Download This PaperEnhancement of Hardness, Wear, and Corrosion Resistance in Ti-6al-4v Alloy Through Multi-Layer Laser Cladding of Tizrnbcrco High Entropy Alloy Coatings
13 Pages Posted: 26 Mar 2024
Abstract
In response to the issues of low hardness and inadequate wear resistance observed in Ti-6Al-4V alloy, this study employs a laser cladding technique to fabricate high-entropy alloy coatings composed of TiZrNbCrCo on the alloy's surface. The investigation explores the effects of varying the number of cladding layers on elemental composition, and its influence on the phase constitution, microstructure, microhardness, as well as wear and electrochemical properties of high-entropy alloy coatings. Empirical thermophysical parameters were used to predict the phase composition of solid solution phases in high-entropy alloy coatings with different layer numbers. The findings indicate that coatings, regardless of the number of layers applied, share a consistent phase composition, featuring a dual-phase body-centered cubic (BCC) structured solid solution. These phases include Nb-rich dendrites (BCC1) and Co-rich interdendritic regions (BCC2). With an increase in the number of cladding layers, the dilution rate decreases, resulting in the formation of petal-like Laves phases enriched in Zr and Co, along with α-Ti precipitates enriched in Zr. The average microhardness of the coatings reaches 747.7 HV0.1, approximately 2.33 times that of the substrate, leading to a reduction of wear volume by 68.6% compared to the substrate. The optimal corrosion resistance is observed when the number of layers reaches two, exhibiting the lowest self-corrosion current (6.46×10-6 A·cm-2), a larger open circuit potential (-0.286 V), and the lowest corrosion rate, indicating a significant enhancement in corrosion resistance.
Keywords: laser cladding, high-entropy alloy, titanium alloy, tribological properties, Corrosion resistance
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