Scalable manufacturing and reprocessing of vitrimerized flexible polyurethane foam (PUF) based on commercial soy polyols†

Industrial Chemistry & Materials Pub Date : 2025-01-11 DOI:10.1039/D4IM00117F

Wangcheng Liu, Yaqiong Zhang, Peter Chen, Lin Shao, Yiding Cao, Baoming Zhao, Ellen C. Lee, Xiaojiang Wang and Jinwen Zhang

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Abstract

As the polyurethane foam (PUF) market, especially in the automotive sector, continues to grow, the environmental impacts of its petrochemical demands and end-of-life waste have motivated the industry to look for more sustainable solutions. This study explores the preparation of recyclable PUFs using commercially available soy polyols (Cargill's BiOH), aiming to enable improved thermal reprocessability of flexible PUFs via vitrimer chemistry. A series of “soy-PUFs” was produced by partially substituting petrochemical polyether polyols with 25% or 50% soy polyols in a standard reference formulation. Incorporation of soy polyols resulted in an increase in the stiffness of the resulting foams. Employing a modest amount (∼0.5 wt%) of dibutyltin dilaurate (DBTDL) in the formulations facilitated dynamic covalent bond exchanges in the cross-linked network during a mild “foam-to-sheet” reprocessing process (160 °C), converting malleable PUFs into densified sheet materials (PUS) with proper compactness and mechanical performance (e.g., tensile modulus = ∼50 MPa). Soy-PUFs demonstrated a modestly enhanced stress relaxation behavior, suggesting adequate reprocessing ability. DMA results demonstrated the phenomenon of forming an “intermediate” region between the hard and soft domains of PUSs after reprocessing.

Keywords: Polyurethane foam; Soybean oil; Polyols; Vitrimer chemistry; Reprocessing; Recycling.

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基于商业大豆多元醇的玻璃化柔性聚氨酯泡沫（PUF）的规模化制造和再加工

随着聚氨酯泡沫（PUF）市场，特别是汽车行业的持续增长，其石化需求和报废废物对环境的影响促使该行业寻求更可持续的解决方案。本研究探索了利用市售大豆多元醇（嘉吉公司的BiOH）制备可回收PUFs的方法，旨在通过vitrimer化学方法提高柔性PUFs的热再加工性。在标准参考配方中，用25%或50%的大豆多元醇部分替代石化聚醚多元醇，生产了一系列“大豆pufs”。大豆多元醇的掺入增加了泡沫的硬度。在配方中加入适量（~ 0.5 wt%）的二酸二丁基锡（DBTDL），在温和的“泡沫到薄片”再加工过程（160°C）中，促进交联网络中的动态共价键交换，将可锻铸puf转化为致密的片状材料（pu），具有适当的密实度和机械性能（例如，拉伸模量= ~ 50 MPa）。大豆pufs表现出适度增强的应力松弛行为，表明有足够的再加工能力。DMA结果表明，经过再加工后，在PUSs的硬畴和软畴之间形成了一个“中间”区域。关键词：聚氨酯泡沫；大豆油;多元醇;Vitrimer化学;后处理;回收利用。

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