Formation of Structural-Phase States, Defect Substructure and Properties of a Surface of Thermomechanically Hardened Low-Carbon Steel

Detection of physical mechanisms of formation and evolution of structural and phase states and dislocation substructures in steels is one of the important problem of condensed-matter physics and contemporary material science because it forms the basis of development and formation of effective method...

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Bibliographic Details
Main Author: V. E. Gromov, Yu. F. Ivanov, E. G. Belov, V. B. Kosterev, D. A. Kosinov
Format: Article
Language:English
Published: G. V. Kurdyumov Institute for Metal Physics of the N.A.S. of Ukraine 2016-12-01
Series:Успехи физики металлов
Online Access:https://doi.org/10.15407/ufm.17.04.303
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Summary:Detection of physical mechanisms of formation and evolution of structural and phase states and dislocation substructures in steels is one of the important problem of condensed-matter physics and contemporary material science because it forms the basis of development and formation of effective methods for increasing the service characteristics of products. Experimental investigations of structural and phase states being formed in a cross-section of products as a result of thermomechanical treatment are very significant for understanding the physical nature of transformations since they make it possible to change structure and mechanical characteristics purposefully. Thermomechanical hardening of low-carbon steel 09Г2C (0.09 wt.% of C, 2 wt.% of Mn, 1 wt.% of Si;) was made by rolling of H-beam ДП 155 and forced water cooling on rolling mill 450 of open joint-stock company ‘EVRAZ Consolidated West-Siberian Metallurgical Plant’. By methods of transmission diffraction electron microscopy, we investigated structural-phase states and defect substructure of H-beam (made of 09Г2С steel) formed during thermomechanical hardening on rolling mill. It is established that defect substructure state of steel α-phase is determined by (a) the mechanisms of γ→α transformation, (b) the regime of high temperature rolling and accelerated cooling, (c) the distance to the surface of the accelerated cooling. The correspondence of dislocation substructure and morphology of α-phase (mechanism of γ→α transformation) is established. In the martensite and bainite crystals, a net-like dislocation structure with a very high dislocation density that varies within the range of 5.8⋅1010–10.0⋅1010 cm−2 is a dominant one. In the ferrite and pearlite grains, a structure of dislocation chaos and net-like dislocation substructure with a relatively low values of scalar density of dislocations varying within the range 2.6·1010–3.5·1010 cm−2 are determined. We analyzed the processes and mechanisms contributing to the formation of nanodimensional phase at the thermomechanical treatment of low-alloy steel. It was shown as follows: (i) in dispersion of cementite plates of pearlite colonies by cutting them with moving dislocations, the particles of 5–30 nm size were formed; (ii) the oval-shape particles of 5–15 nm size were formed during the dissolution of cementite plates of pearlite colonies and repeated precipitation on dislocations, boundaries of subgrains and grains; (iii) during the decomposition of solid solution of carbon in the α-iron occurring in the conditions of ‘self-tempering’ of martensite, the sizes of particles precipitated in the volume of martensite crystals on dislocations are 5–10 nm, and at the boundaries of martensite crystals—10–30 nm; (iv) during the diffusion γ→α transformation at the high degree of deformation and temperatures of treatment, a dispersion of lamellar pearlite structure is observed: thickness of α-phase plates separated by the carbide plates is ≈ 70 nm, while thickness of carbide phase plates is ≈ 25 nm. Using the quantitative parameters of steel structure revealed by the methods of metallography and electron diffraction microscopy, and estimate relations of physical material science, we analyzed physical mechanisms responsible for enhancement the microhardness of surface layer at the thermomechanical hardening. The quantitative parameters characterizing structural and phase state and allowing the possibilities to estimate the value of theoretical yield point for steel were determined. The quantitative correspondence of change of experimentally measured microhardness and theoretically determined yield point along the cross-section of H-beam flange was obtained. It is established that the phenomenon of increase in hardness of steel surface layer is a multi-factor, morphologically multi-component one, and is determined by the nature of γ→α transformation. The main mechanisms responsible for high level of steel surface layer hardness are substructural and deformational ones caused by the formation of martensite and bainite crystals.
ISSN:1608-1021
2617-0795