纳米复合含能材料的制备方法、复合体系及其性能的研究进展

doi:10.11896/cldb.18120114

材料导报

2019, Vol. 33

Issue (23): 3939-3948 https://doi.org/10.11896/cldb.18120114

无机非金属及其复合材料

纳米复合含能材料的制备方法、复合体系及其性能的研究进展

任秀秀, 赵省向, 韩仲熙, 邢晓玲

西安近代化学研究所,西安 710065

Research Progress on Preparation Methods, Composite System and Its Propertyof Nano-Composite Energetic Materials

REN Xiuxiu, ZHAO Shengxiang, HAN Zhongxi, XING Xiaoling

Xi’an Modern Chemistry Research Institute, Xi’an 710065

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摘要纳米复合含能材料是目前世界各国军事领域重点发展的新型含能材料。纳米复合含能材料的特征主要体现在纳米级到原子级上的反应性组分的紧密混合,其具有比表面积大、化学反应活性高、扩散距离短、反应物之间接触面积很大等优点,促进了复合含能材料的快速燃烧和高效能量释放。纳米复合含能材料的高能量密度以及高能量释放速率吸引了研究人员的广泛关注,因此纳米复合含能材料的制备研究发展迅速。常用的制备方法有溶胶-凝胶法、高能球磨法、溶剂-非溶剂法、喷雾干燥法、超临界流体法等;新型的制备方法有喷雾闪蒸、两步法、自组装法等。另外,将多种制备工艺相结合以制备性能更优异的纳米复合含能材料也是一种途径。
纳米复合含能材料体系主要有四种:(1)单质炸药/氧化剂分散在连续介质中的纳米复合材料;(2)亚稳态分子间复合物(MICs);(3)碳纳米管基复合含能材料;(4)纳米多孔硅/氧化剂复合含能材料。根据不同复合体系的反应物特点,需要选用适宜的制备方法,同时,不同的复合体系也有其适合的应用领域。
本文从纳米复合含能材料的制备方法、纳米复合含能材料的复合体系及其性能两方面,详尽地介绍了纳米复合含能材料的常规制备方法和新型制备方法,并归纳了四类主要复合体系的组分特点及典型配方性能。

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关键词: 纳米复合含能材料超级铝热剂碳纳米管亚稳态分子间复合物多孔硅

Abstract: Nano-composite energetic materials are a new type of energetic materials which have been developed in the military field of all countries. Nano-composite energetic materials are characterized by intimate mixing of reactive components from nanometer to atomic level, which have the advantages of high specific surface area, high chemical reactivity, short diffusion distance, and large contact area between reac-tants. Thus, it promotes the rapid combustion and efficient energy release of the composite energetic materials. The high energy density and high energy release rate of nano-composite energetic materials have provoked wide concern of researchers, so the preparation of nano-composite energetic materials has been rapidly developed. Commonly used preparation methods include sol-gel method, high energy ball milling method, solvent-nonsolvent method, spray drying method, supercritical fluid method, etc. New preparation techniques include spray flashing, two-step method, self-assembly method, etc. In addition, it is one of the ways to combine various preparation processes to prepare nanocomposite energetic materials with superior performance.
There are four main types of nano-composite energetic materials systems: (i) nano-composites dispersed in continuous medium by simple explosives/oxidants; (ii) metastable intermolecular complexes (MICs); (iii) carbon nanotube-based composites energetic materials; (iv) nano-porous silicon/oxidant composite energetic materials. According to the characteristics of the reactants of different composite systems, it is necessary to select suitable preparation techniques. At the same time, different composite systems also have their applicable application fields.
In this paper, we introduce the preparation techniques, the composite system and its property of the nano-composite energetic materials in detail. The conventional preparation techniques and the novel preparation techniques of the nano-composite energetic material are described. At last, we summarize the composition characteristics and typical formulation properties of the four main compound systems.

Key words: nano-composite energetic materials super thermite carbon nano-tubes metastable intermolecule complex porous silicon

出版日期: 2019-12-10 发布日期: 2019-09-30

ZTFLH:

TJ55

作者简介: 任秀秀,2016年6月毕业于吉林大学材料物理专业,获得工学学士学位。现为西安近代化学研究所硕士研究生,师从赵省向研究员。主要研究方向为复合含能材料及其炸药配方。
赵省向,西安近代化学研究所研究员,博士研究生导师。毕业于南京理工大学,获得博士学位。现为中国兵器工业集团科技带头人,是国内火炸药领域的专家,设计了多种用于侵彻武器的炸药配方。作为项目总负责人,先后完成了多项重大军工项目。

引用本文:

任秀秀, 赵省向, 韩仲熙, 邢晓玲. 纳米复合含能材料的制备方法、复合体系及其性能的研究进展[J]. 材料导报, 2019, 33(23): 3939-3948.
REN Xiuxiu, ZHAO Shengxiang, HAN Zhongxi, XING Xiaoling. Research Progress on Preparation Methods, Composite System and Its Propertyof Nano-Composite Energetic Materials. Materials Reports, 2019, 33(23): 3939-3948.

链接本文:

http://www.mater-rep.com/CN/10.11896/cldb.18120114 或 http://www.mater-rep.com/CN/Y2019/V33/I23/3939

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