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Parameswaranpillai, Jyotishkumar
in Cooperation with on an Cooperation-Score of 37%
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Publications (6/6 displayed)
- 2023Drop-weight Impact Responses of Kenaf Fibre-Reinforced Composite-Metal Laminates: Effect of Chemical Treatment and Fibre Composition
- 2023Intrinsically modified self-extinguishing fire-retardant epoxy resin using boron-polyol complexcitations
- 2022Recent progress and multifunctional applications of fire-retardant epoxy resinscitations
- 2022Environmental Impact of Quantum Dots and their Polymer Nanocompositescitations
- 2015Volume shrinkage and rheological studies of epoxidised and unepoxidised poly(styrene-block-butadiene-block-styrene) triblock copolymer modified epoxy resin–diamino diphenyl methane nanostructured blend systemscitations
- 2014Reaction-Induced Phase Separation and Thermomechanical Properties in Epoxidized Styrene- block -butadiene- block -styrene Triblock Copolymer Modified Epoxy/DDM Systemcitations
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article
Recent progress and multifunctional applications of fire-retardant epoxy resins
Abstract
To improve the fire retardancy of epoxy resins, researchers use modifiers such as graphene, phosphorus, boron compounds or similar compatible fillers. The quantity of modifiers introduced to the epoxy matrix is crucial because high loading leads to deleterious thermal and mechanical properties. Taking that into account, this review identified the best epoxy-based fire-retardant polymer pertaining to modifier proportion. In this perspective, we classified fire-retardant epoxy resins into three groups: (1) intrinsic, (2) blends, and (3) composites. A closer investigation of the performance-enhanced material compositions based on multifunctional fire-retardant epoxy resins was undertaken. The reviewed key ingredient materials included ionic liquids, phosphorus, boron/boron nitride, aluminum hydroxide, silicone, lignin, graphene, carbon fibers, carbon nanotubes, and clay. Moreover, this review elucidated the multifunctional applications of fire-retardant epoxy resins, factors affecting fire retardancy, and current characterization techniques, including Underwriters Laboratories 94 testing, cone calorimeter, limiting oxygen index, SEM, and GC-FTIR. Finally, we outlined further research possibilities for smart and effective fire-retardant materials.