Additive manufacturing (AM) has undergone significant development over the past decades,
resulting in vast amounts of data that carry valuable information. Numerous research studies …

Manufacturing or repairing parts on-site, high geometric freedom, and feedstock efficiency
have long been regarded as nascent capabilities of additive manufacturing (AM) …

High cost of metal powders has increased the demand for recycling of unmelted powder in
electron beam powder bed fusion additive manufacturing process. However, powder …

Additive manufacturing (AM) is dynamically developing and finding applications in different
industries. The quality of input material is a part of the process and of the final product …

Abstract Ti-6Al-4V alloy is characterised by having excellent mechanical properties and
corrosion resistance combined with low specific weight and biocompatibility. This material is …

Multi-material additive manufacturing by laser powder bed fusion enables arbitrary material
composition in components and thus opens new design possibilities. During the …

Current metal additive manufacturing processes predominantly use heat energy to achieve
shaping and joining. The energy use efficiency and workflow process physics of these …

Additive Manufacturing marks a transformative advancement in space exploration, where
customization and efficient resource use are paramount. Metal additive manufacturing …

Unlocking the potential of additive manufacturing (AM) for space exploration hinges on
overcoming key challenges, notably the ability to manufacture or repair parts on-site during …

The last few years have seen an increasing use of spherical metals powders to produce bulk
parts through metal forming technologies like Additive Manufacturing and Metal Injection …