Advanced manufacturing, more specifically additive manufacturing, has been increasingly explored since the emergence of the so-called Industry 4.0. 3D printing techniques, including the great diversity of technologies and materials that can be used, allow a wide range of applications. In order to further explore and deepen the studies related to this topic, this research investigated the mechanical properties of PH1 stainless steel, manufactured in an EOS M280 printer through the laser layer sintering process. The characteristics of the material were explored, identifying influences of the form of manufacture and comparing its measured properties with those reported by the printer manufacturer and with similar laminated materials found on the market. The tensile, roughness, hardness, impact, M.E.V. and fatigue tests were selected considering obtaining the most relevant properties of the material for the industry of the parts produced by the technology. The measured results were compared with those obtained by traditional manufacturing, so that it was possible to analyze the feasibility and reliability of replacing the manufacturing method. These indicate that the printed material is resistant and can replace parts obtained by traditional manufacturing, but it must be used with some considerations as it is greatly influenced by the printing orientation. Additionally, a script for the digital manufacturing of spare parts was developed, to allow the manufacture of parts that, together with the mechanical tests performed, allows the evaluation of the path to be followed within the additive manufacturing for each part.