Premature failure of an additively manufactured material

Wang, Zhi; Xie, M.S.; Li, Yuanyuan; Zhang, Weiwen; Chao, Yang; Kollo, Lauri; Eckert, J.; Prashanth, Konda Gokuldoss

doi:10.1038/s41427-020-0212-0

Cited by 90 publications

(39 citation statements)

References 43 publications

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“…Generally, the as-built samples are characterized by an increase of n values with increasing distance from the preheated build platform. This behaviour can be explained through the possible increase of high-density defects or dislocations as previously reported by the argumentation of the residuals stress [75]. Sjögren et al [76] study the effective correlation between the dislocation movements and the strain hardening exponent (n), which increases with the increase of the multiplication and entanglement of dislocations.…”

Section: Mechanical Propertiesmentioning

confidence: 65%

“…On the other hand, the mobile dislocation easily traverses the grains if the microstructure presents the fragmented and coarsened Si eutectic (non-cellular structure) as obtained after the T6 HT (Figure 4). Figure 8b reports the strain hardening rate normalized with the true stress [75] of the samples (4), ( 1) and ( 2) as representative of the as-built, direct aged and T6 heat-treated conditions, respectively. Focusing on as-built and direct aged samples, it is worth repeating that the failures occur before the necking formation, and these can be considered as premature failures caused by the mechanisms previously discussed.…”

Section: Mechanical Propertiesmentioning

confidence: 99%

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Work Hardening of Heat-Treated AlSi10Mg Alloy Manufactured by Selective Laser Melting: Effects of Layer Thickness and Hatch Spacing

Ghio

Cerri

2021

Materials

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The present study analyzed the microstructure and the mechanical properties of AlSi10Mg SLMed bars (10 × 10 × 300 mm) and billets (10 × 100 × 300 mm) before and after the direct aging at 200 °C for 4 h and the T6 heat treatment. The discussed results are compared to those obtained by the AlSi10Mg samples manufactured with the same geometry but using different process parameters (layer thickness higher than 40 μm and a hatch spacing lower than 100 μm) and also through the Quality Index (QI). These work conditions allow the obtaining of a microstructural variation and different tensile properties in as-built top samples. In both batches, the cycle time was 45 h and together with the preheated build platform at 150 °C, induced an increase of UTS (Ultimate Tensile Strength) and yield strength on the bottom rather than the top samples due to the aging phenomena. Upon completion of the direct aging heat treatment, the effects induced by the platform were cancelled, keeping a full cellular microstructure that characterized the as-built SLMed (Selective Laser Melted) samples. Moreover, the Considère criterion and the work hardening analysis showed that the failure occurs after the necking formation in some of the T6 heat-treated samples. In this last case, the Si eutectic network globularized into Si particles, causing a decrease of UTS (from around 400 MPa to 290 MPa) in favour of an increase of ductility up to 15% and reaching a QI in the range 400 ÷ 450 MPa. These values place these samples between the high-quality aluminium cast alloy and T6 heat-treated ones.

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Section: Mechanical Propertiesmentioning

confidence: 65%

Section: Mechanical Propertiesmentioning

confidence: 99%

Work Hardening of Heat-Treated AlSi10Mg Alloy Manufactured by Selective Laser Melting: Effects of Layer Thickness and Hatch Spacing

Ghio

Cerri

2021

Materials

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“…In addition, other compositions related to the present composition (Al-20Si-5Fe-3Cu-1Mg) like Al-20Si-5Fe [ 65 , 66 ] and Al-20Si-5Fe-2X (X = Cu, Ni, Cr) [ 10 ] irrespective of the form present (powder or melt-spun ribbons or hot consolidated specimens) show the presence of three phases (α-Al, Si, and δ-Al 4 FeSi 2 ) like the gas atomized Al-20Si-5Fe-3Cu-1Mg powder. Hence, in the present case, the non-equilibrium nature of the SLM process and the presence of anisotropic heat extraction conditions [ 67 ] lead to the formation of the other two phases, Al 2 CuMg and β-Al 5 FeSi.…”

