PBF-LB of large-area magnesium WE43 structures surface-enhanced by plasma electrolytic oxidation

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Autoren

  • Arvid Abel
  • Anutsek Sharma
  • Hannes Holländer
  • Dawn Zheng
  • Nicole Emminghaus
  • Anna Buling
  • Jörg Hermsdorf
  • Jörg Zerrer
  • Stefan Kaierle

Organisationseinheiten

Externe Organisationen

  • Laser Zentrum Hannover e.V. (LZH)
  • Eloxalwerk Ludwigsburg Helmut Zerrer GmbH (ELB)
Forschungs-netzwerk anzeigen

Details

OriginalspracheEnglisch
Seiten (von - bis)683-694
Seitenumfang12
FachzeitschriftProgress in Additive Manufacturing
Jahrgang9
Ausgabenummer3
Frühes Online-Datum24 Mai 2024
PublikationsstatusVeröffentlicht - Juni 2024

Abstract

Due to the improved understanding of the industry, additive manufacturing processes are becoming increasingly accepted for fabricating complex lightweight components. The focus of the magnesium research is primarily on small implant structures. Due to challenges in the manufacturing process and oxidation behavior, large structures for lightweight components are mainly fabricated with titanium. This paper expands the scope of the laser-based powder bed fusion (PBF-LB) of larger-area magnesium parts with surface enhancement using the Ultraceramic® by the plasma electrolytic oxidation (PEO). For this purpose, the PBF-LB process development for cylindric structures with a diameter of 31 mm is carried out. The processing strategies are adapted for a crack and porosity free process. To mitigate the inherent oxidation of the biodegradable WE43 and reduce the surface wear in tribologically challenging applications, the additively manufactured magnesium is modified by the Ultraceramic®. The thickness of the ceramic surface could be tailored between 10 and 40 µm, while enclosing adhering powder particles of the PBF. Electrochemical impedance spectroscopy showed an increased resistance to corrosion by an increased modulus |Z0.01| by a factor of 658. The tribological behavior was characterized in pin-on-disc experiments and showed a decrease of surface wear down to 7.9 × 10–6 mm3/N·m up to a Hertzian pressure of 720 MPa tested by a tungsten carbide ball. Therefore, the synthesis of the PBF-LB of large-area magnesium parts and the PEO of the Ultraceramic® enables lightweight components for challenging oxidative and tribological conditions in real world applications.

ASJC Scopus Sachgebiete

Zitieren

PBF-LB of large-area magnesium WE43 structures surface-enhanced by plasma electrolytic oxidation. / Abel, Arvid; Sharma, Anutsek; Holländer, Hannes et al.
in: Progress in Additive Manufacturing, Jahrgang 9, Nr. 3, 06.2024, S. 683-694.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Abel, A, Sharma, A, Holländer, H, Zheng, D, Emminghaus, N, Buling, A, Hermsdorf, J, Zerrer, J & Kaierle, S 2024, 'PBF-LB of large-area magnesium WE43 structures surface-enhanced by plasma electrolytic oxidation', Progress in Additive Manufacturing, Jg. 9, Nr. 3, S. 683-694. https://doi.org/10.1007/s40964-024-00664-3
Abel, A., Sharma, A., Holländer, H., Zheng, D., Emminghaus, N., Buling, A., Hermsdorf, J., Zerrer, J., & Kaierle, S. (2024). PBF-LB of large-area magnesium WE43 structures surface-enhanced by plasma electrolytic oxidation. Progress in Additive Manufacturing, 9(3), 683-694. https://doi.org/10.1007/s40964-024-00664-3
Abel A, Sharma A, Holländer H, Zheng D, Emminghaus N, Buling A et al. PBF-LB of large-area magnesium WE43 structures surface-enhanced by plasma electrolytic oxidation. Progress in Additive Manufacturing. 2024 Jun;9(3):683-694. Epub 2024 Mai 24. doi: 10.1007/s40964-024-00664-3
Abel, Arvid ; Sharma, Anutsek ; Holländer, Hannes et al. / PBF-LB of large-area magnesium WE43 structures surface-enhanced by plasma electrolytic oxidation. in: Progress in Additive Manufacturing. 2024 ; Jahrgang 9, Nr. 3. S. 683-694.
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abstract = "Due to the improved understanding of the industry, additive manufacturing processes are becoming increasingly accepted for fabricating complex lightweight components. The focus of the magnesium research is primarily on small implant structures. Due to challenges in the manufacturing process and oxidation behavior, large structures for lightweight components are mainly fabricated with titanium. This paper expands the scope of the laser-based powder bed fusion (PBF-LB) of larger-area magnesium parts with surface enhancement using the Ultraceramic{\textregistered} by the plasma electrolytic oxidation (PEO). For this purpose, the PBF-LB process development for cylindric structures with a diameter of 31 mm is carried out. The processing strategies are adapted for a crack and porosity free process. To mitigate the inherent oxidation of the biodegradable WE43 and reduce the surface wear in tribologically challenging applications, the additively manufactured magnesium is modified by the Ultraceramic{\textregistered}. The thickness of the ceramic surface could be tailored between 10 and 40 µm, while enclosing adhering powder particles of the PBF. Electrochemical impedance spectroscopy showed an increased resistance to corrosion by an increased modulus |Z0.01| by a factor of 658. The tribological behavior was characterized in pin-on-disc experiments and showed a decrease of surface wear down to 7.9 × 10–6 mm3/N·m up to a Hertzian pressure of 720 MPa tested by a tungsten carbide ball. Therefore, the synthesis of the PBF-LB of large-area magnesium parts and the PEO of the Ultraceramic{\textregistered} enables lightweight components for challenging oxidative and tribological conditions in real world applications.",
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T1 - PBF-LB of large-area magnesium WE43 structures surface-enhanced by plasma electrolytic oxidation

