Fatigue crack growth behavior of Inconel 718 produced by selective laser melting

Additive layer manufacturing has recently gained a lot of interest due to the feasibility of producing metallic components directly from a computer-aided design file of the part. Selective laser melting, one of the main additive layer manufacturing technologies, is currently capable of producing ne...

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Main Authors: R. Konecná, L. Kunz, G. Nicoletto, A. Baca
Format: Article
Language:English
Published: Gruppo Italiano Frattura 2015-12-01
Series:Frattura ed Integrità Strutturale
Subjects:
Online Access:https://212.237.37.202/index.php/fis/article/view/1625
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spelling doaj-aa2c195e4a0648289802b300179896552021-01-30T17:15:29ZengGruppo Italiano FratturaFrattura ed Integrità Strutturale1971-89932015-12-011035Fatigue crack growth behavior of Inconel 718 produced by selective laser meltingR. KonecnáL. KunzG. NicolettoA. Baca Additive layer manufacturing has recently gained a lot of interest due to the feasibility of producing metallic components directly from a computer-aided design file of the part. Selective laser melting, one of the main additive layer manufacturing technologies, is currently capable of producing nearly ready-to-use parts made of metallic materials. Their microstructure, however, differs substantially from that produced by conventional manufacturing. That is why a detailed study and knowledge of the relation of specific microstructure, parameters of the selective laser melting process and mechanical properties is of utmost significance. This study reports on the investigation of the fatigue crack growth behavior in Inconel 718 superalloy produced by selective laser melting. The fatigue crack growth curve and the threshold values of the stress intensity factor for propagation of long cracks were experimentally determined on compact-tension specimens fabricated using a RENISHAW A250 system and the recommended processing parameters. The fatigue crack growth rates and the fatigue crack paths both in the threshold and in the Paris region were investigated. The crack propagation curves and the crack propagation threshold were compared with literature data describing the behavior of conventionally manufactured material. The mechanism of fatigue crack growth was discussed in terms of the specific microstructure produced by selective laser melting. https://212.237.37.202/index.php/fis/article/view/1625Inconel 718selective laser meltingFatigue crack growthFractography
collection DOAJ
language English
format Article
sources DOAJ
author R. Konecná
L. Kunz
G. Nicoletto
A. Baca
spellingShingle R. Konecná
L. Kunz
G. Nicoletto
A. Baca
Fatigue crack growth behavior of Inconel 718 produced by selective laser melting
Frattura ed Integrità Strutturale
Inconel 718
selective laser melting
Fatigue crack growth
Fractography
author_facet R. Konecná
L. Kunz
G. Nicoletto
A. Baca
author_sort R. Konecná
title Fatigue crack growth behavior of Inconel 718 produced by selective laser melting
title_short Fatigue crack growth behavior of Inconel 718 produced by selective laser melting
title_full Fatigue crack growth behavior of Inconel 718 produced by selective laser melting
title_fullStr Fatigue crack growth behavior of Inconel 718 produced by selective laser melting
title_full_unstemmed Fatigue crack growth behavior of Inconel 718 produced by selective laser melting
title_sort fatigue crack growth behavior of inconel 718 produced by selective laser melting
publisher Gruppo Italiano Frattura
series Frattura ed Integrità Strutturale
issn 1971-8993
publishDate 2015-12-01
description Additive layer manufacturing has recently gained a lot of interest due to the feasibility of producing metallic components directly from a computer-aided design file of the part. Selective laser melting, one of the main additive layer manufacturing technologies, is currently capable of producing nearly ready-to-use parts made of metallic materials. Their microstructure, however, differs substantially from that produced by conventional manufacturing. That is why a detailed study and knowledge of the relation of specific microstructure, parameters of the selective laser melting process and mechanical properties is of utmost significance. This study reports on the investigation of the fatigue crack growth behavior in Inconel 718 superalloy produced by selective laser melting. The fatigue crack growth curve and the threshold values of the stress intensity factor for propagation of long cracks were experimentally determined on compact-tension specimens fabricated using a RENISHAW A250 system and the recommended processing parameters. The fatigue crack growth rates and the fatigue crack paths both in the threshold and in the Paris region were investigated. The crack propagation curves and the crack propagation threshold were compared with literature data describing the behavior of conventionally manufactured material. The mechanism of fatigue crack growth was discussed in terms of the specific microstructure produced by selective laser melting.
topic Inconel 718
selective laser melting
Fatigue crack growth
Fractography
url https://212.237.37.202/index.php/fis/article/view/1625
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AT abaca fatiguecrackgrowthbehaviorofinconel718producedbyselectivelasermelting
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