Abstract
The nanosized powders have gained attention to produce materials exhibiting novel properties and for developing advanced technologies as well. Nanosized materials exhibit substantially favourable qualities such as improved catalytic activity, augmentation in reactivity, and reduction in melting temperature. Several researchers have pointed out the influence of ultrafine aluminium (∼100 nm) and nanoaluminium (<100 nm) on burning rates of the composite solid propellants comprising AP as the oxidizer. The inclusion of ultrafine aluminium augments the burning rate of the composite propellants by means of aluminium particle’s ignition through the leading edge flames (LEFs) anchoring above the interfaces of coarse AP/binder and the binder/fine AP matrix flames as well. The sandwiches containing 15% of nanoaluminium solid loading in the binder lamina exhibit the burning rate increment of about 20–30%. It was noticed that the burning rate increment with nanoaluminium is around 1.6–2 times with respect to the propellant compositions without aluminium for various pressure ranges and also for different micron-sized aluminium particles in the composition. The addition of nano-Al in the composite propellants washes out the plateaus in burning rate trends that are perceived from non-Al and microaluminized propellants; however, the burning rates of nanoaluminized propellants demonstrate low-pressure exponents at the higher pressure level. The contribution of catalysts towards the burning rate in the nanoaluminized propellants is reduced and is apparent only with nanosized catalysts. The near-surface nanoaluminium ignition and diffusion-limited nano-Al particle combustion contribute heat to the propellant-regressing surface that dominates the burning rate. Quench-collected nanoaluminized propellant residues display notable agglomeration, although a minor percentage of the agglomerates are in the 1–3 µm range; however, these are within 5 µm in size. Percentage of elongation and initial modulus of the propellant are decreased when the coarse AP particles are replaced by aluminium in the propellant composition.
Highlights
Solid propellants have been utilized in various applications such as space launch vehicles, missiles, and spacecrafts
A lot of experiments have been carried out in the past to find out the effect of Journal of Chemistry single/combined formulation parametric variations in the burning rates. e accomplishment of the “ultrafine” aluminium particle with a size of ∼100 nm or above in composite propellant combustion features has been reported by several investigators. e contribution of aluminium towards catalytic effects on the deflagration of ammonium perchlorate (AP) pellets was investigated by Romonadova and Pokhil [3], and burning rates of the dry-pressed mixtures of AP and ultrafine aluminium were reported
It was mentioned that the ultrafine aluminium addition enhances the burning rate of the propellant by means of near-surface aluminium particle ignition as supported by leading edge flames (LEFs) formed above the binder/coarse AP boundaries and from the binder/fine AP matrix flames
Summary
Solid propellants have been utilized in various applications such as space launch vehicles, missiles, and spacecrafts. Burning rate augmentation owing to nanoaluminium addition is about 1.6–2 times with respect to other nonaluminized and aluminized propellant counterparts for various pressures and aluminium contents, investigated by Ivanov et al [5]. Popenko et al [10] stated the burning rate enhancement and reduction in the pressure exponent value of HMXbased condensed systems by including relatively low quantities (1.25–5%) of ultrafine aluminium particles; there is no consequence or undesirable effect towards rheological properties of the modelled propellant due to its addition. Jawalkar et al [15] investigated the viscosity buildup and mechanical properties of the IPDI-/TDI-cured propellants All these properties for conventional microaluminized propellants have been compared with nanoaluminized counterparts (bicurative system). The values obtained for the end of mix viscosity are comparable to the conventional propellant formulations either with TDI or IPDI as the curing agent
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