Abstract
Modification of composite solid propellant burning rates becomes a requirement based on the necessities of a mission. Literature discusses about various burn rate modifiers which can modify the burning rates effectively. This paper attempts to understand the behavior and mechanism of (dry) activated charcoal (a recently reported burn rate modifier) in composite solid propellant combustion. Extensive experimental studies are performed to achieve this objective. Effects of activated charcoal are studied on the individual components (fuel and oxidizer) of a composite solid propellant. Its behavior when present at various locations in a sandwich propellant and the quenched surface structures these sandwich propellants is also studied. These studies are further extended to composite propellants as well. From these studies, it is concluded that activated charcoal acts on the primary diffusion flame and enhances the binder melt flow over the surface. The unique features observed with activated charcoal (enhancement in burning the rates is observed only at low pressures and burn rate pressure index reduced) are justified with the proposed mechanism and site of its action. Understanding the mechanism of activated charcoal provided an opportunity to tailor a propellant composition, with activated charcoal coated on ammonium perchlorate, which exhibited very high burning rates (17.34 mm/s at 70 bar) and a near plateau burning (n ~0.08) in the pressure range of 20–70 bar. Also, this paper proposes a mechanism, as to what causes a propellant to have a relatively larger binder melt flow and consequently lower n has been answered.
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Abbreviations
- AC:
-
Activated charcoal
- AP:
-
Ammonium perchlorate
- CC:
-
Copper chromite
- Cu2O:
-
Cuprous oxide
- DOA:
-
Dioctyl adipate
- DSC:
-
Differential scanning calorimetry
- HTPB:
-
Hydoxyl terminated poly butadiene
- IO:
-
Iron oxide
- IPDI:
-
Isophorone di-isocynate
- LiF:
-
Lithium fluoride
- LPDL:
-
Low pressure deflagration limit
- n :
-
Burn rate pressure index
- PDF:
-
Primary diffusion flame
- SEM:
-
Scanning electron microscope
- TGA:
-
Thermal gravimetric analysis
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Ishitha, K., Ramakrishna, P.A. Activated charcoal: as burn rate modifier and its mechanism of action in non-metalized composite solid propellants. Int J Adv Eng Sci Appl Math 6, 76–96 (2014). https://doi.org/10.1007/s12572-014-0112-z
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DOI: https://doi.org/10.1007/s12572-014-0112-z