Enhancement of the Mechanical Properties in Al–Si–Cu–Fe–Mg Alloys with Various Processing Parameters

Ahn, Su-Seong; Sharief, Pathan; Koo, Jar-Myung; Baeg, Chang-Hyun; Jeong, Chanuk; Son, Hyoen-Taek; Kim, Yong-Ho; Lee, Kap Ho; Hong, Soon‐Jik

doi:10.3390/ma11112150

Cited by 21 publications

(16 citation statements)

References 23 publications

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“…Two precipitate shapes are present; needle-like precipitates of Si, with a length of 55 ± 13 nm and thickness of 6 ± 1 nm, and rather spherical precipitates of 16 ± 3 nm in diameter which are thus likely Al 2 Cu-based precipitates. The increased precipitate density can be related to the solution treatment during the T6 regime in which the Si intercellular network dissolved; an increased Si content in Al matrix promotes the diffusion coefficient of Cu in aluminium [17].…”

Section: Temmentioning

confidence: 99%

Specific Response of Additively Manufactured AlSi9Cu3Fe Alloy to Precipitation Strengthening

et al. 2019

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The additive manufacturing of Al-Si-Cu/Mg alloys along with their precipitation strengthening represents a promising option of producing high-strength complex-shaped light-weight components for special applications in automotive or aerospace. In this paper, we follow our previous research on AlSi9Cu3Fe alloy prepared by one of the additive manufacturing technologies, selective laser melting (SLM). We characterize the precipitation strengthening of this material during conventional T6 heat treatment, and also present the possibility of its precipitation strengthening by annealing at temperatures of 413-453 K without previous solutionizing. We revealed the specific response of the studied material consisting in the simultaneous precipitation of semi-coherent θ′ precipitates and Si platelets. By characterization of hardness, mechanical performance under tensile loading and microstructure, we demonstrate that the AlSi9Cu3Fe alloy is not stable when prepared by SLM and its stability can be induced by additional heat treatment. The results of our work thus yield with a practical recommendation for applications where temperature increase may occur.

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Section: Temmentioning

confidence: 99%

Specific Response of Additively Manufactured AlSi9Cu3Fe Alloy to Precipitation Strengthening

et al. 2019

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“…In this work, we will use an Al–Si alloy for study. The Al–Si series is the most important system of the Al alloys, because of its excellent castability, weldability, and superior wear resistance [29,30,31,32,33,34,35]. The content, size, scale, and distribution of the Si phase have been commonly believed to strongly affect the mechanical properties and castability of the alloys [36,37,38,39,40,41,42,43].…”

Section: Introductionmentioning

confidence: 99%

Promoted Anodizing Reaction and Enhanced Coating Performance of Al–11Si Alloy: The Role of an Equal-Channel-Angular-Pressed Substrate

et al. 2019

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In this paper, the effect of the equal-channel-angular-pressed (ECAPed) substrate on the coating formation and anticorrosion performance of the anodized Al–11Si alloy was systematically investigated. The ECAP process dramatically refines both Al and Si phases of the alloy. The parallel anodizing circuit is designed to enable a comparative study of anodizing process between the cast and the ECAPed alloys by tracking their respective anodizing current quota. The optimum coatings of both alloys were obtained after anodization for 30 min. The ECAPed alloy attained a thicker, more compact, and more uniform coating. Energetic crystal defects in the fine Al grains of the ECAPed substrate promote the anodizing reaction and lead to the thicker coating. Fragmented and uniformly distributed fine Si particles in the ECAPed alloy effectively suppress the coating cracks, enhancing the compactness of the coating. Overall, the ECAP-coated sample exhibits the best anticorrosion performance, which is evidenced by the concurrently enhanced prevention of coating and improved corrosion resistance of the substrate.

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“…Several authors have studied the Vickers microhardness, including Tillová, et al [5], who, studying the intermetallic phases in Al-Si recycled alloys presents a microhardness of 483 HV, in addition, Isadarea, et al [17] studied Mechanical Properties of 7075 Aluminum Alloy, they found for this alloy the microhardness of 201 HV, however, the microhardness of 567 HV for Al-Si-Cu-Mg-Fe extruded alloy was measured by the authors Ahn [18]. Though, some authors, Kubota [19] and Xu, et al [20] determined the microhardness of pure aluminum, around 50 HV.…”

Section: Vickers Microhardness Measurementsmentioning

confidence: 99%

Effects of the Aluminum Alloy with Intermetallic a Phase on the Microstructural and Corrosion Resistance

Meza¹

2021

Int J Robot Eng

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The aluminum alloy with intermetallic α-Al 15 (Fe,Mn,Cr) 4 Si 2 phase with polygonal morphology, denoted by Al-α alloy was processed by controlled solidification and this alloy was studied in order to evaluate the microstructure, microhardness, corrosion resistance and electrochemical impedance when this alloy was immersed in an electrolytic medium at 0.1 mol/L solution of sulfuric acid.The intermetallic α-Al 15 (Fe,Mn,Cr) 4 Si 2 with polyhedron morphology presents a microhardness of 483 HV and being much higher than pure aluminum. The polarization resistance of the pure Al is much higher than Al-α alloy and the corrosion rate in pure Al is low, however, the corrosion rate in Al-α alloy is moderate. The Al-α alloy electrode presents a larger area of the voltammogram than the pure Al electrode and pure Al presents a larger region passivity, however, through Nyquist diagram, both samples presented the capacitive semicircle and inductance region. Being so, the polarization resistance was a lot bigger in pure Al than the Al-α alloy, and these results were similar to result of micro polarization. This alloy is suitable for use in many automotive applications increasing lifetime of its components, due to, it has low density, high microhardness and in sulfuric acid medium has noble behavior and presents a good corrosion resistance, and a low corrosion rate.

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Enhancement of the Mechanical Properties in Al–Si–Cu–Fe–Mg Alloys with Various Processing Parameters

Cited by 21 publications

References 23 publications

Specific Response of Additively Manufactured AlSi9Cu3Fe Alloy to Precipitation Strengthening

Specific Response of Additively Manufactured AlSi9Cu3Fe Alloy to Precipitation Strengthening

Promoted Anodizing Reaction and Enhanced Coating Performance of Al–11Si Alloy: The Role of an Equal-Channel-Angular-Pressed Substrate

Effects of the Aluminum Alloy with Intermetallic a Phase on the Microstructural and Corrosion Resistance

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