Section: Resultsmentioning

confidence: 99%

“…The Vickers microhardness of the Al-20Si-5Fe-3Cu-1Mg gas atomized powder is observed to be 234 HV, which is very close to the hardness of the SLM sample, suggesting that SLM and gas atomization process exhibit similar cooling rates, however different is the solidification conditions [ 64 ]. However, similar compositions like Al-20Si-5Fe, and Al-20Si-5Fe-2X (X = Cu, Ni, Cr) [ 10 , 66 , 67 ] processed via powder metallurgical route (gas atomization and subsequent hot consolidation) show hardness of the samples varying in the range 140–200 HV. The hardness is significantly lower than the present SLM sample owing to the presence of Cu and Mg, which promotes the formation of the intermetallic phases Al 2 CuMg and β-Al 5 FeSi.…”

Section: Resultsmentioning

confidence: 99%

Effect of Substrate Plate Heating on the Microstructure and Properties of Selective Laser Melted Al-20Si-5Fe-3Cu-1Mg Alloy

Jia

et al. 2021

Materials

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The Al-20Si-5Fe-3Cu-1Mg alloy was fabricated using selective laser melting (SLM). The microstructure and properties of the as-prepared SLM, post-treated SLM, and SLM with substrate plate heating are studied. The as-prepared SLM sample shows a non-uniform microstructure with four different phases: fcc-αAl, eutectic Al-Si, Al2MgSi, and δ-Al4FeSi2. With thermal treatment, the phases become coarser and the δ-Al4FeSi2 phase transforms partially to β-Al5FeSi. The sample produced with SLM substrate plate heating shows a relatively uniform microstructure without a distinct difference between hatch overlaps and track cores. Room temperature compression test results show that an as-prepared SLM sample reaches a maximum strength (862 MPa) compared to the heat-treated (524 MPa) and substrate plate heated samples (474 MPa) due to the presence of fine microstructure and the internal stresses. The reduction in strength of the sample produced with substrate plate heating is due to the coarsening of the microstructure, but the plastic deformation shows an improvement (20%). The present observations suggest that substrate plate heating can be effectively employed not only to minimize the internal stresses (by impacting the cooling rate of the process) but can also be used to modulate the mechanical properties in a controlled fashion.

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“…The dislocation density of the PBF‐L alloys is high, of the order of 1 × 10 14 m m −3 . [ 20,122 ] The dislocation interactions with each other will give rise to strengthening, where the dislocations impede with each other. The dislocation strengthening is given by [ 123,124 ]

Δ σ_{d} = m α G b / ρ

where m is the Schmid factor, α is a proportionality constant, b is the Burger's vector, and ρ is dislocation density.…”

Section: Strengthening Mechanismsmentioning

confidence: 99%

Additive Manufacturing of Aluminum‐Based Metal Matrix Composites—A Review

et al. 2021

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Aluminum metal matrix composites (AMMCs) offer the potential to combine the advantages of both the aluminum alloys (low density and high ductility) and the reinforcements (high strength and high elastic modulus [EM]), therefore show superior specific strength, high specific stiffness, low coefficient of thermal expansion (CTE), and outstanding wear resistance. [1,2] Therefore, AMMCs meet the rapidly growing demand of advanced lightweight materials in many industrial areas such as automotive, aerospace, marine, and military. Traditionally, AMMCs are produced by two processing routes: melt processing or powder metallurgy. Although such composites are already in use in the aerospace and automobile sectors, many challenges in both melt and powder metallurgy processing routes prevent their widespread applications. The main challenges associated with the melt processing route are heterogeneous distribution of reinforcement leading to aggregation (due to the poor wettability of reinforcement), detrimental reactions at the interface (due to the high temperature of melt and a long dwell time of reinforcement in the melt), and difficulty in subsequent machining (due to the presence of hard second-phase particles). On the contrary, powder metallurgy processed AMMCs are prone to high levels of porosity and inferior mechanical properties leading to premature failure of the components. [3][4][5][6][7] In this context, additive manufacturing (AM) methods such as laser-based powder bed fusion (PBF-L), electron beam-based

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Premature failure of an additively manufactured material

Cited by 90 publications

References 43 publications

Work Hardening of Heat-Treated AlSi10Mg Alloy Manufactured by Selective Laser Melting: Effects of Layer Thickness and Hatch Spacing

Work Hardening of Heat-Treated AlSi10Mg Alloy Manufactured by Selective Laser Melting: Effects of Layer Thickness and Hatch Spacing

Effect of Substrate Plate Heating on the Microstructure and Properties of Selective Laser Melted Al-20Si-5Fe-3Cu-1Mg Alloy

Additive Manufacturing of Aluminum‐Based Metal Matrix Composites—A Review

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