Microstructure and mechanical behavior of laser additive manufactured AISI 316 stainless steel stringers

•We produce large aspect ratio stainless steel structures with very good tensile properties.•The flexural tests proved that the cladded layers had very good formability.•The appearance of delta ferrite, which is deleterious to the corrosion properties, was avoided. Laser additive manufacturing of st...

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Published inMaterials in engineering Vol. 55; pp. 526 - 532
Main Authors de Lima, Milton Sergio Fernandes, Sankaré, Simon
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 01.03.2014
Subjects
Laser additive manufacturing
Lasers
Stainless steels
Lasers
Laser additive manufacturing
Stainless steels
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Abstract •We produce large aspect ratio stainless steel structures with very good tensile properties.•The flexural tests proved that the cladded layers had very good formability.•The appearance of delta ferrite, which is deleterious to the corrosion properties, was avoided. Laser additive manufacturing of stainless steels is a promising process for near net shape fabrication of parts requiring good mechanical and corrosion properties with a minimal waste generation. This work focuses on high aspect ratio AISI 316 steel structures made by superposition of sequential layers. A special nozzle for precise powder delivery together with a monomode fiber laser allowed producing high quality steel stringers on AISI 316 steel substrates. Although the stringers average compositions were inside the austenite plus ferrite range, only austenite phase was verified. The cladded structure presented some internal pores and cracks, responsible by the low Young’s moduli. However, the tensile properties were similar to the base material and other literature results. The three-point flexural tests also produced good results in terms of formability. The fabricated structures proved to be useful for use in mechanical construction.
AbstractList •We produce large aspect ratio stainless steel structures with very good tensile properties.•The flexural tests proved that the cladded layers had very good formability.•The appearance of delta ferrite, which is deleterious to the corrosion properties, was avoided. Laser additive manufacturing of stainless steels is a promising process for near net shape fabrication of parts requiring good mechanical and corrosion properties with a minimal waste generation. This work focuses on high aspect ratio AISI 316 steel structures made by superposition of sequential layers. A special nozzle for precise powder delivery together with a monomode fiber laser allowed producing high quality steel stringers on AISI 316 steel substrates. Although the stringers average compositions were inside the austenite plus ferrite range, only austenite phase was verified. The cladded structure presented some internal pores and cracks, responsible by the low Young’s moduli. However, the tensile properties were similar to the base material and other literature results. The three-point flexural tests also produced good results in terms of formability. The fabricated structures proved to be useful for use in mechanical construction.
Author de Lima, Milton Sergio Fernandes
Sankaré, Simon
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  surname: Sankaré
  fullname: Sankaré, Simon
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Snippet •We produce large aspect ratio stainless steel structures with very good tensile properties.•The flexural tests proved that the cladded layers had very good...
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StartPage 526
SubjectTerms Laser additive manufacturing
Lasers
Stainless steels
Title Microstructure and mechanical behavior of laser additive manufactured AISI 316 stainless steel stringers
URI https://dx.doi.org/10.1016/j.matdes.2013.10.016
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