Abstract
The use of polymer composite materials in the aeronautics and automotive sectors has increased dramatically, and their fire behaviour has become a critical parameter in terms of fire safety. On this premise, it is critical to demonstrate that these composite materials constitute elements whose safety justifies a high level of confidence. This is based on their combustibility and the rate at which flammable and toxic gaseous species are emitted. Thus, strict fire safety regulations are enforced by the relevant authorities concerned because of their potential fire risk. This study analysed papers published between 1970 and 2021 that described the devices used to characterise the thermal behaviour of composite materials at various scales. The objective was to highlight the thermophysical phenomena, making it possible to accurately assess the flammability and thermal stability of polymer composite materials. The results of this research reveal that the small-scale facilities provide detailed understanding and mastery of the thermal reaction properties of the composites. While with the medium scale, the extended fire reaction parameters, which are the key indicators of the fire safety performance, can be determined. On a large scale, the tests were carried out using devices such as the NexGen burner recommended by the FAA. Therefore, with such assays, it is possible to assess the rates of thermal degradation as well as quantified pyrolysis gases. However, compared to other scales, there were very few works on a large scale. In addition, by focusing on the polluting nature of synthetic composite materials, there is also few research studies aimed at designing new polymer composite materials from biological sources.
Highlights
Over the last decades, polymer composites have shown considerable potential in a wide range of applications
When composites are heated above the glass transition temperature (Tg) of the polymer matrix, pyrolysis gas is released as a result of heat degradation
The results showed that the peak of heat release rate (pHRR) and total smoke production (TSP) of glass fibre-reinforced polybutylene terephthalate (GRPBT)/cerium hypophosphite (CHp) composites were reduced by 76% and 44%, respectively
Summary
Polymer composites have shown considerable potential in a wide range of applications. In comparison to metal alloys, the properties of these composite materials constitute an effective and viable alternative Their advantages stem from the fact that they are light, robust, have a high specific resistance, and are corrosion resistant [1,2]. When composites are heated above the glass transition temperature (Tg) of the polymer matrix (typically above 300–400 ◦ C), pyrolysis gas is released as a result of heat degradation. These materials deform as a result of structural failure due to stiffness and creep resistance losses. When examining a fire scenario in this way, the polymer resins released will produce a smoke (mixture of unburned gases), highlighting an environment that is hazardous to human health and property due to its toxicity and flammability [2,3,4,5]
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