Study of Ignition of High-Energy Materials with Boron and Aluminum and Titanium Diborides; Combustion, Explosion, and Shock Waves; Vol. 54, iss. 3
| Parent link: | Combustion, Explosion, and Shock Waves Vol. 54, iss. 3.— 2018.— [P. 350-356] |
|---|---|
| Glavni avtor: | |
| Korporativna značnica: | |
| Drugi avtorji: | , , |
| Izvleček: | Title screen This paper describes the ignition of high-energy materials (HEMs) on the basis of ammonium perchlorate and ammonium nitrate and an energetic binder, containing the powders of Al (base composition), B, AlB2, AlB12, and TiB2, upon initiation of the process by a CO2 laser in the heat flux density range of 90–200 W/cm2. The ignition delay time and surface temperature of the reaction layer during the heating and ignition of HEMs in air are determined. It is obtained that the complete replacement of a micron-sized aluminum powder by amorphous boron in the composition of HEMs significantly reduces the ignition delay time of the sample (by 2.2–2.8 times) with the same heat flux density, and this occurs due to the high chemical activity of and difference between the mechanisms of oxidation of boron particles. The use of aluminum diboride in HEMs reduces the ignition delay time by 1.7–2.2 times in comparison with the base composition. The ignition delay time of the HEM sample with titanium diboride decreases slightly (by 10–25%) relative to the ignition delay time of the base composition. Режим доступа: по договору с организацией-держателем ресурса |
| Jezik: | angleščina |
| Izdano: |
2018
|
| Teme: | |
| Online dostop: | https://doi.org/10.1134/S0010508218030127 |
| Format: | Elektronski Book Chapter |
| KOHA link: | https://koha.lib.tpu.ru/cgi-bin/koha/opac-detail.pl?biblionumber=660046 |
Podobne knjige/članki
Effect of boron and aluminum diboride on ignition of high-energy materials; Science and Technology of Energetic Materials; Vol. 80, iss. 5
Izdano: (2019)
Izdano: (2019)
Laser Ignition of Aluminum and Boron Based Powder Systems; Combustion, Explosion, and Shock Waves; Vol. 58, iss. 4
od: Korotkikh A. G. Aleksandr Gennadievich
Izdano: (2022)
od: Korotkikh A. G. Aleksandr Gennadievich
Izdano: (2022)
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
od: Korotkikh A. G. Aleksandr Gennadievich
Izdano: (2022)
od: Korotkikh A. G. Aleksandr Gennadievich
Izdano: (2022)
The Influence of the Ratio of Precursors on the Powdered Product of Plasmodynamic Synthesis in the System Ti-B; Key Engineering Materials; Vol. 769 : High Technology: Research and Applications (HTRA 2017)
od: Gerasimov D. Yu. Dmitry Yurievich
Izdano: (2018)
od: Gerasimov D. Yu. Dmitry Yurievich
Izdano: (2018)
On synthesis of nanocrystalline Ti-B/Ti-B-N phases in a hypersonic plasma jet; 11th International Forum on Strategic Technology (IFOST 2016); Pt. 1
Izdano: (2016)
Izdano: (2016)
Combustion features of dispersed aluminum and boron in high-energy composition; FirePhysChem; Vol. 4, iss. 4
od: Korotkikh A. G. Aleksandr Gennadievich
Izdano: (2024)
od: Korotkikh A. G. Aleksandr Gennadievich
Izdano: (2024)
Study of the Machinability of an Inconel 625 Composite with Added NiTi-TiB2 Fabricated by Direct Laser Deposition; Metals; Vol. 12, iss. 11
Izdano: (2022)
Izdano: (2022)
Исследование обрабатываемости фрезерованием композита Inconel 625 с добавлением NiTi-TiB2, полученного лазерным спеканием; Обработка металлов (технология, оборудование, инструменты); Т. 23, № 1
