Effects of nano-metal oxide additives on ignition and combustion properties of MICs-boron rich fuels

IF 5 Q1 ENGINEERING, MULTIDISCIPLINARY Defence Technology(防务技术) Pub Date : 2024-09-01 DOI:10.1016/j.dt.2024.03.005
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Abstract

Boron has been considered a promising powdered metal fuel for enhancing composite propellants' energy output due to its high energy density. However, the high ignition temperature and low combustion efficiency limit the application of boron powder due to the high boiling point of the boron oxide layer. Much research is ongoing to overcome these shortcomings, and one potential approach is to introduce a small quantity of metal oxide additives to promote the reaction of boron. This study prepared boron-rich fuels with 10 wt% of eight nano-metal oxide additives by mechanical ball milling. The effect of metal oxides on the thermo-oxidation, ignition, and combustion properties of boron powder was comprehensively studied by the thermogravimetric analysis (TG), the electrically heated filament setup (T-jump), and the laser-induced combustion experiments. TG experiments at 5 K/min found that Bi2O3, MoO3, TiO2, Fe2O3, and CuO can promote thermo-oxidation of boron. Compared to pure boron, Tonset can be reduced from 569 °C to a minimum of 449 °C (B/Bi2O3). Infrared temperature measurement in T-jump tests showed that when heated by an electric heating wire at rates from 1000 K/s to 25000 K/s, the ignition temperatures of B/Bi2O3 are the lowest, even lower than the melting point of boron oxide. Ignition images and SEM for the products further showed that the high heating rate is beneficial to the rapid reaction of boron powder in the single-particle combustion state. Fuels (B/Bi2O3, B/MoO3, and B/CuO) were mixed with the oxidant AP and ignited by laser to study the combustion performance. The results showed that B/CuO/AP has the largest flame area, the highest BO2 characteristic spectral intensity, and the largest burn rate for powder lines. To combine the advantages of CuO and Bi2O3, binary metal oxide (CBO, mass ratio of 3:1) was prepared and the test results showed that CBO can very well improve both ignition and combustion properties of boron. Especially B/CBO/AP has the highest burn rate compared with all fuels containing other additives. It was found that multi-component metal-oxide additive can more synergistically improve the reaction characteristics of boron powder than unary additive. These findings contribute to the development of boron-rich fuels and their application in propellants.

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纳米金属氧化物添加剂对富 MICs 硼燃料点火和燃烧特性的影响
硼因其能量密度高,一直被认为是一种很有前途的粉末状金属燃料,可用于提高复合推进剂的能量输出。然而,由于氧化硼层的沸点较高,点火温度高、燃烧效率低,限制了硼粉的应用。为克服这些缺点,目前正在进行大量研究,其中一种可能的方法是引入少量金属氧化物添加剂来促进硼的反应。本研究通过机械球磨法制备了富硼燃料,其中含有 10 wt% 的八种纳米金属氧化物添加剂。通过热重分析(TG)、电加热丝装置(T-jump)和激光诱导燃烧实验,全面研究了金属氧化物对硼粉热氧化、着火和燃烧性能的影响。在 5 K/min 下进行的 TG 实验发现,Bi2O3、MoO3、TiO2、Fe2O3 和 CuO 可促进硼的热氧化。与纯硼相比,Tonset 可从 569 ℃ 降至最低 449 ℃(B/Bi2O3)。T-jump 试验中的红外温度测量显示,当电热丝以 1000 K/s 至 25000 K/s 的速度加热时,B/Bi2O3 的点火温度最低,甚至低于氧化硼的熔点。产品的点火图像和扫描电镜进一步表明,高加热速率有利于硼粉在单颗粒燃烧状态下快速反应。将燃料(B/Bi2O3、B/MoO3 和 B/CuO)与氧化剂 AP 混合并用激光点燃,研究其燃烧性能。结果表明,B/CuO/AP 具有最大的火焰面积、最高的 BO2 特征光谱强度和最大的粉末线燃烧速率。为了结合 CuO 和 Bi2O3 的优点,制备了二元金属氧化物(CBO,质量比为 3:1),试验结果表明,CBO 可以很好地改善硼的点火和燃烧性能。试验结果表明,CBO 能很好地改善硼的点火和燃烧性能,尤其是 B/CBO/AP 与含有其他添加剂的所有燃料相比,燃烧率最高。研究发现,多组分金属氧化物添加剂比单组分添加剂更能协同改善硼粉的反应特性。这些发现有助于富硼燃料的开发及其在推进剂中的应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Defence Technology(防务技术)
Defence Technology(防务技术) Mechanical Engineering, Control and Systems Engineering, Industrial and Manufacturing Engineering
CiteScore
8.70
自引率
0.00%
发文量
728
审稿时长
25 days
期刊介绍: Defence Technology, a peer reviewed journal, is published monthly and aims to become the best international academic exchange platform for the research related to defence technology. It publishes original research papers having direct bearing on defence, with a balanced coverage on analytical, experimental, numerical simulation and applied investigations. It covers various disciplines of science, technology and engineering.
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