Numerical modeling of the heat transfer mechanism in intumescent heat- and fire-protection materials

Кузнецов, Г. В.; Рудзинский, В. П.

doi:10.1007/bf02672725

Combust Explos Shock Waves

1998

DOI: 10.1007/bf02672725

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Numerical modeling of the heat transfer mechanism in intumescent heat- and fire-protection materials

Г. В. Кузнецов

В. П. Рудзинский

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Cited by 3 publications

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“…(iv) From the earliest papers on modeling of intumescent coatings by Cagliostro et al [10], researchers [11][12][13][14][15][16][17][18][19] have shown that the amount the coating expands has a major impact on the thermal resistance of the material. However, in modeling the expansion process virtually all researchers resort to using an 'expansion factor' method; an experimentally measured, post-intumescence, coating thickness is used to calculate a factor used to predict the developing thickness of the coating as a function of the coating temperature [3,4,11] or conversion of gas-producing component (or fractional mass loss) in the coating [10,[12][13][14][15][16][17][18][19][20][21][22][23] (The model of Asaro et al [24] went to the extreme of basing the heat transfer calculations on only the post-intumesence thickness, without taking account of the affect of variation in thickness during heating, with consequent poor agreement between theoretical predictions and experimental data.) It has been noted [25] that the use of an expansion factor can produce predictions that do not agree with experimental observations.…”

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The Modeling of Heat Transfer across Intumescent Polymer Coatings

Griffin

2009

Journal of Fire Sciences

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The use of mathematical models to predict the thermal resistance of polymer-based, intumescent coatings are reviewed and their limitations are discussed. A mathematical model is derived to describe the developing temperature profile across an intumescent coating when exposed to a radiant heat source. The model includes the effects of: the endothermic and exothermic reactions; convective heat transfer as degradation gases are transported through the coating; radiation heat transfer across the developing porous solid; and the increase in thermal resistance as gases are formed and the coating expands. The model predictions are compared with experimental data from the heating of epoxy-based and vinyl acetate-based intumescent coatings in a cone calorimeter. A sensitivity analysis is performed to show the effect of the thermal characteristics of the coating on the thermal resistance of the material. The application of the model to newly developed intumescent coatings is discussed.

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“…Figure16. Predicted and experimental data for substrate temperature for coating B in a low oxygen environment.…”

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The Modeling of Heat Transfer across Intumescent Polymer Coatings

Griffin

2009

Journal of Fire Sciences

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Effect of high-temperature gas flow on ignition of the water-coal fuel particles

Саломатов

Кузнецов

Gutareva

2019

Combustion and Flame

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Numerical Analysis of Heat Transfer in Fire-Protective Coatings Deformable upon Heating

Rudzinsky

Гаращенко

2016

EPJ Web of Conferences

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Abstract. Numerical studies of heat transfer in fire-protective coatings deformable (intumescent) upon heating have been conducted. The optimum combination of the computation-scheme parameters providing stability, convergence and satisfactory accuracy of solutions has been determined. An effect of basic characteristics of materials in real range of their change that made it possible to estimate the degree of influence of properties on the fireprotective efficiency of coatings and the level of warm-up (flame resistance) of structures to be protected with them has been studied. The possibility of using developed models and techniques to estimate and provide the required level of fire safety of polymer-based materials (in particular, elastomers and structures and products on their basis) is considered. The results of estimating the mass rate of evolving gaseous thermal-decomposition products that determine, in a considerable extent, the material combustibility have been presented. The numerical analysis results have demonstrated the potentiality of reducing the combustibility of such materials and increasing limits of their fire resistance at the expense of organizing the intumescence of a material upon heating by means of modification of their initial formulations as well as with the aid of an additional layer made of the intumescent coating compatible with an elastomer.The numerical simulation of heat-mass-transfer processes in polymer-based fire-protective coatings (PFPC) which undergo heating up to temperatures of 1200-1300K typical for fire conditions and are deformed with high intensity upon heating has been performed. The studies have been carried out using a computer program developed by the numerical realization of an original mathematical model that the most fully described in >1, 2@. The factors, which were not before considered, affecting the change dynamics of the forming swollen layer thickness: surface erosion as a result of thermochemical interaction between coke-foam carbon and gas medium, as well as time reduction of the thickness of the intumescent layer at the expense of its shrinkage (settlement) as the quantity of gaseous products of the thermal decomposition of a polymer base of materials passing by transit through the coke-foam layer is reduced, were taken into account.a Corresponding author: a.n

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Numerical modeling of the heat transfer mechanism in intumescent heat- and fire-protection materials

Cited by 3 publications

References 1 publication

The Modeling of Heat Transfer across Intumescent Polymer Coatings

The Modeling of Heat Transfer across Intumescent Polymer Coatings

Effect of high-temperature gas flow on ignition of the water-coal fuel particles

Numerical Analysis of Heat Transfer in Fire-Protective Coatings Deformable upon Heating

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