Litcius/Paper detail

Advances in Flame-Retardant Coatings for Rigid Polyurethane Foams: A Critical Review

Qingjie Guo, Jiong Chen, Lulu Xu, Min Chen, Yan Zhang, Yi Xiao, Yao Yuan, Kate Nguyen, Wei Wang

2025Fire6 citationsDOIOpen Access PDF

Abstract

Rigid polyurethane foams (RPUFs) are essential polymeric materials, prized for their low density, high mechanical strength, and superior thermal insulation, making them indispensable in construction, refrigeration, and transportation. Despite these advantages, their highly porous, carbon-rich structure renders them intrinsically flammable, promoting rapid flame spread, intense heat release, and the generation of toxic smoke. Traditional strategies to reduce flammability have primarily focused on incorporating additive or reactive flame retardants into the foam matrix, which can effectively suppress combustion but often compromise mechanical integrity, suffer from migration or compatibility issues, and involve complex synthesis routes. Despite recent progress, the long-term stability, scalability, and durability of surface flame-retardant coatings for RPUFs remain underexplored, limiting their practical application in industrial environments. Recent advances have emphasized the development of surface-engineered flame-retardant coatings, including intumescent systems, inorganic–organic hybrids, bio-inspired materials, and nanostructured composites. These coatings form protective interfaces that inhibit ignition, restrict heat and mass transfer, promote char formation, and suppress smoke without altering the intrinsic properties of RPUFs. Emerging deposition methods, such as layer-by-layer assembly, spray coating, ultraviolet (UV) curing, and brush application, enable precise control over thickness, uniformity, and adhesion, enhancing durability and multifunctionality. Integrating bio-based and hybrid approaches further offers environmentally friendly and sustainable solutions. Collectively, these developments demonstrate the potential of surface-engineered coatings to achieve high-efficiency flame retardancy while preserving thermal and mechanical performance, providing a pathway for safe, multifunctional, and industrially viable RPUFs.

Topics & Concepts

IntumescentMaterials scienceFlammabilityDurabilityCompatibility (geochemistry)PolyurethaneCharCombustionEnvironmentally friendlyComposite materialNanotechnologyLimitingCoatingThermal barrier coatingFire retardantHazardous wasteThermalSmokeThermal stabilityFlame retardant materials and propertiesFire dynamics and safety researchPolymer composites and self-healing