SYNTHESIS OF FLAME-RESISTANT NANOCOMPOSITE COATINGS, THEIR THERMO-MECHANICAL PROPERTIES, AND PRACTICAL APPLICATION IN THE EVALUATION OF HEAT RESISTANCE.
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https://doi.org/10.5281/zenodo.17792873##article.subject##:
Flame-resistant coatings; nanocomposites; phenol–formaldehyde resins; thermo-mechanical properties; heat resistance; nanosilicates; polymer modification##article.abstract##
This research focuses on the synthesis of flame-resistant nanocomposite coatings and the evaluation of their
thermo-mechanical properties and heat resistance. Phenol–formaldehyde resins modified with nanosilicate additives
were prepared and systematically investigated. The incorporation of nanoscale fillers was found to significantly enhance
the thermal stability, mechanical performance, and flame-retardant behavior of the coatings. Experimental results
demonstrated that these nanocomposites exhibit delayed thermal degradation, higher char yield, improved adhesion,
and resistance to mechanical stress under thermal cycling. The coatings also provided effective protection against hightemperature
exposure, showing promising potential for practical applications in aerospace, construction, and energy
industries.
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