Journal
SURFACE & COATINGS TECHNOLOGY
Volume 284, Issue -, Pages 422-426Publisher
ELSEVIER SCIENCE SA
DOI: 10.1016/j.surfcoat.2015.05.048
Keywords
Energetic materials; Mechanical properties; Strength testing; Blade casting; Tape casting; Additive manufacturing; Aluminum combustion; Thermites; Thin films; Energy generation
Funding
- Army Research Office [W911NF-11-1-0439, W911NF-14-1-0250]
- Idaho National Laboratory
- LDRD program
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This study uses blade casting methods for the synthesis of flexible, free-standing energetic films. Specifically, films include aluminum (Al) and (MoO3) powder thermites combined with potassium perchlorate (KCIO4) and silicone binder. In addition to this base composite, carbon fiber fabric reinforcement fabric has been incorporated to improve the structural integrity of the film. All films were cast at 1 mm thickness with constant percent solids to ensure consistent rheological properties. The films were ignited and flame propagation was recorded with a high speed camera. The results show that the energy propagation of the films increases with increasing mass percent KCIO4. The inclusion of carbon fiber fabric reinforcement fabric in the energetic film decreased the flame speed by 30% but maintained stable and steady energy propagation. The strengths of the films were tested to determine the effects of the carbon fiber fabric reinforcement fabric on the mechanical properties of the films. The non-reinforced film, failed upon initial loading of approximately 2.27 kg while the reinforced film maintained a load of 72.3 kg. While this method of synthesis allows manufacture of a flexible freestanding energetic film, the composition and rheology of the mixed slurry have potential as an extrusion cast energetic for additive manufacturing of energetic materials. (C) 2015 Elsevier ay. All rights reserved.
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