Analysis of RDX-TAGzT pseudo-propellant combustion with detailed chemical kinetics

Abstract

A detailed model of steady-state combustion of a pseudo-propellant containing cyclotrimethylene trinitramine (RDX) and triaminoguanidinium azotetrazolate (TAGzT) is presented. The physicochemical processes occurring within the foam layer, comprised of a liquid and gas bubbles, and a gas-phase region above the burning surface are considered. The chemical kinetics is represented by a global thermal decomposition mechanism within the liquid by considering 18 species and eight chemical reactions. The reactions governing decomposition of TAGzT were deduced from separate confined rapid thermolysis experiments using Fourier transform infrared spectroscopy and time-of-flight mass spectrometry. Within the gas bubbles and gas-phase region, a detailed chemical kinetics mechanism was used by considering up to 93 species and 504 reactions. The pseudo-propellant burn rate was found to be highly sensitive to the global decomposition reactions of TAGzT. The predicted results of burn rate agree well with experimental burn-rate data. The increase in burn rate by inclusion of TAGzT is due in part from exothermic decomposition of the azotetrazolate within the foam layer, and from fast gas-phase reactions between triaminoguanidine decomposition products, such as hydrazine, and oxidiser products from the nitramine decomposition.

Keywords:

• premixed combustion
• detailed chemical kinetics
• RDX
• TAGzT
• burn rate
• temperature sensitivity

Acknowledgements

This material is based upon work supported by the US Army Research Office under Grant W911NF-07-1-0083, with Dr. Ralph Anthenien serving as the programme manager. Shipments of TAGzT from Dr. Christine Michienzi, Naval Surface Warfare Center, and both TAGzT and GzT from Dr. David Chavez of Los Alamos National Laboratory, are gratefully acknowledged.