- Manufacturing of Alloys
Metallic powders of different specific weights, sizes, or shapes can be blended to perfect uniformity in the Inversina. The Inversina is used to homogenize alloys containing coarse tungsten / tungsten carbide, nickel, palladium, platinum, copper, iron, steel, sintered metals, precious metals, carbon, ceramics, and other metallic powders - prior to further processing steps (e.g. metal injection molding, thermal finishing, etc).
- Passivation
The Inversina is used for passivation and/or surface treatment of metallic, ore, ceramic, or glass raw materials. In these cases, beads or other grinding materials are added to the container together with the untreated product and the ingredients are mixed until desired smoothness or roundness has been achieved. The grinding media can then be separated from the end product and recycled.
- Quality Assurance / Quality Control and Sample Preparation
In some cases, a number of samples need to be homogenized prior to further analysis, as when the exact composition of a large batch of metallic raw materials needs to be determined prior to further processing. Using the extremely reliable, reproducible, and efficient method of 3-D Inversion Kinematics, the Inversina can mix any number of powders with different specific weights, sizes, or shapes to perfect uniformity in a very short time.
- References:
The Inversina is used by a number of mining companies and metallic powder manufacturers, including many of the most distinguished mining giants in the world. We invite you to visit our Testimonials section. Personal references are available upon request.
- Publications
Laser cladding of wear resistant metal matrix composite Coatings Thin Solid Films / Elsevier - A. Yakovlev et Al, DIPI, ENISE, Saint Etienne, France (2003)
Development of Tungsten Carbide-Inconel 718 composites
Archives of Civil and Mechanical Engineering: Volume 18, Issue 4, September 2018, p1410–1420
Ti Reactive Sintering of Electrically Conductive Al2O3–TiN Composite: Influence of Ti Particle Size and Morphology on Electrical and Mechanical Properties
Wei Zhai, Xu Song, Tao Li, Bingxue Yu, Wanheng Lu, and Kaiyang Zeng
Materials (Basel). 2017 Dec; 10(12): 1348.
Effects of AGG on fracture toughness of tungsten carbide
Materials Science and Engineering: Volumes 445–446, 15 February 2007, p587–592
Processing and Fabrication of Advanced Materials XIII Materials Science and Engineering: A – Volume 430, Issues 1–2, 25 August 2006, Pages 113–119
Effects of lower cobalt binder concentrations in sintering of tungsten carbide Stallion Press Singapore – Gupta et Al, 2005 (ISBN 981-05-3000-5)
Towards better combustion of lunar regolith with magnesium
Combustion and Flame – Volume 160, Issue 9, September 2013, Pages 1876–1882