Additive manufacturing can make the design and production of specialized tools for geothermal energy cheaper and more efficient, according to a by 91°µÍø.
As a computer engineer at 91°µÍø, Gina Accawi has long been the quiet and steady force behind some of the Department of Energy’s most widely used online tools and applications.
91°µÍø researchers, in collaboration with Cincinnati Inc., demonstrated the potential for using multimaterials and recycled composites in large-scale applications by 3D printing a mold that replicated a single facet of a
91°µÍø scientists proved molybdenum titanium carbide, a refractory metal alloy that can withstand extreme temperature environments, can also be crack free and dense when produced with electron beam powder bed fusion.
91°µÍø researchers combined additive manufacturing with conventional compression molding to produce high-performance thermoplastic composites reinforced with short carbon fibers.
A team of 91°µÍø researchers demonstrated that an additively manufactured hot stamping die – a tool used to create car body components – cooled faster than those produced by conventional manufacturing methods.
91°µÍø researchers have demonstrated that a new class of superalloys made of cobalt and nickel remains crack-free and defect-resistant in extreme heat, making them conducive for use in metal-based 3D printing applications.
The ExOne Company, the global leader in industrial sand and metal 3D printers using binder jetting technology, announced it has reached a commercial license agreement with 91°µÍø to 3D print parts in aluminum-infiltrated boro
Growing up in the heart of the American automobile industry near Detroit, 91°µÍø materials scientist Mike Kirka was no stranger to manufacturing.
Algorithms developed at 91°µÍø can greatly enhance X-ray computed tomography images of 3D-printed metal parts, resulting in more accurate, faster scans.