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废聚氨酯的催化降解及再生材料的制备

The Catalytic Degradation of Waste PU and the Preparation of Recycled Materials.

作者信息

Gu Xiaohua, Xu Jiahao, Zhu Shangwen, Zhao Qinglong, Sun Shaochun, Zhang Yanxun, Su Qingyong, Long Canyan

机构信息

School of Energy and Building Environment, Guilin University of Aerospace Technology, Guilin 541004, China.

Qiqihar School of Materials Science and Engineering, Qiqihar University, Qiqihar 161006, China.

出版信息

Polymers (Basel). 2024 Dec 21;16(24):3581. doi: 10.3390/polym16243581.

DOI:10.3390/polym16243581
PMID:39771435
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11679310/
Abstract

In this paper, we investigated the efficient metal-free phosphorus-nitrogen (PN) catalyst and used the PN catalyst to degrade waste PU with two-component binary mixed alcohols as the alcohol solvent. We examined the effects of reaction temperature, time, and other factors on the hydroxyl value and viscosity of the degradation products; focused on the changing rules of the hydroxyl value, viscosity, and molecular weight of polyols recovered from degradation products with different dosages of the metal-free PN catalyst; and determined the optimal experimental conditions of reaction temperature 180 °C, reaction time 3 h, and PN dosage 0.08%. The optimal experimental conditions were 180 °C, 3 h reaction time, and 0.08% PN dosage, the obtained polyol viscosity was 3716 mPa·s, the hydroxyl value was 409.2 mgKOH/g, and the number average molecular weight was 2616. The FTIR, H, NMR, and other tests showed that the waste urethanes were degraded into oligomers successfully, the recycled polyether polyols were obtained, and a series of recycled polyurethanes with different substitution ratios were then prepared. A series of recycled polyurethane materials with different substitution rates were then prepared and characterized by FTIR, SEM, compression strength, and thermal conductivity tests, which showed that the recycled polyurethane foams had good physical properties such as compression strength and apparent density, and the SEM test at a 20% substitution rate showed that the recycled polyol helped to improve the structure of the blisters.

摘要

在本文中,我们研究了高效无金属磷氮(PN)催化剂,并使用该PN催化剂以两组分二元混合醇作为醇溶剂来降解废聚氨酯。我们考察了反应温度、时间等因素对降解产物羟值和粘度的影响;重点研究了不同用量的无金属PN催化剂从降解产物中回收的多元醇的羟值、粘度和分子量的变化规律;确定了反应温度180℃、反应时间3h、PN用量0.08%的最佳实验条件。最佳实验条件为180℃、反应时间3h、PN用量0.08%,得到的多元醇粘度为3716mPa·s,羟值为409.2mgKOH/g,数均分子量为2616。FTIR、H、NMR等测试表明,废聚氨酯成功降解为低聚物,得到了回收聚醚多元醇,然后制备了一系列不同取代率的回收聚氨酯。然后制备了一系列不同取代率的回收聚氨酯材料,并通过FTIR、SEM、抗压强度和热导率测试对其进行了表征,结果表明回收聚氨酯泡沫具有良好的物理性能,如抗压强度和表观密度,20%取代率下的SEM测试表明回收多元醇有助于改善泡孔结构。

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