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通过热法或紫外光阳离子法制备的全生物基环氧化植物油热固性材料的可持续获取。

Sustainable access to fully biobased epoxidized vegetable oil thermoset materials prepared by thermal or UV-cationic processes.

作者信息

Malburet Samuel, Di Mauro Chiara, Noè Camilla, Mija Alice, Sangermano Marco, Graillot Alain

机构信息

Specific Polymers 150 Avenue des Cocardières 34160 Castries France

Université Côte d'Azur, Institut de Chimie de Nice, UMR 7272 CNRS 28 Avenue Valrose 06108 Nice Cedex 02 France.

出版信息

RSC Adv. 2020 Nov 18;10(68):41954-41966. doi: 10.1039/d0ra07682a. eCollection 2020 Nov 11.

DOI:10.1039/d0ra07682a
PMID:35516529
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9057863/
Abstract

Beyond the need to find a non-toxic alternative to DiGlycidyl Ether of Bisphenol-A (DGEBA), the serious subject of non-epichlorohydrin epoxy resins production remains a crucial challenge that must be solved for the next epoxy resin generations. In this context, this study focuses on the valorization of vegetable oils (VOs) into thermoset materials by using (i) epoxidation of the VOs through the "double bonds to epoxy" synthetic route and (ii) synthesis of crosslinked homopolymers by UV or hardener-free thermal curing processes. A thorough identification, selection and physico-chemical characterization of non-edible or non-valuated natural vegetable oils were performed. Selected VOs, characterized by a large range of double bond contents, were then chemically modified into epoxides thanks to an optimized, robust and sustainable method based on the use of acetic acid, hydrogen peroxide and Amberlite® IR-120 at 55 °C in toluene or cyclopentyl methyl ether (CMPE) as a non-hazardous and green alternative solvent. The developed environmentally friendly epoxidation process allows reaching almost complete double bond conversion with an epoxy selectivity above 94% for the 12 studied VOs. Finally, obtained epoxidized vegetable oils (EVOs), characterized by an epoxy index from 2.77 to 6.77 m g were cured using either UV or hardener-free thermal curing. Both methods enable the synthesis of 100% biobased EVO thermoset materials whose thermomechanical performances were proved to linearly increase with the EVOs' epoxy content. This paper highlights that tunable thermomechanical performances ( from -19 to 50 °C and from -34 to 36 °C) of EVO based thermoset materials can be reached by well selecting the starting VO raw materials.

摘要

除了需要找到双酚A二缩水甘油醚(DGEBA)的无毒替代品外,非环氧氯丙烷环氧树脂的生产这一严肃课题仍是下一代环氧树脂必须解决的关键挑战。在此背景下,本研究聚焦于通过以下方式将植物油(VO)转化为热固性材料:(i)通过“双键到环氧”合成路线对VO进行环氧化,以及(ii)通过紫外线或无固化剂热固化工艺合成交联均聚物。对不可食用或未被重视的天然植物油进行了全面鉴定、筛选和物理化学表征。选定的VO具有广泛的双键含量,然后通过一种基于在55°C下于甲苯或环戊基甲基醚(CMPE)(一种无毒且绿色的替代溶剂)中使用乙酸、过氧化氢和Amberlite® IR - 120的优化、稳健且可持续的方法,将其化学改性为环氧化合物。所开发的环境友好型环氧化工艺对于所研究的12种VO,几乎能实现双键的完全转化,环氧选择性高于94%。最后,使用紫外线或无固化剂热固化对所得环氧值为2.77至6.77 m g的环氧植物油(EVO)进行固化。这两种方法都能够合成100%生物基EVO热固性材料,其热机械性能被证明会随着EVO的环氧含量线性增加。本文强调,通过精心选择起始VO原料,可以实现基于EVO的热固性材料可调节的热机械性能(玻璃化转变温度从 - 19到50°C,熔点从 - 34到36°C)。

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