One of the bottleneck issues for commercial scale-up of Ti additive manufacturing lies in high cost of raw material, i.e. the spherical Ti powder that is often made by gas atomization. In this study, we address this significant issue by way of powder modification & ball milling processing, which shows that it is possible to produce printable Ti powders based on ultra-low cost, originally unprintable hydrogenation-dehydrogenation (HDH) Ti powder. It is also presented that the as-printed Ti using the modified powder exhibits outstanding mechanical properties, showing a combination of excellent fracture strength (~895 MPa) and high ductility (~19.0% elongation).
Ultra-low cost Ti powder for selective laser melting additive manufacturing and superior mechanical properties associated
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引用本文： Hou Y H, Liu B, Liu Y, Zhou Y H, Song T T, Zhou Q et al. Ultra-low cost Ti powder for selective laser melting additive manufacturing and superior mechanical properties associated. Opto-Electron Adv 2, 180028 (2019).
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