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High-Brightness and High-Power Laser Welding of Powder Metallurgy Shape Memory Alloy: Welding-Parameter-Dependent Microstructure

Despite the growing interest in using powder metallurgy shape memory alloys, there is limited research on their joining and welding aiming to expand their applications. In this research, we utilized a high-power, high-brightness disk laser welding process to join spark-plasma-sintered Ti-51 at.% Ni...

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Main Authors: Bahador, Abdollah, Umeda, Junko, Mizutani, Masami, Hamzah, Esah, Yusof, Farazila, Kondoh, Katsuyoshi
Format: Article
Published: Springer Verlag (Germany) 2020
Subjects:
TJ Mechanical engineering and machinery
Online Access:http://eprints.um.edu.my/26046/
https://doi.org/10.1007/s11665-020-04597-0
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spelling my.um.eprints.260462021-10-04T06:50:33Z http://eprints.um.edu.my/26046/ High-Brightness and High-Power Laser Welding of Powder Metallurgy Shape Memory Alloy: Welding-Parameter-Dependent Microstructure Bahador, Abdollah Umeda, Junko Mizutani, Masami Hamzah, Esah Yusof, Farazila Kondoh, Katsuyoshi TJ Mechanical engineering and machinery Despite the growing interest in using powder metallurgy shape memory alloys, there is limited research on their joining and welding aiming to expand their applications. In this research, we utilized a high-power, high-brightness disk laser welding process to join spark-plasma-sintered Ti-51 at.% Ni shape memory alloy and studied the primary factors that affect the strength and functionality of the created sound welds such as intermetallics and martensite (B19′) phase formation. The introduction of high-power laser could impede the formation of B19′ and undesirable intermetallics such as TiNi3 and Ti2Ni; however, the desired Ti3Ni4 would also be suppressed and post-weld heat treatment was necessary to induce them again. The microstructure of fusion zones was significantly altered, producing coarse columnar grains with centerline and equiaxed weld centers. Additionally, high-power laser welding of powder metallurgy Ti-Ni alloy triggered amorphous phase formation in the welds due to rapid cooling. It was found that a laser power of 3 kW and welding speed of 6 m/min are optimal welding parameters, since the produced weld solidified along favorable [001] direction of strain recovery in Ti-Ni shape memory alloys. © 2020, ASM International. Springer Verlag (Germany) 2020 Article PeerReviewed Bahador, Abdollah and Umeda, Junko and Mizutani, Masami and Hamzah, Esah and Yusof, Farazila and Kondoh, Katsuyoshi (2020) High-Brightness and High-Power Laser Welding of Powder Metallurgy Shape Memory Alloy: Welding-Parameter-Dependent Microstructure. Journal of Materials Engineering and Performance, 29 (2). pp. 987-996. ISSN 1059-9495 https://doi.org/10.1007/s11665-020-04597-0 doi:10.1007/s11665-020-04597-0
institution Universiti Malaya
building UM Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Malaya
content_source UM Research Repository
url_provider http://eprints.um.edu.my/
topic TJ Mechanical engineering and machinery
spellingShingle TJ Mechanical engineering and machinery
Bahador, Abdollah
Umeda, Junko
Mizutani, Masami
Hamzah, Esah
Yusof, Farazila
Kondoh, Katsuyoshi
High-Brightness and High-Power Laser Welding of Powder Metallurgy Shape Memory Alloy: Welding-Parameter-Dependent Microstructure
description Despite the growing interest in using powder metallurgy shape memory alloys, there is limited research on their joining and welding aiming to expand their applications. In this research, we utilized a high-power, high-brightness disk laser welding process to join spark-plasma-sintered Ti-51 at.% Ni shape memory alloy and studied the primary factors that affect the strength and functionality of the created sound welds such as intermetallics and martensite (B19′) phase formation. The introduction of high-power laser could impede the formation of B19′ and undesirable intermetallics such as TiNi3 and Ti2Ni; however, the desired Ti3Ni4 would also be suppressed and post-weld heat treatment was necessary to induce them again. The microstructure of fusion zones was significantly altered, producing coarse columnar grains with centerline and equiaxed weld centers. Additionally, high-power laser welding of powder metallurgy Ti-Ni alloy triggered amorphous phase formation in the welds due to rapid cooling. It was found that a laser power of 3 kW and welding speed of 6 m/min are optimal welding parameters, since the produced weld solidified along favorable [001] direction of strain recovery in Ti-Ni shape memory alloys. © 2020, ASM International.
format Article
author Bahador, Abdollah
Umeda, Junko
Mizutani, Masami
Hamzah, Esah
Yusof, Farazila
Kondoh, Katsuyoshi
author_facet Bahador, Abdollah
Umeda, Junko
Mizutani, Masami
Hamzah, Esah
Yusof, Farazila
Kondoh, Katsuyoshi
author_sort Bahador, Abdollah
title High-Brightness and High-Power Laser Welding of Powder Metallurgy Shape Memory Alloy: Welding-Parameter-Dependent Microstructure
title_short High-Brightness and High-Power Laser Welding of Powder Metallurgy Shape Memory Alloy: Welding-Parameter-Dependent Microstructure
title_full High-Brightness and High-Power Laser Welding of Powder Metallurgy Shape Memory Alloy: Welding-Parameter-Dependent Microstructure
title_fullStr High-Brightness and High-Power Laser Welding of Powder Metallurgy Shape Memory Alloy: Welding-Parameter-Dependent Microstructure
title_full_unstemmed High-Brightness and High-Power Laser Welding of Powder Metallurgy Shape Memory Alloy: Welding-Parameter-Dependent Microstructure
title_sort high-brightness and high-power laser welding of powder metallurgy shape memory alloy: welding-parameter-dependent microstructure
publisher Springer Verlag (Germany)
publishDate 2020
url http://eprints.um.edu.my/26046/
https://doi.org/10.1007/s11665-020-04597-0
_version_ 1713200127165857792
score 13.160551

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