Kinetic Prediction for Isothermal Transformation of Inclusions in a Bearing Steel

The detailed mechanism of divorced pearlite in bearing steels began to be actively discussed more recently. The survey of divorced pearlite in higher Mn bearing steel was carried out through scanning electronic microscope following isothermal transformation heat treatment. The results show that while divorced transformation taking place in the higher Mn bearing steel just slightly below A1, the cementite could be produced in such way as growing on the base of pre-existing cementite particles in austenite, or emerge either in globular particles or in short rod directly from the austenite. Under isothermal transformation, the carbon atoms in austenite prefer to precipitate on the original boundary of the austenite. The enough small size of the cementite particles remained in the austenite is helpful for getting spheroidal cementite particles structure through divorced eutectoid transformation.

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The Use of Acoustic Emission and Neural Network in the Study of Phase Transformation below MS

Materials ◽

10.3390/ma14030551 ◽

2021 ◽

Vol 14 (3) ◽

pp. 551

Author(s):

Małgorzata Łazarska ◽

Tadeusz Z. Wozniak ◽

Zbigniew Ranachowski ◽

Andrzej Trafarski ◽

Szymon Marciniak

Keyword(s):

Neural Network ◽

Heat Treatment ◽

Artificial Neural Network ◽

Acoustic Emission ◽

Isothermal Transformation ◽

Bearing Steel ◽

Optimal Heat Treatment ◽

Isothermal Hardening ◽

Start Temperature ◽

Event Occurrence

Acoustic emission and dilatometry were applied to investigate the characteristics of phase transformations in bearing steel 100CrMnSi6-4 during austempering below the martensite start temperature (MS 175 °C) at 150 °C. The aim of this study is to characterize the product of transformation occurring below the MS temperature using various research methods. Analysis of the dilatometric curves shows that, after the formation of athermal martensite below the MS temperature, the austenite continues to undergo isothermal transformation, indicating the formation of bainite. Additionally, tests were carried out with the use of acoustic emission during isothermal hardening of the adopted steel. The obtained acoustic emission signals were analyzed using an artificial neural network. The results, in the form of a graph of the frequency of acoustic emission (AE) event occurrence as a function of time, make it possible to infer about the bainite isothermal transformation. The results of this research may be used in the future to design optimal heat treatment methods and, consequently, may enable desired microstructure shaping.

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Adjustment of Isothermal Transformation Diagrams Using Finite-Element Optimization of the Jominy Test

Metals ◽

10.3390/met10070931 ◽

2020 ◽

Vol 10 (7) ◽

pp. 931

Author(s):

Missam Irani ◽

Sukhwan Chung ◽

Mincheol Kim ◽

Kwangoh Lee ◽

Mansoo Joun

Keyword(s):

Finite Element ◽

Optimization Procedure ◽

Practical Method ◽

Isothermal Transformation ◽

Bearing Steel ◽

Practical Case ◽

Design Variables ◽

Jominy Test ◽

Optimization Parameters ◽

Transformation Diagrams

A practical method for adjusting and optimizing isothermal transformation (IT) diagrams using the Jominy test is presented. The method is based on a finite-element optimization procedure, which iteratively minimizes the error between the target phase fractions and the corresponding finite-element solutions at the sample points using an optimization tool. A standard Jominy test of AISI 52100 bearing steel is used to investigate the feasibility and reliability of the method. Three optimization parameters for each IT diagram curve are mathematically applied to the modified Kirkaldy model. These parameters are the design variables in the optimization. The curves obtained from the modified Kirkaldy model are used as the initial guesses in the optimization and they approach the experimental IT diagram by minimizing the error. Good agreement is observed between the optimized diagram and the experimental diagram reported in the literature. The predicted phase fractions using the experimental IT diagram, the IT diagram obtained from the modified Kirkaldy model, and those obtained from the optimized model are compared and demonstrate that the adjustment or optimization procedure significantly improves the accuracy of the predicted phase fraction of the model. The applicability of the method is investigated in a practical case study.

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Spray-Formed Bearing Steel with High Oxide Cleanliness and Small and Fine Dispersed Inclusions*

HTM Journal of Heat Treatment and Materials ◽

10.3139/105.110243 ◽

2014 ◽

Vol 69 (6) ◽

pp. 368-376 ◽

Cited By ~ 3

Author(s):

A. Schulz ◽

W. Trojahn ◽

C. Meyer ◽

V. Uhlenwinkel

Keyword(s):

Bearing Steel ◽

Dispersed Inclusions

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Isothermal transformation behavior of thermally-grown wüstite

Materials at High Temperatures ◽

10.3184/096034000783640776 ◽

2000 ◽

Vol 17 (2) ◽

pp. 311-319 ◽

Cited By ~ 38

Author(s):

B. Gleeson ◽

S.M.M. Hadavi ◽

D.J. Young

Keyword(s):

Isothermal Transformation ◽

Transformation Behavior ◽

Thermally Grown

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Effect of Hardness, Surface Finish and Grain Size on Rolling Contact Fatigue Life of M50 Bearing Steel

10.21236/ada284420 ◽

1958 ◽

Author(s):

R. A. Baughman

Keyword(s):

Grain Size ◽

Fatigue Life ◽

Surface Finish ◽

Rolling Contact Fatigue ◽

Contact Fatigue ◽

Bearing Steel ◽

Rolling Contact ◽

Contact Fatigue Life

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Effects of structural inhomogeneities on the steel balls resistance to loading

Voprosy Materialovedeniya ◽

10.22349/1994-6716-2020-103-3-29-38 ◽

2020 ◽

pp. 29-38

Author(s):

O. B. Berdnik ◽

I. N. Tsareva ◽

L. A. Krivina ◽

S. V. Kirikov ◽

S. I. Gerasimov ◽

...

Keyword(s):

Brittle Fracture ◽

Bearing Steel ◽

Metallographic Analysis ◽

Structural Factors ◽

Steel Shkh15 ◽

Maximum Hardness ◽

High Shock ◽

Steel Balls ◽

Plasticity Coefficient ◽

Microstructure Of The Material

When conducting impact tests of protective glasses, nonunique cases of destruction of balls made of bearing steel ShKh15 were recorded. The causes of their destruction were determined. The state of the material was studied by fractographic and metallographic analysis, hardness and microhardness measurement. In the structure of the metal of all the balls, no critical defects were found such as flockens, shells and microcracks, but adverse factors were detected in the microstructure of the material, namely, the presence of fineneedle martensite with excessive carbides. It is established that the detected structural factors lead to liability to brittle fracture, an increase in the hardness of the material, a decrease in plasticity. To prevent brittle fracture of the balls and provide a reserve of plasticity of steel ShKh15 at high shock loads assessment calculations of ductility coefficient were made; and it was recommended to limit the maximum hardness of the material critical value HV=5.70 HPa (54 HRC), with the corresponding plasticity coefficient equal to 0.8.

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