Abstract
In order to improve thermal conductivity, energy performance, and combustion performance of the aluminum-containing thermite, nanocarbon materials were added to thermite. Aluminum/molybdenum and trioxide/nanocarbon materials (Al/MoO3/NCM) were fabricated by electrostatic spinning technology. The Al and MoO3 particles of the nAl/MoO3/NCM thermite are much smaller than nitrocellulose (NC); thus, the two components can be better attached to NC fibers. Results on thermal conductivity demonstrated that the addition of NCM can improve the thermal conductivity of Al/MoO3, and the addition of reduced graphene oxide (RGO) has a more significant impact on thermal conductivity. Energy performance analysis results indicated that the energy performance of Al/MoO3/NCM thermite spinning is the best when the value of combustion oxygen equivalent ratio (Φ) is 0.90–1.00. The combustion performance results show that the addition of NCM can significantly increase the combustion rate of thermites, and the addition of RGO improves its combustion rate the most, followed by carbon nanotubes (CNT) and nanoflake graphite (NFG) being the lowest. By changing the shape of the Al/MoO3/NCM charge and the internal composition of the charge, the sensitivity of the agent can be adjusted, and the matching performance and use performance of the electric igniter can be improved.
Highlights
Thermite is a mixture of metal fuel and metal oxide, and it can undergo a violent oxidation–reduction reaction under external energy stimulation
The particles of the micron and sub-micron Al/MoO3 /Nanocarbon materials (NCMs) thermite cannot be attached to the NC fiber, the components can be effectively dispersed and uniformly mixed in Figure 2c,f, which can be proved5 from of 16 the corresponding microzone element distribution map
Al/MoO3 /NCMs were fabricated via electrostatic spinning technology
Summary
Thermite is a mixture of metal fuel and metal oxide, and it can undergo a violent oxidation–reduction reaction under external energy stimulation. Thermite has been widely used in the energy of incendiary agents, ignition powders, high-energy explosives, and solid rocket propellants [1,2]. Due to its excellent combustion and energy properties, such as high energy density, adjustable energy release rate, ignition sensitivity and reaction speed, and non-toxic reaction products, nanothermite has attracted widespread attention in the past decade. Adding a small amount of graphite to energetic materials, such as explosives and propellants, can increase dispersion properties, prevent static electricity, change the burning rate, and reduce sensitivity [7,8]. Carbon nanotubes are functionalized or combined with other substances and introduced into the energetic material system, which can improve ignition, energy release, and other properties of the agent [9,10,11,12]. Determination of the effective properties of CNT-reinforced composite is a highly complicated
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