Mn/Bi2O3烟火延期药的性能研究

IF 0.7 4区工程技术 Q4 CHEMISTRY, APPLIED

Central European Journal of Energetic Materials Pub Date : 2021-03-30 DOI:10.22211/CEJEM/134798

S. Tichapondwa, Shasha Guo, W. Roux

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引用次数: 2

摘要

化学延时雷管在矿山爆破中应用广泛。为了实现有效的爆破，引爆必须按照特定的发射模式，按照精确控制的时间顺序进行。硅燃料基烟火组合物广泛应用于矿山雷管中，并得到了很好的研究。然而，其中一些配方被认为是有问题的，因为它们含有重金属，这些重金属具有生物累积性，对环境有毒。因此，需要探索适合这些应用的替代配方。锰燃料系统由于其金属性质和锰燃料的几种氧化态而具有吸引力。本研究的重点是表征Mn/Bi2O3组合物在慢到中等延时应用中的燃烧性能。所述组合物支持在惰性氦气氛中在25至55重量%的Mn范围内的燃烧。在开放式燃烧试验中记录了2.5至11.2 mm·s–1的燃烧率，而在玻璃管中进行的封闭式燃烧试验的燃烧率为6.3至11.2 mm•s–1。反应产物的X射线衍射分析和热力学模拟都证实了MnO和Bi是主要的反应产物，还检测到了未反应的Mn和Bi2O3。这表明该组合物的主要反应是简单的铝热剂型反应。

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Performance of Mn/Bi2O3 Pyrotechnic Time Delay Compositions

Chemical time delay detonators are used widely in mine blasting applications. In order to achieve effective blasting, detonations must follow a precisely controlled timing sequence in a specified firing pattern. Silicon fuelbased pyrotechnic compositions are widely used in mining detonators and are well studied. However, some of these formulations are deemed to be problematic, as they contain heavy metals which are bio-accumulative and toxic to the environment. Therefore, there is need to explore alternative formulations which are suitable for these applications. Manganese-fueled systems are attractive due to their metallic properties and several oxidation states of the manganese fuel. This study focused on characterizing the burn properties of Mn/Bi2O3 compositions for slow to intermediate time delay applications. The compositions supported combustion in the 25 to 55 wt.% Mn range in an inert helium atmosphere. Burn rates between 2.5 and 11.2 mm·s–1 were recorded in open burn tests, whilst closed burn tests in glass tubes resulted in burn rates of 6.3 to 11.2 mm·s–1. Both X-ray diffraction analysis of the reaction products and thermodynamic simulations confirmed that MnO and Bi are the main reaction products, with unreacted Mn and Bi2O3 also being detected. This suggests that the dominant reaction for this composition is a simple thermite-type reaction.

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来源期刊

Central European Journal of Energetic Materials CHEMISTRY, APPLIED-ENGINEERING, CHEMICAL

CiteScore

1.80

自引率

25.00%

发文量

审稿时长

>12 weeks

期刊介绍： CEJEM – the newest in Europe scientific journal on energetic materials It provides a forum for scientists interested in the exchange of practical and theoretical knowledge concerning energetic materials: propellants, explosives and pyrotechnics. The journal focuses in particular on the latest results of research on various problems of energetic materials. Topics: ignition, combustion and detonation phenomenon; formulation, synthesis and processing; analysis and thermal decomposition; toxicological, environmental and safety aspects of energetic materials production, application, utilization and demilitarization; molecular orbital calculations; detonation properties and ballistics; biotechnology and hazards testing CEJEM presents original research and interesting reviews. Contributions are from experts in chemistry, physics and engineering from leading research centers in Europe, America and Asia. All submissions are independently refereed by Editorial Board members and by external referees chosen on international basis.