Bio-production of fire retardant and hydrophobic packaging paperboard with enhanced tensile strength through coating with modified cellulose nanofiber

IF 2.4 3区 农林科学 Q1 FORESTRY
Mehrnoosh Tavakoli, Ali Ghassemian, Mohammadreza Dehghani Firouzabadi, Bartłomiej Mazela, Wojciech Grześkowiak
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Abstract

The challenge of creating cellulose-based materials resistant to fire, water, and are eco-friendly has surged in various industries. Innovative bio-based cellulose substances, especially those with robust fire and humidity resistance, are pivotal for high-quality cellulose-based packaging. This study focuses on TEMPO-oxidized cellulose nanofibers at concentrations of 2, 2.5, and 3wt%, modified using three chemical combinations: "ammonium dihydrogen phosphate + albumin", "silica + methyltrimethoxysilane", and a mixture of all four ingredients. Each combination, with a constant level of 14% and a coat weight of 3.5 g.m−2, was applied to the surface of the produced paperboards. Flame retardancy analysis results indicate that modified TEMPO-oxidized CNF at 3wt%, employing the quadruple combination, offers suitable fire properties in the prepared paperboard, mainly due to intumescent phosphorus-based flame retardants. These retardants reduce the peak heat release rate as a function of the heat release temperature. Furthermore, silicon groups by blocking functional hydroxyl groups, induced hydrophobicity in cellulose nanofibers, as indicated by contact angle and water uptake measurements. Tensile strength significantly improved after incorporating wettable bio-retardants into cellulose nanofibers and coating them onto the cellulose matrix. Also, the roughness and homogeneity of the surface of the paperboard increased when the solid of CNF increased from 2 to 2.5, and 3wt%, respectively according to the FESEM analysis. This modification system offers potential as a foundational substrate for high-quality pharmaceutical and hygienic packaging, providing degradable alternatives to non-recyclable plastics and achieving eco-friendly advantages.

Abstract Image

通过涂覆改性纤维素纳米纤维,用生物技术生产抗张强度更高的阻燃疏水包装纸板
在各行各业中,如何创造出防火、防水、环保的纤维素基材料已成为一个巨大的挑战。创新的生物基纤维素物质,尤其是那些具有强大的防火和防潮性能的物质,对于高品质的纤维素基包装至关重要。本研究的重点是使用三种化学组合对浓度分别为 2、2.5 和 3wt% 的 TEMPO 氧化纤维素纳米纤维进行改性:"磷酸二氢铵+白蛋白"、"二氧化硅+甲基三甲氧基硅烷 "以及所有四种成分的混合物。每种组合的含量均为 14%,涂布重量为 3.5 g.m-2,涂布在生产的纸板表面。阻燃性分析结果表明,采用四种组合的 3wt% 改性 TEMPO 氧化 CNF 在制备的纸板中具有合适的防火性能,这主要归功于膨胀性磷基阻燃剂。这些阻燃剂可降低峰值热释放率,使其与热释放温度成函数关系。此外,硅基团通过阻断功能性羟基,诱导纤维素纳米纤维的疏水性,这一点可通过接触角和吸水率测量得到。在纤维素纳米纤维中加入可湿性生物阻燃剂并将其涂覆在纤维素基体上后,拉伸强度明显提高。此外,根据 FESEM 分析,当 CNF 的固含量分别从 2wt% 增加到 2.5wt% 和 3wt% 时,纸板表面的粗糙度和均匀性也有所提高。这种改性系统有望成为高质量药品和卫生包装的基础基材,为不可回收塑料提供可降解的替代品,实现生态友好的优势。
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来源期刊
European Journal of Wood and Wood Products
European Journal of Wood and Wood Products 工程技术-材料科学:纸与木材
CiteScore
5.40
自引率
3.80%
发文量
124
审稿时长
6.0 months
期刊介绍: European Journal of Wood and Wood Products reports on original research and new developments in the field of wood and wood products and their biological, chemical, physical as well as mechanical and technological properties, processes and uses. Subjects range from roundwood to wood based products, composite materials and structural applications, with related jointing techniques. Moreover, it deals with wood as a chemical raw material, source of energy as well as with inter-disciplinary aspects of environmental assessment and international markets. European Journal of Wood and Wood Products aims at promoting international scientific communication and transfer of new technologies from research into practice.
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