I. V. Sorokin scite author profile

Abstract. Boron and its compounds are among the most promising metal fuel components to be used in solid propellants for solid fuel rocket engine and ramjet engine. Papers studying boron oxidation mostly focus on two areas: oxidation of single particles and powders of boron, as well as boroncontaining composite solid propellants. This paper presents the results of an experimental study of the ignition and combustion of the high-energy material samples based on ammonium perchlorate, ammonium nitrate, and an energetic combustible binder. Powders of aluminum, amorphous boron and aluminum diboride, obtained by the SHS method, were used as the metallic fuels. It was found that the use of aluminum diboride in the solid propellant composition makes it possible to reduce the ignition delay time by 1.7-2.2 times and significantly increase the burning rate of the sample (by 4.8 times) as compared to the solid propellant containing aluminum powder. The use of amorphous boron in the solid propellant composition leads to a decrease in the ignition delay time of the sample by a factor of 2.2-2.8 due to high chemical activity and a difference in the oxidation mechanism of boron particles. The burning rate of this sample does not increase significantly.

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Ignition and Combustion of Composite Solid Propellants Based on a Double Oxidizer and Boron-Based Additives

Коротких

Sorokin

Selikhova

et al. 2020

Russ. J. Phys. Chem. B

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Study of the chemical activity of metal powders based on aluminum, boron and titanium

Коротких

Sorokin

2020

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Effect of Metal Additives on the Combustion Characteristics of High-Energy Materials

2016

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Abstract. Thermodynamic calculation of combustion parameters and equilibrium composition of HEMs combustion products showed, that at the increase of aluminum powder dispersity the specific impulse and combustion temperature of solid propellants are reduced due to the decrease of the mass fraction of active aluminum in particles. Partial or complete replacement of aluminum by metal powder (B, Mg, AlB 2 , Al\Mg alloy, Fe, Ti and Zr) in HEMs composition leads to the reduce of the specific impulse and combustion temperature. Replacement of aluminum powder by boron and magnesium in HEM reduces the mass fraction of condensed products in the combustion chamber of solid rocket motor. So, for compositions HEMs with boron and aluminum boride the mass fraction in chamber is reduced by 24 and 36 %, respectively, with respect to the composition HEMs with Al powder. But the mass fraction of CCPs in the nozzle exit increases by 13 % for HEMs with aluminum boride due to the formation of boron oxide in the condensed combustion products. Partial replacement of 2 wt. % aluminum powder by iron and copper additives in HEM leads to the reduce of CCPs mass fraction in chamber by 4-10 % depending on the aluminum powder dispersity duo to these metals are not formed condensed products at the HEMs combustion in chamber.

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I. V. Sorokin

Effect of B, Fe, Ti, Cu nanopowders on the laser ignition of Al-based high-energy materials

Ignition and combustion of high-energy materials containing aluminum, boron and aluminum diboride

Ignition and Combustion of Composite Solid Propellants Based on a Double Oxidizer and Boron-Based Additives

Study of the chemical activity of metal powders based on aluminum, boron and titanium

Effect of Metal Additives on the Combustion Characteristics of High-Energy Materials

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