Manufacturing of titanium components with 3DPMD

Kevin Hoefer; Alexander Nitsche; André Haelsig; Peter Mayr

doi:10.3390/met9050562

Manufacturing of titanium components with 3DPMD

Kevin Hoefer
, Alexander Nitsche
, André Haelsig
, Peter Mayr

Chemnitz University of Technology

Research output: Contribution to journal › Article › peer-review

10 Scopus citations

Abstract

Within this work, the 3D plasma metal deposition (3DPMD) process is introduced as an additive manufacturing process for titanium components. For this purpose, demonstrators were designed, manufactured and subsequently analyzed. Process-structure-property relationships are discussed. By analyzing the microstructure, the chemical composition and the mechanical-technological properties, it is shown that the production of titanium parts with 3DPMD is possible. The micro tensile tests showed that a load parallel to the build direction is the most critical case for the component. Furthermore, a brittle material behavior could be determined due to enhanced oxygen content in the component. By subsequent heat treatment, the brittle failure behavior could be increased to a fracture elongation of 4.6%. In sum, the 3DPMD process has the potential to manufacture near-net-shape titanium parts out of metal powders. Critical issues are the protection of the weldment and the lack of ductility of the titanium component.

Original language	English
Article number	562
Journal	Metals
Volume	9
Issue number	5
DOIs	https://doi.org/10.3390/met9050562
State	Published - May 2019
Externally published	Yes

Keywords

3DPMD
Additive manufacturing
Plasma transferred arc
Powder deposition
Titanium

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10.3390/met9050562

Cite this

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title = "Manufacturing of titanium components with 3DPMD",

abstract = "Within this work, the 3D plasma metal deposition (3DPMD) process is introduced as an additive manufacturing process for titanium components. For this purpose, demonstrators were designed, manufactured and subsequently analyzed. Process-structure-property relationships are discussed. By analyzing the microstructure, the chemical composition and the mechanical-technological properties, it is shown that the production of titanium parts with 3DPMD is possible. The micro tensile tests showed that a load parallel to the build direction is the most critical case for the component. Furthermore, a brittle material behavior could be determined due to enhanced oxygen content in the component. By subsequent heat treatment, the brittle failure behavior could be increased to a fracture elongation of 4.6\%. In sum, the 3DPMD process has the potential to manufacture near-net-shape titanium parts out of metal powders. Critical issues are the protection of the weldment and the lack of ductility of the titanium component.",

keywords = "3DPMD, Additive manufacturing, Plasma transferred arc, Powder deposition, Titanium",

author = "Kevin Hoefer and Alexander Nitsche and Andr{\'e} Haelsig and Peter Mayr",

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year = "2019",

month = may,

doi = "10.3390/met9050562",

language = "English",

volume = "9",

journal = "Metals",

issn = "2075-4701",

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TY - JOUR

T1 - Manufacturing of titanium components with 3DPMD

AU - Hoefer, Kevin

AU - Nitsche, Alexander

AU - Haelsig, André

AU - Mayr, Peter

PY - 2019/5

Y1 - 2019/5

N2 - Within this work, the 3D plasma metal deposition (3DPMD) process is introduced as an additive manufacturing process for titanium components. For this purpose, demonstrators were designed, manufactured and subsequently analyzed. Process-structure-property relationships are discussed. By analyzing the microstructure, the chemical composition and the mechanical-technological properties, it is shown that the production of titanium parts with 3DPMD is possible. The micro tensile tests showed that a load parallel to the build direction is the most critical case for the component. Furthermore, a brittle material behavior could be determined due to enhanced oxygen content in the component. By subsequent heat treatment, the brittle failure behavior could be increased to a fracture elongation of 4.6%. In sum, the 3DPMD process has the potential to manufacture near-net-shape titanium parts out of metal powders. Critical issues are the protection of the weldment and the lack of ductility of the titanium component.

AB - Within this work, the 3D plasma metal deposition (3DPMD) process is introduced as an additive manufacturing process for titanium components. For this purpose, demonstrators were designed, manufactured and subsequently analyzed. Process-structure-property relationships are discussed. By analyzing the microstructure, the chemical composition and the mechanical-technological properties, it is shown that the production of titanium parts with 3DPMD is possible. The micro tensile tests showed that a load parallel to the build direction is the most critical case for the component. Furthermore, a brittle material behavior could be determined due to enhanced oxygen content in the component. By subsequent heat treatment, the brittle failure behavior could be increased to a fracture elongation of 4.6%. In sum, the 3DPMD process has the potential to manufacture near-net-shape titanium parts out of metal powders. Critical issues are the protection of the weldment and the lack of ductility of the titanium component.

KW - 3DPMD

KW - Additive manufacturing

KW - Plasma transferred arc

KW - Powder deposition

KW - Titanium

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DO - 10.3390/met9050562

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SN - 2075-4701

VL - 9

JO - Metals

JF - Metals

IS - 5

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ER -

Manufacturing of titanium components with 3DPMD

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Keywords

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