Effect of Surface and Subsurface Defects on Fatigue Behavior of AlSi10Mg Alloy Processed by Laser Powder Bed Fusion (L-PBF)

Nasab, Milad Hamidi; Giussani, A.; Gastaldi, Dario; Tirelli, Valeria; Vedani, Maurizio

doi:10.3390/met9101063

Cited by 35 publications

(16 citation statements)

References 42 publications

(88 reference statements)

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“…Towards this aim, a defect-based modelling approach for internal pores has been used with great success [12,14,15]. This was also demonstrated for surface and subsurface pores in [16]. In [15] the authors clearly demonstrated, by the detection through computed tomography (CT) scan of all the defects present in specimens, that the critical defects were the ones with the largest stress intensity factor (SIF), thus supporting the adoption of "extreme value" concepts for estimating the maximum size of defects for fatigue assessment [12] and for comparing the "quality" of different treatments [17,18].…”

Section: Introductionmentioning

confidence: 99%

“…X-ray tomography has been used with great success to provide insights into additively manufactured materials, also for viewing of fatigue crack locations [28][29][30]. Recently the detailed analysis of thin struts manufactured in Ti6Al4V combining CT-scan and scanning electron microscopy (SEM) showed that the effect of surface features responsible for fatigue failures could be modelled by Kitagawa-Takahashi diagram [14,16,31]. However, a systematic study about the reasons why failure occurs in some critical surface features and their behaviour for different surface qualities is still lacking.…”

Section: Introductionmentioning

confidence: 99%

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Killer notches: The effect of as-built surface roughness on fatigue failure in AlSi10Mg produced by laser powder bed fusion

Plessis

Beretta

2020

Additive Manufacturing

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Killer notches: The effect of as-built surface roughness on fatigue failure in AlSi10Mg produced by laser powder bed fusion

Plessis

Beretta

2020

Additive Manufacturing

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“…The formation of spatter particles ejected from the laser-powder interaction zone, particularly from the melt-pool area, are known to consistently affect the surface properties of the manufactured parts, as well as to generate inner defects in the sub-surface area, which are difficult to remove without properly tuning the post-processing steps [86,[124][125][126][127]. Furthermore, very large spatter particles are most likely to generate lack-of-fusion defects in the final parts since, being potentially bigger (larger diameter) than the layer thickness, the process parameters may be not sufficient to fully melt them, and the spreading of the next powder layer could be inefficient [35].…”

Section: Spattermentioning

confidence: 99%

Material Reuse in Laser Powder Bed Fusion: Side Effects of the Laser—Metal Powder Interaction

Santecchia

Spigarelli

Cabibbo

2020

Metals

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Metal additive manufacturing is changing the way in which engineers and designers model the production of three-dimensional (3D) objects, with rapid growth seen in recent years. Laser powder bed fusion (LPBF) is the most used metal additive manufacturing technique, and it is based on the efficient interaction between a high-energy laser and a metal powder feedstock. To make LPBF more cost-efficient and environmentally friendly, it is of paramount importance to recycle (reuse) the unfused powder from a build job. However, since the laser-powder interaction involves complex physics phenomena and generates by-products which might affect the integrity of the feedstock and the final build part, a better understanding of the overall process should be attained. The present review paper is focused on the clarification of the interaction between laser and metal powder, with a strong focus on its side effects. Figure 1. Schematics of the laser powder bed fusion (LPBF) equipment. Adapted from Reference [9] with permission from Elsevier.While the market and the applications of laser powder bed fusion continuously and impressively grew in recent years, there is a common view across users and researchers concerning the repeatability of the process in terms of chemical composition and mechanical properties of the final parts, which are of paramount importance when challenging environmental or testing conditions are considered [10][11][12][13][14][15][16].The most typical approach to study the microstructural and mechanical properties of parts built by LPBF is to compare them with castings of the same alloy or, rather, the corresponding alloy since the starting material is metal powder rather than a fuse. However, in some existing alloys designed for cast and wrought parts, laser additive manufacturing processing results in cracking or other microstructure deficiencies [11,12,16,17]. It is worth noting that LPBF has more similarities with laser welding rather than casting, since the two laser-based techniques have some common features (i.e., melt-pool formation, moving heat source) [18]. However, process parameters are, in general, quite different in terms of laser power and scan speed, and the laser-matter interaction is much more complicated in LPBF processes, since the powder feedstock is inherently unstable and the solidified material undergoes multiple thermal cycles corresponding to the fusion of subsequent layers during the additive process [19][20][21][22]. Furthermore, owing to the similarities with welding and to the complicated interaction between laser and metal particles, when comparing laser powder bed fusion with other metal forming processes, it is evident that the range of processable alloys is very limited and the number of high-productivity commercially available alloys is even smaller [23]. One of the reasons behind this is that the level of metal powder sensitivity to the laser action during LPBF is not yet fully understood, despite the efforts of the scientific community to uncover it [24][25][26][27], and ...

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“…The generation of cracks is attributed to the residual stress caused by steep temperature gradients (Gu et al, 2012) (Kaufmann et al, 2016) (Harrison et al, 2015) (Han et al, 2018). Owing to these internal defects, SLM parts exhibit mechanical properties inferior to those of forged parts (Zhang et al, 2017) (Balachandramurthi et al, 2018) (Konečná et al, 2016) (Nasab et al, 2019) (Voisin et al, 2018). Internal defects cause stress concentration (Talemi, 2020) and deteriorate the mechanical properties, especially the fatigue properties, of SLM parts.…”

Section: Introductionmentioning

confidence: 99%

Relationship between internal defect size and fatigue limit in selective laser melted Inconel 718

Ogawahara

Sasaki

2021

Mechanical Engineering Journal

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Effect of Surface and Subsurface Defects on Fatigue Behavior of AlSi10Mg Alloy Processed by Laser Powder Bed Fusion (L-PBF)

Cited by 35 publications

References 42 publications

Killer notches: The effect of as-built surface roughness on fatigue failure in AlSi10Mg produced by laser powder bed fusion

Killer notches: The effect of as-built surface roughness on fatigue failure in AlSi10Mg produced by laser powder bed fusion

Material Reuse in Laser Powder Bed Fusion: Side Effects of the Laser—Metal Powder Interaction

Relationship between internal defect size and fatigue limit in selective laser melted Inconel 718

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