Nanostructural Evolution of Hard Turning Layers in Carburized Steel

Nanostructural Evolution of Hard Turning Layers in Carburized Steel

Bibliographic Details
Main Author: Bedekar, Vikram
Language:English
Published: The Ohio State University / OhioLINK 2013
Subjects:
Industrial Engineering
Materials Science
Hard Turning
Nanostructure
White Layer
TEM
Glancing Angle X-ray diffraction
retained austenite transformation
Online Access:http://rave.ohiolink.edu/etdc/view?acc_num=osu1366195383
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spelling ndltd-OhioLink-oai-etd.ohiolink.edu-osu13661953832021-08-03T05:22:06Z Nanostructural Evolution of Hard Turning Layers in Carburized Steel Bedekar, Vikram Industrial Engineering Materials Science Hard Turning Nanostructure White Layer TEM Glancing Angle X-ray diffraction retained austenite transformation The mechanisms of failure for components subjected to contact fatigue are sensitive to the structure and properties of the material surface. Although, the bulk material properties are determined by the steel making, forming and the heat treatment; the near surface material properties are altered during final material removal processes such as hard turning or grinding. Therefore, the ability to optimize, modulate and predict the near surface properties during final metal removal operations would be extremely useful in the enhancement of service life of a component. Hard machining is known to induce severely deformed layers causing dramatic microstructural transformations. These transformations occur via grain refinement or thermal phenomena depending upon cutting conditions. The aim of this work is to engineer the near surface nanoscale structure and properties during hard turning by altering strain, strain rate, temperature and incoming microstructure. The near surface material transformations due to hard turning were studied on carburized SAE 8620 bearing steel. Variations in parent material microstructures were introduced by altering the retained austenite content. The strain, strain rate and temperature achieved during final metal cutting were altered by varying insert geometry, insert wear and cutting speed. The subsurface evolution was quantified by a series of advanced characterization techniques such as transmission electron microscopy (TEM), glancing angle X-ray diffraction (GAXRD), X-ray stress evaluation and nanoindentation which were coupled with numerical modeling. Results showed that the grain size of the nanocrystalline near surface microstructure can be effectively controlled by altering the insert geometry, insert wear, cutting speed and the incoming microstructure. It was also evident that the near surface retained austenite decreased at lower cutting speed indicating transformation due to plastic deformation, while it increased at higher cutting speed indicated thermal transformation. Nanoindentation tests showed that the substructures produced by plastic deformation follow the Hall-Petch relationship while the structures produced by thermal transformation did not. This indicated a change in the hardness driver from dislocation hardening to phase transformation, both of which have a significant impact on fatigue life. Using hardness based flow stress numerical model, these relationships between the processing conditions and structural parameters were further explored. Results indicated that the hard turning process design space can be partitioned into three regions based on thermal phase transformations, plastic grain refinement, and a third regime where both mechanisms are active. It was found that the Zener-Holloman parameter can not only be used to predict post-turning grain size but also to partition the process space into regions of dominant microstructural mechanisms. 2013-07-25 English text The Ohio State University / OhioLINK http://rave.ohiolink.edu/etdc/view?acc_num=osu1366195383 http://rave.ohiolink.edu/etdc/view?acc_num=osu1366195383 unrestricted This thesis or dissertation is protected by copyright: all rights reserved. It may not be copied or redistributed beyond the terms of applicable copyright laws.
collection NDLTD
language English
sources NDLTD
topic Industrial Engineering
Materials Science
Hard Turning
Nanostructure
White Layer
TEM
Glancing Angle X-ray diffraction
retained austenite transformation
spellingShingle Industrial Engineering
Materials Science
Hard Turning
Nanostructure
White Layer
TEM
Glancing Angle X-ray diffraction
retained austenite transformation
Bedekar, Vikram
Nanostructural Evolution of Hard Turning Layers in Carburized Steel
author Bedekar, Vikram
author_facet Bedekar, Vikram
author_sort Bedekar, Vikram
title Nanostructural Evolution of Hard Turning Layers in Carburized Steel
title_short Nanostructural Evolution of Hard Turning Layers in Carburized Steel
title_full Nanostructural Evolution of Hard Turning Layers in Carburized Steel
title_fullStr Nanostructural Evolution of Hard Turning Layers in Carburized Steel
title_full_unstemmed Nanostructural Evolution of Hard Turning Layers in Carburized Steel
title_sort nanostructural evolution of hard turning layers in carburized steel
publisher The Ohio State University / OhioLINK
publishDate 2013
url http://rave.ohiolink.edu/etdc/view?acc_num=osu1366195383
work_keys_str_mv AT bedekarvikram nanostructuralevolutionofhardturninglayersincarburizedsteel
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