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两种天然丝瓜络纤维的结构与性能深度分析

In-Depth Analysis of the Structure and Properties of Two Varieties of Natural Luffa Sponge Fibers.

作者信息

Chen Yuxia, Su Na, Zhang Kaiting, Zhu Shiliu, Zhao Lei, Fang Fei, Ren Linyan, Guo Yong

机构信息

College of Forest and Garden, Anhui Agricultural University, Hefei 230036, China.

出版信息

Materials (Basel). 2017 Apr 29;10(5):479. doi: 10.3390/ma10050479.

DOI:10.3390/ma10050479
PMID:28772838
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5459036/
Abstract

The advancement in science and technology has led to luffa sponge (LS) being widely used as a natural material in industrial application because of its polyporous structure and light texture. To enhance the utility of LS fibers as the reinforcement of lightweight composite materials, the current study investigates their water absorption, mechanical properties, anatomical characteristics and thermal performance. Hence, moisture regain and tensile properties of LS fiber bundles were measured in accordance with American Society for Testing and Materials (ASTM) standards while their structural characteristics were investigated via microscopic observation. Scanning electron microscopy (SEM) was used to observe the surface morphology and fractured surface of fiber bundles. The test results show that the special structure where the phloem tissues degenerate to cavities had a significant influence on the mechanical properties of LS fiber bundles. Additionally, the transverse sectional area occupied by fibers in a fiber bundle (S), wall thickness, ratio of wall to lumen of fiber cell, and crystallinity of cellulose had substantial impact on the mechanical properties of LS fiber bundles. Furthermore, the density of fiber bundles of LS ranged within 385.46-468.70 kg/m³, significantly less than that of jute (1360.40 kg/m³) and Arenga engleri (950.20 kg/m³). However, LS fiber bundles demonstrated superior specific modulus than Arenga engleri.

摘要

科学技术的进步使得丝瓜海绵(LS)因其多孔结构和轻质质地而被广泛用作工业应用中的天然材料。为了提高LS纤维作为轻质复合材料增强材料的实用性,本研究调查了它们的吸水性、力学性能、解剖特征和热性能。因此,按照美国材料与试验协会(ASTM)标准测量了LS纤维束的回潮率和拉伸性能,同时通过显微镜观察研究了它们的结构特征。使用扫描电子显微镜(SEM)观察纤维束的表面形态和断裂表面。试验结果表明,韧皮组织退化为空腔的特殊结构对LS纤维束的力学性能有显著影响。此外,纤维束中纤维所占的横截面积(S)、壁厚、纤维细胞壁腔比以及纤维素的结晶度对LS纤维束的力学性能有重大影响。此外,LS纤维束的密度在385.46 - 468.70 kg/m³范围内,明显低于黄麻(1360.40 kg/m³)和砂糖椰子(950.20 kg/m³)。然而,LS纤维束的比模量优于砂糖椰子。

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