The influence of aluminum and ammonium perchlorate dispersion on characteristics of the laser ignition; Science and Technology of Energetic Materials; Vol. 79, iss. 6

The influence of aluminum and ammonium perchlorate dispersion on characteristics of the laser ignition; Science and Technology of Energetic Materials; Vol. 79, iss. 6

Библиографические подробности
Источник:	Science and Technology of Energetic Materials Vol. 79, iss. 6.— 2018.— [P. 186-189]
Автор-организация:	Национальный исследовательский Томский политехнический университет Инженерная школа новых производственных технологий Отделение материаловедения
Другие авторы:	Forat E. V. Egor Viktorovich, Medvedev V. V. Valeriy Viktorovich, Tsipilev V. P. Vladimir Papilovich, Yakovlev A. N. Aleksey Nikolaevich
Примечания:	Title screen Laser ignition of the stoichiometric mixtures based on aluminum and ammonium perchlorate has been experimentally studied. A laser with a radiation wavelength of 1.06 μm and a pulse duration of 0.8 ms was used to initiate ignition. The ignition thresholds were determined for samples with different degree of dispersion of both aluminum and ammonium perchlorate. The samples were exposed to laser radiation in confined conditions in order to prevent gas pressure relief. The difference in the mixture sensitivity to laser radiation is discussed within the theory of thermal ignition and light scattering.
Язык:	английский
Опубликовано:	2018
Предметы:	электронный ресурс труды учёных ТПУ ammonium perchlorate aluminum laser ignition перхлорат аммония алюминий лазерное зажигание
Online-ссылка:	http://www.jes.or.jp/mag/stem/Vol.79/No.6.05.html
Формат:	Электронный ресурс Статья
Запись в KOHA:	https://koha.lib.tpu.ru/cgi-bin/koha/opac-detail.pl?biblionumber=661160

Схожие документы

Effect of aluminum particles dispersity on characteristics of ammonium perchlorate-aluminum composition laser ignition; Energy Fluxes and Radiation Effects (EFRE-2016)
Опубликовано: (2016)

Conditions of Millisecond Laser Ignition and Thermostability for Ammonium Perchlorate/Aluminum Mixtures; Propellants, Explosives, Pyrotechnics; Vol. 42, iss. 3
Опубликовано: (2017)

Dielecric Relaxation in Energy Condensed Systems on the Basis of Polyefirretane Elastomer. II. Temperature Dependence and Ignition; Combustion, Explosion and Shock Waves; Vol. 55, No. 2
Опубликовано: (2019)

The influence of ammonium perchlorate on the activity of aluminum powders of different particle size; Energy Fluxes and Radiation Effects (EFRE-2016)
Опубликовано: (2016)

Ignition and Combustion of Composite Solid Propellants Based on a Double Oxidizer and Boron-Based Additives; Russian Journal of Physical Chemistry B; Vol. 14, iss. 4
Опубликовано: (2020)

Effect of ammonium perchlorate and aluminum composition density on characteristics of laser ignition; Propellants, Explosives, Pyrotechnics; Vol. 43, iss. 2
по: Medvedev V. V. Valeriy Viktorovich
Опубликовано: (2018)

Effect of the addition of ultrafine aluminum powders on the rheological properties and burning rate of energetic condensed systems; Combustion, Explosion and Shock Waves; Vol. 9, № 5
Опубликовано: (2007)

Physico-chemical study of the systems on the basis of sodium and ammonium perchlorate; Bulletin of the Tomsk Polytechnic University; Vol. 310, № 1
Опубликовано: (2007)

Effect of Ammonium Nitrate and Combustible Binder on the Ignition Characteristics of High-Energy Materials Containing Aluminum Borides; Combustion, Explosion, and Shock Waves; Vol. 58, iss. 5
по: Korotkikh A. G. Aleksandr Gennadievich
Опубликовано: (2022)

The effect of aluminum particles dispersity on characteristics of ammonium perchlorate-aluminum composition laser ignition; Journal of Physics: Conference Series; Vol. 830 : Energy Fluxes and Radiation Effects 2016
Опубликовано: (2017)

Effect of boron and aluminum diboride on ignition of high-energy materials; Science and Technology of Energetic Materials; Vol. 80, iss. 5
Опубликовано: (2019)

Laser Ignition of Aluminum and Boron Based Powder Systems; Combustion, Explosion, and Shock Waves; Vol. 58, iss. 4
по: Korotkikh A. G. Aleksandr Gennadievich
Опубликовано: (2022)

New Method for Studying the Ignition Characteristics of Condensed Systems by Laser Radiation; Russian Physics Journal; Vol. 62, iss. 11
Опубликовано: (2020)

Зажигание пиротехнического состава (перхлорат аммония+алюминий) лазерным излучением; Фундаментальные и прикладные проблемы современной механики
Опубликовано: (2004)

Влияние дисперсности частиц алюминия на характеристики лазерного зажигания пиротехнического состава на основе перхлората аммония и алюминия; "Орбита молодёжи" и перспективы развития российской космонавтики
по: Форат Е. В. Егор Викторович
Опубликовано: (2017)

Особенности лазерного зажигания пиротехнического состава (перхлорат аммония + ультрадисперсный алюминий) при различных плотностях образцов; Фундаментальные и прикладные проблемы современной механики
по: Медведев В. В. Валерий Викторович
Опубликовано: (2006)

