Microstructure characteristics and mechanical properties of a laser cladded Fe-based martensitic stainless steel coating

In the present work, a Fe-based alloy (Fe60) coating was fabricated by laser cladding (LC) process. Heat treatment was conducted by heating the LC coating to 1050 °C by 30 °C/min, holding for 30 min and cooling in air. Microstructure characteristics of the coatings before and after heat treatment we...

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Bibliographic Details
Published in:Surface & coatings technology 2021-02, Vol.408, p.126795, Article 126795
Main Authors: Guo, Weimin, Li, Xiaoqiang, Ding, Ning, Liu, Guoqiang, He, Jianqun, Tian, Linan, Chen, Lizong, Zaïri, Fahmi
Format: Article
Language:English
Subjects:
Cementite
Chromium
Civil Engineering
Cleavage
Coatings
Dendritic structure
EBSD
Electron backscatter diffraction
Engineering Sciences
Ferrous alloys
Fractures
Heat treating
Heat treatment
Iron carbides
Laser beam cladding
Laser beam heating
Laser cladding coating
Martensite
Martensitic stainless steels
Mechanical properties
Micro-hardness
Microhardness
Microscopy
Microstructure
Optical microscopy
Residual stress
Retained austenite
Tensile strength
Ultimate tensile strength
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Summary:In the present work, a Fe-based alloy (Fe60) coating was fabricated by laser cladding (LC) process. Heat treatment was conducted by heating the LC coating to 1050 °C by 30 °C/min, holding for 30 min and cooling in air. Microstructure characteristics of the coatings before and after heat treatment were studied using optical microscopy (OM), scanning electron microscopy (SEM), energy dispersive spectrometer (EDS) and electron backscatter diffraction detector (EBSD). Micro-hardness, tensile strength of the coatings before and after heat treatment were also acquired. Before heat treatment, the LC coating was composed of martensite dendrite matrix with a small number of ferrite and retained austenite grains and a large number of fine carbides (Fe3C, M7C3 and M23C6) that are rich in Cr element in inter-dendritic area. After heat treatment, the martensite dendrite matrix was retained and a large number of new carbide particles precipitated in martensite dendrites, while the size and Cr content of inter-dendrite carbide particles increased. Micro-hardness of the coating decreased from 800 HV1 to 650 HV1 due to the release of residual stress and carbon atoms in the BCC structure lattice, elimination of high density defaults. However, ultimate tensile strength of the coating increased from 450 MPa to 550 MPa due to the precipitate hardening effect of new precipitated carbide particles in dendrites. The tear and cleavage appearance of the fractures proved that the fractures are quasi-cleavage fracture. •Micro-hardness of the coating was decreased while ultimate tensile stress was increased after heat treatment.•The increase of image quality indicates that the residual stress were largely released during heat treatment.•The release of carbon atoms from the BCC structure caused the hardness decrease of the coating.•Newly formed carbide particles in dendrites are rich in Cr and Mn, lack in Si.
ISSN:0257-8972
1879-3347
DOI:10.1016/j.surfcoat.2020.126795