Are All Solid Propellant Burning Rate Modifiers Catalysts?

Kalman, Joseph

doi:10.1002/prep.202200148

Cited by 10 publications

(2 citation statements)

References 8 publications

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“…1(a). In order to counteract this effect, ballistic modifiers (also known as burn rate catalysts) 4 are added to the propellant system, which alter the burning behaviour of the propellant in three distinct ways. 5 First, in the low-pressure range it enhances combustion, in a process termed super-rate burning, where typically 0.8 < n < 2.0.…”

Section: Introductionmentioning

confidence: 99%

Accounting for super-, plateau- and mesa-rate burning by lead and copper-based ballistic modifiers in double-base propellants: a computational study

Warren,

Rowell,

McMaster

et al. 2023

Phys. Chem. Chem. Phys.

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Section: Introductionmentioning

confidence: 99%

Accounting for super-, plateau- and mesa-rate burning by lead and copper-based ballistic modifiers in double-base propellants: a computational study

Warren,

Rowell,

McMaster

et al. 2023

Phys. Chem. Chem. Phys.

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“…However, when tested as a burning-rate modifier, it showed very good positive results towards the inhibition of the burning rate of pyrotechnic compositions, which is typical of high-nitrogen compounds [ 18 , 19 ]. The modifier is employed to adjust and control the burning rate of various energy-rich compositions (gun propellants, СРТТ, pyrotechnic compositions) in order to achieve the required parameters without the need for total re-formulation, which is essential in some cases for pyrotechnic compositions and solid propellants to burn stably [ 20 , 21 ]. Additionally, effective inhibitors can act as flame-extinguishing agents, which are important for fire- fighting in coal mines.…”

Section: Introductionmentioning

confidence: 99%

Macrocycle as a “Container” for Dinitramide Salts

et al. 2022

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Dinitramic acid salts are promising components as oxidizers and burning-rate modifiers of high-energy compositions. However, most of these salts are not free of drawbacks such as hygroscopicity. Therefore, their application under special conditions of use and storage is limited. The synthesis and storage of stable dinitramic acid salts is a topical issue. Here, we synthesized an adduct starting from the nickel salt of dinitramic acid with carbohydrazide and glyoxal to settle the problem of stability and storage of that salt. The chemical composition of the adduct was confirmed by infrared spectroscopy and elemental analysis. The Ni content was determined by atomic emission spectroscopy. Thermogravimetric DSC and TGA analyses showed the adduct to have three decomposition stages. The adduct exhibits a good thermal stability and a low sensitivity to mechanical stimuli. Here, the adduct is demonstrated to be a promising burning-rate inhibitor of pyrotechnic compositions.

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A Metal Inorganic Framework Designed as a Propellant Burn Rate Modifier

Vaz,

Pantoya,

Miller

et al. 2023

Adv Eng Mater

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The kinetics of a strategically synthesized burn rate enhancer (BRE) were investigated in its reaction with ammonium perchlorate (AP). The BRE was designed for multi‐ functionality by: (1) producing reactive gases that couple with AP gas production, (2) trapping reactive gases with high surface area, and (3) exposing metal cations to incite exothermic reactions at a temperature coincident with AP decomposition. This study advances inorganic synthesis by introducing a metal inorganic framework (MIF) composed of an aluminum cation (Al+3) surrounded by inorganic “linker” molecules of oxidizing species. To increase surface area, a porous, amorphous MIF (a‐MIF) was synthesized by controlling solution properties of an acid‐base precipitation reaction. Upon gas generation, the high surface area and aluminum‐rich surface of a‐MIF accelerate AP decomposition and induce an exothermic reaction that is otherwise endothermic in thermal equilibrium analysis. AP decomposition rate was advanced by reducing peak onset temperature and increasing decomposition rate with the addition of a‐MIF (i.e., from 17% min‐1 at 401°C to 18% min‐1 at 365°C). The enthalpy of AP decomposition increased from +240 J g‐1 to ‐1040 J g‐1. Results introduce an approach for increasing the decomposition rate of solid oxidizers by demonstrating a recipe for designing and synthesizing an MIF.This article is protected by copyright. All rights reserved.

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Are All Solid Propellant Burning Rate Modifiers Catalysts?

Cited by 10 publications

References 8 publications

Accounting for super-, plateau- and mesa-rate burning by lead and copper-based ballistic modifiers in double-base propellants: a computational study

Accounting for super-, plateau- and mesa-rate burning by lead and copper-based ballistic modifiers in double-base propellants: a computational study

Macrocycle as a “Container” for Dinitramide Salts

A Metal Inorganic Framework Designed as a Propellant Burn Rate Modifier

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