Fatigue strength assessment of additively manufactured metallic structures considering bulk and surface layer characteristics

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Fatigue strength assessment of additively manufactured metallic structures considering bulk and surface layer characteristics. / Schneller, W.; Leitner, M.; Pomberger, S. et al.
in: Additive Manufacturing, Jahrgang 40.2021, Nr. April, 101930, 04.2021.

Publikationen: Beitrag in FachzeitschriftArtikelForschung(peer-reviewed)

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@article{92ebe18840364fc8a98d75ee5db47281,
title = "Fatigue strength assessment of additively manufactured metallic structures considering bulk and surface layer characteristics",
abstract = "This paper extends a previously published fatigue strength estimation methodology for additively manufactured metallic bulk material by additionally accounting for effects of as-built surface layers. Interaction of intrinsic defects and surface texture convergently initiates fatigue failure. Holistic consideration of influencing factors significantly contributes to scientific fatigue assessment of structures fabricated by Laser-Powder Bed Fusion (L-PBF). Surface texture is highly dependent on the building parameters and performed post treatments. Three dimensional, optical topography scans form the basis of determining representative areal surface texture parameters. Areal notch valley depth Sv, alongside notch radii ρ evaluation, enables usage of a modified Peterson{\textquoteright}s approach. Effects of notch-like roughness features are quantified by a reduction factor ks, as analogously published for bulk material imperfections kb. Superimposition of ex- and intrinsic material characteristics is empirically assessed by an interaction exponent derived from experimental fatigue data. Macroscopic, tensile residual stresses acting as mean stresses are considered by Smith-Watson-Topper{\textquoteright}s approach. Unifying presented influencing factors derives a comprehensive model, conceived to estimate fatigue strength of additively manufactured metallic structures. Regardless of post processing condition, sound applicability of developed design approach is substantiated by averaging −7.1%, comparing estimated fatigue strength to experimental results.",
keywords = "17-4PH, AlSi10Mg, Fatigue, L-PBF, Residual stress, Scalmalloy",
author = "W. Schneller and M. Leitner and S. Pomberger and F. Gr{\"u}n and S. Leuders and T. Pfeifer and O. Jantschner",
year = "2021",
month = apr,
doi = "10.1016/j.addma.2021.101930",
language = "English",
volume = "40.2021",
journal = "Additive Manufacturing",
issn = "2214-8604",
publisher = "Elsevier",
number = "April",

}

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TY - JOUR

T1 - Fatigue strength assessment of additively manufactured metallic structures considering bulk and surface layer characteristics

AU - Schneller, W.

AU - Leitner, M.

AU - Pomberger, S.

AU - Grün, F.

AU - Leuders, S.

AU - Pfeifer, T.

AU - Jantschner, O.

PY - 2021/4

Y1 - 2021/4

N2 - This paper extends a previously published fatigue strength estimation methodology for additively manufactured metallic bulk material by additionally accounting for effects of as-built surface layers. Interaction of intrinsic defects and surface texture convergently initiates fatigue failure. Holistic consideration of influencing factors significantly contributes to scientific fatigue assessment of structures fabricated by Laser-Powder Bed Fusion (L-PBF). Surface texture is highly dependent on the building parameters and performed post treatments. Three dimensional, optical topography scans form the basis of determining representative areal surface texture parameters. Areal notch valley depth Sv, alongside notch radii ρ evaluation, enables usage of a modified Peterson’s approach. Effects of notch-like roughness features are quantified by a reduction factor ks, as analogously published for bulk material imperfections kb. Superimposition of ex- and intrinsic material characteristics is empirically assessed by an interaction exponent derived from experimental fatigue data. Macroscopic, tensile residual stresses acting as mean stresses are considered by Smith-Watson-Topper’s approach. Unifying presented influencing factors derives a comprehensive model, conceived to estimate fatigue strength of additively manufactured metallic structures. Regardless of post processing condition, sound applicability of developed design approach is substantiated by averaging −7.1%, comparing estimated fatigue strength to experimental results.

AB - This paper extends a previously published fatigue strength estimation methodology for additively manufactured metallic bulk material by additionally accounting for effects of as-built surface layers. Interaction of intrinsic defects and surface texture convergently initiates fatigue failure. Holistic consideration of influencing factors significantly contributes to scientific fatigue assessment of structures fabricated by Laser-Powder Bed Fusion (L-PBF). Surface texture is highly dependent on the building parameters and performed post treatments. Three dimensional, optical topography scans form the basis of determining representative areal surface texture parameters. Areal notch valley depth Sv, alongside notch radii ρ evaluation, enables usage of a modified Peterson’s approach. Effects of notch-like roughness features are quantified by a reduction factor ks, as analogously published for bulk material imperfections kb. Superimposition of ex- and intrinsic material characteristics is empirically assessed by an interaction exponent derived from experimental fatigue data. Macroscopic, tensile residual stresses acting as mean stresses are considered by Smith-Watson-Topper’s approach. Unifying presented influencing factors derives a comprehensive model, conceived to estimate fatigue strength of additively manufactured metallic structures. Regardless of post processing condition, sound applicability of developed design approach is substantiated by averaging −7.1%, comparing estimated fatigue strength to experimental results.

KW - 17-4PH

KW - AlSi10Mg

KW - Fatigue

KW - L-PBF

KW - Residual stress

KW - Scalmalloy

UR - http://www.scopus.com/inward/record.url?scp=85101801640&partnerID=8YFLogxK

U2 - 10.1016/j.addma.2021.101930

DO - 10.1016/j.addma.2021.101930

M3 - Article

AN - SCOPUS:85101801640

VL - 40.2021

JO - Additive Manufacturing

JF - Additive Manufacturing

SN - 2214-8604

IS - April

M1 - 101930

ER -