Reactive active propulsion
Само за регистроване кориснике
2012
Конференцијски прилог (Објављена верзија)
Метаподаци
Приказ свих података о документуАпстракт
A new interior ballistic concept of reactive active projectile propulsion is analyzed. During acceleration in a rocket launcher the projectile is separated from the rocket engine chamber by the action of active granular propellant charge located behind the projectile stabilizer. The projectile is then additionally accelerated with corresponding deceleration of the rocket engine chamber. The active propellant charge is initiated by the pyrotechnic delay during the rocket engine function. The interior ballistic cycle terminates near the front of the rocket launcher by the extraction completion of the projectile stabilizer from the launching tube. A theoretical model for reactive active propulsion is presented. The model includes simultaneous function of rocket engine and active propellant charge in the launcher. The computer code RAP (Reactive Active Propulsion) for interior ballistic cycle of reactive active projectiles is developed. The parametric study is carried out based on the RAP ...code calculations. The moment of active charge initiation by the pyrotechnic train is found to be very important parameter for regular function of the system. Computational results show possibilities of reactive active propulsion interior ballistic concept to significantly increase projectile performance.
Кључне речи:
projectile propulsion / interior ballistics / propellant charge / computer codeИзвор:
5th International Scientific Conference on Defensive Technologies – OTEH 2012, 2012, 255-259Издавач:
- Belgrade : Military Technical Institute
Финансирање / пројекти:
- Рентабилни избор нових технологија и концепција одбране кроз друштвене промене и стратешке оријентације Србије у 21. веку (RS-MESTD-Integrated and Interdisciplinary Research (IIR or III)-47029)
Колекције
Институција/група
Mašinski fakultetTY - CONF AU - Micković, Dejan AU - Jaramaz, Slobodan AU - Elek, Predrag AU - Micković, Dušan AU - Jaramaz, Dragana PY - 2012 UR - https://machinery.mas.bg.ac.rs/handle/123456789/4895 AB - A new interior ballistic concept of reactive active projectile propulsion is analyzed. During acceleration in a rocket launcher the projectile is separated from the rocket engine chamber by the action of active granular propellant charge located behind the projectile stabilizer. The projectile is then additionally accelerated with corresponding deceleration of the rocket engine chamber. The active propellant charge is initiated by the pyrotechnic delay during the rocket engine function. The interior ballistic cycle terminates near the front of the rocket launcher by the extraction completion of the projectile stabilizer from the launching tube. A theoretical model for reactive active propulsion is presented. The model includes simultaneous function of rocket engine and active propellant charge in the launcher. The computer code RAP (Reactive Active Propulsion) for interior ballistic cycle of reactive active projectiles is developed. The parametric study is carried out based on the RAP code calculations. The moment of active charge initiation by the pyrotechnic train is found to be very important parameter for regular function of the system. Computational results show possibilities of reactive active propulsion interior ballistic concept to significantly increase projectile performance. PB - Belgrade : Military Technical Institute C3 - 5th International Scientific Conference on Defensive Technologies – OTEH 2012 T1 - Reactive active propulsion EP - 259 SP - 255 UR - https://hdl.handle.net/21.15107/rcub_machinery_4895 ER -
@conference{ author = "Micković, Dejan and Jaramaz, Slobodan and Elek, Predrag and Micković, Dušan and Jaramaz, Dragana", year = "2012", abstract = "A new interior ballistic concept of reactive active projectile propulsion is analyzed. During acceleration in a rocket launcher the projectile is separated from the rocket engine chamber by the action of active granular propellant charge located behind the projectile stabilizer. The projectile is then additionally accelerated with corresponding deceleration of the rocket engine chamber. The active propellant charge is initiated by the pyrotechnic delay during the rocket engine function. The interior ballistic cycle terminates near the front of the rocket launcher by the extraction completion of the projectile stabilizer from the launching tube. A theoretical model for reactive active propulsion is presented. The model includes simultaneous function of rocket engine and active propellant charge in the launcher. The computer code RAP (Reactive Active Propulsion) for interior ballistic cycle of reactive active projectiles is developed. The parametric study is carried out based on the RAP code calculations. The moment of active charge initiation by the pyrotechnic train is found to be very important parameter for regular function of the system. Computational results show possibilities of reactive active propulsion interior ballistic concept to significantly increase projectile performance.", publisher = "Belgrade : Military Technical Institute", journal = "5th International Scientific Conference on Defensive Technologies – OTEH 2012", title = "Reactive active propulsion", pages = "259-255", url = "https://hdl.handle.net/21.15107/rcub_machinery_4895" }
Micković, D., Jaramaz, S., Elek, P., Micković, D.,& Jaramaz, D.. (2012). Reactive active propulsion. in 5th International Scientific Conference on Defensive Technologies – OTEH 2012 Belgrade : Military Technical Institute., 255-259. https://hdl.handle.net/21.15107/rcub_machinery_4895
Micković D, Jaramaz S, Elek P, Micković D, Jaramaz D. Reactive active propulsion. in 5th International Scientific Conference on Defensive Technologies – OTEH 2012. 2012;:255-259. https://hdl.handle.net/21.15107/rcub_machinery_4895 .
Micković, Dejan, Jaramaz, Slobodan, Elek, Predrag, Micković, Dušan, Jaramaz, Dragana, "Reactive active propulsion" in 5th International Scientific Conference on Defensive Technologies – OTEH 2012 (2012):255-259, https://hdl.handle.net/21.15107/rcub_machinery_4895 .