Technology Description

A number of studies have shown that microstructural refinement of tungsten can reduce its strain hardening and strain-rate sensitivity and thereby induce a shear localization response to high rates of strain, e.g. the type observed in anti-armor penetrator applications. However, for these materials to be seriously considered for deployment, their fabrication into high-density penetrators must be validated using approaches that are scaleable to high-volume production. In this project, two competitive, low-cost powder synthesis approaches--freeze-dry powders and glycine-nitrate synthesis--will be evaluated with respect to crystallite size, phase dispersion, sinterability, and potential for nanophase retention in the final consolidated material. Each is currently a proven, high-volume process for synthesizing nanocomposite and nanocrystalline powders. A series of high-volume powder consolidation processes also will be evaluated for their potential in yielding very high density and high ductility nanocomposite compacts, including combinations of sintering, hot isostatic pressing, swaging, and sinter forging. Based on these results, a single synthesis process and consolidation approach will be selected for further optimization and testing utilizing tungsten production equipment where possible. Results from high strain rate compression testing and measures of material producibility will be used as feedback data in evaluating process improvement. To validate the optimized processing conditions, prototype ballistic testing will be conducted using ¼-scale penetrator rods. Ongoing Department of Defense (DoD) health and environmental studies on tungsten-based materials will be monitored throughout the project. Based on the findings, nanocomposite samples may be submitted for toxicology testing.