A Study of Thermal Degradation and Fire Behaviour of Polymer Composites and Their Gaseous Emission Assessment

Ogabi, Raphael; Manescau, Brady; Chetehouna, Khaled; Gascoin, Nicolas

doi:10.3390/en14217070

Cited by 13 publications

(16 citation statements)

References 112 publications

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“…The exposure of organic and inorganic compounds to heat causes their thermal degradation. Basically, a flame is formed when the thermal degradation of combustible materials is oxidative and is characterized by the generation and emission of heat and light [ 35 ]. The flame is the light emitted by the fire and serves as a visual indicator of the heat generated.…”

Section: Thermal Degradation and Flammabilitymentioning

confidence: 99%

Flame Retardant Coatings: Additives, Binders, and Fillers

et al. 2022

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This review provides an intensive overview of flame retardant coating systems. The occurrence of flame due to thermal degradation of the polymer substrate as a result of overheating is one of the major concerns. Hence, coating is the best solution to this problem as it prevents the substrate from igniting the flame. In this review, the descriptions of several classifications of coating and their relation to thermal degradation and flammability were discussed. The details of flame retardants and flame retardant coatings in terms of principles, types, mechanisms, and properties were explained as well. This overview imparted the importance of intumescent flame retardant coatings in preventing the spread of flame via the formation of a multicellular charred layer. Thus, the intended intumescence can reduce the risk of flame from inherently flammable materials used to maintain a high standard of living.

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Section: Thermal Degradation and Flammabilitymentioning

confidence: 99%

Flame Retardant Coatings: Additives, Binders, and Fillers

et al. 2022

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“…For example, for styrofoam, the polymer-based composites are especially well-suited as insulating materials in civil engineering due to their low density, low thermal conductivity and good sound insulation properties [1]. However, most polymer composites are subject to thermal decomposition at high temperatures, which leads to degradation of their structural integrity and the release of toxic or flammable gases into the atmosphere as a result of polymer decomposition [2]. In this aspect, ceramic materials [3] and their structural analogous produced from aluminosilicate materials [4,5], such as geopolymers [6,7], are considered to be more effective in terms of environmental friendliness and durability.…”

Section: Introductionmentioning

confidence: 99%

The Effect of Different Modifying Methods on Physical, Mechanical and Thermal Performance of Cellular Geopolymers as Thermal Insulation Materials for Building Structures

Kozhukhova

Teslya

et al. 2022

Buildings

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Geopolymers represent a new class of inorganic materials that have great potential for practical application due to the properties of used raw materials, as well as the peculiarities of the cementitious matrix structure formed during the geopolymerization process. Cellular geopolymer specimens were produced in this study using class F fly ash product, which is characterized by low reactivity during geopolymerization. Several standard methods, as well as microstructural studies were applied to evaluate the effect of the following factors on the physical-mechanical and thermophysical characteristics of cellular geopolymers: the use of various mineral modifying components for synthesis of geopolymer systems; high-temperature treatment; the introduction method of alkaline activator. It was observed that “ageing” an aqueous alkali solution for 24 h before mixing with fly ash and foam agent was able to provide a boost of compressive strength of cellular geopolymer specimens up to about 2.5 times, while decreasing the average density by about 28% for all experimental mixes, except for PC-modified mixes. Additionally, high-temperature treatment at 600 °C enables an enhanced strengthening effect of pore structure in cellular geopolymer matrix up to 1.5 times. This phenomenon is especially pronounced for the mixes with 24 h “aged” alkaline solution with exception for PC-modified mixes; for those, high-temperature treatment at 600 °C leads to strength decrease up to 40%. The introduction method of alkaline activator and high-temperature treatment showed a controversial effect on thermal conductivity coefficient depending on the mineral modifying component used for the synthesis of cellular geopolymers. The proposed method for calculation of total porosity of cellular structure of geopolymers as a polycomponent material demonstrated a high degree of correlation with the R2 value of at least 0.96 between the average density and the calculated total porosity. However, a low degree of correlation with R2 not exceeding 0.29 was observed for the measured nanoporosity, regardless of the introduction method of alkaline activator and high-temperature treatment.

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“…There are many studies on the combustion behavior of kerosene flames at both small and medium scales, but there is still a need for research on the fire response properties of large oil burners (the criteria for defining the scales of thermal and fire facilities used for testing materials are based on the test conditions such as the generated maximum flame temperature, heat flux, etc., and the specimen dimension impinged by the flame), particularly with the specific burner type being considered. 19,20 This is important for gaining a deeper understanding of how these burners behave and identifying ways to optimize their performance (in terms of maximum flame temperature, heat flux, and gas emission concentration). 20 Aviation test standards have been the subject of in-depth investigations and analyses since they are essential to assuring the safety and dependability of airplanes.…”

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confidence: 99%

“…19,20 This is important for gaining a deeper understanding of how these burners behave and identifying ways to optimize their performance (in terms of maximum flame temperature, heat flux, and gas emission concentration). 20 Aviation test standards have been the subject of in-depth investigations and analyses since they are essential to assuring the safety and dependability of airplanes. The need to provide precise principles and processes for testing aircraft systems, components, and materials has motivated the development of aviation test standards.…”

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confidence: 99%

“…The purpose of this test bench is to provide a platform for studying and evaluating the fire resistance of materials under simulated accident conditions. 7,20,25 The gun-type burner is equipped with an air supply circuit that regulates the air at a pressure range of 2.15-4.5 bar. A manual valve is used to control the flow of air, which is first cooled down by a water exchanger and then passes through a frozen coil to ensure that its temperature is between 5 and 15 C before entering the burner (Cooling the air helps to improve the efficiency and performance of the burner).…”

mentioning

confidence: 99%

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Investigation of the flame properties and fire behavior of carbon‐reinforced PEKK, BMI and phenolic composites impacted by Jet‐A1/air flames

Ogabi,

Manescau,

Chetehouna

et al. 2023

Fire and Materials

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This paper provides an experimental investigation of a kerosene/air burner (the NexGen burner designed on the FAA's proposed ISO 2685 standard), which is used to generate flame/burnt gases impinging on material samples in the field of fire safety. The purpose of this study is to characterize this burner, and experimental means are implemented to better understand the effects of the equivalence ratio on the spatial distribution of the gas temperature (thermocouples), the heat flux (heat flux gauge), and gas emission species. Hence, the measured flame temperature, heat flux, and heat release rate increase up to a critical value of equivalence ratio equal to 1.03. Furthermore, a pyrolysis test was carried out on composite materials and the results of the comparative analysis of carbon‐phenolic, carbon‐BMI, and carbon‐PEKK materials show that carbon‐PEKK had the lowest mass loss, highest back‐face temperature without significant material delamination, and the lowest concentration of gas emission species.

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A Study of Thermal Degradation and Fire Behaviour of Polymer Composites and Their Gaseous Emission Assessment

Cited by 13 publications

References 112 publications

Flame Retardant Coatings: Additives, Binders, and Fillers

Flame Retardant Coatings: Additives, Binders, and Fillers

The Effect of Different Modifying Methods on Physical, Mechanical and Thermal Performance of Cellular Geopolymers as Thermal Insulation Materials for Building Structures

Investigation of the flame properties and fire behavior of carbon‐reinforced PEKK, BMI and phenolic composites impacted by Jet‐A1/air flames

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