TY - JOUR
T1 - The creep behaviour of nickel alloy 718 manufactured by laser powder bed fusion
AU - Sanchez, S.
AU - Gaspard, G.
AU - Hyde, C.J.
AU - Ashcroft, I.A.
AU - Ravi, G.A.
AU - Clare, A.T.
N1 - Funding Information:
This work has been supported by the Engineering and Physical Sciences Research Council [EP/S513854/1]. Thank you to Shane Maskill for his creep testing expertise and for grinding the specimens, Alex Jackson-Crisp for machining specimens, Nigel Neate and the University of Nottingham nano and microscale Research Centre for additional SEM and EBSD imaging, James Murray for conducting the Alicona scans and Alistair Speidel for assisting with the use of MountainsMaps and ImageJ software.
Funding Information:
This work has been supported by the Engineering and Physical Sciences Research Council [ EP/S513854/1 ]. Thank you to Shane Maskill for his creep testing expertise and for grinding the specimens, Alex Jackson-Crisp for machining specimens, Nigel Neate and the University of Nottingham nano and microscale Research Centre for additional SEM and EBSD imaging, James Murray for conducting the Alicona scans and Alistair Speidel for assisting with the use of MountainsMaps and ImageJ software.
Publisher Copyright:
© 2021 The Author(s)
PY - 2021/6
Y1 - 2021/6
N2 - Components manufactured by laser powder bed fusion (LPBF) are limited by their performance for use in critical applications. LPBF materials have microstructural defects, such as suboptimal grain size and morphology, and macroscale anomalies, such as lack of fusion. This results in LPBF components performing below their wrought counterparts for various mechanical properties, such as creep which has seldom been researched. To understand the creep behaviour of LPBF alloy 718, parts were fabricated using different scanning strategies and build orientations and creep tested at 650 °C under a 600 MPa load. Heat treatment increased the creep life by a factor of 5, confirming its necessity. The build orientation and stress state were shown to be determining factors in the creep failure mechanisms. The Meander scanning strategy resulted in a 58% increase in creep life compared to the Stripe strategy, due to the detrimental effects of the numerous laser overlapping regions in the Stripe strategy. For a given strategy, a 24% increase in creep life compared to wrought alloy 718 was observed, indicating that LPBF has the potential to surpass wrought material properties. As a result of this work, it is possible to propose build strategies for high temperature creep applications.
AB - Components manufactured by laser powder bed fusion (LPBF) are limited by their performance for use in critical applications. LPBF materials have microstructural defects, such as suboptimal grain size and morphology, and macroscale anomalies, such as lack of fusion. This results in LPBF components performing below their wrought counterparts for various mechanical properties, such as creep which has seldom been researched. To understand the creep behaviour of LPBF alloy 718, parts were fabricated using different scanning strategies and build orientations and creep tested at 650 °C under a 600 MPa load. Heat treatment increased the creep life by a factor of 5, confirming its necessity. The build orientation and stress state were shown to be determining factors in the creep failure mechanisms. The Meander scanning strategy resulted in a 58% increase in creep life compared to the Stripe strategy, due to the detrimental effects of the numerous laser overlapping regions in the Stripe strategy. For a given strategy, a 24% increase in creep life compared to wrought alloy 718 was observed, indicating that LPBF has the potential to surpass wrought material properties. As a result of this work, it is possible to propose build strategies for high temperature creep applications.
KW - Creep
KW - Fractography
KW - Laser powder bed fusion
KW - Nickel alloy 718
UR - http://www.scopus.com/inward/record.url?scp=85103115096&partnerID=8YFLogxK
U2 - 10.1016/j.matdes.2021.109647
DO - 10.1016/j.matdes.2021.109647
M3 - Article
AN - SCOPUS:85103115096
SN - 0264-1275
VL - 204
JO - Materials and Design
JF - Materials and Design
M1 - 109647
ER -