Effect of Post‐heat Treatment on the Tensile and Cryogenic Impact Toughness Properties of Inconel 718 Manufactured by Selective Laser Melting

Park, So‐Yeon; Kim, Kyu‐Sik; Kim, Min Cheol; Kassner, M.E.; Lee, Kee‐Ahn

doi:10.1002/adem.202001005

Cited by 13 publications

(3 citation statements)

References 38 publications

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“…SLM samples revealed half of the ductility value compared with ACR samples, as was also shown in [35]. A similar problem was observed in the determination of notch toughness at room temperature (see Figure 16).…”

supporting

confidence: 77%

“…However, the production of parts from Inconel 718 by additive manufacturing is very promising from the point of view of the very low machinability of the material. SLM samples revealed half of the ductility value compared with ACR samples, as was also shown in [35]. A similar problem was observed in the determination of notch toughness at room temperature (see Figure 16).…”

supporting

confidence: 77%

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Comparison of the Structure, Mechanical Properties and Effect of Heat Treatment on Alloy Inconel 718 Produced by Conventional Technology and by Additive Layer Manufacturing

Švec,

Solfronk,

Nováková

et al. 2023

Materials

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The nickel-iron-based alloy Inconel 718 is a progressive material with very good mechanical properties at elevated and lower temperatures. It is used both as wrought and cast alloys as well as material for additive manufacturing technologies. This is the reason why it has received so much attention, as supported by numerous publications. However, these are almost exclusively focused on a specific type of production and processing, and thus only report differences in the mechanical properties between samples prepared by different technologies. Therefore, the major aim of this research was to show how the structure and mechanical properties differ between samples produced by conventional production (wrought alloy) and additively manufactured SLM (Selective Laser Melting). It is shown that by applying appropriate heat treatment, similar strength properties at room and elevated temperatures can be achieved for SLM samples as for wrought samples. In addition, the mechanical properties are also tested up to a temperature of 900 °C, in contrast to the results published so far. Furthermore, it is proven that the microstructures of the wrought (here rolled) and SLM alloys differ significantly both in terms of grain shape and the size and distribution of precipitates.

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supporting

confidence: 77%

supporting

confidence: 77%

Comparison of the Structure, Mechanical Properties and Effect of Heat Treatment on Alloy Inconel 718 Produced by Conventional Technology and by Additive Layer Manufacturing

Švec,

Solfronk,

Nováková

et al. 2023

Materials

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“…Vertical samples (ZX) had the poorest fracture toughness, horizontal XZ samples the best Results were attributed to tensile stress-strain response XZ samples were also noted to contain lower porosity [130] AlSi10Mg K IC calculated from fatigue fracture surfaces for vertical, diagonal and horizontal samples were 12.8 MPa m 0.5 vs 13.1 MPa m 0.5 and 14.0 MPa m 0.5 , respectively LoF pores along melt-pool boundaries aided crack propagation in vertical samples [151] AlSi10Mg Horizontal Charpy samples contain more gas pores but performed better than vertical samples due to microstructural reasons-cracks go across rather than along melt-pool boundaries Pores enlarged during T6 caused toughness to decrease and horizontal samples now performed worse than vertical samples Attributed to pores causing cracks to deviate from their usual path and the reduced load-bearing section area HIP ? T6 mitigated the pore growth issue, but Si coarsening limited toughness improvements (i) coalescence of porosity during impact [149], (ii) altering of the crack propagation path from one based on microstructure toward one based on porosity distribution [150,151], (iii) increased stress-concentration effects [75], and (iv) a substantial reduction in the actual cross-sectional area occupied by material that is available to absorb impact energy [148]. Thus, when Wang et al surveyed existing literature on the impact toughness of LPBF 316L and found a wide scatter in the impact toughness, as shown in Fig.…”

Section: Ref Alloymentioning

confidence: 99%

A critical review on the effects of process-induced porosity on the mechanical properties of alloys fabricated by laser powder bed fusion

et al. 2022

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Laser powder bed fusion (LPBF) is an emerging additive manufacturing technique that is currently adopted by a number of industries for its ability to directly fabricate complex near-net-shaped components with minimal material wastage. Two major limitations of LPBF, however, are that the process inherently produces components containing some amount of porosity and that fabricated components tend to suffer from poor repeatability. While recent advances have allowed the porosity level to be reduced to a minimum, consistent porosity-free fabrication remains elusive. Therefore, it is important to understand how porosity affects mechanical properties in alloys fabricated this way in order to inform the safe design and application of components. To this aim, this article will review recent literature on the effects of porosity on tensile properties, fatigue life, impact and fracture toughness, creep response, and wear behavior. As the number of alloys that can be fabricated by this technology continues to grow, this overview will mainly focus on four alloys that are commonly fabricated by LPBF—Ti-6Al-4 V, Inconel 718, AISI 316L, and AlSi10Mg.

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A comprehensive literature review on laser powder bed fusion of Inconel superalloys

Volpato¹,

Tetzlaff²,

Fredel³

2022

Additive Manufacturing

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Effect of Post‐heat Treatment on the Tensile and Cryogenic Impact Toughness Properties of Inconel 718 Manufactured by Selective Laser Melting

Cited by 13 publications

References 38 publications

Comparison of the Structure, Mechanical Properties and Effect of Heat Treatment on Alloy Inconel 718 Produced by Conventional Technology and by Additive Layer Manufacturing

Comparison of the Structure, Mechanical Properties and Effect of Heat Treatment on Alloy Inconel 718 Produced by Conventional Technology and by Additive Layer Manufacturing

A critical review on the effects of process-induced porosity on the mechanical properties of alloys fabricated by laser powder bed fusion

A comprehensive literature review on laser powder bed fusion of Inconel superalloys

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