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使用12-羟基硬脂酸丙酯作为糖酵解反应物的化学回收商业聚氨酯(PUR)泡沫,用于增强柔韧性的汽车应用。

Chemically recycled commercial polyurethane (PUR) foam using 2-hydroxypropyl ricinoleate as a glycolysis reactant for flexibility-enhanced automotive applications.

作者信息

Jašek Vojtěch, Montag Petr, Menčík Přemysl, Přikryl Radek, Kalendová Alena, Figalla Silvestr

机构信息

Institute of Materials Chemistry, Faculty of Chemistry, Brno University of Technology 61200 Brno Czech Republic

Tomas Bata University in Zlin, Faculty of Technology, Department of Polymer Engineering 76001 Zlín Czech Republic.

出版信息

RSC Adv. 2024 Sep 20;14(41):29966-29978. doi: 10.1039/d4ra04972a. eCollection 2024 Sep 18.

DOI:10.1039/d4ra04972a
PMID:39309646
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11413739/
Abstract

The automotive industry uses polyurethane (PUR) foam core in the vehicle headliner composite. The sector demands recycling suggestions to reduce its scrap and decrease the expenses. This work investigated the PUR depolymerization using synthesized 2-hydroxypropyl ricinoleate (2-HPR) from castor oil and incorporated the liquid recyclate (REC) into the original PUR foam. The synthesis of 2-HPR yielded 97.5%, and the following PUR depolymerization ( glycolysis) reached 87.2% yield. The synthesized products were verified by GPC, FTIR, ESI-MS, and H NMR cross-analysis. The laboratory experiments (565 mL) included rheological, structural, and reactivity investigations. Added 30% REC content decreased the apparent viscosity to 109 mPa s from standard 274 mPa s. The reactivity of the 30% REC system increased by 51.2% based on the cream time due to the high REC amine value. The block foam density of systems with 15% REC and above decreased by 14.8%. A system with 20% REC content was the most prospective for up-scale. The industrially significant up-scale (125 L) was performed successfully, and the tensile and flexural test specimens were sampled from the up-scaled foam. The tensile characteristic (tensile strength 107 ± 8 kPa and elongation 9.2 ± 0.7%) and flexural characteristic (flexural strength 156 ± 12 kPa and flexural strain at deformation limit 23.4 ± 0.6%) confirmed that the REC incorporation in the standard PUR foam improves the applicable significant mechanical properties and assures the manufacture improve.

摘要

汽车行业在汽车顶篷复合材料中使用聚氨酯(PUR)泡沫芯。该行业需要回收建议以减少废料并降低成本。这项工作研究了使用从蓖麻油合成的2-羟基丙基蓖麻油酸酯(2-HPR)对PUR进行解聚,并将液体回收物(REC)掺入原始PUR泡沫中。2-HPR的合成产率为97.5%,随后的PUR解聚(醇解)产率达到87.2%。通过凝胶渗透色谱(GPC)、傅里叶变换红外光谱(FTIR)、电喷雾电离质谱(ESI-MS)和核磁共振氢谱(H NMR)交叉分析对合成产物进行了验证。实验室实验(565毫升)包括流变学、结构和反应性研究。添加30%的REC含量可使表观粘度从标准的274毫帕秒降至109毫帕秒。由于REC胺值较高,基于乳化时间,30%REC体系的反应性提高了51.2%。含15%及以上REC的体系的块状泡沫密度降低了14.8%。含20%REC的体系最具扩大规模的前景。成功进行了具有工业意义的扩大规模(125升),并从扩大规模的泡沫中取样进行拉伸和弯曲测试。拉伸特性(拉伸强度107±8千帕和伸长率9.2±0.7%)和弯曲特性(弯曲强度156±12千帕和变形极限处的弯曲应变23.4±0.6%)证实,将REC掺入标准PUR泡沫中可改善适用的重要机械性能,并确保制造工艺得到改进。

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