Flammability and smoke generation of glass-fiber-reinforced polyester laminates (GFRPs) modified with L-arginine phosphate (ArgPA) have been investigated. The composition, structure, and thermal degradation processes of ArgPA were assessed by the elemental, FTIR, and thermogravimetric analyses. Flammability and smoke emission of GFRPs varying by different amounts (5-15 wt.%) of bio-based flame retardant (FR) prepared via hand lay-up method were assessed in terms of the limiting oxygen index (LOI) and smoke density tests. It was observed that the addition of ArgPA results in the formation of a charred layer with visible bubbles. The LOI of GFRP with 15 wt.% of ArgPA increased from 20.73 / % (non-modified GFRP) to 24.55 / %, and the material classification was improved from combustible to self-extinguishing. FRs usually increase the specific optical density of smoke, which was also observed for ArgPA-modified GFRPs. However, the specific optical density of smoke at the 4th minute of measurement (D) obtained for ArgPA-modified GFRPs was lower than for GFRPs modified with commercially used APP. TG/FTIR studies of resin modified with ArgPA revealed the presence of phosphorus compounds and non-combustible gases in the decomposition products. Results demonstrate the potential of ArgPA as an effective, bio-based FR for the enhancement of GFRP fire safety.
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- The study focuses on creating bio-based composites using starch and wood fibers to address environmental issues linked to non-renewable materials, but these bio-composites are flammable due to their high carbon content.
- To improve fire resistance, flame retardants like ammonium polyphosphate and calcium carbonate were added, resulting in two composite types (SWA-5 and SWA-10) that achieved high fire safety ratings and impressive limiting oxygen indexes.
- SWA-10 showed a significant reduction in heat release and smoke production, while both composites demonstrated good mechanical properties, thermal insulation, and biodegradability, making them ideal for eco-friendly construction applications.
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