材料科学
高氯酸铵
燃烧
聚偏氟乙烯
制作
复合材料
纳米复合材料
成核
点火系统
自燃温度
热分解
微尺度化学
纳米颗粒
热喷涂
放热反应
化学工程
纳米技术
化学
复合数
热力学
有机化学
聚合物
数学教育
病理
工程类
物理
替代医学
医学
涂层
数学
作者
Haiyang Wang,Dylan J. Kline,Miles C. Rehwoldt,Tao Wu,Wenji Zhao,Xizheng Wang,Michael R. Zachariah
出处
期刊:ACS applied polymer materials
[American Chemical Society]
日期:2019-03-05
卷期号:1 (5): 982-989
被引量:40
标识
DOI:10.1021/acsapm.9b00016
摘要
With the advent of additive manufacturing methods combined with the increased interest in using nanoparticle components to formulate energetics materials, structure–function relationships and manufacturing methods have become intertwined. In this article, we explore three different approaches to formulate composites and evaluate the combustion properties. Here polyvinylidene fluoride (PVDF) was used to assemble both aluminum nanoparticles (Al NPs) and ammonium perchlorate (AP). Three different fabrication techniques, 3D-print, electrospray (E-spray), and electrospin (E-spin), were employed in this work. Composites of Al/PVDF and composites with a high oxidizer content, employing AP, were studied. The relationship between architecture and the burning rate of both Al/PVDF and Al/AP/PVDF was investigated by studying the thermal decomposition at high and low heating rates, and flame temperatures via the color camera pyrometry on microscale ignition/combustion events. By studying the release of HF, ignition temperatures, and the flame front, we propose a mechanism for the combustion of the multicomponent energetic films. Flame temperature, completeness of reaction, and a significant difference in ignition temperature appear to favor the E-spray material. However, the large difference in propagation velocity between E-spray and E-spun, given the minor difference in density, clearly points to the importance of microarchitecture on reaction properties. The relative energy release rate of E-spun Al/PVDF compared to the E-sprayed and 3-D printed case is an enhancement of ∼6× and 18×, respectively, and the energy release rate of E-spun Al/AP/PVDF is ∼19× higher than that of E-sprayed and 3D-printed samples. This implies that the lowest density spun material offers the highest mass energy release rate by far.
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