Efficient Build-Up of High-Strength Aluminum Structures Using Friction Stir Additive Manufacturing

Martina E. Sigl; Paula Danninger; Christian Bernauer; Roman Hartl; Michael F. Zaeh

doi:10.4028/p-6p7o75

Efficient Build-Up of High-Strength Aluminum Structures Using Friction Stir Additive Manufacturing

Martina E. Sigl, Paula Danninger, Christian Bernauer, Roman Hartl, Michael F. Zaeh

Lehrstuhl für Werkzeugmaschinen und Fertigungstechnik

Technische Universität München

Publikation: Beitrag in Buch/Bericht/Konferenzband › Konferenzbeitrag › Begutachtung

4 Zitate (Scopus)

Abstract

Friction Stir Additive Manufacturing (FSAM) is a novel process with which large-scale aluminum structures can be produced from high-strength alloys such as the 7xxx series. Due to the prevalence of these alloys in airplanes and rockets, the process offers high application potential, for example in fabricating stringers and stiffeners. The building process in FSAM is characterized by sequentially stacking and friction stir lap welding (FSLW) metal sheets. Before adding the next layer, the surface is machined (i.e., by milling). So far, this is a necessary step to enable gap-free welding of the layers, which results in increased costs and reduced layer heights. The investigations described in this paper were aimed at improving the weld surface quality to enable defect-free FSAM without the additional machining step. For this, FSLW was conducted using different welding tools. The resulting welds were evaluated based on superficial and internal characteristics as well as the mechanical properties (shear strength). With a welding tool in which both a rotating and a stationary shoulder were combined, defect-free weld seams with a mean underfill and a mean flash height of 0.07 mm were produced. In a subsequent study, it was proven that defect-free FSAM without surface machining is possible up to the fifth layer using the combined welding tool.

Originalsprache	Englisch
Titel	Achievements and Trends in Material Forming- Peer-reviewed extended papers selected from the 25th International Conference on Material Forming, ESAFORM 2022
Redakteure/-innen	Gabriela Vincze, Frédéric Barlat
Herausgeber (Verlag)	Trans Tech Publications Ltd
Seiten	176-186
Seitenumfang	11
ISBN (Print)	9783035717594
DOIs	https://doi.org/10.4028/p-6p7o75
Publikationsstatus	Veröffentlicht - 2022
Veranstaltung	25th International Conference on Material Forming, ESAFORM 2022 - Braga, Portugal Dauer: 27 Apr. 2022 → 29 Apr. 2022

Publikationsreihe

Name	Key Engineering Materials
Band	926 KEM
ISSN (Print)	1013-9826
ISSN (elektronisch)	1662-9795

Konferenz

Konferenz	25th International Conference on Material Forming, ESAFORM 2022
Land/Gebiet	Portugal
Ort	Braga
Zeitraum	27/04/22 → 29/04/22

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10.4028/p-6p7o75

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Sigl, M. E., Danninger, P., Bernauer, C., Hartl, R., & Zaeh, M. F. (2022). Efficient Build-Up of High-Strength Aluminum Structures Using Friction Stir Additive Manufacturing. in G. Vincze, & F. Barlat (Hrsg.), Achievements and Trends in Material Forming- Peer-reviewed extended papers selected from the 25th International Conference on Material Forming, ESAFORM 2022 (S. 176-186). (Key Engineering Materials; Band 926 KEM). Trans Tech Publications Ltd. https://doi.org/10.4028/p-6p7o75

Sigl, Martina E. ; Danninger, Paula ; Bernauer, Christian et al. / Efficient Build-Up of High-Strength Aluminum Structures Using Friction Stir Additive Manufacturing. Achievements and Trends in Material Forming- Peer-reviewed extended papers selected from the 25th International Conference on Material Forming, ESAFORM 2022. Hrsg. / Gabriela Vincze ; Frédéric Barlat. Trans Tech Publications Ltd, 2022. S. 176-186 (Key Engineering Materials).

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abstract = "Friction Stir Additive Manufacturing (FSAM) is a novel process with which large-scale aluminum structures can be produced from high-strength alloys such as the 7xxx series. Due to the prevalence of these alloys in airplanes and rockets, the process offers high application potential, for example in fabricating stringers and stiffeners. The building process in FSAM is characterized by sequentially stacking and friction stir lap welding (FSLW) metal sheets. Before adding the next layer, the surface is machined (i.e., by milling). So far, this is a necessary step to enable gap-free welding of the layers, which results in increased costs and reduced layer heights. The investigations described in this paper were aimed at improving the weld surface quality to enable defect-free FSAM without the additional machining step. For this, FSLW was conducted using different welding tools. The resulting welds were evaluated based on superficial and internal characteristics as well as the mechanical properties (shear strength). With a welding tool in which both a rotating and a stationary shoulder were combined, defect-free weld seams with a mean underfill and a mean flash height of 0.07 mm were produced. In a subsequent study, it was proven that defect-free FSAM without surface machining is possible up to the fifth layer using the combined welding tool.",

