Properties of Rigid Polyurethane Foam Modified by Tung Oil-Based Polyol and Flame-Retardant Particles

Although tung oil is renewable, with an abundant production and low price in China, and it is used to synthesize different polyols for rigid polyurethane foam (RPUF), it remains a challenge to improve the properties of RPUF by redesigning the formula. Therefore, we propose four novel compounds to st...

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Veröffentlicht in:	Polymers 2020-01, Vol.12 (1), p.119
Hauptverfasser:	Zhou, Wei, Hao, Shu-Jie, Feng, Guo-Dong, Jia, Pu-You, Ren, Xiao-Li, Zhang, Meng, Zhou, Yong-Hong
Format:	Artikel
Sprache:	eng
Schlagworte:	Acids Aluminum Aluminum phosphate Catalysts Chemical synthesis Environmental impact Flame retardants High temperature Insulation Mechanical properties Polyols Polyurethane foam Pore size Renewable resources Silicon dioxide Thermal stability Vegetable oils Viscosity
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creator	Zhou, Wei Hao, Shu-Jie Feng, Guo-Dong Jia, Pu-You Ren, Xiao-Li Zhang, Meng Zhou, Yong-Hong
description	Although tung oil is renewable, with an abundant production and low price in China, and it is used to synthesize different polyols for rigid polyurethane foam (RPUF), it remains a challenge to improve the properties of RPUF by redesigning the formula. Therefore, we propose four novel compounds to strengthen the properties of RPUF, such as the catalyst-free synthesis of tung oil-based polyol (PTOK), aluminum phosphate micro-capsule (AM), silica micro-capsule (SiM), and grafted epoxidized monoglyceride of tung oil on the surface of SiO (SiE), which were designed and introduced into the RPUF. Because of the PTOK with a catalytic function, the foaming process of some RPUF samples was catalyst-free. The results show that the incorporation of AM, SiM, and SiE, respectively, endow RPUF with a better thermal stability at a high temperature, and the , , and of RPUF appeared to be reduced, however, the and residue rate at 800 °C were improved, which may have a positive effect on the extension of the rescue time in case of fire, and the limiting oxygen index (LOI) value was increased to 22.6%. The formula, containing 25% PTOK made the RPUF environment-friendly. The results were obtained by comparing the pore size and mechanical properties of the RPUF-the AM had a better dispersion in the foam, and the foam obtained a better mechanical, thermal, and flame retardancy.
doi_str_mv	10.3390/polym12010119
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subjects	Acids Aluminum Aluminum phosphate Catalysts Chemical synthesis Environmental impact Flame retardants High temperature Insulation Mechanical properties Polyols Polyurethane foam Pore size Renewable resources Silicon dioxide Thermal stability Vegetable oils Viscosity
title	Properties of Rigid Polyurethane Foam Modified by Tung Oil-Based Polyol and Flame-Retardant Particles
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