作者
Sun Yi,Liping Yuan,Liandon Tang,Youhua Fan,Jiajing Yu,Jianzheng Qiao,Zizhi Huang
摘要
Epoxy resin, known for its excellent mechanical properties, chemical resistance, and dimensional stability, has been widely employed in advanced electronic packaging, high-performance coatings, and aerospace engineering. However, its inherent flammability has limited its applications. To address this issue, a ZnAl-NO 3 -LDH was synthesized via co-precipitation and subsequently modified by ion-exchange intercalation with [SiW 12 O 40 ] 4− to form ZnAl-SiW 12 O 40 -LDH (SiW-LDH). The obtained SiW-LDH was then combined with AMP intumescent flame retardants composed of APP, MEL, and PER to enhance the fire resistance properties of the epoxy–polyamide resin (EP). The resulting 2 %SiW-LDH/AMP/EP coatings containing 24.5 wt% AMP and 2 wt% SiW-LDH exhibited excellent flame-retardant properties, achieving an LOI value of 35.3 % and a UL-94 V-0 rating. Additionally, the total heat release (THR) and total smoke production (TSP) recorded during cone calorimeter tests decreased by 69.7 % and 70.9 %, respectively. Moreover, further analysis of the residual char of SiW-LDH/AMP/EP demonstrated that the catalytic carbonization co-effect of AMP and SiW-LDH promoted the formation of a dense and continuous char layer with aromatic structures containing Al O, W O, Si O, W C, Zn 2+ , P–O–C, and P N moieties. Notably, these structures enhanced the flame retardancy, smoke suppression, charring, and thermal insulation properties of the EP. These properties also originated from the dilution of non-combustible gases and the heat-absorbing action upon the thermal decomposition of SiW-LDH/AMP during combustion. Overall, these results demonstrate that the incorporation of SiW-LDH and AMP into epoxy matrices effectively enhances the flame retardancy and thermal insulation properties of polymer systems. • Developed SiW-LDH/AMP flame-retardant system for epoxy-polyamide coatings • Achieved LOI of 35.3 % and UL-94 V-0 rating • Reduced THR by 69.7 % and TSP by 70.9 % • Formed dense char layer during combustion • Enhanced thermal insulation and flame retardancy