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author = "Sigl, {Martina E.} and Paula Danninger and Christian Bernauer and Roman Hartl and Zaeh, {Michael F.}",

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Sigl, ME, Danninger, P, Bernauer, C, Hartl, R & Zaeh, MF 2022, Efficient Build-Up of High-Strength Aluminum Structures Using Friction Stir Additive Manufacturing. in G Vincze & F Barlat (Hrsg.), Achievements and Trends in Material Forming- Peer-reviewed extended papers selected from the 25th International Conference on Material Forming, ESAFORM 2022. Key Engineering Materials, Bd. 926 KEM, Trans Tech Publications Ltd, S. 176-186, 25th International Conference on Material Forming, ESAFORM 2022, Braga, Portugal, 27/04/22. https://doi.org/10.4028/p-6p7o75

Efficient Build-Up of High-Strength Aluminum Structures Using Friction Stir Additive Manufacturing. / Sigl, Martina E.; Danninger, Paula; Bernauer, Christian et al.
Achievements and Trends in Material Forming- Peer-reviewed extended papers selected from the 25th International Conference on Material Forming, ESAFORM 2022. Hrsg. / Gabriela Vincze; Frédéric Barlat. Trans Tech Publications Ltd, 2022. S. 176-186 (Key Engineering Materials; Band 926 KEM).

Publikation: Beitrag in Buch/Bericht/Konferenzband › Konferenzbeitrag › Begutachtung

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T1 - Efficient Build-Up of High-Strength Aluminum Structures Using Friction Stir Additive Manufacturing

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AU - Danninger, Paula

AU - Bernauer, Christian

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AU - Zaeh, Michael F.

PY - 2022

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N2 - Friction Stir Additive Manufacturing (FSAM) is a novel process with which large-scale aluminum structures can be produced from high-strength alloys such as the 7xxx series. Due to the prevalence of these alloys in airplanes and rockets, the process offers high application potential, for example in fabricating stringers and stiffeners. The building process in FSAM is characterized by sequentially stacking and friction stir lap welding (FSLW) metal sheets. Before adding the next layer, the surface is machined (i.e., by milling). So far, this is a necessary step to enable gap-free welding of the layers, which results in increased costs and reduced layer heights. The investigations described in this paper were aimed at improving the weld surface quality to enable defect-free FSAM without the additional machining step. For this, FSLW was conducted using different welding tools. The resulting welds were evaluated based on superficial and internal characteristics as well as the mechanical properties (shear strength). With a welding tool in which both a rotating and a stationary shoulder were combined, defect-free weld seams with a mean underfill and a mean flash height of 0.07 mm were produced. In a subsequent study, it was proven that defect-free FSAM without surface machining is possible up to the fifth layer using the combined welding tool.

AB - Friction Stir Additive Manufacturing (FSAM) is a novel process with which large-scale aluminum structures can be produced from high-strength alloys such as the 7xxx series. Due to the prevalence of these alloys in airplanes and rockets, the process offers high application potential, for example in fabricating stringers and stiffeners. The building process in FSAM is characterized by sequentially stacking and friction stir lap welding (FSLW) metal sheets. Before adding the next layer, the surface is machined (i.e., by milling). So far, this is a necessary step to enable gap-free welding of the layers, which results in increased costs and reduced layer heights. The investigations described in this paper were aimed at improving the weld surface quality to enable defect-free FSAM without the additional machining step. For this, FSLW was conducted using different welding tools. The resulting welds were evaluated based on superficial and internal characteristics as well as the mechanical properties (shear strength). With a welding tool in which both a rotating and a stationary shoulder were combined, defect-free weld seams with a mean underfill and a mean flash height of 0.07 mm were produced. In a subsequent study, it was proven that defect-free FSAM without surface machining is possible up to the fifth layer using the combined welding tool.

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KW - temperature control

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Sigl ME, Danninger P, Bernauer C, Hartl R, Zaeh MF. Efficient Build-Up of High-Strength Aluminum Structures Using Friction Stir Additive Manufacturing. in Vincze G, Barlat F, Hrsg., Achievements and Trends in Material Forming- Peer-reviewed extended papers selected from the 25th International Conference on Material Forming, ESAFORM 2022. Trans Tech Publications Ltd. 2022. S. 176-186. (Key Engineering Materials). doi: 10.4028/p-6p7o75

Efficient Build-Up of High-Strength Aluminum Structures Using Friction Stir Additive Manufacturing

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