Curing Viscosity of HTPB‐Based Binder Embedding Micro‐ and Nano‐Aluminum Particles

Maggi, F.

doi:10.1002/prep.201400010

Cited by 16 publications

(10 citation statements)

References 25 publications

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“…The presence of the activation layer did not interact with curing processes or generated internal bubbling, at the mixing temperature of 36°C. These observations are in line with binder-fuel viscosity analyses recently published by the same research group [41]. For combustion tests, an increase of burning rate in the order of about + 20 %, with respect to the original non-activated powders, was observed.…”

Section: Application In Propellantssupporting

confidence: 90%

Activated aluminum powders for space propulsion

et al. 2015

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Section: Application In Propellantssupporting

confidence: 90%

Activated aluminum powders for space propulsion

et al. 2015

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“…The most prominent result observed was the decrease in the ignition time and increase in the burning rate for compositions containing nano-Al [38,155,156]. However, the wide utilization of nanometals is limited by several factors, i. e., (i) the reduced metal content and associated performance losses [160] (note the surprising positive effect of the oxide layer [165]), (ii) stability issues, e. g., oxidation during storage [166], (iii) coalescence prior to reaction, diminishing the effects of nanosize [167,168], (iv) the gradual increase in viscosity for compositions with a binder [169], and (v) the difficulty of obtaining a uniform composite mixture with nanocomponents [156,170].…”

Section: Energetic Inks For Rms: Composition and Componentsmentioning

confidence: 99%

Progress in Additive Manufacturing of Energetic Materials: Creating the Reactive Microstructures with High Potential of Applications

Muravyev

Моногаров

Schaller

et al. 2019

Propellants Explo Pyrotec

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The modern “energetic‐on‐a‐chip” trend envisages reducing size and cost while increasing safety and maintaining the performance of energetic articles. However, the fabrication of reactive structures at micro‐ and nanoscales remains a challenge due to the spatial limitations of traditional tools and technologies. These mature techniques, such as melt casting or slurry curing, represent the formative approach to design as distinct from the emerging additive manufacturing (3D printing). The present review discusses various methods of additive manufacturing based on their governing principles, robustness, sample throughput, feasible compositions and available geometries. For chemical composition, nanothermites are among the most promising systems due to their high ignition fidelity and energetic performance. Applications of reactive microstructures are highlighted, including initiators, thrusters, gun propellants, caseless ammunition, joining and biocidal agents. A better understanding of the combustion and detonation phenomena at the micro‐ and nanoscale along with the advancement of deposition technologies will bring further developments in this field, particularly for the design of micro/nanoelectromechanical systems (MEMS/NEMS) and propellant grains with improved performance.

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“…A higher dampening was observed with powders having large specific surface area. The slowest viscosity build-up was reported from propellants with uncoated nano aluminium powders [22][23].…”

Section: Effect Of Nano-aluminium On End Viscosity Curing Reactions mentioning

confidence: 99%

Tailoring of Mechanical Properties of Highly Filled Nano‐Aluminized Propellants by Modifying Binder Polymer Microstructure

Sanyal

Chakravarthy

Ramesh

et al. 2020

Propellants Explo Pyrotec

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Use of nano sized aluminium powder in place of micron sized powder leads to increase in specific impulse of solid composite propellants. However, poor mechanical properties of nano-aluminized propellants prevent their use in actual rocket motors. An attempt has been made here, to improve the mechanical properties by using different HTPB resins having different functionality type distribution. Adjustment of isocyanate to hydroxyl ratio, and ratio of the chain extender, Butane-diol, to the cross-linker, Tri-Methylol-Propane, had also been tried to investigate their effect on mechanical properties. Nano-aluminium content in the propellant samples could be raised to the conventional level of 18 % by use of Iso Decyl Pelargonate as plasticizer in place of Dioctyl Adipate. This made the samples at par with the conventional micro-aluminium propellants, and the experimental results comparable. The microstructural changes of HTPB significantly improved the tensile strength of the nano-aluminium propellants to 0.65 MPa and break elongation to 17 % respectively. Recorded heat of combustion values are at 5990 J/g. These figures meet industrial tolerance and make the propellant acceptable for use while increasing its specific impulse beyond today's conventional levels. The technology established has potentials to increase nano-aluminium content further, and augment ballistic properties of solid motors, upholding the required industrial restrictions of rheological and physico-mechanical parameters.

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Curing Viscosity of HTPB‐Based Binder Embedding Micro‐ and Nano‐Aluminum Particles

Cited by 16 publications

References 25 publications

Activated aluminum powders for space propulsion

Activated aluminum powders for space propulsion

Progress in Additive Manufacturing of Energetic Materials: Creating the Reactive Microstructures with High Potential of Applications

Tailoring of Mechanical Properties of Highly Filled Nano‐Aluminized Propellants by Modifying Binder Polymer Microstructure

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