Izdano: (2021)
Izdano: (2021)
Combustion characteristics of high-energy material containing dispersed aluminum, boron, and aluminum borides; Combustion, Explosion and Shock Waves; Vol. 59, No. 4
Izdano: (2023)
Izdano: (2023)
Исследование зажигания высокоэнергетических материалов с бором и диборидами алюминия и титана; Физика горения и взрыва; Т. 54, № 3
Izdano: (2018)
Izdano: (2018)
Ignition and combustion of high-energy materials containing aluminum, boron and aluminum diboride; MATEC Web of Conferences; Vol. 194 : Heat and Mass Transfer in the Thermal Control System of Technical and Technological Energy Equipment (HMTTSC 2018)
od: Korotkikh A. G. Aleksandr Gennadievich
Izdano: (Les Ulis, EDP Sciences, 2018)
od: Korotkikh A. G. Aleksandr Gennadievich
Izdano: (Les Ulis, EDP Sciences, 2018)
Ignition of High Energy Material Containing Ultradispersed Al/B Powder; Russian Journal of Physical Chemistry B; Vol. 16, iss. 2
od: Korotkikh A. G. Aleksandr Gennadievich
Izdano: (2022)
od: Korotkikh A. G. Aleksandr Gennadievich
Izdano: (2022)
Synthesis of titanium diboride by electric arc plasma in air; Materials Chemistry and Physics; Vol. 328
Izdano: (2024)
Izdano: (2024)
Лазерная наплавка металлокерамических покрытий TiB2-Ni с использованием вакуумной металлизации; Перспективы развития фундаментальных наук; Т. 1 : Физика
od: Баянова Е. О.
Izdano: (2025)
od: Баянова Е. О.
Izdano: (2025)
Effect of Ultrafine Al/B, Ti/B, and Fe/B Powders on the Ignition and Combustion Characteristics of High-Energy Materials; Combustion, Explosion, and Shock Waves; Vol. 59, iss. 6
od: Sorokin I. V. Ivan Viktorovich
Izdano: (2023)
od: Sorokin I. V. Ivan Viktorovich
Izdano: (2023)
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
Izdano: (2020)
Izdano: (2020)
Synthesis of high-entropy diboride TiZrNbHfTaB2 by vacuum-free direct current arc plasma method; International Journal of Refractory Metals and Hard Materials; Vol. 134
Izdano: (2026)
Izdano: (2026)
Ignition of Rotating Samples of High-Energy Materials by Laser Radiation; Combustion, Explosion, and Shock Waves; Vol. 57, iss. 1
Izdano: (2021)
Izdano: (2021)
Ignition study of high-energy materials containing Al, B, AlB2 and TiB2 powders; MATEC Web of Conferences; Vol. 115 : XXXIII Siberian Thermophysical Seminar (STS-33)
Izdano: (2017)
Izdano: (2017)
Зажигание и горение высокоэнергетических материалов, содержащих алюминий, бор и диборид алюминия; Химическая физика и мезоскопия; Т. 20, № 1
Izdano: (2018)
Izdano: (2018)
Получение диборида циркония безвакуумным электродуговым методом; Перспективы развития фундаментальных наук; Т. 2 : Химия
od: Кузнецова А. А.
Izdano: (2024)
od: Кузнецова А. А.
Izdano: (2024)
Al–Cu Powder Oxidation Kinetics during Heating in Air; Combustion, Explosion, and Shock Waves; Vol. 58, iss. 2
od: Korotkikh A. G. Aleksandr Gennadievich
Izdano: (2022)
od: Korotkikh A. G. Aleksandr Gennadievich
Izdano: (2022)
Preparation and properties of composite material based on hafnium diboride and aluminum; IOP Conference Series: Materials Science and Engineering; Vol. 1019 : 14th International Forum on Strategic Technology (IFOST 2019)
Izdano: (2021)
Izdano: (2021)
A study of mechanical properties ceramics based on titanium diboride; Химия и химическая технология в XXI веке
od: Pogorelova S. O.
