Bukaemskii et al., 2001 - Google Patents
Explosive Synthesis of Ultradisperse Aluminum Oxide in an Oxygen‐Containing MediumBukaemskii et al., 2001
- Document ID
- 13527182929289309722
- Author
- Bukaemskii A
- Beloshapko A
- Publication year
- Publication venue
- Combustion, Explosion and Shock Waves
External Links
Snippet
Explosive synthesis of ultradisperse aluminum oxide in an oxygen‐containing medium is studied. Synthesis conditions that are most optimal for production of the material in the ultradisperse state are determined. A physical model of the process is proposed. It is shown …
- 230000015572 biosynthetic process 0 title abstract description 35
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| DeLuca | Overview of Al-based nanoenergetic ingredients for solid rocket propulsion | |
| Trunov et al. | Ignition of aluminum powders under different experimental conditions | |
| Berner et al. | Nanoparticles of energetic materials: synthesis and properties | |
| Ivanov et al. | Productions of ultra‐fine powders and their use in high energetic compositions | |
| RU2258195C1 (en) | Lining of shaped charge | |
| Prümmer | Explosive compaction of powders, principle and prospects | |
| US4416840A (en) | Al2 O3 Ceramic composite | |
| US9249020B2 (en) | Nanocrystaline spherical ceramic oxides, process for the synthesis and use thereof | |
| Bukaemskii et al. | Explosive Synthesis of Ultradisperse Aluminum Oxide in an Oxygen‐Containing Medium | |
| Pivkina et al. | Nanosized components of energetic systems: structure, thermal behavior, and combustion | |
| Hastings et al. | Highly reactive spheroidal milled aluminum | |
| Grebe et al. | Combustion synthesis and subsequent explosive densification of titanium carbide ceramics | |
| Ma et al. | Energetic characteristics of highly reactive Si nanoparticles prepared by magnesiothermic reduction of mesoporous SiO2 | |
| US4407968A (en) | Ceramic Al2 O3 substoichiometric TiC body | |
| Ilyin et al. | Synthesis and characterization of metal carbides nanoparticles produced by electrical explosion of wires | |
| Lebedeva et al. | Agglomeration of the condensed phase of energetic condensed systems containing modified aluminum | |
| Gromov et al. | Aluminum powders for energetics: Properties and oxidation behavior | |
| Glotov et al. | Combustion of aluminum and boron agglomerates free falling in air. I. Experimental approach | |
| Gromov et al. | Interaction of tungsten nanopowders with air under different conditions | |
| Prümmer | Powder compaction | |
| RU2228238C1 (en) | Method for making composite products on base of borides and carbides of metals of iv-vi, viii groups | |
| Pang et al. | Effect of hydroborate iron additives (BH-Fe) on the properties of composite solid rocket propellants | |
| Adadurov et al. | Technological fundamentals of SHS compacting | |
| Guo et al. | Combustion Characteristics of a Novel Grain‐Binding High Burning Rate Propellant | |
| Deribas et al. | Long–pulse explosive compaction of a diamond powder |