Choosing a Suitable Heat Treatment Regime for Stress-Relief and Microstructure Stabilization of Ti6Al4V Alloy 3D-printed by SLM Method

Michaela Roudnická; Eduardo Alarcon Tarquino; Dalibor Vojtech

doi:10.4028/www.scientific.net/DDF.403.11

Paper Titles

Properties of Borided Cemented Carbides with Various Binders
p.1

Choosing a Suitable Heat Treatment Regime for Stress-Relief and Microstructure Stabilization of Ti6Al4V Alloy 3D-printed by SLM Method
p.11

Formation of Microstructure during Sub-Zero Treatments of Chromium and Chromium-Vanadium Ledeburitic Steels
p.19

Sintering Problems during Preparation of Ti-Al-Si Alloys
p.37

Fe-Me-B Diffusion Layers for Surface Modification of Carbon Steels
p.47

Fe-Al-Si Alloys for Applications in Internal Combustion Engines
p.57

Heat Treatment of High-Strength 3D-Printed Maraging Steel
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Properties of Cryogenic Treated Cemented Carbides (WC-Co)
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Choosing a Suitable Heat Treatment Regime for Stress-Relief and Microstructure Stabilization of Ti6Al4V Alloy 3D-printed by SLM Method

Abstract:

During the processing of Ti6Al4V alloy by a 3D printing method SLM (selective laser melting), high internal stresses are developed in the material as a result of high temperature gradients between microvolumes of the powder melted at a given time and the already solidified material. Cooling rates thus reach up to the order of 10⁸ °C·s^-1. At such rates, a diffusionless martensitic transformation occurs, which also contributes to internal stresses in the material. High internal stresses can be a problem already during production; they can manifest themselves by cracking of products, deformations of thin parts, etc. Even in defectless products, internal stresses negatively affect their properties; in particular, they reduce ductility. Therefore, it is desirable to include a heat treatment after the 3D printing, which would reduce the stresses and transform the metastable martensitic structure into a stable one. As a result of the heat treatment, the ductility increases at the expense of strength. The subject of this paper is to find such heat treatment regime that provides the best combination of mechanical properties.

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Periodical:

Defect and Diffusion Forum (Volume 403)

Pages:

11-18

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https://doi.org/10.4028/www.scientific.net/DDF.403.11

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Online since:

September 2020

Authors:

Michaela Roudnická*, Eduardo Alarcon Tarquino, Dalibor Vojtech

Keywords:

3D Printing, Heat Treatment, SLM, Ti6Al4V

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