Optimization of the post-process heat treatment strategy for a Near-α Titanium base alloy produced by laser powder bed fusion

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Optimization of the post-process heat treatment strategy for a Near-α Titanium base alloy produced by laser powder bed fusion. / Fleißner-Rieger, Christian; Pfeifer, Tanja; Turk, Christoph et al.
In: Materials, Vol. 15.2022, No. 3, 1032, 28.01.2022, p. 1-14.

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@article{d712f8ae0174489a87131b8aa3228ba0,
title = "Optimization of the post-process heat treatment strategy for a Near-α Titanium base alloy produced by laser powder bed fusion",
abstract = "During the last decades, titanium alloys have been of great interest for lightweight applications due to their high strength in combination with a low material density. Current research activities focus on the investigation of near-α titanium alloys produced by laser powder bed fusion (LPBF). These alloys are known for their superior tensile strength and high creep resistance. This study focuses on the optimization of post-process heat treatments and the impact on tensile and creep strength of a LPBF produced Ti6242S alloy. Therefore, a variety of annealing steps were conducted to gain knowledge about the decomposition process of the non-equilibrium as-built microstructure and the arising influence on the mechanical properties. Components made of Ti6242S and produced by LPBF reveal an extraordinarily high ultimate tensile strength of about 1530 MPa at room temperature, but show a low elongation at fracture (A5 = 4.3%). Based on microstructure-property relationships, this study recommends precise heat treatments on how to improve the desired mechanical properties in terms of strength, ductility as well as creep resistance. Moreover, this study shows a triplex heat treatment, which enhances the elongation at fracture (A5) to 16.5%, while the ultimate tensile strength is still at 1100 MPa.",
author = "Christian Flei{\ss}ner-Rieger and Tanja Pfeifer and Christoph Turk and Helmut Clemens",
year = "2022",
month = jan,
day = "28",
doi = "10.3390/ma15031032",
language = "English",
volume = "15.2022",
pages = "1--14",
journal = "Materials",
issn = "1996-1944",
publisher = "Multidisciplinary Digital Publishing Institute (MDPI)",
number = "3",

}

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TY - JOUR

T1 - Optimization of the post-process heat treatment strategy for a Near-α Titanium base alloy produced by laser powder bed fusion

AU - Fleißner-Rieger, Christian

AU - Pfeifer, Tanja

AU - Turk, Christoph

AU - Clemens, Helmut

PY - 2022/1/28

Y1 - 2022/1/28

N2 - During the last decades, titanium alloys have been of great interest for lightweight applications due to their high strength in combination with a low material density. Current research activities focus on the investigation of near-α titanium alloys produced by laser powder bed fusion (LPBF). These alloys are known for their superior tensile strength and high creep resistance. This study focuses on the optimization of post-process heat treatments and the impact on tensile and creep strength of a LPBF produced Ti6242S alloy. Therefore, a variety of annealing steps were conducted to gain knowledge about the decomposition process of the non-equilibrium as-built microstructure and the arising influence on the mechanical properties. Components made of Ti6242S and produced by LPBF reveal an extraordinarily high ultimate tensile strength of about 1530 MPa at room temperature, but show a low elongation at fracture (A5 = 4.3%). Based on microstructure-property relationships, this study recommends precise heat treatments on how to improve the desired mechanical properties in terms of strength, ductility as well as creep resistance. Moreover, this study shows a triplex heat treatment, which enhances the elongation at fracture (A5) to 16.5%, while the ultimate tensile strength is still at 1100 MPa.

AB - During the last decades, titanium alloys have been of great interest for lightweight applications due to their high strength in combination with a low material density. Current research activities focus on the investigation of near-α titanium alloys produced by laser powder bed fusion (LPBF). These alloys are known for their superior tensile strength and high creep resistance. This study focuses on the optimization of post-process heat treatments and the impact on tensile and creep strength of a LPBF produced Ti6242S alloy. Therefore, a variety of annealing steps were conducted to gain knowledge about the decomposition process of the non-equilibrium as-built microstructure and the arising influence on the mechanical properties. Components made of Ti6242S and produced by LPBF reveal an extraordinarily high ultimate tensile strength of about 1530 MPa at room temperature, but show a low elongation at fracture (A5 = 4.3%). Based on microstructure-property relationships, this study recommends precise heat treatments on how to improve the desired mechanical properties in terms of strength, ductility as well as creep resistance. Moreover, this study shows a triplex heat treatment, which enhances the elongation at fracture (A5) to 16.5%, while the ultimate tensile strength is still at 1100 MPa.

U2 - 10.3390/ma15031032

DO - 10.3390/ma15031032

M3 - Article

VL - 15.2022

SP - 1

EP - 14

JO - Materials

JF - Materials

SN - 1996-1944

IS - 3

M1 - 1032

ER -