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A strategy to achieve high-strength WNiFe composite-like alloys with low W content by laser melting deposition

Shangcheng Zhou, Lu Wang, Yao-Jian Liang, Yichao Zhu, Ruizhi Jian, Benpeng Wang, Liang Wang, Yunfei Xue, Fuchi Wang, Hongnian Cai, Yang Ren

2020Materials & Design40 citationsDOIOpen Access PDF

Abstract

Preparing bulk WNiFe alloys with high strengths and low W content (<80 wt%) is challenging. Here, we present a strategy, powder-fed laser melting deposition (LMD), to solve this problem. The LMD-prepared WNiFe (LMD WNiFe) samples show high mechanical strengths and low W contents of 50 and 75 wt%. The W particles in the LMD WNiFe samples uniformly distribute in the matrix (γ), exhibiting fine particle sizes of approximately one-fifth of those of conventional 93WNiFe alloys prepared by liquid phase sintering (LPS). The ultimate tensile strengths of the 50 and 75 wt% samples are 1120 and 1316 MPa, respectively, which are 24.44 and 59.33% higher than those of the LPS-prepared 93WNiFe alloy (LPS 93WNiFe). These results suggest a useful strategy for preparing low-W-content, high-strength WNiFe alloys with fine, uniformly distributed W particles. This finding offers new potential applications of WNiFe alloys in additive manufacturing.

Topics & Concepts

Materials scienceUltimate tensile strengthComposite numberDeposition (geology)AlloySinteringSelective laser sinteringPhase (matter)Particle (ecology)Composite materialMetallurgyMatrix (chemical analysis)PaleontologyChemistryOceanographyOrganic chemistrySedimentBiologyGeologyAdditive Manufacturing Materials and ProcessesHigh Entropy Alloys StudiesAdvanced materials and composites
A strategy to achieve high-strength WNiFe composite-like alloys with low W content by laser melting deposition | Litcius