Blown-powder direct-energy-deposition of titanium-diboride-strengthened IN718 Ni-base superalloy
Blown-powder direct-energy-deposition of titanium-diboride-strengthened IN718 Ni-base superalloy
This paper reports on the adoption of TiB2 as an inoculant to fabricate IN718 via the direct energy deposition (DED) process. Effective grain refinement and low texture were achieved in IN718/TiB2 using a TiB2 powder size of d90 = 10 μm and mass fraction of 1.5 wt%. The use of low linear energy density (33.08 J/mm) produced IN718/TiB2 deposits free from large grains (>300 μm), however at the cost of the formation of interlayer defects. By comparison, the large grains were present in deposits made with a linear energy density of 78.74 J/mm and also in deposits manufactured without an included inoculant. Production of deposits at lower energies without interlayer defects was possible by reducing the powder flow rate to 7 g/min. However, this caused a moderate increase in grain size. The TiB2 inoculant reduced the Laves phase network by replacing it with homogeneously distributed Cr-, Mo-, Nb-, and B-enriched needle-shaped precipitates. Tensile strength increased by 300–500 MPa with TiB2 addition, but at the cost of significant ductility drop, regardless of the deposition conditions. The IN718 deposit displayed many micro-cracks at the network of Laves phase during tensile loading, whereas micro-cracks in the IN718/TiB2 occurred at the interface between the needle-shaped precipitates and the matrix. The strength enhancement in IN718/TiB2 was by a combination of strengthening mechanisms: grain boundary, dislocation structure formation, Orowan-type and load transfer related to the needle-shaped precipitates.
Sarkar, Riddhi
97df7410-6878-4c93-9f0c-d9abc49eceb3
Chen, Bo
be54a9a8-da2a-4e6f-ae0e-0b076be87daf
Fitzpatrick, Michael E.
b926f6e7-c189-4ad6-8a63-b783ebc4423d
Hilditch, Tim
858a3a17-d8f4-4b3f-9129-fb467c13d462
Fabijanic, Daniel
bbf0d960-0c29-4920-9181-501a532417bc
31 August 2023
Sarkar, Riddhi
97df7410-6878-4c93-9f0c-d9abc49eceb3
Chen, Bo
be54a9a8-da2a-4e6f-ae0e-0b076be87daf
Fitzpatrick, Michael E.
b926f6e7-c189-4ad6-8a63-b783ebc4423d
Hilditch, Tim
858a3a17-d8f4-4b3f-9129-fb467c13d462
Fabijanic, Daniel
bbf0d960-0c29-4920-9181-501a532417bc
Sarkar, Riddhi, Chen, Bo and Fitzpatrick, Michael E.
,
et al.
(2023)
Blown-powder direct-energy-deposition of titanium-diboride-strengthened IN718 Ni-base superalloy.
Materials Science and Engineering: A, 885, [145617].
(doi:10.1016/j.msea.2023.145617).
Abstract
This paper reports on the adoption of TiB2 as an inoculant to fabricate IN718 via the direct energy deposition (DED) process. Effective grain refinement and low texture were achieved in IN718/TiB2 using a TiB2 powder size of d90 = 10 μm and mass fraction of 1.5 wt%. The use of low linear energy density (33.08 J/mm) produced IN718/TiB2 deposits free from large grains (>300 μm), however at the cost of the formation of interlayer defects. By comparison, the large grains were present in deposits made with a linear energy density of 78.74 J/mm and also in deposits manufactured without an included inoculant. Production of deposits at lower energies without interlayer defects was possible by reducing the powder flow rate to 7 g/min. However, this caused a moderate increase in grain size. The TiB2 inoculant reduced the Laves phase network by replacing it with homogeneously distributed Cr-, Mo-, Nb-, and B-enriched needle-shaped precipitates. Tensile strength increased by 300–500 MPa with TiB2 addition, but at the cost of significant ductility drop, regardless of the deposition conditions. The IN718 deposit displayed many micro-cracks at the network of Laves phase during tensile loading, whereas micro-cracks in the IN718/TiB2 occurred at the interface between the needle-shaped precipitates and the matrix. The strength enhancement in IN718/TiB2 was by a combination of strengthening mechanisms: grain boundary, dislocation structure formation, Orowan-type and load transfer related to the needle-shaped precipitates.
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Accepted/In Press date: 25 August 2023
e-pub ahead of print date: 26 August 2023
Published date: 31 August 2023
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Local EPrints ID: 489872
URI: http://eprints.soton.ac.uk/id/eprint/489872
ISSN: 0921-5093
PURE UUID: 30110366-d46b-4827-9eae-52be4c760728
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Date deposited: 07 May 2024 16:30
Last modified: 08 May 2024 02:08
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Author:
Riddhi Sarkar
Author:
Bo Chen
Author:
Michael E. Fitzpatrick
Author:
Tim Hilditch
Author:
Daniel Fabijanic
Corporate Author: et al.
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