Tensile Deformation Behavior of Medium Manganese Steels with High Carbon Concentrations and Austenitic Microstructures

Tensile Deformation Behavior of Medium Manganese Steels with High Carbon Concentrations and Austenitic Microstructures

Tensile properties of the Fe⁻1.44C⁻8Mn⁻1.9Al (mass %) steel with a fully austenitic microstructure, obtained by rapid quenching from the austenite range, was determined at room temperature. Tensile tests were performed using specimens prepared in two different routes in...

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Main Authors: Guoqing Luan, Olena Volkova, Javad Mola
Format: Article
Language:English
Published: MDPI AG 2018-11-01
Series:Metals
Subjects:
medium-Mn steel
high-C steel
tensile test
austenite
fracture surface
Online Access:https://www.mdpi.com/2075-4701/8/11/902
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spelling doaj-748eed8f9c6043d1ba9c49a13540a8002020-11-24T20:56:59ZengMDPI AGMetals2075-47012018-11-0181190210.3390/met8110902met8110902Tensile Deformation Behavior of Medium Manganese Steels with High Carbon Concentrations and Austenitic MicrostructuresGuoqing Luan0Olena Volkova1Javad Mola2Institute of Iron and Steel Technology, Technische Universität Bergakademie Freiberg, Leipziger St. 34, 09599 Freiberg, GermanyInstitute of Iron and Steel Technology, Technische Universität Bergakademie Freiberg, Leipziger St. 34, 09599 Freiberg, GermanyInstitute of Iron and Steel Technology, Technische Universität Bergakademie Freiberg, Leipziger St. 34, 09599 Freiberg, GermanyTensile properties of the Fe⁻1.44C⁻8Mn⁻1.9Al (mass %) steel with a fully austenitic microstructure, obtained by rapid quenching from the austenite range, was determined at room temperature. Tensile tests were performed using specimens prepared in two different routes involving an exchanged sequence of machining and heat treatment as the last processing steps prior to tensile tests. In spite of the occurrence of deformation twinning, total tensile elongations in both processing routes remained below 18%. Abrupt stress drops during tensile tests suggested the occurrence of discontinuities in tensile specimens. Detailed examination of the fracture surface indicated a mixed intergranular⁻transgranular fracture mode. Furthermore, a high density of surface cracks was observed near the outer surface in the gauge section of fractured tensile specimens. The origin of surface cracks could not be identified. The coincidence of surface cracks with the grain boundaries, especially those nearly perpendicular to the tensile direction, is thought to be responsible for the accelerated grain boundary decohesion and the premature fracture of tensile specimens.https://www.mdpi.com/2075-4701/8/11/902medium-Mn steelhigh-C steeltensile testaustenitefracture surface
collection DOAJ
language English
format Article
sources DOAJ
author Guoqing Luan
Olena Volkova
Javad Mola
spellingShingle Guoqing Luan
Olena Volkova
Javad Mola
Tensile Deformation Behavior of Medium Manganese Steels with High Carbon Concentrations and Austenitic Microstructures
Metals
medium-Mn steel
high-C steel
tensile test
austenite
fracture surface
author_facet Guoqing Luan
Olena Volkova
Javad Mola
author_sort Guoqing Luan
title Tensile Deformation Behavior of Medium Manganese Steels with High Carbon Concentrations and Austenitic Microstructures
title_short Tensile Deformation Behavior of Medium Manganese Steels with High Carbon Concentrations and Austenitic Microstructures
title_full Tensile Deformation Behavior of Medium Manganese Steels with High Carbon Concentrations and Austenitic Microstructures
title_fullStr Tensile Deformation Behavior of Medium Manganese Steels with High Carbon Concentrations and Austenitic Microstructures
title_full_unstemmed Tensile Deformation Behavior of Medium Manganese Steels with High Carbon Concentrations and Austenitic Microstructures
title_sort tensile deformation behavior of medium manganese steels with high carbon concentrations and austenitic microstructures
publisher MDPI AG
series Metals
issn 2075-4701
publishDate 2018-11-01
description Tensile properties of the Fe⁻1.44C⁻8Mn⁻1.9Al (mass %) steel with a fully austenitic microstructure, obtained by rapid quenching from the austenite range, was determined at room temperature. Tensile tests were performed using specimens prepared in two different routes involving an exchanged sequence of machining and heat treatment as the last processing steps prior to tensile tests. In spite of the occurrence of deformation twinning, total tensile elongations in both processing routes remained below 18%. Abrupt stress drops during tensile tests suggested the occurrence of discontinuities in tensile specimens. Detailed examination of the fracture surface indicated a mixed intergranular⁻transgranular fracture mode. Furthermore, a high density of surface cracks was observed near the outer surface in the gauge section of fractured tensile specimens. The origin of surface cracks could not be identified. The coincidence of surface cracks with the grain boundaries, especially those nearly perpendicular to the tensile direction, is thought to be responsible for the accelerated grain boundary decohesion and the premature fracture of tensile specimens.
topic medium-Mn steel
high-C steel
tensile test
austenite
fracture surface
url https://www.mdpi.com/2075-4701/8/11/902
work_keys_str_mv AT guoqingluan tensiledeformationbehaviorofmediummanganesesteelswithhighcarbonconcentrationsandausteniticmicrostructures
AT olenavolkova tensiledeformationbehaviorofmediummanganesesteelswithhighcarbonconcentrationsandausteniticmicrostructures
AT javadmola tensiledeformationbehaviorofmediummanganesesteelswithhighcarbonconcentrationsandausteniticmicrostructures
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