Abstract
Surface remelting and subsequent nitriding improves the surface properties of cast irons. Upon remelting, a white-solidified surface layer forms, which contains coarse Si-free eutectic cementite (θ) and Si-enriched ferrite, pearlite or martensite in the intercarbidic regions between the eutectic θ. Nitriding produces a compound layer at the surface, which is composed of ε and γ’-iron (carbo)nitrides and enhances the corrosion resistance. Nitriding of white-solidified Fe-C-Si alloys, being model materials for remelted low-alloy ferritic cast irons, has shown that Si dissolved in α-Fe notably affects the formation of ε and γ’ in intercarbidic regions while Si simultaneously precipitates as amorphous nitride, X. Under process conditions only allowing for the formation of γ’ in pure Fe, Si dissolved in α-Fe promotes the formation of ε over the formation γ’, whereas Si-free eutectic θ transforms into nitride following the sequence θ → ε → γ’. The present work studies the nitriding of white-solidified Fe-3.5wt.%C-3wt.%-M alloys with additions of M = 1 wt.% Mn, 1 wt.% Cu or 1 wt.% Mn + 1 wt.% Cu, serving as model materials for remelted pearlitic cast irons. The presence of Mn and/or Cu causes notable deviations from the nitriding behavior known from Fe-C-Si alloys. Mn accelerates the precipitation of X in intercarbidic regions and obstructs the transformation of ε formed from Si-free θ into γ’. Cu promotes the formation of γ’ in Si-rich intercarbidic regions, surpassing the ε-promoting effect of Si.
Highlights
Nitriding is frequently employed to improve the mechanical surface properties and corrosion resistance of Fe-base alloys by generating a compound layer (CL) at the material’s surface, which is composed of γ’-Fe4(N,C) and ε-Fe3(N,C)1-xnitrides [1]
Nitriding of white-solidified Fe-C-Si alloys, being model materials for remelted low-alloy ferritic cast irons, has shown that Si dissolved in α-Fe notably affects the formation of ε and γ’ in intercarbidic regions while Si simultaneously precipitates as amorphous nitride, X
The present work studies the nitriding of white-solidified Fe-3.5wt.%C-3wt.%-M alloys with additions of M = 1 wt.% Mn, 1 wt.% Cu or 1 wt.% Mn + 1 wt.% Cu, serving as model materials for remelted pearlitic cast irons
Summary
Nitriding is frequently employed to improve the mechanical surface properties and corrosion resistance of Fe-base alloys by generating a compound layer (CL) at the material’s surface, which is composed of γ’-Fe4(N,C) and ε-Fe3(N,C)1-x (carbo)nitrides [1]. The nitriding behavior of surface-remelted ferritic low-alloy cast irons (GJS‐400‐15, GJV‐300), containing only negligible additions of alloying elements other than C and Si, compares with the nitriding behavior of the Fe-C-Si model alloys studied by the present authors: Si-free θ transforms into nitride according to the above transformation sequence θ → ε → γ’ and Si-stabilized ε forms from α-Fe in Si-rich ferrite/pearlite under γ’ conditions [4]. The acceleration of the otherwise slow precipitation of X due to the presence of Mn and/or Cu might lead to a faster depletion of α-Fe in Si, reducing the ε-promoting effect of Si. Different solubilities of Mn and/or Cu in ε and γ’ might affect the stability range of ε and γ’, and, the type of Fe nitride forming under given process conditions. The results are compared with findings previously reported by the present authors for white-solidified and nitrided Fe-3.5C-0/1.5/3Si model alloys [5,6,7,8]
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