共查询到19条相似文献,搜索用时 187 毫秒
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碳纳米管纤维是一种碳纳米管的宏观聚集体,是由碳纳米管及管束组装而成的连续纱线,具有高强、高韧、高导电等特性,在结构功能一体化复合材料、纤维状能源器件、人工肌肉以及轻质导电线缆等领域具有非常广泛的应用前景。经过近二十年的发展,碳纳米管纤维材料在连续制备技术、高性能化以及应用探索等方面相继取得了突破性的研究进展。本文总结了碳纳米管纤维材料的发展历程,对比介绍了碳纳米管纤维的不同连续制备与组装技术,重点讨论了碳纳米管纤维结构与性能之间的关联规律,并对目前碳纳米管纤维的高性能化方法进行了综述。在此基础上,对碳纳米管纤维材料的发展思路以及未来的应用方向进行了展望。 相似文献
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有机高性能纤维是全球化纤工业的重要发展方向之一。提升现有纤维力学性能的同时研发新型结构功能一体化的纤维对提升我国在航天航空等领域的国际地位具有重要意义。以石墨烯和碳纳米管为代表的烯碳材料具备优异的力、电、热学等性能,可用于改性传统有机高性能纤维。通过制备不同物化性质的烯碳材料并设计合理的改性方式,可将烯碳材料优异的性能传递到传统纤维中,形成具备更高力、电、热学等性能的烯碳材料改性有机高性能纤维。本文首先综述了烯碳材料改性有机高性能纤维的制备方式,包括烯碳材料的分散与功能化、烯碳材料对有机高性能纤维的改性方法,阐述了烯碳材料改性有机高性能纤维的力、电、热学等性能以及烯碳材料的增强机理,进而总结了烯碳材料改性有机高性能纤维的应用,并对其现存的挑战和未来的发展做出展望。 相似文献
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概述了近几年来本研究组在高分子材料辐照接枝制备功能性高分子材料方面的研究进展.分别以丙烯酸、顺丁烯二酸、苯乙烯接枝聚四氟乙烯纤维,制备了不同酸性的聚四氟乙烯功能纤维.以N-异丙基丙烯酰胺接枝壳聚糖制备温度及pH敏感材料,获得了性能特异的新型功能性高分子材料.报道了该类新型功能高分子材料的各种特异性能,如对金属离子优异的分离、吸附和解吸性能、超强酸性和一系列潜在用途. 相似文献
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随着小型化、可穿戴等特征的智能电子以及物联网传感设备的发展,新型纤维状柔性化、小型化电化学储能器件已成为重要的研究方向。同时,对纤维材料和柔性储能器件的性能提出了更高的要求,如可任意弯折、可拉伸、可折叠、高储能密度等。石墨烯纤维具有独特的结构、优异的导电性、良好机械性能和电化学性质,已证明了是一种极具前景、高性能的新型纤维状柔性储能材料。目前,研究者已开发了多种石墨烯基纤维微观结构的调控策略来进一步改进其性能。本文首先系统总结了石墨烯基纤维的制备方法和其性能提升的策略,然后详细讨论其在柔性化纤维状超级电容器、金属离子电池、热电发电机、太阳能电池和相变材料等储能领域中的最新应用进展。最后,对石墨烯基纤维在能源存储和转换领域中存在的挑战和机会进行了展望。 相似文献
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碳纳米管改性聚苯硫醚熔纺纤维的结构与性能研究 总被引:1,自引:0,他引:1
将多壁碳纳米管(MWCNTs)和聚苯硫醚(PPS)经过熔融挤出后制备成复合材料切片,并采用熔融纺丝法制得碳纳米管改性聚苯硫醚复合纤维.采用扫描电镜(SEM)、拉曼光谱、示差扫描量热分析(DSC)、动态机械分析(DMA)以及力学性能测试等表征手段研究了复合纤维中碳管的分散状态,与基体的界面作用,复合纤维的结晶性能以及力学性能,从而探讨了聚苯硫醚/碳纳米管复合纤维体系的微观结构与宏观性能之间的关系.研究表明,聚苯硫醚分子结构与碳纳米管之间具有的π-π共轭作用使碳管较为均匀的分散在基体中,界面结合较为紧密.同时熔融纺丝过程中的拉伸作用使碳管进一步解缠并使碳管沿纤维拉伸方向取向.另一方面,拉曼光谱显示拉伸作用有效地增强了界面作用,有利于外界应力的传递.碳管的良好分散以及强的界面作用使复合纤维力学性能得到大幅度的提高,当碳管含量达到5 wt%时,复合纤维的模量有了明显的提高,拉伸强度较纯PPS纤维提高了近220%. 相似文献
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Biocomposites based on poly(butylene succinate) (PBS) and curaua fibers have been produced by compression molding, and investigated as a function of fiber length and amount. Mechanical tests, water uptake and morphology studies were carried out in order to assess the composite features according to the characteristics of the reinforcing agents. It turns out that the impact and flexural strengths increase with fiber content. Moreover, the fiber length, varying from 1 to 4 cm for the composite reinforced with 20 wt% of fiber, influences impact strength, which is higher for shorter than for longer fibers. However, flexural strength is not greatly influenced by the length of the fibers. Water uptake studies reveal a higher sensitivity of the material to fiber content rather than fiber size. Biocomposites, which are characterized by enhanced mechanical properties as compared to PBS, can have different applications, for example in rigid packaging or interior car parts. 相似文献
