Influence of defects on axial fatigue strength of maraging steel specimens produced by additive manufacturing

Influence of defects on axial fatigue strength of maraging steel specimens produced by additive manufacturing

Nowadays many materials such as steels, aluminium and titanium alloys can be realised by powder bed solutions melting subsequently powder layers by means of a laser or electron beam (Laser Beam Melting – LBM and Electron Beam Melting – EBM). The microstructure realised by layer-by-layer solidificati...

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Main Authors: Rigon Daniele, Meneghetti Giovanni, Görtler Michael, Cozzi Daniele, Waldhauser Wolfgang, Dabalà Manuele
Format: Article
Language:English
Published: EDP Sciences 2018-01-01
Series:MATEC Web of Conferences
Online Access:https://doi.org/10.1051/matecconf/201816502005
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spelling doaj-7e0f307a0e804b25a81abe17531791742021-02-02T05:43:38ZengEDP SciencesMATEC Web of Conferences2261-236X2018-01-011650200510.1051/matecconf/201816502005matecconf_fatigue2018_02005Influence of defects on axial fatigue strength of maraging steel specimens produced by additive manufacturingRigon DanieleMeneghetti GiovanniGörtler MichaelCozzi DanieleWaldhauser WolfgangDabalà ManueleNowadays many materials such as steels, aluminium and titanium alloys can be realised by powder bed solutions melting subsequently powder layers by means of a laser or electron beam (Laser Beam Melting – LBM and Electron Beam Melting – EBM). The microstructure realised by layer-by-layer solidification having high cooling rate cannot be considered isotropic. Therefore, the mechanical properties could be influenced by the building direction. Regarding maraging steel, the study of the influence of the building direction and the heat treatment on the static and axial fatigue strength has been investigated in a previous contribution. A large scatter of the fatigue test results was found because of the presence of detrimental surface and subsurface defects. The aim of this contribution is to present additional axial fatigue test results of maraging steel characterized by different build orientation and providing an analysis of the defects observed at the crack initiation area of the fracture surface.https://doi.org/10.1051/matecconf/201816502005
collection DOAJ
language English
format Article
sources DOAJ
author Rigon Daniele
Meneghetti Giovanni
Görtler Michael
Cozzi Daniele
Waldhauser Wolfgang
Dabalà Manuele
spellingShingle Rigon Daniele
Meneghetti Giovanni
Görtler Michael
Cozzi Daniele
Waldhauser Wolfgang
Dabalà Manuele
Influence of defects on axial fatigue strength of maraging steel specimens produced by additive manufacturing
MATEC Web of Conferences
author_facet Rigon Daniele
Meneghetti Giovanni
Görtler Michael
Cozzi Daniele
Waldhauser Wolfgang
Dabalà Manuele
author_sort Rigon Daniele
title Influence of defects on axial fatigue strength of maraging steel specimens produced by additive manufacturing
title_short Influence of defects on axial fatigue strength of maraging steel specimens produced by additive manufacturing
title_full Influence of defects on axial fatigue strength of maraging steel specimens produced by additive manufacturing
title_fullStr Influence of defects on axial fatigue strength of maraging steel specimens produced by additive manufacturing
title_full_unstemmed Influence of defects on axial fatigue strength of maraging steel specimens produced by additive manufacturing
title_sort influence of defects on axial fatigue strength of maraging steel specimens produced by additive manufacturing
publisher EDP Sciences
series MATEC Web of Conferences
issn 2261-236X
publishDate 2018-01-01
description Nowadays many materials such as steels, aluminium and titanium alloys can be realised by powder bed solutions melting subsequently powder layers by means of a laser or electron beam (Laser Beam Melting – LBM and Electron Beam Melting – EBM). The microstructure realised by layer-by-layer solidification having high cooling rate cannot be considered isotropic. Therefore, the mechanical properties could be influenced by the building direction. Regarding maraging steel, the study of the influence of the building direction and the heat treatment on the static and axial fatigue strength has been investigated in a previous contribution. A large scatter of the fatigue test results was found because of the presence of detrimental surface and subsurface defects. The aim of this contribution is to present additional axial fatigue test results of maraging steel characterized by different build orientation and providing an analysis of the defects observed at the crack initiation area of the fracture surface.
url https://doi.org/10.1051/matecconf/201816502005
work_keys_str_mv AT rigondaniele influenceofdefectsonaxialfatiguestrengthofmaragingsteelspecimensproducedbyadditivemanufacturing
AT meneghettigiovanni influenceofdefectsonaxialfatiguestrengthofmaragingsteelspecimensproducedbyadditivemanufacturing
AT gortlermichael influenceofdefectsonaxialfatiguestrengthofmaragingsteelspecimensproducedbyadditivemanufacturing
AT cozzidaniele influenceofdefectsonaxialfatiguestrengthofmaragingsteelspecimensproducedbyadditivemanufacturing
AT waldhauserwolfgang influenceofdefectsonaxialfatiguestrengthofmaragingsteelspecimensproducedbyadditivemanufacturing
AT dabalamanuele influenceofdefectsonaxialfatiguestrengthofmaragingsteelspecimensproducedbyadditivemanufacturing
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