Burning Mechanism of Aluminized Solid Rocket Propellants Based on Energetic Binders

A standard quench bomb (QB) ¡ widely used to characterize condensed phase from metalized solid propellant combustion ¡ is studied in detail. Experimental and numerical investigations proved that collected particles are mostly unburned aluminum (Al) agglomerates despite large quenching distances. Particles are actually found to quench early as propellant surface is swept by inert pressurant. Further improvements of the QB are proposed which allow measuring both Al agglomerates and alumina residue with the same setup. Finally, the results obtained on a typical aluminized ammonium perchlorate (AP) / hydroxyl-terminated polybutadiene (HTPB) propellant are brie §y discussed.

Section: Alumina Residues: Particle Analysissupporting

confidence: 51%

Detailed analysis of a quench bomb for the study of aluminum agglomeration in solid propellants

Gallier¹,

Kratz²,

Quaglia³

et al. 2016

“…Occurrence SL at propellant burning is possible only at formation of a carbon skeleton [36,38]. Consequently, the possibility of the carbon skeleton formation and SL is connected with conditions of the binder decomposition ¡ ¦rst of all, with oxidizing components concentration.…”

Section: Formation Of the Skeleton Layermentioning

confidence: 99%

“…Within other structural formations ¡ ¤interpocket bridges¥ which are characterized by increased oxidizing components concentration ¡ formation of the SL does not occur. It should be noted that the usage of active binders leads to increase of oxidizing components as well as within the ¤pockets¥ which, in turn, leads to suppression of the agglomeration process [36].…”

Section: Formation Of the Skeleton Layermentioning

confidence: 99%

Analysis and synthesis of solutions for the agglomeration process modeling

Babuk

Dolotkazin

Nizyaev

2013

The present work is devoted development of model of agglomerating process for propellants based on ammonium perchlorate (AP), ammonium dinitramide (ADN), HMX, inactive binder, and nanoaluminum. Generalization of experimental data, development of physical picture of agglomeration for listed propellants, development and analysis of mathematical models are carried out. Synthesis of models of various phenomena taking place at agglomeration implementation allows predicting of size and quantity, chemical composition, structure of forming agglomerates and its fraction in set of condensed combustion products. It became possible in many respects due to development of new model of agglomerating particle evolution on the surface of burning propellant. Obtained results correspond to available experimental data. It is supposed that analogical method based on analysis of mathematical models of particular phenomena and their synthesis will allow implementing of the agglomerating process modeling for other types of metalized solid propellants.

“…It can be asserted that agglomerates form only from the metal fuel participating in SL formation. The necessary condition of SL formation is the availability of connected structures from metal particles [13,21]. In turn, their occurrence can be closely connected with two phenomena:…”

Section: Physical Concept Of Condensed Combustion Product Formationmentioning

confidence: 99%

Condensed combustion products from burning of nanoaluminum-based propellants: properties and formation mechanism

Babuk¹,

Glebov²,

Dolotkazin³

et al. 2009

The experimental results obtained within a joint international research e¨ort regarding the formation of condensed combustion products from nanoaluminum-based solid propellants (SPs) are reported. Data on the size, structure, chemical composition, and quantity of condensed combustion products (CCPs) as well as conditions of their formation are discussed. On the basis of the collected experimental data, a general physical picture of condensed combustion products formation is portrayed. The results of this study allow carrying out the analysis of good quality propellants using nanoaluminum.