Characterization of Aluminum Powders: III. Non‐Isothermal Oxidation and Combustion of Modern Aluminized Solid Propellants with Nanometals and Nanooxides

Aluminum powders were comprehensively described as the prospective ingredients of the modern propellants. The paper also studied the influence of micro‐ and nanopowders of metals (μ‐Me and n‐Me) and metal oxides (μ‐MeO and n‐MeO) on the burning process of modern aluminized propellant with HMX, CL‐20...

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Veröffentlicht in:Propellants, explosives, pyrotechnics explosives, pyrotechnics, 2020-05, Vol.45 (5), p.730-740
Hauptverfasser: Gromov, Alexander A., Sergienko, Alexey V., Popenko, Elena M., Slyusarsky, Konstantin V., Larionov, Kirill B., Dzidziguri, Ella L., Nalivaiko, Anton Y.
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container_end_page 740
container_issue 5
container_start_page 730
container_title Propellants, explosives, pyrotechnics
container_volume 45
creator Gromov, Alexander A.
Sergienko, Alexey V.
Popenko, Elena M.
Slyusarsky, Konstantin V.
Larionov, Kirill B.
Dzidziguri, Ella L.
Nalivaiko, Anton Y.
description Aluminum powders were comprehensively described as the prospective ingredients of the modern propellants. The paper also studied the influence of micro‐ and nanopowders of metals (μ‐Me and n‐Me) and metal oxides (μ‐MeO and n‐MeO) on the burning process of modern aluminized propellant with HMX, CL‐20, AP, and active binder. The following metal additives were used: Al, B, Zn, Ni, Co, and Mo. The effect of the following oxides CoO, V2O5, MnO2, and Fe2O3 was studied together with LiF. The combustion tests of modified propellant compositions were carried out in the Vielle bomb in a pressure range 2–10 MPa. n‐Me addition resulted in an increase in the burning rate by 10 % for n‐B, by 30–40 % for n‐Ni and n‐Mo in the studied pressure range. The introduction of n‐Cu caused a burning rate to increase fivefold. n‐Zn additive resulted in increasing of the propellant burning rate by 130 % and 260 % at 4 and 10 MPa, respectively. It was probably caused by the catalytic activity of those metals in the gaseous phase. The effect of complex additive was observed to be insignificant for additives with μ‐Co3O4, μ‐V2O5, μ‐Fe2O3 and n‐Fe2O3. The burning rate of propellant with n‐CuO additive value was higher by a factor of 4 in comparison with the basic formulation in the studied pressure range.
doi_str_mv 10.1002/prep.201900163
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The effect of the following oxides CoO, V2O5, MnO2, and Fe2O3 was studied together with LiF. The combustion tests of modified propellant compositions were carried out in the Vielle bomb in a pressure range 2–10 MPa. n‐Me addition resulted in an increase in the burning rate by 10 % for n‐B, by 30–40 % for n‐Ni and n‐Mo in the studied pressure range. The introduction of n‐Cu caused a burning rate to increase fivefold. n‐Zn additive resulted in increasing of the propellant burning rate by 130 % and 260 % at 4 and 10 MPa, respectively. It was probably caused by the catalytic activity of those metals in the gaseous phase. The effect of complex additive was observed to be insignificant for additives with μ‐Co3O4, μ‐V2O5, μ‐Fe2O3 and n‐Fe2O3. 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subjects Additives
Aluminizing
Aluminum
Ammonium perchlorate
Burning rate
Catalytic activity
Cobalt oxides
Combustion
Cyclic nitramine
HMX
Lithium fluoride
Manganese dioxide
Metal oxides
Molybdenum
Nanopowder
Nickel
Oxidation
Propellant
Propellant tests
Solid propellants
Vanadium pentoxide
Zinc
title Characterization of Aluminum Powders: III. Non‐Isothermal Oxidation and Combustion of Modern Aluminized Solid Propellants with Nanometals and Nanooxides
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