Effect of thermal exposure on microstructure and nano-hardness of broached Inconel 718

Inconel 718 is a high strength, heat resistant superalloy that is used extensively for components in hot sections of gas turbine engines. This paper presents an experimental study on the thermal stability of broached Inconel 718 in terms of microstructure and nano-hardness. The broaching process us...

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Main Authors: Chen Zhe, Peng Ru Lin, Avdovic Pajazit, Zhou Jinming, Moverare Johan, Karlsson Fredrik, Johansson Sten
Format: Article
Language:English
Published: EDP Sciences 2014-01-01
Series:MATEC Web of Conferences
Online Access:http://dx.doi.org/10.1051/matecconf/20141408002
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spelling doaj-6aad04297ba44d3eb73098c6b52095f32021-02-02T07:12:58ZengEDP SciencesMATEC Web of Conferences2261-236X2014-01-01140800210.1051/matecconf/20141408002matecconf_eurosuperalloys14_08002Effect of thermal exposure on microstructure and nano-hardness of broached Inconel 718Chen Zhe0Peng Ru Lin1Avdovic Pajazit2Zhou Jinming3Moverare JohanKarlsson Fredrik4Johansson Sten5Division of Engineering Materials, Linköping UniversityDivision of Engineering Materials, Linköping UniversitySiemens Industrial Turbomachinery ABDivision of Production and Materials Engineering, Lund UniversitySiemens Industrial Turbomachinery ABDivision of Engineering Materials, Linköping University Inconel 718 is a high strength, heat resistant superalloy that is used extensively for components in hot sections of gas turbine engines. This paper presents an experimental study on the thermal stability of broached Inconel 718 in terms of microstructure and nano-hardness. The broaching process used in this study is similar to that used in gas turbine industries for machining fir-tree root fixings on turbine discs. Severe plastic deformation was found under the broached surface. The plastic deformation induces a work-hardened layer in the subsurface region with a thickness of ∼50 μm. Thermal exposure was conducted at two temperatures, 550 ∘C and 650 ∘C respectively, for 300 h. Recrystallization occurs in the surface layer during thermal exposure at 550 ∘C and α-Cr precipitates as a consequence of the growth of recrystallized δ phases. More recrystallized grains with a larger size form in the surface layer and the α-Cr not only precipitates in the surface layer, but also in the sub-surface region when the thermal exposure temperature goes up to 650 ∘C. The thermal exposure leads to an increase in nano-hardness both in the work-hardened layer and in the bulk material due to the coarsening of the main strengthening phase γ′′. http://dx.doi.org/10.1051/matecconf/20141408002
collection DOAJ
language English
format Article
sources DOAJ
author Chen Zhe
Peng Ru Lin
Avdovic Pajazit
Zhou Jinming
Moverare Johan
Karlsson Fredrik
Johansson Sten
spellingShingle Chen Zhe
Peng Ru Lin
Avdovic Pajazit
Zhou Jinming
Moverare Johan
Karlsson Fredrik
Johansson Sten
Effect of thermal exposure on microstructure and nano-hardness of broached Inconel 718
MATEC Web of Conferences
author_facet Chen Zhe
Peng Ru Lin
Avdovic Pajazit
Zhou Jinming
Moverare Johan
Karlsson Fredrik
Johansson Sten
author_sort Chen Zhe
title Effect of thermal exposure on microstructure and nano-hardness of broached Inconel 718
title_short Effect of thermal exposure on microstructure and nano-hardness of broached Inconel 718
title_full Effect of thermal exposure on microstructure and nano-hardness of broached Inconel 718
title_fullStr Effect of thermal exposure on microstructure and nano-hardness of broached Inconel 718
title_full_unstemmed Effect of thermal exposure on microstructure and nano-hardness of broached Inconel 718
title_sort effect of thermal exposure on microstructure and nano-hardness of broached inconel 718
publisher EDP Sciences
series MATEC Web of Conferences
issn 2261-236X
publishDate 2014-01-01
description Inconel 718 is a high strength, heat resistant superalloy that is used extensively for components in hot sections of gas turbine engines. This paper presents an experimental study on the thermal stability of broached Inconel 718 in terms of microstructure and nano-hardness. The broaching process used in this study is similar to that used in gas turbine industries for machining fir-tree root fixings on turbine discs. Severe plastic deformation was found under the broached surface. The plastic deformation induces a work-hardened layer in the subsurface region with a thickness of ∼50 μm. Thermal exposure was conducted at two temperatures, 550 ∘C and 650 ∘C respectively, for 300 h. Recrystallization occurs in the surface layer during thermal exposure at 550 ∘C and α-Cr precipitates as a consequence of the growth of recrystallized δ phases. More recrystallized grains with a larger size form in the surface layer and the α-Cr not only precipitates in the surface layer, but also in the sub-surface region when the thermal exposure temperature goes up to 650 ∘C. The thermal exposure leads to an increase in nano-hardness both in the work-hardened layer and in the bulk material due to the coarsening of the main strengthening phase γ′′.
url http://dx.doi.org/10.1051/matecconf/20141408002
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