Počet záznamů: 1  

Microstructural characterization and mechanical behaviour of laser powder Bed Fusion stainless steel 316L

  1. 1.
    0583696 - ÚFM 2025 RIV NL eng J - Článek v odborném periodiku
    Crisafulli, D. - Fintová, Stanislava - Santonocito, D. - D'Andrea, D.
    Microstructural characterization and mechanical behaviour of laser powder Bed Fusion stainless steel 316L.
    Theoretical and Applied Fracture Mechanics. Roč. 131, Jun (2024), č. článku 104343. ISSN 0167-8442. E-ISSN 1872-7638
    Institucionální podpora: RVO:68081723
    Klíčová slova: Additive Manufacturing * Energy Methods * Mechanical Behaviour * Microstructure Characterization * SS AISI 316L
    Obor OECD: Mechanical engineering
    Impakt faktor: 5.3, rok: 2022
    Způsob publikování: Open access
    https://www.sciencedirect.com/science/article/pii/S0167844224000922?via%3Dihub

    Laser Powder Bed Fusion (L-PBF) is a highly precise and customizable additive manufacturing (AM) technique
    that uses a high-energy laser to selectively melt and fuse powdered material into a three-dimensional object.
    However, depending on the process parameters, the final components may have potential flaws that can affect
    their quality and mechanical properties, due to porosity, melting and incomplete fusion of powder particles and
    because the process involves local heating and sometimes uneven heat transfer, the processed components may
    warp or crack due to residual stresses or thermal gradients. The manufacturing process itself reflects in the final
    component structure having a detrimental effect on the strength, durability, fatigue resistance, and corrosion.
    In this work, static tensile and fatigue tests were performed on traditional and L-PBF manufactured AISI 316L
    stainless steel specimens. The energetic release has been evaluated with an infrared camera during the static and
    fatigue tests aiming to identify material thermal response to the loading and to predict the failure in rapid way
    adopting Thermographic Methods. Differences were observed comparing the fatigue data of the L-PBF processed
    specimens with the traditional material. However, analysis of internal structure, porosity, and surface characteristics of the AM material in combination with fractographic analysis helped to explain the differences in the fatigue life. The observed energy release, different for both material types, was discussed based on the structural characteristics. The results show that the crack originates from a defect on the surface or just below the surface, with a transgranular propagation.
    Trvalý link: https://hdl.handle.net/11104/0352712

     
     
Počet záznamů: 1  

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