The effects of Cr addition on microstructure, hardness and tensile properties of as-cast Al–3.8wt.%Cu–(Cr) alloys

The effects of Cr addition on microstructure, hardness and tensile properties of as-cast Al–3.8wt.%Cu–(Cr) alloys

An investigation is made on the effects of Cr addition (0.25 and 0.50 wt%) on the solidification evolution, microstructure formation, hardness and tensile properties of Al–3.8Cu–(Cr) alloys. Solidification experiments were carried out in a vertical furnace using a metallic mold cooled from the botto...

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Main Authors: Thiago M. Ribeiro, Eduardo Catellan, Amauri Garcia, Carlos A. dos Santos
Format: Article
Language:English
Published: Elsevier 2020-05-01
Series:Journal of Materials Research and Technology
Subjects:
Al–Cu–Cr Alloy
Solidification
Microstructure
Hardness
Tensile strength
Online Access:http://www.sciencedirect.com/science/article/pii/S2238785420312199
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spelling doaj-c64d32a79f72441782af062c583adaf62020-11-25T03:14:16ZengElsevierJournal of Materials Research and Technology2238-78542020-05-019366206631The effects of Cr addition on microstructure, hardness and tensile properties of as-cast Al–3.8wt.%Cu–(Cr) alloysThiago M. Ribeiro0Eduardo Catellan1Amauri Garcia2Carlos A. dos Santos3Pontifícia Universidade Católica do Rio Grande do Sul – PUCRS, School of Technology, Av. Ipiranga, 6681, 90.619-900, Porto Alegre, RS, BrazilPontifícia Universidade Católica do Rio Grande do Sul – PUCRS, School of Technology, Av. Ipiranga, 6681, 90.619-900, Porto Alegre, RS, BrazilUniversity of Campinas – UNICAMP, Department of Manufacturing and Materials Engineering, 13083-860, Campinas, SP, BrazilPontifícia Universidade Católica do Rio Grande do Sul – PUCRS, School of Technology, Av. Ipiranga, 6681, 90.619-900, Porto Alegre, RS, Brazil; Corresponding author.An investigation is made on the effects of Cr addition (0.25 and 0.50 wt%) on the solidification evolution, microstructure formation, hardness and tensile properties of Al–3.8Cu–(Cr) alloys. Solidification experiments were carried out in a vertical furnace using a metallic mold cooled from the bottom, thus permitting solidified ingots under transient heat flow conditions to be obtained. The solidification system was instrumented with thermocouples at positions along the length of the ingot to permit the solidification cooling rate to be determined from bottom to top of the ingots. The ingots were transversally and longitudinally sectioned to extract specimens for metallographic analyze, hardness and tensile tests. The macrostructures are shown to be entirely columnar along the length of the Al–3.8Cu and Al–3.8Cu–0.25Cr alloys ingots, whereas the Al–3.8Cu–0.50Cr alloy is shown to have a columnar-to-equiaxed transition close to the top. For any alloy ingot examined, the Al-rich matrix is characterized by a cellular morphology for high cooling rates followed by cellular/dendritic transitions with the decrease in cooling rate. The addition of Cr to the Al–3.8Cu alloy promoted the formation of Al23CuFe and Al7CuCrFe phases precipitated in the matrix and eutectic mixture, preventing formation of isolated Al–Fe intermetallic compounds. Hardness and tensile strength increased with increasing alloy Cr content, with highest values of both properties associated with the Al–3.8Cu–0.50Cr alloy ingot. Experimental equations correlating hardness/tensile strength and cellular spacing are proposed. These equations were coupled to the theoretical Hunt–Lu model to estimate hardness and ultimate tensile strength as a function of the cellular spacing.http://www.sciencedirect.com/science/article/pii/S2238785420312199Al–Cu–Cr AlloySolidificationMicrostructureHardnessTensile strength
collection DOAJ
language English
format Article
sources DOAJ
author Thiago M. Ribeiro
Eduardo Catellan
Amauri Garcia
Carlos A. dos Santos
spellingShingle Thiago M. Ribeiro
Eduardo Catellan
Amauri Garcia
Carlos A. dos Santos
The effects of Cr addition on microstructure, hardness and tensile properties of as-cast Al–3.8wt.%Cu–(Cr) alloys
Journal of Materials Research and Technology
Al–Cu–Cr Alloy
Solidification
Microstructure
Hardness
Tensile strength
author_facet Thiago M. Ribeiro
Eduardo Catellan
Amauri Garcia
Carlos A. dos Santos
author_sort Thiago M. Ribeiro
title The effects of Cr addition on microstructure, hardness and tensile properties of as-cast Al–3.8wt.%Cu–(Cr) alloys
title_short The effects of Cr addition on microstructure, hardness and tensile properties of as-cast Al–3.8wt.%Cu–(Cr) alloys
title_full The effects of Cr addition on microstructure, hardness and tensile properties of as-cast Al–3.8wt.%Cu–(Cr) alloys
title_fullStr The effects of Cr addition on microstructure, hardness and tensile properties of as-cast Al–3.8wt.%Cu–(Cr) alloys
title_full_unstemmed The effects of Cr addition on microstructure, hardness and tensile properties of as-cast Al–3.8wt.%Cu–(Cr) alloys
title_sort effects of cr addition on microstructure, hardness and tensile properties of as-cast al–3.8wt.%cu–(cr) alloys
publisher Elsevier
series Journal of Materials Research and Technology
issn 2238-7854
publishDate 2020-05-01
description An investigation is made on the effects of Cr addition (0.25 and 0.50 wt%) on the solidification evolution, microstructure formation, hardness and tensile properties of Al–3.8Cu–(Cr) alloys. Solidification experiments were carried out in a vertical furnace using a metallic mold cooled from the bottom, thus permitting solidified ingots under transient heat flow conditions to be obtained. The solidification system was instrumented with thermocouples at positions along the length of the ingot to permit the solidification cooling rate to be determined from bottom to top of the ingots. The ingots were transversally and longitudinally sectioned to extract specimens for metallographic analyze, hardness and tensile tests. The macrostructures are shown to be entirely columnar along the length of the Al–3.8Cu and Al–3.8Cu–0.25Cr alloys ingots, whereas the Al–3.8Cu–0.50Cr alloy is shown to have a columnar-to-equiaxed transition close to the top. For any alloy ingot examined, the Al-rich matrix is characterized by a cellular morphology for high cooling rates followed by cellular/dendritic transitions with the decrease in cooling rate. The addition of Cr to the Al–3.8Cu alloy promoted the formation of Al23CuFe and Al7CuCrFe phases precipitated in the matrix and eutectic mixture, preventing formation of isolated Al–Fe intermetallic compounds. Hardness and tensile strength increased with increasing alloy Cr content, with highest values of both properties associated with the Al–3.8Cu–0.50Cr alloy ingot. Experimental equations correlating hardness/tensile strength and cellular spacing are proposed. These equations were coupled to the theoretical Hunt–Lu model to estimate hardness and ultimate tensile strength as a function of the cellular spacing.
topic Al–Cu–Cr Alloy
Solidification
Microstructure
Hardness
Tensile strength
url http://www.sciencedirect.com/science/article/pii/S2238785420312199
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