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Cold Sintering Process Saves Energy, Material

Researchers at Penn State University (University Park, PA) have devised a novel method for sintering, a widely used manufacturing process for powdered materials. The new process, which uses much less time and energy than current approaches, could have global implications on manufacturing and energy savings and pave the way for new discoveries.

3D Printing Large Metal Parts for Land, Sea, Air

Sciaky Inc. (Chicago) has staked its claim to being the leading provider of metal 3D printing solutions for large parts approved for land, sea, air, and space applications, with the latest success being its Electron Beam Additive Manufacturing (EBAM) technology. Sciaky was called upon to manufacture a titanium variable ballast (VB) tank for a submarine manufacturer.

The Quest for Safer 3D Printing Materials

When Desktop Metal introduced its “office-friendly” Studio metal prototype printer earlier this year, the company renewed attention on the issue of safer materials for binder jetting, an additive manufacturing method.

All In with Additive

How new CAD/CAM programming and simulation software can help address additive manufacturing processes.

SLM Solutions Group signs long-term cooperation pact with multi-machine order

LUBECK, GERMANY, June 19, 2017 – SLM Solutions Group AG, a leading supplier of metal-based additive manufacturing technology, signed a long-term cooperation agreement with BeamIT S.p.a., which is based in Fornovo di Taro, Italy. The cooperation concerns the joint development and testing of various parameters for setting the machines when using various metal powders.

New 3D Printer Makes Fully Isotropic Parts, Virtually Eliminates Post-Processing

One of the “dirty secrets” of 3D printing is the universal need to take additional steps to render the output usable, including removing the part from its support, curing the part, or improving the surface. Aside from additional cycle time and cost, these steps often require or emit toxic chemicals, necessitating special ventilation and making them unsuitable for a standard office environment. For example, parts built with fused deposition modeling (FDM) must spend about four to eight hours in a heated, agitated sodium hydroxide bath.