聚磷酸铵
材料科学
阻燃剂
层状双氢氧化物
热塑性聚氨酯
铵
复合材料
热塑性塑料
聚氨酯
化学工程
聚磷酸盐
磷酸盐
化学
氢氧化物
有机化学
工程类
弹性体
作者
Sheng‐Chao Huang,Cong Deng,Shui-Xiu Wang,Wenchao Wei,Hong Chen,Yu‐Zhong Wang
标识
DOI:10.1016/j.polymdegradstab.2019.05.006
摘要
In the past work, few study considers an effect of nanoparticle as a synergistic flame retardant on the interfacial interaction between flame retardants and polymer matrix, as well as further influence on the flame retardancy and mechanical properties of flame-retarding polymers. In this work, the electrostatic action was used to prepare a novel ammonium [email protected] double hydroxide ([email protected]) in which the LDH nanoparticles accumulated at the surface of APP to achieve the highly-efficient synergistic action of LDH in thermoplastic polyurethane/APP (TPU/APP) and reduce the deterioration of APP to mechanical properties of TPU. Scanning electron microscope, etc., demonstrated that the [email protected] was prepared successfully. Combustion tests results showed that the [email protected] had much higher flame-retarding efficiency than the APP/LDH which was prepared through a simple physical blending process. Only 1.0 wt% LDH made the TPU pass the V-0 rating with no dripping in the UL-94 test and a limiting oxygen index (LOI) of 29.2% in the case of 7.0 wt% [email protected] However, the TPU/APP/LDH with 1.0 wt% LDH did not pass the V-0 rating, and a dripping behavior also existed at 7.0 wt% APP/LDH. In cone calorimeter test, the heat release and smoke production of TPU/[email protected] were also lower than the corresponding values of TPU/APP/LDH under equal amount of LDH. The analysis of flame-retardant mechanism proved that an enhanced condensed action induced by the interfacial LDH dominated the better flame retardance of [email protected] system than that of APP/LDH system. Another important aspect is that the mechanical properties of [email protected] system showed remarkable improvements in comparison with those of APP/LDH system. The tensile strength of TPU with 7.0 wt% [email protected] was 32.5% higher than that of TPU with 7.0 wt% APP/LDH under equal 1.0 wt% LDH. Meanwhile, the elongation at break for the former was maintained at 863.0%, almost equal to that of TPU. This work illustrates that the interfacial accumulation of LDH may enhance its synergistic flame-retarding efficiency and meanwhile achieve the mechanical enhancement for TPU/APP.
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