Heat Treatments and Critical Quenching Rates in Additively Manufactured Al–Si–Mg Alloys

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Heat Treatments and Critical Quenching Rates in Additively Manufactured Al–Si–Mg Alloys. / Hitzler, Leonhard; Hafenstein, Stephan; Mendez Martin, Francisca et al.
in: Materials, Jahrgang 13.2020, Nr. 3, 720, 05.02.2020.

Publikationen: Beitrag in FachzeitschriftArtikelForschung(peer-reviewed)

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APA

Hitzler, L., Hafenstein, S., Mendez Martin, F., Clemens, H., Sert, E., Öchsner, A., Merkel, M., & Werner, E. (2020). Heat Treatments and Critical Quenching Rates in Additively Manufactured Al–Si–Mg Alloys. Materials, 13.2020(3), Artikel 720. Vorzeitige Online-Publikation. https://doi.org/10.3390/ma13030720

Vancouver

Hitzler L, Hafenstein S, Mendez Martin F, Clemens H, Sert E, Öchsner A et al. Heat Treatments and Critical Quenching Rates in Additively Manufactured Al–Si–Mg Alloys. Materials. 2020 Feb 5;13.2020(3):720. Epub 2020 Feb 5. doi: 10.3390/ma13030720

Author

Hitzler, Leonhard ; Hafenstein, Stephan ; Mendez Martin, Francisca et al. / Heat Treatments and Critical Quenching Rates in Additively Manufactured Al–Si–Mg Alloys. in: Materials. 2020 ; Jahrgang 13.2020, Nr. 3.

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@article{bdb7a19b32c341eaaf43d23138d83e48,
title = "Heat Treatments and Critical Quenching Rates in Additively Manufactured Al–Si–Mg Alloys",
abstract = "Laser powder-bed fusion (LPBF) has significantly gained in importance and has become one of the major fabrication techniques within metal additive manufacturing. The fast cooling rates achieved in LPBF due to a relatively small melt pool on a much larger component or substrate, acting as heat sink, result in fine-grained microstructures and high oversaturation of alloying elements in the ff-aluminum. Al-Si-Mg alloys thus can be effectively precipitation hardened. Moreover, the solidified material undergoes an intrinsic heat treatment, whilst the layers above are irradiated and the elevated temperature in the built chamber starts the clustering process of alloying elements directly after a scan track is fabricated. These silicon-magnesium clusters were observed with atom probe tomography in as-built samples. Similar beneficial clustering behavior at higher temperatures is known from the direct-aging approach in cast samples, whereby the artificial aging is performed immediately after solution annealing and quenching. Transferring this approach to LPBF samples as a possible post-heat treatment revealed that even after direct aging, the outstanding hardness of the as-built condition could, at best, be met, but for most instances it was significantly lower. Our investigations showed that LPBF Al-Si-Mg exhibited a high dependency on the quenching rate, which is significantly more pronounced than in cast reference samples, requiring two to three times higher quenching rate after solution annealing to yield similar hardness results. This suggests that due to the finer microstructure and the shorter diffusion path in Al-Si-Mg fabricated by LPBF, it is more challenging to achieve a metastable oversaturation necessary for precipitation hardening. This may be especially problematic in larger components.",
author = "Leonhard Hitzler and Stephan Hafenstein and {Mendez Martin}, Francisca and Helmut Clemens and Enes Sert and Andreas {\"O}chsner and Markus Merkel and Ewald Werner",
note = "Publisher Copyright: {\textcopyright} 2020 by the authors.",
year = "2020",
month = feb,
day = "5",
doi = "10.3390/ma13030720",
language = "English",
volume = "13.2020",
journal = "Materials",
issn = "1996-1944",
publisher = "Multidisciplinary Digital Publishing Institute (MDPI)",
number = "3",

}

RIS (suitable for import to EndNote) - Download

TY - JOUR

T1 - Heat Treatments and Critical Quenching Rates in Additively Manufactured Al–Si–Mg Alloys

AU - Hitzler, Leonhard

AU - Hafenstein, Stephan

AU - Mendez Martin, Francisca

AU - Clemens, Helmut

AU - Sert, Enes

AU - Öchsner, Andreas

AU - Merkel, Markus

AU - Werner, Ewald

N1 - Publisher Copyright: © 2020 by the authors.

PY - 2020/2/5

Y1 - 2020/2/5

N2 - Laser powder-bed fusion (LPBF) has significantly gained in importance and has become one of the major fabrication techniques within metal additive manufacturing. The fast cooling rates achieved in LPBF due to a relatively small melt pool on a much larger component or substrate, acting as heat sink, result in fine-grained microstructures and high oversaturation of alloying elements in the ff-aluminum. Al-Si-Mg alloys thus can be effectively precipitation hardened. Moreover, the solidified material undergoes an intrinsic heat treatment, whilst the layers above are irradiated and the elevated temperature in the built chamber starts the clustering process of alloying elements directly after a scan track is fabricated. These silicon-magnesium clusters were observed with atom probe tomography in as-built samples. Similar beneficial clustering behavior at higher temperatures is known from the direct-aging approach in cast samples, whereby the artificial aging is performed immediately after solution annealing and quenching. Transferring this approach to LPBF samples as a possible post-heat treatment revealed that even after direct aging, the outstanding hardness of the as-built condition could, at best, be met, but for most instances it was significantly lower. Our investigations showed that LPBF Al-Si-Mg exhibited a high dependency on the quenching rate, which is significantly more pronounced than in cast reference samples, requiring two to three times higher quenching rate after solution annealing to yield similar hardness results. This suggests that due to the finer microstructure and the shorter diffusion path in Al-Si-Mg fabricated by LPBF, it is more challenging to achieve a metastable oversaturation necessary for precipitation hardening. This may be especially problematic in larger components.

AB - Laser powder-bed fusion (LPBF) has significantly gained in importance and has become one of the major fabrication techniques within metal additive manufacturing. The fast cooling rates achieved in LPBF due to a relatively small melt pool on a much larger component or substrate, acting as heat sink, result in fine-grained microstructures and high oversaturation of alloying elements in the ff-aluminum. Al-Si-Mg alloys thus can be effectively precipitation hardened. Moreover, the solidified material undergoes an intrinsic heat treatment, whilst the layers above are irradiated and the elevated temperature in the built chamber starts the clustering process of alloying elements directly after a scan track is fabricated. These silicon-magnesium clusters were observed with atom probe tomography in as-built samples. Similar beneficial clustering behavior at higher temperatures is known from the direct-aging approach in cast samples, whereby the artificial aging is performed immediately after solution annealing and quenching. Transferring this approach to LPBF samples as a possible post-heat treatment revealed that even after direct aging, the outstanding hardness of the as-built condition could, at best, be met, but for most instances it was significantly lower. Our investigations showed that LPBF Al-Si-Mg exhibited a high dependency on the quenching rate, which is significantly more pronounced than in cast reference samples, requiring two to three times higher quenching rate after solution annealing to yield similar hardness results. This suggests that due to the finer microstructure and the shorter diffusion path in Al-Si-Mg fabricated by LPBF, it is more challenging to achieve a metastable oversaturation necessary for precipitation hardening. This may be especially problematic in larger components.

UR - http://www.scopus.com/inward/record.url?scp=85079625909&partnerID=8YFLogxK

U2 - 10.3390/ma13030720

DO - 10.3390/ma13030720

M3 - Article

VL - 13.2020

JO - Materials

JF - Materials

SN - 1996-1944

IS - 3

M1 - 720

ER -