Abstract
Extensive research has been conducted on polyester flame retardants and anti-droplet modifications in recent years. The conventional methods used to improve the effectiveness of the anti-droplet modifications usually involve improving the melt fluidity and the combustion char formation through reactive cross-linking. However, these methods, while reducing the droplets, may produce more smoke. This study proposes a combustion cross-linking method which avoids the droplet and flame retardancy synergistic modification problem. Based on the flame retardancy of polyester, anti-droplet properties were realized using a collaborative cross – linking structure formed by a phosphorus – containing flame – retardant group and acid silicon solvent to achieve a flame retardant and anti-droplets result. The results show that the phosphorus–silicon copolyester presents an enhancement effect for flame retardancy, confirmed by obvious reductions in the peak value of heat release rate (78.4%) and total heat release (44.2%). Meanwhile, the total smoke release and smoke product rate of phosphorus–silicon copolyester are decreased by 45.1% and 41.5%, respectively. And the phosphorus–silicon copolyester has a high LOI value of 34.8 ± 0.1% and UL-94 is V-0 rating with superior anti-dripping performance. Flame retardancy index (FRI) of the copolyesters containing phosphorus–silica are up to 4.3093 (good flame retardancy). Nonisothermal differential scanning calorimetry (DSC) was performed for qualitative analysis of network formation by the aid of Cure Index (CI) dimensionless criterion. It was observed that the acidic silica led to Excellent cure situation. The TG-DSC, XPS, and FTIR results validate the thermal cross-linking ability of the copolymer due to the synergistic cross-linking effect between the self-cross-linking characteristic of the catalysed acidic silica sol containing the phosphorus flame retardant. The SEM-EDX and Raman results further verify the effectiveness of the condensed-phase flame-retardant mechanism. Phosphorus–silicon copolyester has good spinnability, flame retardancy and anti-droplets properties. Which provides a simple method for preparing polyester by using this combustion synergistic crosslinking effect to achieve flame retardant and anti-dripping modification of copolymers.
Highlights
The burning of textiles is the most important factor leading to casualties in indoor res, and about 50% of indoor res are caused by textiles
Jouyandeh et al.[32,33,34,35,36] targeted almost all properties of thermoset composites are more or less dependent on the situation of network formation in a system, proposes a dimensionless criterion which based on nonisothermal differential scanning calorimetry, known as ‘cure index’, for typical epoxy-based systems containing 0D nanoparticles, hereina er referred to as “Cure Index (CI)”
A comparative study was performed on curing potential and associated performance of low- lled epoxy/amine composites containing pristine halloysite nanotubes (P-HNTs), alkaliactivated HNTs (A-HNTs), and silane-functionalized A-HNTs (F-HNTs), hydroxyl-rich halloysite nanotube (HNT)/silica nanosphere (SiO2) core/shell particles are functionalized with multiarm hyperbranched polyethylenimine macromolecule and epoxy/Fe3O4 systems as model nanocomposite coatings, the synergistic cross-linking effect of additives on curing properties of the materials was not mentioned
Summary
The burning of textiles is the most important factor leading to casualties in indoor res, and about 50% of indoor res are caused by textiles. To deal with these problems, this study proposes a combustion cross-linking method which improves the properties of the droplets by incorporating a synergistically crosslinkable structure of phosphorus-containing ame-retardant groups and acidic silica sol.
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