采用更环保的双交联方法生产聚氨酯分散体/羧基丁腈橡胶混合物

Ivy Gan , W.S. Chow , S.H. Khoo , M.D. Shafiq
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引用次数: 0

摘要

在环氧树脂和有机改性硅氧烷交联剂的作用下,制备了一种由聚氨酯分散体(PUD)和羧基丁腈橡胶(XNBR)按 80:20 的比例组成的胶乳混合物。研究的目的是在不加入硫和促进剂的情况下,提高 PUD/XNBR 胶乳混合物的拉伸、热和化学特性。研究表明,环氧化物和有机改性硅氧烷交联剂的联合作用显示了充分的分子间氢键,从而产生了优异的拉伸强度。差示扫描量热法(DSC)分析表明,由于引入了两种交联剂,在一定程度上产生了有序的氢键,从而改变了链的取向和熔焓。固化分子结构的紧密程度可能与加热焓密切相关,在以下序列中,PUD80/XNBR20/E1 的结构松散,其次是 PUD80/XNBR20/E0.5S0.5 和 PUD80/XNBR20/S1。化学膨胀研究显示了交联剂组合对氢键(有序和无序)的影响,从而证实了其耐化学性的增强。这项研究证实,分子间氢键的形成带来了理想的机械和耐化学性能,使乳胶混合物适用于手套应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Polyurethane dispersion/carboxylated nitrile butadiene rubber blends produced by a greener dual crosslinking approach

Polyurethane dispersion/carboxylated nitrile butadiene rubber blends produced by a greener dual crosslinking approach

A latex blend comprising polyurethane dispersion (PUD) and carboxylated nitrile butadiene rubber (XNBR) in an 80:20 ratio was prepared in the presence of epoxide and organo-modified siloxane crosslinkers. The aim of the study was to enhance the tensile, thermal, and chemical properties of the PUD/XNBR latex blend without the incorporation of sulphur and accelerator. Studies revealed that the combined action of epoxide and organo-modified siloxane crosslinker demonstrated adequate intermolecular hydrogen bonding, thereby resulting in superior tensile strength. Differential scanning calorimetry (DSC) analysis showed alterations in chain orientation and melting enthalpy due to the introduction of two crosslinkers that impart ordered hydrogen bonding to a certain degree. The compactness of the structure of the cure molecule may be closely related to the heating enthalpy, as in the following sequence, PUD80/XNBR20/E1 will have a loosely packed structure, followed by PUD80/XNBR20/E0.5S0.5 and PUD80/XNBR20/S1. Chemical swelling studies revealed the impact of crosslinker combinations on hydrogen bonding (both ordered and disordered), affirming the consequential enhancement in chemical resistance. This study confirms that the attained intermolecular hydrogen bonding results in desirable mechanical and chemical resistance performance, making the latex blend suitable for glove applications.

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