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Saito N Aoki K Usui Y Shimizu M Hara K Narita N Ogihara N Nakamura K Ishigaki N Kato H Haniu H Taruta S Kim YA Endo M 《Chemical Society reviews》2011,40(7):3824-3834
Carbon fibers are state-of-the-art materials with properties that include being light weight, high strength, and chemically stable, and are applied in various fields including aeronautical science and space science. Investigation of applications of carbon fibers to biomaterials was started 30 or more years ago, and various products have been developed. Because the latest technological progress has realized nano-level control of carbon fibers, applications to biomaterials have also progressed to the age of nano-size. Carbon fibers with diameters in the nano-scale (carbon nanofibers) dramatically improve the functions of conventional biomaterials and make the development of new composite materials possible. Carbon nanofibers also open possibilities for new applications in regenerative medicine and cancer treatment. The first three-dimensional constructions with carbon nanofibers have been realized, and it has been found that the materials could be used as excellent scaffolding for bone tissue regeneration. In this critical review, we summarize the history of carbon fiber application to the biomaterials and describe future perspectives in the new age of nano-level control of carbon fibers (122 references). 相似文献
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通过优化聚(R-3-羟基丁酸酯-co-R-3-羟基己酸酯)(PHBHHx)原纤维的制备工艺,采用较低的挤出温度,极大加快了原纤维的结晶速率,缩短了后续加工所需时间.随后通过“等温结晶-拉伸-固定长度退火”的方法制备了力学性能优异的PHBHHx纤维,纤维平均拉伸强度达262 MPa,断裂伸长率大于120%.利用二维X射线衍射和拉曼光谱研究了纤维的晶体结构,结果表明高强度的PHBHHx纤维中晶区和非晶区的分子链都具有很好的取向性,并且纤维中没有形成β晶结构.进一步研究发现通过改变退火工艺,可以很方便地调节纤维的力学性能,使得PHBHHx材料可以广泛应用于不同的领域. 相似文献
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Despite that poly (lactic acid) (PLA) has satisfactory biodegradation in vivo, its application in biomedicine is restricted due to its unsatisfactory cytocompatibility. Silk fiber (SF) has outstanding biocompatibility and silk fibroin protein obtained from silk by degumming has good hydrophilicity. Therefore, combining the PLA and silk can improve hydrophilicity of PLA to apply as biomedical materials. In this study, different concentrations of sodium hypochlorite (NaClO) were used to separate the silk to obtain multiscale silk fibers (MSFs), which were implanted into the PLA electrospun fibrous membranes (EFMs). The morphology and structure of silk fibers separated by different concentrations of NaClO were studied by Zetasizer Nano ZS, UV spectroscopy, Fourier transform infrared spectroscopy, X-ray diffraction, and scanning electron microscopy. Moreover, the biocompatibility of the surface-modified PLA composite membranes by MSFs was investigated by cell cultivation and proliferation. The results showed that the surface-modified PLA EFMs through MSF bundles obtained from NaClO split silk exhibited a certain improvement on PLA hydrophilicity and enhancement on cellular compatibility, which could have a broad prospect in the practical application of biomedical materials. 相似文献
