Microstructure and Properties of ZrC Enhanced Laser Cladding CoCrNi Alloy Cladding Layer

doi:10.12442/j.issn.1002-185X.20230107

Home > Archive>Volume 53, Issue 3, 2024 >778-786. DOI:10.12442/j.issn.1002-185X.20230107

Microstructure and Properties of ZrC Enhanced Laser Cladding CoCrNi Alloy Cladding Layer
DOI:
                        10.12442/j.issn.1002-185X.20230107
                    
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                        Ran Liu1Ran Liu
School of Mechanical and Materials Engineering,North China University of Technology
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Xianting Dang1Xianting Dang
School of Mechanical and Materials Engineering,North China University of Technology
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Chuqi Chen1Chuqi Chen
School of Mechanical and Materials Engineering,North China University of Technology
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Tao Wu2Tao Wu
Zhejiang Institute of Mechanical Electrical Engineering
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Affiliation:1.School of Mechanical and Materials Engineering,North China University of Technology;2.Zhejiang Institute of Mechanical Electrical Engineering
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Abstract:

ZrC strengthened CoCrNi-based laser cladded coatings with different content of ZrC were prepared on the surface of low carbon steel. The effects of ZrC addition on microstructure, hardness and wear resistance of CoCrni-based medium entropy alloy coating were investigated. The results show that there is a good metallurgical bond between the cladding layer and the matrix without obvious cracks and defects. The CoCrNi alloy coating without ZrC is composed of single-phase FCC structure. With the addition of ZrC in the coating, the coating phase compositions change to FCC+ ZrC0.7+Cr23C6+ZrO2 multiple phase structures. The grains of the coating were significantly refined, and the combination of grain boundary strengthening, solution strengthening and dispersion strengthening (Orowan) was realized, which effectively improved the hardness and wear resistance of the coating. However, ZrO2 produced by the combination of Zr in ZrC and O in the air also has an adverse effect on the performance of the coating, mainly because the presence of ZrO2 will cause the uneven distribution of particles in the coating and weaken the effect of dispersion strengthening. Therefore, when the content of ZrC is small, the performance of the coating is not improved. However, when ZrC content in the coating increases to 5wt.%, more ZrC0.7 phase is separated out from the coating, which can effectively improve the performance of the material. The hardness is 651±15 HV_0.1 and the friction coefficient is 0.161 which is much lower owing to the synergetic strengthening effect.

Key words:CoCrNi, composite;coating, laser;cladding, wear;resistance

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[Ran Liu, Xianting Dang, Chuqi Chen, Tao Wu. Microstructure and Properties of ZrC Enhanced Laser Cladding CoCrNi Alloy Cladding Layer[J]. Rare Metal Materials and Engineering,2024,53(3):778~786.]
DOI：10.12442/j. issn.1002-185X.20230107

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Received:March 03,2023
Revised:April 26,2023
Adopted:April 27,2023
Online: March 27,2024
Published: March 20,2024

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