Fluoroelastomer pyrotechnic time delay compositions

Potgieter, Gerard; Kaci, Mustapha; Fabbro, Olinto Del; Labuschagne, George; Kelly, Cheryl

doi:10.1007/s10973-016-5613-5

Cited by 9 publications

(14 citation statements)

References 12 publications

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“…The measured burning rate results, listed in Table 1, were comparable to results obtained in other studies [12,16]. Filaments extruded for 3D printable compositions based on PVDF, with 20 wt.% aluminium as fuel, exhibited burning rates of up to 18.7 ±1.3 mm•s −1 [12].…”

Section: Burn Rate and Time To Ignitionsupporting

confidence: 85%

“…Filaments extruded for 3D printable compositions based on PVDF, with 20 wt.% aluminium as fuel, exhibited burning rates of up to 18.7 ±1.3 mm•s −1 [12]. Potgieter et al [16] measured the burning rates of energetic films based on Viton B fluoropolymer as oxidant with 50 wt.% metal fuel. Their films had a thickness of 245 ± 21 µm and they were prepared via a slurry casting process.…”

Section: Burn Rate and Time To Ignitionmentioning

confidence: 99%

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Extrudable Gassy Pyrotechnic Time Delay Compositions

Grobler¹,

Cowgill²,

Focke³

et al. 2018

Cent. Eur. J. Energ. Mater.

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A copolymer of chlorotrifluoroethylene and vinylidene fluoride was investigated to assess its viability as an oxidiser, for aluminium as the fuel, in an extrudable pyrotechnic composition for application in 3D printing. Experimental results and EKVI thermochemical modelling suggested that a fuel loading of 30 wt.% would provide the maximum energy output. DTA and TGA analysis were performed in order to ascertain processing limits. With the addition of a processing aid LFC-1 ® samples could be extruded successfully. Printing with the compositions had limited success. The high melt viscosity paired with the filament's susceptibility to excessive preheating caused the print quality to be low. Delamination did not occur due to good fusion achieved during layer deposition. With minor compositional adjustments printing quality could be improvedy.

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Section: Burn Rate and Time To Ignitionsupporting

confidence: 85%

Section: Burn Rate and Time To Ignitionmentioning

confidence: 99%

Extrudable Gassy Pyrotechnic Time Delay Compositions

Grobler¹,

Cowgill²,

Focke³

et al. 2018

Cent. Eur. J. Energ. Mater.

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“…Upon ignition the black powder core will burn at a steady rate, transferring the flame front to the detonator. Alternatively, it has been suggested that fluoropolymer-based systems could be used in a similar fashion [8]. The production of the fuse can be simplified by extruding a fluoropolymer filled with a suitable fuel, e. g. aluminum, since it will only consist of a single part.…”

Section: Safety Fuse and Gassy Delaysmentioning

confidence: 99%

“…The calculation and analysis using the differential equation (8), as well as other relevant energy and mass continuity equations, are simplified by converting them into dimensionless form. This automatically leads to characteristic dimensionless parameters that are included in the list of dimensionless groups or numbers enumerated in Table 1 [57a].…”

Section: Elementary Model For a Cylindrical Delay Elementmentioning

confidence: 99%

“…The reaction kinetics were assumed second order in conversion. The differential equation (8), in its dimensionless form, was solved numerically subject to the boundary conditions stated in equation (9). A parametric analysis was then performed to determine the ignition criteria for gasless selfpropagating reactions through an ignition temperature analysis.…”

Section: Ignitionmentioning

confidence: 99%

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Review of Gasless Pyrotechnic Time Delays

Focke

Tichapondwa

Montgomery

et al. 2018

Propellants Explo Pyrotec

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Gasless pyrotechnic delay compositions for time‐sequencing energetic events are reviewed. They are mixtures of powdered fuels and oxidants capable of a highly exothermic oxidation‐reduction reaction. Trends favor ‘green’ compositions targeted to replace compositions containing perchlorates, chromates, lead and barium. Thermite‐based reactions dominate but intermetallics (especially multi‐layered versions) and hybrids appear promising considering progress in self‐propagating high temperature synthesis technology. Improving computer modelling will require better description of condensed phase reactions. Progress was made with the development of “hot spot” models and expressing reactivity in terms of the number of contact points (or contact surface area) between particles. Promising processing advances include mechanochemical synthesis of reactive particle composites by arrested milling or comminution of cold‐rolled multilayer intermetallics. Dry mixing of reactive powders has made way for slurry mixing followed by spray drying.

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