AU - Abel, Arvid

AU - Sharma, Anutsek

AU - Holländer, Hannes

AU - Zheng, Dawn

AU - Emminghaus, Nicole

AU - Buling, Anna

AU - Hermsdorf, Jörg

AU - Zerrer, Jörg

AU - Kaierle, Stefan

N1 - Publisher Copyright: © The Author(s) 2024.

PY - 2024/6

Y1 - 2024/6

N2 - Due to the improved understanding of the industry, additive manufacturing processes are becoming increasingly accepted for fabricating complex lightweight components. The focus of the magnesium research is primarily on small implant structures. Due to challenges in the manufacturing process and oxidation behavior, large structures for lightweight components are mainly fabricated with titanium. This paper expands the scope of the laser-based powder bed fusion (PBF-LB) of larger-area magnesium parts with surface enhancement using the Ultraceramic® by the plasma electrolytic oxidation (PEO). For this purpose, the PBF-LB process development for cylindric structures with a diameter of 31 mm is carried out. The processing strategies are adapted for a crack and porosity free process. To mitigate the inherent oxidation of the biodegradable WE43 and reduce the surface wear in tribologically challenging applications, the additively manufactured magnesium is modified by the Ultraceramic®. The thickness of the ceramic surface could be tailored between 10 and 40 µm, while enclosing adhering powder particles of the PBF. Electrochemical impedance spectroscopy showed an increased resistance to corrosion by an increased modulus |Z0.01| by a factor of 658. The tribological behavior was characterized in pin-on-disc experiments and showed a decrease of surface wear down to 7.9 × 10–6 mm3/N·m up to a Hertzian pressure of 720 MPa tested by a tungsten carbide ball. Therefore, the synthesis of the PBF-LB of large-area magnesium parts and the PEO of the Ultraceramic® enables lightweight components for challenging oxidative and tribological conditions in real world applications.

AB - Due to the improved understanding of the industry, additive manufacturing processes are becoming increasingly accepted for fabricating complex lightweight components. The focus of the magnesium research is primarily on small implant structures. Due to challenges in the manufacturing process and oxidation behavior, large structures for lightweight components are mainly fabricated with titanium. This paper expands the scope of the laser-based powder bed fusion (PBF-LB) of larger-area magnesium parts with surface enhancement using the Ultraceramic® by the plasma electrolytic oxidation (PEO). For this purpose, the PBF-LB process development for cylindric structures with a diameter of 31 mm is carried out. The processing strategies are adapted for a crack and porosity free process. To mitigate the inherent oxidation of the biodegradable WE43 and reduce the surface wear in tribologically challenging applications, the additively manufactured magnesium is modified by the Ultraceramic®. The thickness of the ceramic surface could be tailored between 10 and 40 µm, while enclosing adhering powder particles of the PBF. Electrochemical impedance spectroscopy showed an increased resistance to corrosion by an increased modulus |Z0.01| by a factor of 658. The tribological behavior was characterized in pin-on-disc experiments and showed a decrease of surface wear down to 7.9 × 10–6 mm3/N·m up to a Hertzian pressure of 720 MPa tested by a tungsten carbide ball. Therefore, the synthesis of the PBF-LB of large-area magnesium parts and the PEO of the Ultraceramic® enables lightweight components for challenging oxidative and tribological conditions in real world applications.

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KW - Magnesium

KW - Plasma electrolytic oxidation

KW - Ultraceramic

KW - WE43

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VL - 9

SP - 683

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JO - Progress in Additive Manufacturing

JF - Progress in Additive Manufacturing

SN - 2363-9512

IS - 3

ER -