透明全纳米纤维素层压板的性能-厚度相关性

IF 0.3 4区 工程技术 Q4 MATERIALS SCIENCE, TEXTILES
Shun Ishioka, Takayuki Hirano, Nobuhiro Matoba, Noriyuki Isobe, Shuji Fujisawa, Tsuguyuki Saito
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引用次数: 0

摘要

仅由纤维素纳米纤维(CNFs)组成的毫米厚层压材料具有光学透明性、高强度和热各向异性。这些CNF层压板是通过堆叠薄的CNF薄片,并将分散在水/乙醇混合物中的CNF作为粘合剂,然后热压制成的。层叠CNF片材的数量可以在很宽的尺寸范围内控制层叠厚度。本文报道了这种全cnf板材料的材料性能与层压厚度之间的关系。采用1 ~ 15片CNF片材,制备了不同厚度(~30 ~ 500 μm)的CNF层压板。层压板中CNFs的结晶度通过增加堆叠层的数量而大大提高。这种结晶度的趋势可以解释为在热压过程中干燥较厚的层压板所需的时间较长。层合板的可见光透过率用Beer-Lambert定律描述得很好;薄片间结合界面处的散射和/或反射估计小得可以忽略不计。层合板的弹性模量随层数的增加而增加,最高可达36gpa。这种增加的趋势可以用层压板中CNFs的结晶度增强来解释。层合板的抗拉强度变化较大,且随层数的变化趋势不明显。热导率随着层数的增加而增加,这是由于结晶度的提高。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Property-Thickness Correlations of Transparent All-Nanocellulose Laminates
Millimeter-thick laminated materials comprised solely of cellulose nanofibers (CNFs) combine optical transparency, high strength, and thermal anisotropy. These CNF laminates were fabricated by stacking thin CNF sheets and applying CNFs dispersed in a water/ethanol mixture as binder, followed by hot pressing. The number of stacked CNF sheets can control the laminate thickness within a wide range of dimensions. Here, we report the correlation between the material properties and laminate thickness of this all-CNF plate material. CNF laminates with different thicknesses (~30-500 μm) were fabricated using 1-15 CNF sheets. The crystallinity of the CNFs in the laminates was greatly enhanced by increasing the number of stacked sheets. This trend in crystallinity is explained by the longer period of time required for drying thicker laminates in the hot press process. The visible-light transmittance of the laminates was well described by the Beer–Lambert law; scattering and/or reflection at the binding interface between sheets were estimated to be negligibly small. The elastic modulus of the laminates increased with increasing number of stacked sheets and reached a maximum of 36 GPa. This increasing trend was explained by the enhanced crystallinity of the CNFs in the laminates. The tensile strengths of the laminates varied greatly, and no clear trend as a function of the number of stacked sheets was found. The thermal conductivity increased with increasing number of stacked sheets, which was attributed to the enhanced crystallinity.
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来源期刊
Journal of Fiber Science and Technology
Journal of Fiber Science and Technology Materials Science-Materials Science (miscellaneous)
CiteScore
0.50
自引率
0.00%
发文量
17
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