Chenxiao Song , Wei Zhao , Jinpeng Bi , Shuai Li , Hairui Gao , Hui Zhang , Song Gao , Yuexia Lv , Weifeng Rao
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引用次数: 0
Abstract
In this study, CoCrFeNiNbVx (x = 0, 0.5, 1, 1.5) high-entropy alloy (HEA) laser cladding layers were fabricated to investigate the effects of V content on the microstructure evolution, as well as room-temperature and high-temperature wear resistance of the cladding layers. It was found that all cladding layers exhibited a typical hypereutectic morphology. With increasing x, the stability of the FCC phase decreased, gradually transitioning from FCC phase + Laves phase (primary Laves phase + secondary Laves phase) + NbC to BCC phase + Laves phase (primary Laves phase + secondary Laves phase). At x = 1, the primary Laves phase accounted for 41.6 % of the structure and exhibited optimal size uniformity. Compared to DT4 industrial pure iron, the microhardness of the cladding layers was significantly improved, which can be attributed to the combined effects of second-phase strengthening, solid solution strengthening and dispersion strengthening. As x increased, the microhardness, room-temperature wear resistance, and high-temperature wear resistance of the cladding layers initially increased and then decreased, reaching optimal values at x = 1, where they were 1.61, 7.04, and 7.40 times higher than those at x = 0, respectively. The improvement in room-temperature wear resistance can be attributed to the increased Laves phase content and the formation of Fe-, V-, and Nb-enriched oxide layers. The enhancement in high-temperature wear resistance is due to the increased Laves phase content and the lubricating effect of VxOy. The addition of V significantly improves the properties of high-entropy alloys and provides an effective approach for preparing cladding layers with good wear resistance and high-temperature wear resistance.
期刊介绍:
This journal is a platform for publishing innovative research and overviews for advancing our understanding of the structure, property, and functionality of complex metallic alloys, including intermetallics, metallic glasses, and high entropy alloys.
The journal reports the science and engineering of metallic materials in the following aspects:
Theories and experiments which address the relationship between property and structure in all length scales.
Physical modeling and numerical simulations which provide a comprehensive understanding of experimental observations.
Stimulated methodologies to characterize the structure and chemistry of materials that correlate the properties.
Technological applications resulting from the understanding of property-structure relationship in materials.
Novel and cutting-edge results warranting rapid communication.
The journal also publishes special issues on selected topics and overviews by invitation only.
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