Journal
PROGRESS IN ORGANIC COATINGS
Volume 177, Issue -, Pages -Publisher
ELSEVIER SCIENCE SA
DOI: 10.1016/j.porgcoat.2022.107388
Keywords
Multifunctional composites; Thermal analysis; Mechanical testing; High -temperature properties
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The composites phosphorus-silicon flame retardant was used to modify waterborne poly-urethane (WPU) and characterized. The flame retardancy, residual carbon morphology, and graphitization of the modified WPU films were evaluated. The results showed that the flame-retardant films had low heat release rate and total heat release values, as well as increased limiting oxygen index and improved strength and shield properties.
The composites phosphorus-silicon flame retardant was simultaneously employed to modify waterborne poly-urethane (WPU). The WPU films modified with the composites flame retardant were characterized in detail. The composites flame retardancy, residual carbon morphology, and graphitization of the films were evaluated by cone calorimetry, scanning electron microscopy (SEM), and Raman spectroscopy, respectively. The results showed that the weight loss temperature of the WPU film was 402.45 degrees C when the weight loss rate was as high as 90 % in the N2 atmosphere, and the PHRR and THR values of the flame-retardant films were as low as 222.3 kW/ m2 and 22.9 MJ/m2, respectively. Compared with the neat WPU, the LOI of the film decorated with the com-posites flame retardant was increased by 39.13 %. The high graphitization degree of the residue char was formed to improve strength and shield properties of the modified WPU film. The flame-retardant mechanism was attributed to the active phosphorus-containing free-radical quenching effect and diluting effect of nonflammable gases in the gas phase, and owing to the catalysis effect the formation of phosphorus/silicon-rich char residue layers in the condensed phase.
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