寻找具有高 Tg 的刚性、韧性聚酯--高异山梨醇含量的可再生芳香族聚酯

Bruno Bottega Pergher, Daniel H. Weinland, Robert-Jan van Putten and Gert-Jan M. Gruter
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引用次数: 0

摘要

在冲击强度和弹性模量(刚度)之间取得良好平衡的可再生聚酯并不多见,尤其是在结合高玻璃化转变温度(Tg)的情况下。如果能获得这样的高性能特性,就可以用来自生物或回收来源的化学可回收聚酯来替代 ABS 和聚碳酸酯等高性能聚合物。开发这些材料的挑战之一是选择合适的单体/共聚物比例组成,并制造出高分子量的材料,这可能是一个挑战,因为一些最有前途的硬质二元醇(如异山梨醇)是非活性的。本研究利用(潜在的)可再生单体制成芳香族聚酯,使用生物基异山梨醇来提高其 Tg 值并抑制其结晶,同时使用柔性助二醇来提高抗冲击强度。为了在目标聚酯中加入大量异山梨醇,我们采用了本研究小组之前开发的反应性酚类溶剂合成法。所选成分显示出较高的 Tg 值(90 °C)和较高的拉伸模量(1850 兆帕)。我们的研究表明,较硬的 2,5-呋喃二甲酸 (FDCA) 和二甘醇等极性较强的单体会导致较高的硬度,但冲击强度(<5 kJ m-2)却有所降低。将对苯二甲酸和异山梨醇与 1,4-丁二醇、1,4-环己烷二甲醇 (CHDM) 和 1,3-丙二醇等柔性更强的二元醇结合在一起,可以实现更好的平衡,包括高拉伸模量(1850 兆帕)和高冲击强度(10 kJ m-2)。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

The search for rigid, tough polyesters with high Tg – renewable aromatic polyesters with high isosorbide content†

The search for rigid, tough polyesters with high Tg – renewable aromatic polyesters with high isosorbide content†

The search for rigid, tough polyesters with high Tg – renewable aromatic polyesters with high isosorbide content†

Renewable polyesters with a good balance between impact strength and elastic modulus (stiffness) are not very common, especially when combined with high glass transition temperature (Tg). Achieving such high performance properties would enable the substitution of high performance polymers like ABS and polycarbonate with chemically recyclable polyesters from bio-based or recycled sources. One of the challenges in developing these materials is to select the right composition of the right monomers/comonomer ratios and making these materials with high molecular weight, which can be challenging since some of the most promising rigid diols, such as isosorbide, are unreactive. This study comprises aromatic polyesters from (potentially) renewable monomers, using bio-based isosorbide as a means to increase their Tg and to inhibit their crystallization, while using flexible co-diols to improve impact strength. To incorporate a high amount of isosorbide into the targeted polyesters, we used the synthesis method with reactive phenolic solvents previously developed in our group. The selected compositions display high Tg's (>90 °C) and high tensile modulus (>1850 MPa). We show that more polar monomers such as the stiffer 2,5-furandicarboxylic acid (FDCA) and diethylene glycol cause high stiffness but decreased impact strength (<5 kJ m−2). Combining terephthalic acid and isosorbide with more flexible diols like 1,4-butanediol, 1,4-cyclohexanedimethanol (CHDM) and 1,3-propanediol provides a better balance, including the combination of high tensile modulus (>1850 MPa) and high impact strength (>10 kJ m−2).

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