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Microstructural study and wear behavior of ductile iron surface alloyed by Inconel 617
Highlights The Ni-base alloy was deposited on the surface of ductile iron by TIG welding process. Microstructure of alloyed layer consisted of carbides embedded in Ni-rich dendrite. Hardness and wear resistance of coated sample greatly improved. The formation of oxide layer and delamination were dominant mechanisms of wear.
Abstract In this research, microstructure and wear behavior of Ni-based alloy is discussed in detail. Using tungsten inert gas welding process, coating of nearly 1–2mm thickness was deposited on ductile iron. Optical and scanning electron microscopy, as well as X-ray diffraction analysis and electron probe microanalysis were used to characterize the microstructure of the surface alloyed layer. Micro-hardness and wear resistance of the alloyed layer was also studied. Results showed that the microstructure of the alloyed layer consisted of M23C6 carbides embedded in Ni-rich solid solution dendrites. The partial melted zone (PMZ) had eutectic ledeburit plus martensite microstructure, while the heat affected zone (HAZ) had only a martensite structure. It was also noticed that hardness and wear resistance of the alloyed layer was considerably higher than that of the substrate. Improvement of wear resistance is attributed to the solution strengthening effect of alloying elements and also the presence of hard carbides such as M23C6. Based on worn surface analysis, the dominant wear mechanisms of alloyed layer were found to be oxidation and delamination.
Microstructural study and wear behavior of ductile iron surface alloyed by Inconel 617
Highlights The Ni-base alloy was deposited on the surface of ductile iron by TIG welding process. Microstructure of alloyed layer consisted of carbides embedded in Ni-rich dendrite. Hardness and wear resistance of coated sample greatly improved. The formation of oxide layer and delamination were dominant mechanisms of wear.
Abstract In this research, microstructure and wear behavior of Ni-based alloy is discussed in detail. Using tungsten inert gas welding process, coating of nearly 1–2mm thickness was deposited on ductile iron. Optical and scanning electron microscopy, as well as X-ray diffraction analysis and electron probe microanalysis were used to characterize the microstructure of the surface alloyed layer. Micro-hardness and wear resistance of the alloyed layer was also studied. Results showed that the microstructure of the alloyed layer consisted of M23C6 carbides embedded in Ni-rich solid solution dendrites. The partial melted zone (PMZ) had eutectic ledeburit plus martensite microstructure, while the heat affected zone (HAZ) had only a martensite structure. It was also noticed that hardness and wear resistance of the alloyed layer was considerably higher than that of the substrate. Improvement of wear resistance is attributed to the solution strengthening effect of alloying elements and also the presence of hard carbides such as M23C6. Based on worn surface analysis, the dominant wear mechanisms of alloyed layer were found to be oxidation and delamination.
Microstructural study and wear behavior of ductile iron surface alloyed by Inconel 617
Arabi Jeshvaghani, R. (author) / Jaberzadeh, M. (author) / Zohdi, H. (author) / Shamanian, M. (author)
2013-08-17
7 pages
Article (Journal)
Electronic Resource
English
Microstructural study and wear behavior of ductile iron surface alloyed by Inconel 617
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