Izdano: (2019)
od: Pogorelova S. O.
Izdano: (2019)
Dependence of the product's phase composition on the ratio of precursors in plasmodynamic synthesis of titanium diboride; Химия и химическая технология в XXI веке
od: Pogorelova S. O.
Izdano: (2018)
od: Pogorelova S. O.
Izdano: (2018)
Obtaining nanodispersed product of Titanium Diboride in an arc discharge of magnetoplasma accelerator; Gas Discharge Plasmas and Their Applications (GDP 2019)
od: Pogorelova S. O.
Izdano: (2019)
od: Pogorelova S. O.
Izdano: (2019)
Ultra high fluence implantation of aluminum ions into CP–Ti; Journal of Alloys and Compounds; Vol. 793
Izdano: (2019)
Izdano: (2019)
Products of combustion of mixtures of aluminum and tungsten nanopowders in air; Combustion, Explosion, and Shock Waves; Vol. 43. № 4
od: Ilyin A. P. Aleksandr Petrovich
Izdano: (2007)
od: Ilyin A. P. Aleksandr Petrovich
Izdano: (2007)
Elemental and phase composition of TiB2–Mo coating sprayed on a steel by electro-explosive method; Inorganic Materials: Applied Research; Vol. 8, iss. 3
Izdano: (2017)
Izdano: (2017)
Влияние параметров электродугового синтеза на структуру и свойства диборида циркония в безвакуумных условиях; Современные проблемы машиностроения
od: Шугонцов Я. А.
Izdano: (2025)
od: Шугонцов Я. А.
Izdano: (2025)
Структура и свойства диборида циркония и горячепрессованной керамики; Огнеупоры и техническая керамика; № 11
Izdano: (2006)
Izdano: (2006)
Исследование расхода графитовых элементов при безвакуумном электродуговом синтезе диборида гафния; Бутаковские чтения
od: Шляхов Т. С.
Izdano: (2025)
od: Шляхов Т. С.
Izdano: (2025)
Синтез нанокристаллического диборида титана в гиперскоростной плазменной струе; Письма в Журнал технической физики; Т. 44, вып. 7
od: Сивков А. А. Александр Анатольевич
Izdano: (2018)
od: Сивков А. А. Александр Анатольевич
Izdano: (2018)
Исследование свойств порошковых нанокомпозитов на основе диборида титана, полученных методом SPS; Современные техника и технологии; Т. 2
od: Степанова И. В.
Izdano: (2004)
od: Степанова И. В.
Izdano: (2004)
Синтез диборида хрома безвакумным электродуговым методом; Концентрированные потоки энергии в космической технике,электронике, экологии и медицине
od: Стовпец Д. Е. Даниил Евгеньевич
Izdano: (2023)
od: Стовпец Д. Е. Даниил Евгеньевич
Izdano: (2023)
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
Izdano: (2019)
Izdano: (2019)
Using burnable absorber in thorium reactor; Перспективы развития фундаментальных наук; Т. 2 : Химия
od: Khrapov D. Dmitriy
Izdano: (2016)
od: Khrapov D. Dmitriy
Izdano: (2016)
Solid Energetic Material Based on Aluminum Micropowder Modified by Microwave Radiation; Crystals; Vol. 12, iss. 4
Izdano: (2022)
Izdano: (2022)
Плазмодинамический синтез ультрадисперсных фаз системы Ti-B; Химия и химическая технология в XXI веке
od: Погорелова С. О.
Izdano: (2017)
od: Погорелова С. О.
Izdano: (2017)
Изучение влияния механической активации на синтез материалов на основе диборида титана в режиме СВС; Химия и химическая технология в XXI веке; Т. 1
od: Касаткин Д. Д.
Izdano: (2015)
od: Касаткин Д. Д.
Izdano: (2015)