Advancements and Perspectives in Additive Manufacturing of Tungsten Alloys and Composites: Challenges and Solutions
Mehrdad Zarinejad,
Yunxiang Tong,
Mojtaba Salehi,
Chengfa Mu,
Nian Wang,
Yonglong Xu,
Sajjad Rimaz,
Lintao Tian,
Kai Xiang Kuah,
Xiaotong Chen
Affiliations
Mehrdad Zarinejad
Research and Development Institute, Wenzhou Hongfeng Electrical Alloy Co., Ltd., No. 5600, Oujin Avenue, Oujiangkou Industry Cluster, Wenzhou 325700, China
Yunxiang Tong
Institute of Materials Processing and Intelligent Manufacturing, College of Materials Science and Chemical Engineering, Harbin Engineering University, Harbin 150001, China
Mojtaba Salehi
Additive Manufacturing Division, Singapore Institute of Manufacturing Technology (SIMTech), Agency for Science, Technology and Research (A*STAR), 5 Cleantech Loop, Singapore 636732, Singapore
Chengfa Mu
Research and Development Institute, Wenzhou Hongfeng Electrical Alloy Co., Ltd., No. 5600, Oujin Avenue, Oujiangkou Industry Cluster, Wenzhou 325700, China
Nian Wang
Wenzhou Hongfeng Alloy Co., Ltd., No. 1633, Binhai First Avenue, Wenzhou Economic and Technology Development Zone, Wenzhou 325603, China
Yonglong Xu
Wenzhou Hongfeng Alloy Co., Ltd., No. 1633, Binhai First Avenue, Wenzhou Economic and Technology Development Zone, Wenzhou 325603, China
Sajjad Rimaz
Department of Chemical and Bimolecular Engineering, National University of Singapore, 4 Engineering Drive 4, Singapore 117585, Singapore
Lintao Tian
Research and Development Institute, Wenzhou Hongfeng Electrical Alloy Co., Ltd., No. 5600, Oujin Avenue, Oujiangkou Industry Cluster, Wenzhou 325700, China
Kai Xiang Kuah
Department of Materials Science and Engineering, National University of Singapore, 9 Engineering Drive 1, Singapore 117575, Singapore
Xiaotong Chen
Research and Development Institute, Wenzhou Hongfeng Electrical Alloy Co., Ltd., No. 5600, Oujin Avenue, Oujiangkou Industry Cluster, Wenzhou 325700, China
This review explores additive manufacturing (AM) for refractory tungsten (W) and its alloys, highlighting the primary challenges and determining factors in the AM of pure W, W alloys and composites. The challenges mainly arise from W’s high melting point, low laser absorptivity, high thermal conductivity, high melt viscosity, high oxygen affinity, high ductile-to-brittle transition temperature, and inherent embrittlement, which lead to defects and anomalies in AM-produced parts. This review focuses on both processes and alloying strategies to address the issues related to densification, micro-cracking, and the resultant properties in W-based components. Cracking in additively manufactured W remains a persistent issue due to thermal stress, embrittlement, and oxide formation. Powder characteristics, process parameters, and thermal management strategies are crucial for W densification. Throughout the review, existing knowledge and insights are organized into comprehensive tables, serving as valuable resources for researchers delving deeper into this topic. Future research in W-AM should focus on understanding the interaction between AM process parameters and microstructural and material design. Advances in atomic-level understanding, thermodynamic modeling, and data analytics have the potential to significantly enhance the precision, sustainability, and applicability of W-AM.
