone calorimeter. In addition, numerical simulations with Fire Dynamics Simulator were performed to gradually assess the ability of the model(s) to reproduce each element composing the sandwich structure. Numerical and experimental results are compared and then discussed. Overall, the model provides a good agreement with the experimental data and encourages to model higher scales. Copyright © 2012 John Wiley & Sons, Ltd.

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Comparison of Pyrolysis Behavior Results between the Cone Calorimeter and the Fire Propagation Apparatus Heat Sources

Cited by 25 publications

References 14 publications

Absorption and reflection of infrared radiation by polymers in fire‐like environments

Absorption and reflection of infrared radiation by polymers in fire‐like environments

Effects of reduced oxygen environment on the reaction to fire of a poly(urethane‐isocyanurate) foam

Modelling decomposition and fire behaviour of small samples of a glass‐fibre‐reinforced polyester/balsa‐cored sandwich material

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