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改性原纤维素长丝材料作为硬质绝缘聚氨酯泡沫中的多元醇替代品。

Modified raw cellulose filaments material as polyol substitute in rigid insulating polyurethane foam.

作者信息

Beaufils-Marquet Manon, Blanchet Pierre, Cao Loïse, Winninger Jérémy, Pépin Simon, Landry Véronic

机构信息

Department of Wood and Forest Sciences, Faculty of Forestry, Geography, and Geomatics, Université Laval, 2405 rue de la Terrasse, Québec City, QC, G1V 0A6, Canada.

NSERC Industrial Research Chair on Eco-responsible Wood Construction (CIRCERB), Université Laval, 2425 rue de l'Université, Québec City, QC, G1V 0A6, Canada.

出版信息

Sci Rep. 2025 Feb 26;15(1):6934. doi: 10.1038/s41598-025-89807-2.

DOI:10.1038/s41598-025-89807-2
PMID:40011530
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11865483/
Abstract

Current research in building insulation is primarily focused on enhancing the performance of polyurethane foam or exploring alternatives with biobased materials, with particular attention placed on polyols. This study investigated the use of modified cellulose filaments as a polyol to enhance the environmental performance of polyurethane foam. Two distinct etherification methods were employed to modify cellulose filaments (CFs), yielding accessible and reactive ether functions from the hydroxyl (OH) groups of CFs. Polyols and the resulting polyurethane foam were characterized. Kinetics of foam formation, morphology, density, thermal conductivity, and mechanical properties in compression were studied. Analysis revealed reduced reactivity with modified CFs as a substitute of the petroleum-based polyol, affecting foaming. Impacts on the resulting properties of the foam were observed, such as the size of the cells (from 0.14 ± 0.06 mm for petroleum-based polyol foams to 0.03 ± 0.03 mm for foams with 70% substitution with biobased polyols 1 and 2), and cells opening (from 92 ± 2% for petroleum-based polyol foams to 8 ± 3% with 70% substitution with biobased polyols). These results lead to non-compliance with the canadian polyurethane foam standard, requiring a closed cell rate of over 90%. A deterioration in mechanical properties through loss of stiffness and a drastic reduction in the maximum strength (yield strength) the material can withstand below the required standard were also measured. However, noteworthy conductivity results were obtained (0.041 ± 0.004 W m‧K with 70% of substitution with biobased polyols 1 and 2). Foam properties were partly due to different polyol properties, such as functionality and viscosity.

摘要

当前建筑保温材料的研究主要集中在提高聚氨酯泡沫的性能或探索生物基材料的替代品,尤其关注多元醇。本研究调查了使用改性纤维素长丝作为多元醇来提高聚氨酯泡沫的环境性能。采用两种不同的醚化方法对纤维素长丝(CFs)进行改性,从CFs的羟基(OH)基团产生可及的和反应性的醚官能团。对多元醇和所得聚氨酯泡沫进行了表征。研究了泡沫形成的动力学、形态、密度、热导率和压缩力学性能。分析表明,用改性CFs替代石油基多元醇时反应性降低,影响发泡。观察到对泡沫所得性能的影响,如泡孔尺寸(从石油基多元醇泡沫的0.14±0.06毫米到用生物基多元醇1和2替代70%的泡沫的0.03±0.03毫米)和泡孔开孔率(从石油基多元醇泡沫的92±2%到用生物基多元醇替代70%时的8±3%)。这些结果导致不符合加拿大聚氨酯泡沫标准,该标准要求闭孔率超过90%。还测量了由于刚度损失导致的力学性能恶化以及材料所能承受的最大强度(屈服强度)大幅降低至低于所需标准。然而,获得了值得注意的热导率结果(用生物基多元醇1和2替代70%时为0.041±0.004W m‧K)。泡沫性能部分归因于不同的多元醇性能,如官能度和粘度。

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