Fatigue crack initiation and propagation in plain and notched PBF-LB/M, WAAM, and wrought 316L stainless steel specimens
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in: Materials and Design, Jahrgang 244, 113122, 01.08.2024.
Publikation: Beiträge in Zeitschriften › Zeitschriftenaufsätze › Forschung › begutachtet
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T1 - Fatigue crack initiation and propagation in plain and notched PBF-LB/M, WAAM, and wrought 316L stainless steel specimens
AU - Braun, Moritz
AU - Chen, Ting
AU - Shen, Junjun
AU - Fassmer, Henrik
AU - Klusemann, Benjamin
AU - Sheikhi, Shahram
AU - Ehlers, Sören
AU - Müller, Eckehard
AU - Sarmast, Ardeshir
AU - Schubnell, Jan
N1 - Publisher Copyright: © 2024 The Author(s)
PY - 2024/8/1
Y1 - 2024/8/1
N2 - Additively manufactured (AM) components—either made by laser-powder bed fusion or wire and arc additive manufacturing—typically contain process-related defects on and near surfaces that can be removed by machining. Various studies have shown that post-treatment, such as machining significantly improves the fatigue strength of AM parts. To this day, however, hardly any studies have investigated the fatigue strength of post-treated additively manufactured components with notches. In this study, fatigue tests were performed on plain and notched specimens to determine and compare the crack initiation and crack propagation behavior due to different manufacturing-related effects. Tests were performed on specimens produced by the two aforementioned AM processes and compared to specimens taken from wrought sheets. The fatigue strength of AM materials is influenced by microstructure, defects, residual stress, and notches. PBF-LB/M specimens exhibit the highest fatigue strength in plain, notch-free conditions, attributed to differences in microstructure and static strength affecting fatigue crack initiation. Notched specimens show larger differences among materials, with PBF-LB/M having shorter fatigue crack propagation life related to line-type defect clusters, while the plain PBF-LB/M specimens are less affected as their fatigue strength is primarily determined by fatigue crack initiation.
AB - Additively manufactured (AM) components—either made by laser-powder bed fusion or wire and arc additive manufacturing—typically contain process-related defects on and near surfaces that can be removed by machining. Various studies have shown that post-treatment, such as machining significantly improves the fatigue strength of AM parts. To this day, however, hardly any studies have investigated the fatigue strength of post-treated additively manufactured components with notches. In this study, fatigue tests were performed on plain and notched specimens to determine and compare the crack initiation and crack propagation behavior due to different manufacturing-related effects. Tests were performed on specimens produced by the two aforementioned AM processes and compared to specimens taken from wrought sheets. The fatigue strength of AM materials is influenced by microstructure, defects, residual stress, and notches. PBF-LB/M specimens exhibit the highest fatigue strength in plain, notch-free conditions, attributed to differences in microstructure and static strength affecting fatigue crack initiation. Notched specimens show larger differences among materials, with PBF-LB/M having shorter fatigue crack propagation life related to line-type defect clusters, while the plain PBF-LB/M specimens are less affected as their fatigue strength is primarily determined by fatigue crack initiation.
KW - Fatigue strength assessment
KW - Hybrid additive manufacturing
KW - Microstructural defects
KW - Post-production treatment
KW - Selective laser melting
KW - Wire arc additive manufacturing
KW - Engineering
UR - http://www.scopus.com/inward/record.url?scp=85197744098&partnerID=8YFLogxK
UR - https://www.mendeley.com/catalogue/5425f6ac-5c1b-3776-b220-a53897acf8bc/
U2 - 10.1016/j.matdes.2024.113122
DO - 10.1016/j.matdes.2024.113122
M3 - Journal articles
AN - SCOPUS:85197744098
VL - 244
JO - Materials and Design
JF - Materials and Design
SN - 0264-1275
M1 - 113122
ER -