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通过天然生物材料对纸张进行的全生物基双层阻燃处理。

The fully bio-based bilayered flame retardant treatment for paper via natural bio-materials.

作者信息

Sun Zhihao, Liu Xinlong, Hu Qiaosheng, Zhao Qing, Qi Xuyao, Xu Fei, Li Jingxian, Ma Zhongfei

机构信息

School of the Environment and Safety Engineering (School of the Emergency Management), Jiangsu University, Zhenjiang, China.

Key Laboratory of Gas and Fire Control for Coal Mines (China University of Mining and Technology), Ministry of Education, Xuzhou, China.

出版信息

Front Chem. 2024 Dec 18;12:1503694. doi: 10.3389/fchem.2024.1503694. eCollection 2024.

DOI:10.3389/fchem.2024.1503694
PMID:39744613
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11689656/
Abstract

In this paper, we report a novel method for enhancing the flame retardancy of wood-based paper by utilizing natural biomaterials. The research constructed a bilayered structure coating on paper fiber surfaces, incorporating mixed starch (MS), adenosine triphosphate (ATP), and phytic acid (PA) as natural bio-based flame retardants. The structural configuration of the coating comprises MS/ATP and MS/PA, which were sequentially assembled as bottom and top parts, respectively, through pneumatic spraying. The surface morphological features and elemental distribution analysis of treated paper indicated that bio-materials were successfully assembled, which resulted in a uniform flame retardant coating on the paper fiber surface. Compared to the untreated paper, the limiting oxygen index of 20 bilayers (BL) treated paper increased substantially from 19.07% to 24.00%, and the thermogravimetric analysis showed out the residual char yield enhanced from 23.80% to 38.10% under nitrogen atmosphere. The cone calorimeter test results of 20 BL treated paper have approximately a 50.00% reduction than the untreated paper in both peak and total heat release rates. During thermal exposure, the top and bottom parts of the bilayered structure coating are successively flame retarded prior to paper fiber degrading. The method presented in this paper provides an environmentally sustainable approach for producing flame retardant wood-based paper.

摘要

在本文中,我们报告了一种利用天然生物材料提高木质纸张阻燃性的新方法。该研究在纸纤维表面构建了一种双层结构涂层,将混合淀粉(MS)、三磷酸腺苷(ATP)和植酸(PA)作为天然生物基阻燃剂纳入其中。涂层的结构配置包括MS/ATP和MS/PA,它们分别通过气动喷涂依次组装为底部和顶部。处理后纸张的表面形态特征和元素分布分析表明,生物材料成功组装,从而在纸纤维表面形成了均匀的阻燃涂层。与未处理的纸张相比,20层(BL)处理后纸张的极限氧指数从19.07%大幅提高到24.00%,热重分析表明在氮气气氛下残余炭产率从23.80%提高到38.10%。20 BL处理后纸张的锥形量热仪测试结果在峰值和总热释放率方面比未处理的纸张大约降低了50.00%。在热暴露过程中,双层结构涂层的顶部和底部在纸纤维降解之前依次起到阻燃作用。本文提出的方法为生产阻燃木质纸张提供了一种环境可持续的途径。

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