A study of the global kinetics of thermal degradation of a fibre-intumescent mixture

A study of the global kinetics of thermal degradation of a fibre-intumescent mixture

A mathematical model is being developed to predict the behaviour of an intumescent flame retardant within a rigid, resin-impregnated, textile-reinforced composite during exposure to heat. As part of a larger programme of research into flame retardant composites, there exist considerable empirical da...

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Bibliographic Details
Published in:Polymer degradation and stability Vol. 77; no. 2; pp. 187 - 194
Main Authors: Neininger, Susan M., Staggs, J.E.J., Horrocks, A.R., Hill, N.J.
Format: Journal Article Conference Proceeding
Language:English
Published: Oxford Elsevier Ltd 2002
Elsevier Science
Subjects:
Applied sciences
Cellulosic fibre
Char formation
Composites
Exact sciences and technology
Forms of application and semi-finished materials
Intumescent
Kinetics
Mathematical modelling
Polymer industry, paints, wood
Pyrolysis
Technology of polymers
Thermal decomposition
Char formation
Pyrolysis
Thermal decomposition
Intumescent
Mathematical modelling
Kinetics
Cellulosic fibre
Cellulose hydrate
Fiber reinforced material
Thermooxidative degradation
Epoxy resin
Flame retardant
Pentaerythritol
Experimental study
Composite material
Additive
Reaction mechanism
Organic phosphate
Kinetic parameter
Degradation product
Textile fiber
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Summary:A mathematical model is being developed to predict the behaviour of an intumescent flame retardant within a rigid, resin-impregnated, textile-reinforced composite during exposure to heat. As part of a larger programme of research into flame retardant composites, there exist considerable empirical data showing the enhancement of char formation, at temperatures greater than 400 °C, when an intumescent based on melamine phosphate is dispersed on the surface of a flame-retardant, cellulosic fibre. Visil (Sateri, Finland), is a flame-retardant viscose fibre containing polysilicic acid which interacts with phosphate or polyphosphate components of the intumescent to form a resistant char-bonded structure. When introduced into a composite either as a pulverised additive, or as additional layers with glass fabric in the composite structure, it has been shown to promote enhanced char formation. In order to model the thermal decomposition of a cellulosic fibre and intumescent mixture, a number of different decomposition schemes, involving competitive and successive reactions, have been considered. The thermogravimetric mass loss curve displays at least three waves of overlapping reactions, so that the kinetics cannot be estimated by the usual differential or integral methods. A simple, reduced kinetic scheme has been compared with a temperature dependent scheme to determine the effect of increased heating rates on the yield of solid residue. The results will be used in later work for the interpretation of Arrhenius parameters estimated from thermogravimetric data by the method of minimisation of least squares.
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content type line 23
ISSN:0141-3910
1873-2321
DOI:10.1016/S0141-3910(02)00033-2