Effect of solution aging treatment on microstructure and properties of Fe‐0.5C‐11Cr corrosion resistant alloy by laser cladding

Fang, Zhao; Guo, Tao; Li, Qiang; Yin, Yulong; Zhang, Ruihua; Nan, Xueli

doi:10.1016/j.jallcom.2022.166142

Cited by 7 publications

(3 citation statements)

References 11 publications

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“…[ 2 ] By using cladding laser prepare wear‐resistant and corrosion‐resistant coating on the surface of 3Cr13 martensitic stainless steel, it can improve its service life. [ 3 ] Compared with other wear and corrosion‐resistant alloys such as cobalt and nickel, steel‐based wear and corrosion‐resistant materials have lower price and better compatibility with the 3Cr13 matrix, [ 4,5 ] so they have a wider application prospect in the petrochemical field.…”

Section: Introductionmentioning

confidence: 99%

Effect of Scanning Speed on Microstructure and Properties of Laser Cladding Fe‐0.3C‐15Cr‐1Ni High Hardness Corrosion‐Resistant Alloy Coating on 3Cr13 Surface

Dong,

Guo,

Zhang

et al. 2024

steel research int.

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Fe‐0.3C‐15Cr‐1Ni high hardness corrosion‐resistant alloy coating is prepared on the surface of 3Cr13 by laser cladding technology. The effects of scanning speeds on the microstructure, microhardness, and corrosion resistance of the coating are studied. The results show that the microstructure of the cladding layer is mainly composed of intracrystalline martensite and carbides distributed along the grain boundaries. When scanning speed increases from 3 to 5 mm s−1, the grain is obviously fined, and the number of carbides increases, further increasing scanning speed, the grain refinement degree decreases and the carbide quantity decreases gradually. When scanning speed is 5 mm s−1, the microhardness reaches the maximum, the corrosion resistance is significantly improved at 5 and 7 mm s−1, and the pitting potential and passivation zone width increase by 180–219% and 69–78%, respectively, compared with 3 mm s−1 sample, but further increases scanning speed to 9 mm s−1, the hardness and corrosion resistance significantly reduce. This is because scanning rate affects the component undercooling degree of the dynamic molten pool and the temperature gradient at the solidification interface front, which affects the growth of dendrites, the number of carbides, and further affects the alloying elements in the carbide and matrix.

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Section: Introductionmentioning

confidence: 99%

Effect of Scanning Speed on Microstructure and Properties of Laser Cladding Fe‐0.3C‐15Cr‐1Ni High Hardness Corrosion‐Resistant Alloy Coating on 3Cr13 Surface

Dong,

Guo,

Zhang

et al. 2024

steel research int.

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“…In general, strength, ductility and toughness are essential and demanding properties for structural engineering applications; however, strength and ductility are competing properties in metallic systems and often an optimum synergy in a metallic coating is required [1]. High-energy beams such as lasers or plasma arcs are commonly used to deposit carbide-reinforced metal matrix composite coatings, where carbides are incorporated into coatings via either ex-situ or in-situ synthesis [2][3][4][5]. Among these routines, chemical reactions between strong carbide-forming elements (e.g., V, Ti, Nb, Cr, Mo) and carbon impurities in the matrix are advantageous for producing thermodynamically stable hard reinforcements which may strengthen the matrix significantly [6][7][8].…”

Section: Introductionmentioning

confidence: 99%

In-situ micromechanical analysis of a high-vanadium high-speed steel coating made with additive manufacturing

Dong

Chabok

et al. 2023

Materials Science and Engineering: A

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“…Compared with the Co-based and Ni-based self-fusible cladding powder, the similar elements between laser-cladding stainless steel-based alloy coating and steel matrix make the diffusion of elements not obvious in the process of laser cladding, resulting in a low dilution rate of the cladding layer and strong interface bonding strength, which can effectively solve the cracking problem of laser-cladding layer. [9] Most notably, steelbased powders are relatively inexpensive, which give steel-based alloys a unique advantage in industrial applications. [10,11] Unfortunately, the cast-like structure of carbides distributed along grain boundaries in laser-cladding stainless steel alloy coatings has a very adverse effect on toughness and corrosion resistance of the cladding coatings, which restricts the application of laser-cladding stainless steel alloy coatings.…”

Section: Introductionmentioning

confidence: 99%

Effect of CeO₂ on Microstructure and Properties of Wear and Corrosion Resistance Martensitic Stainless Steel‐Based Coating on Laser Cladding

Fang

Guo

Zhang³

et al. 2022

steel research int.

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The effects of CeO2 on the quantity, morphology, and distribution of carbides, the microhardness, friction and wear properties, and corrosion resistance of 0.3C–16Cr martensitic stainless steel‐based cladding layer are investigated. The results show that the addition of CeO2 inhibits the dendrite growth and improves the morphology, size, and distribution of carbides in the cladding layer. The hardness shows a peak with the increase in CeO2 content, the wear rate of the cladding layer with CeO2 decreases, and the wear resistance increases. In addition, CeO2 significantly improves the corrosion resistance of the cladding layer, causing the pitting potential to increase and the blunt current density to decrease. Compared with the original sample, the wear amount and dimensional blunt current density of the sample with 0.3% CeO2 content are reduced by 55.36% and 35.32%, respectively, and the pitting potential is increased by 2.71 times. The comprehensive performance of the cladding layer is the best. This is mainly because CeO2 can increase the latent heat of crystallization during the cooling process of the cladding layer, reduce the constitutional supercooling, inhibit the directional growth of dendrites, improve the uniformity of the microstructure and composition, and thereby improve the wear resistance and corrosion resistance.

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Effect of solution aging treatment on microstructure and properties of Fe‐0.5C‐11Cr corrosion resistant alloy by laser cladding

Cited by 7 publications

References 11 publications

Effect of Scanning Speed on Microstructure and Properties of Laser Cladding Fe‐0.3C‐15Cr‐1Ni High Hardness Corrosion‐Resistant Alloy Coating on 3Cr13 Surface

Effect of Scanning Speed on Microstructure and Properties of Laser Cladding Fe‐0.3C‐15Cr‐1Ni High Hardness Corrosion‐Resistant Alloy Coating on 3Cr13 Surface

In-situ micromechanical analysis of a high-vanadium high-speed steel coating made with additive manufacturing

Effect of CeO₂ on Microstructure and Properties of Wear and Corrosion Resistance Martensitic Stainless Steel‐Based Coating on Laser Cladding

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Effect of solution aging treatment on microstructure and properties of Fe‐0.5C‐11Cr corrosion resistant alloy by laser cladding

Cited by 7 publications

References 11 publications

Effect of Scanning Speed on Microstructure and Properties of Laser Cladding Fe‐0.3C‐15Cr‐1Ni High Hardness Corrosion‐Resistant Alloy Coating on 3Cr13 Surface

Effect of Scanning Speed on Microstructure and Properties of Laser Cladding Fe‐0.3C‐15Cr‐1Ni High Hardness Corrosion‐Resistant Alloy Coating on 3Cr13 Surface

In-situ micromechanical analysis of a high-vanadium high-speed steel coating made with additive manufacturing

Effect of CeO2 on Microstructure and Properties of Wear and Corrosion Resistance Martensitic Stainless Steel‐Based Coating on Laser Cladding

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Effect of CeO₂ on Microstructure and Properties of Wear and Corrosion Resistance Martensitic Stainless Steel‐Based Coating on Laser Cladding