One of the serious obstacles preventing wide industrial use of additive manufacturing (AM)
in metals and alloys is a lack of materials available for this technology. It is particularly true …

Abstract 316L stainless steel alloy is well known for its corrosion resistance and combination
of strength and ductility. By using direct metal additive manufacturing, 316L parts can be …

A feasibility study was performed to fabricate ITER In-Vessel components by one of the
metal additive manufacturing methods, Electron Beam Melting®(EBM®). Solid specimens of …

Additive manufacturing (AM) represents the present and the future of manufacturing
production, thanks to a new design paradigm that allows the customization of components …

Additive manufacturing, including laser powder bed fusion, offers possibilities for the
production of materials with properties comparable to conventional technologies. The main …

Today, a large number of different steels are being processed by Additive Manufacturing
(AM) methods. The different matrix microstructure components and phases (austenite, ferrite …

Additive manufacturing (AM) consists in building parts from scratch, usually by stacking
layers onto one another. Mostly used for rapid prototyping purposes, several AM processes …

The fabrication of multi-material structures using Ti–6Al–4V and copper was explored with
the additive manufacturing (AM) technology of electron beam melting (EBM). A new method …

The ability to fabricate or join components of 316 L austenitic stainless steel using additive
manufacturing (AM) processes such as laser and electron beam melting (EBM®) offers …

Additive manufacturing (AM), applied to metal industry, is a family of processes that allows
complex shape components to be realized from raw materials in the form of powders …