Ensuring the potential of Caryota urens fruit stem fibre as biodegradable reinforcement for polymer composite structural applications

IF 3.5 4区 工程技术 Q3 ENERGY & FUELS
Loganathan T G, Vinoth Kumar K, Balasubramanian M, Venkatachalam Gopalan, Shukur Bin Abu Hasan, Balaji Krishnabharathi A
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Abstract

The work deals with the extraction and characterization of fibre from the unexplored Caryota urens fruit stem (CUFS). The spadix of Caryota urens (CU) has compound spadix inflorescence with a core and branching fruit stems covered by a boat-shaped spathe. The ripened fruit stems of the spadix after the removal of peripheral fruits and their residues are used for fibre extraction process. The fibre from the fruit stem is extracted by soaking it in portable water and then pounded. The mechanical and physical properties of the unexplored CUFS are quantified by tensile test, XRD analysis, SEM, FTIR spectroscopy, and TGA analysis to ascertain their ability to be a reinforcement for bio-composites. The maximum tensile strength and strain of 10 mm fibre are 11 N and 9.9%. The XRD analysis records a 63.39% crystallinity index and a 5.078 nm crystal size. The TGA recorded the thermal stability of fibre at 250 °C with a mass reduction rate of 5.35% per min. The SEM and FTIR report the favourable features of fibre towards adhesion and interfacial bonding with the matrix. Such quantified fibres are woven as unidirectional mats and treated by silane to four variants of epoxy laminates with and without Sisal hybridization. The laminate configurations F1 and F3 are 4 layers of CUFS mat without and with silane treatment, whereas F2 and F4 represent hybridization with Sisal (Sisal/CUFS/CUFS/Sisal) and silane treated, respectively. The silane treatment has significantly improved the storage modulus of the CUFS fibre composite up to 36.96% and the CUFS–Sisal hybrid composite to 128%. The tensile strength of the silane-treated laminate (F3) has increased by 12% over the untreated (F1) laminate attributed to the effect of fibre sizing. However, the combined effect of silane treatment and hybridization has witnessed a 67.7% rise in tensile strength (F4). These characteristics of CU fruit stem fibre ensure the profound calibre to be a potential reinforcement in bio-composite for lightweight structural applications.

Abstract Image

确保 Caryota urens 果实茎纤维在聚合物复合结构应用中作为生物可降解加固材料的潜力
这项工作涉及从尚未开发的 Caryota urens 果茎(CUFS)中提取纤维并确定其特征。Caryota urens(CU)的穗状花序为复式穗状花序,有一个核心和分枝果茎,果茎上覆盖着一个船形佛焰苞。穗状花序的成熟果茎在去除外围果实及其残留物后,可用于纤维提取过程。提取果茎纤维的方法是将其浸泡在便携式水中,然后捣碎。通过拉伸试验、XRD 分析、扫描电子显微镜、傅里叶变换红外光谱和 TGA 分析,对未开发的 CUFS 的机械和物理特性进行量化,以确定其作为生物复合材料增强材料的能力。10 毫米纤维的最大拉伸强度和应变分别为 11 牛顿和 9.9%。XRD 分析显示,结晶度指数为 63.39%,晶体尺寸为 5.078 nm。热重分析仪记录了纤维在 250 °C 下的热稳定性,质量减少率为每分钟 5.35%。扫描电子显微镜(SEM)和傅立叶变换红外光谱(FTIR)显示,纤维与基体之间的粘附和界面结合具有良好的特性。这些定量纤维被编织成单向毡,并用硅烷处理成四种不同的环氧树脂层压板(含剑麻杂化和不含剑麻杂化)。层压结构 F1 和 F3 是未经硅烷处理和经硅烷处理的 4 层 CUFS 纤维毡,而 F2 和 F4 则分别代表与剑麻杂化(剑麻/CUFS/CUFS/剑麻)和硅烷处理。经硅烷处理后,CUFS 纤维复合材料的储存模量提高了 36.96%,CUFS-剑麻杂化复合材料的储存模量提高了 128%。经硅烷处理的复合材料(F3)的拉伸强度比未经处理的复合材料(F1)提高了 12%,这归因于纤维施胶的效果。然而,在硅烷处理和杂交的共同作用下,抗拉强度(F4)提高了 67.7%。中大果茎纤维的这些特性确保了它在轻质结构应用的生物复合材料中成为一种潜在的增强材料。
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来源期刊
Biomass Conversion and Biorefinery
Biomass Conversion and Biorefinery Energy-Renewable Energy, Sustainability and the Environment
CiteScore
7.00
自引率
15.00%
发文量
1358
期刊介绍: Biomass Conversion and Biorefinery presents articles and information on research, development and applications in thermo-chemical conversion; physico-chemical conversion and bio-chemical conversion, including all necessary steps for the provision and preparation of the biomass as well as all possible downstream processing steps for the environmentally sound and economically viable provision of energy and chemical products.
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