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近十年,有机聚合物及其复合热电材料与柔性器件取得了显著进展,在废热回收利用、可穿戴电子学、软体机器人和物联网等领域有广泛的应用.其中,聚(3,4-乙烯二氧噻吩):聚苯乙烯磺酸(PEDOT:PSS)是迄今研究最多也是性能最高的聚合物体系.本文对近年来有关PEDOT:PSS热电性能有效提升主要策略的文献报道进行了总结.首先,从PEDOT:PSS的二次掺杂/去掺杂、酸或碱处理和离子液体处理方面等,重点论述了掺杂/去掺杂策略的研究进展;然后,分别从改善聚集态结构、构筑PEDOT微纳米结构和与碳纳米材料复合等3个方面,重点介绍了采用此3种策略提升PEDOT:PSS热电性能的研究进展;最后,对该领域进行总结,提出了开展进一步研究的建议,并对其未来发展前景进行展望. 相似文献
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Balaji K.V. Kamyar Shirvanimoghaddam Guru Sankar Rajan Amanda V. Ellis Minoo Naebe 《Materials Today Chemistry》2020
Balancing the performance, durability and safety requirements of automotive systems with the regulatory landscape in an environment of climate change has accelerated the search for sustainable fiber reinforced polymer composites for automobile structures. Glass fiber reinforced thermoplastic polymer composites (GFRP) are widely used in certain structures like front end modules and liftgate; However, they cannot be used in more demanding applications due to their low mechanical properties. Carbon fiber reinforced thermoplastic polymer composites (CFRP) are promising candidates for applications like bonnet, but their use is constrained by cost. Basalt fiber reinforced thermoplastic polymer composites (BFRP) are sustainable materials that can be positioned between GFRP and CFRP in terms of performance and cost-effectiveness. The mechanical performance of the BFRP depend on the quality of the fiber-matrix interface that aids in efficient load transfer from the matrix to the fiber. Typically, basalt fibers are inert in nature and need treatments to improve its adhesion to polymeric matrices. The major chemical treatments that are reviewed in this article include matrix functionalization, silane treatment, functionalized nanomaterial coating and plasma polymerization. The physical treatments reviewed include plasma treatment and milling. It is evident that chemically treating the basalt fiber with a functionalized nanomaterial yields BFRP with a good stiffness – toughness balance that can be used for challenging metal replacements as also in new emerging areas like sensing and 3D printing. 相似文献
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《高分子科学杂志,A辑:纯化学与应用化学》2013,50(12):1231-1243
Poly(glycolic acid) (PGA) has long been a popular polymer in the tissue engineering field. PGA possesses many favorable properties such as biocompatibility, bioabsorbability, and tensile strength. The traditional fiber formation techniques of melt extrusion and cold-drawing are generally limited to fibers of 10–12 μm in diameter. Electrostatic spinning, or electrospinning, is an attractive approach for the production of much smaller diameter fibers which are of interest as tissue engineering scaffolds. We demonstrate the ability to control the fiber diameter of PGA as a function of solution concentration and fiber orientation, as well as show a correlation between the fiber orientation, elastic modulu, and strain to failure of PGA in a uniaxial model. 相似文献