Aluminosilicate ores processed by a fluoride method; Refractories and Industrial Ceramics; Vol. 47,iss. 3
Опубликовано: (2006)

Ignition of Rotating Samples of High-Energy Materials by Laser Radiation; Combustion, Explosion, and Shock Waves; Vol. 57, iss. 1
Опубликовано: (2021)

Effect of Decomposition of CuO Film on Ignition of Organic Explosives by a Laser Pulse; Propellants, Explosives, Pyrotechnics; Vol. 44, iss. 12
по: Khaneft A. V. Aleksandr Villivich
Опубликовано: (2019)

Study of Ignition of High-Energy Materials with Boron and Aluminum and Titanium Diborides; Combustion, Explosion, and Shock Waves; Vol. 54, iss. 3
по: Korotkikh A. G. Aleksandr Gennadievich
Опубликовано: (2018)

Phase Formation Processes in Natural Magnesium Silicates of Various Structures by Ammonium Fluoride Treatment; Refractories and Industrial Ceramics; Vol. 61, iss. 2
по: Sharafeev Sh. M. Sharif Mnirovich
Опубликовано: (2020)

The Effect of Metal Film Thickness on Ignition of Organic Explosives with a Laser Pulse; Molecules; Vol. 24, iss. 24
по: Khaneft A. V. Aleksandr Villivich
Опубликовано: (2019)

Ignition of Organic Explosive Materials by a Copper Oxide Film Absorbing a Laser Pulse; Propellants, Explosives, Pyrotechnics; Vol. 43, iss. 8
по: Dolgachev V. A. Vadim Aleksandrovich
Опубликовано: (2018)

Size effect of lead azid initiation by CO[2] laser radiation; Energy Fluxes and Radiation Effects (EFRE-2016)
Опубликовано: (2016)

Gel fuels based on oil-filled cryogels: Corrosion of tank material and spontaneous ignition; Chemical Engineering Journal; Vol. 421, pt. 2
Опубликовано: (2021)

Combustion features of dispersed aluminum and boron in high-energy composition; FirePhysChem; Vol. 4, iss. 4
по: Korotkikh A. G. Aleksandr Gennadievich
Опубликовано: (2024)

A novel low-energy approach to leucoxene concentrate desiliconization by ammonium bifluoride solutions; Chemical technology and biotechnology; Vol. 98, iss. 3
Опубликовано: (2023)

Термическое разложение перхолатов, гуанидиния и хлората аммония: Диссертация на соискание ученой степени кандидата химических наук
по: Исаев Р. Н.
Опубликовано: (Томск, 1971)

Effect of Volume Compression on Laser Pulse Initiation Thresholds of Energetic Materials; Russian Physics Journal; Vol. 66, iss. 2
Опубликовано: (2023)

Influence of the energy fluence and the aluminum layer thickness on the ignition delay time of explosive materials by a laser pulse; Energy Fluxes and Radiation Effects (EFRE-2016)
по: Khaneft A. V. Aleksandr Villivich
Опубликовано: (2016)

Conditions of the Water–Coal Fuel Drop Dispersion at Their Ignition in the Conditions of High-Temperature Heating; Combustion Science and Technology; Vol. 191, iss. 12
Опубликовано: (2018)

Fluorination of beryllium concentrates with ammonium fluorides; Russian Journal of Applied Chemistry; Vol. 81, iss. 2
по: Andreev A. A. Artyom Andreevich
Опубликовано: (2008)

Low-temperature method for desiliconization of polymetallic slags by ammonium bifluoride solution; Environmental Science and Pollution Research (ESPR); Vol. 30, iss. 11
Опубликовано: (2023)

Ammonium fluoride roasting and water leaching of leucoxene concentrates to produce a high grade titanium dioxide resource (of the Yaregskoye deposit, Timan, Russia); Hydrometallurgy; Vol. 210
Опубликовано: (2022)

Взаимодействие монацита и бифторида аммония; Известия Томского политехнического университета [Известия ТПУ]. Инжиниринг георесурсов; Т. 330, № 2
Опубликовано: (2019)

Monitoring of Nanopowder Combustion Ignited by Laser Radiation; Progress in Electromagnetics Research Symposium (PIERS-Toyama)
Опубликовано: (2018)

Ignition of High Energy Material Containing Ultradispersed Al/B Powder; Russian Journal of Physical Chemistry B; Vol. 16, iss. 2
по: Korotkikh A. G. Aleksandr Gennadievich
Опубликовано: (2022)

Влияние дисперсности порошка алюминия на воспламенение и удельный импульс тяги ВЭМ; Современные техника и технологии; Т. 3
по: Янковский С. А. Станислав Александрович
Опубликовано: (2014)

Зажигание и горение смесевых твердых топлив на основе двойного окислителя и борсодержащих добавок; Химическая физика; Т. 39, № 7
Опубликовано: (2020)

Conditions for the production of pigmentary titanium dioxide of rutile and anatase modifications by ilmenite processing with ammonium fluoride; Theoretical Foundations of Chemical Engineering; Vol. 43, iss. 5
по: Andreev A. A. Artyom Andreevich
Опубликовано: (2009)